The complete guide_to_chain

U.S. Tsubaki, Inc., Wheeling, Illinois
The Complete Guide to Chain

ii
The Complete Guide to Chain
© 1997 by U.S. Tsubaki, Inc.
First English-language edition, 1997
ISBN 0-9658932-0-0
Library of Congress 97-061464
Translated and printed with permission
of Kogyo Chosakai Publishing Co., Ltd.
Distributed in North America, Australia, and Europe
by U.S. Tsubaki, Inc., 301 East Marquardt Drive,
Wheeling, Illinois 60090. Originally published by
Kogyo Chosakai Publishing Co., Ltd., under the title:
Machine Elements Manual, Chain.
Original Editor: Tsubakimoto Chain Co.
Original Publisher: Sachio Shimura
All rights reserved. No part of this book may be
reproduced or utilized in any form or by any means,
electronic or mechanical, including photocopying,
recording, or by any information storage and retrieval
system, without permission in writing from
the publisher.

iii
Contributors
Supervising Editor
Kyosuke Otoshi
Director
Chain Products Division
Editor
Makoto Kanehira
Manager
Production Engineering Department
Writers
Makoto Kanehira
Manager
Production Engineering Department
Tomofumi Otani
Manager
Engineering Department
Chain Engineering Section
Masayuki Yoshikawa
Manager
Engineering Department
Conveyor Chain Engineering Section
Toshio Takahashi
Manager
Roller Chain Production Department
Engineering Plastics Manufacturing Section

CONTRIBUTORS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ii
PREFACE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . xiii
ACKNOWLEDGMENTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . xv
BASICS SECTION
1. CHAIN BASICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
1.1 WHAT IS A CHAIN? . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
1.1.1 Basic Structure of Power Transmission Chain . . . . . . . . . . . . 2
1.1.2 Basic Structure of Small Pitch Conveyor Chain . . . . . . . . . . . 4
1.1.3 Basic Structure of Large Pitch Conveyor Chain—
Engineering Class . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
1.1.4 Functions of Chain Parts . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
1.2 ADVANTAGES AND DISADVANTAGES OF CHAIN FOR
POWER TRANSMISSION AND CONVEYORS . . . . . . . . . . . . . . . . . . 6
1.2.1 Power Transmission Uses . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
1.2.2 Conveyance Uses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
1.3 SPROCKETS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
2. CHAIN DYNAMICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
2.1 CHAINS UNDER TENSION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
2.1.1 Elastic Stretch, Plastic Deformation, and Breakage . . . . . . . . . 9
2.1.2 Engagement with Sprockets . . . . . . . . . . . . . . . . . . . . . . . . 12
2.2 CHAIN DRIVE IN ACTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
2.2.1 Chordal Action . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
2.2.2 Repeated Load Tension, Fatigue Failure . . . . . . . . . . . . . . . 17
2.2.3 Transmission Capability of Drive Chains . . . . . . . . . . . . . . . 19
2.2.3.1 Difference Between Linear Tension and Wrapping . . 19
2.2.3.2 Effect of Normal Chain Wear on Fatigue Strength . . . 20
2.2.3.3 Strength Differences Between Chain and the
Connecting Links and Offset Links . . . . . . . . . . . . . 20
2.2.4 Wear of Working Parts . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
2.2.5 Noise and Vibration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
2.3 CHARACTERISTIC PHENOMENA IN CONVEYOR CHAIN . . . . . . . . . 24
2.3.1 Coefficient of Friction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
2.3.2 Dynamic Tension of Starting and Stopping . . . . . . . . . . . . . 26
2.3.3 Wear Between Rollers and Bushings . . . . . . . . . . . . . . . . . . 27
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Contents

vi
2.3.4 Strength of Attachments . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
2.3.5 Stick Slip . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
2.3.6 Relative Differences in Chain’s Total Length . . . . . . . . . . . . 29
2.3.7 Take-Up . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29
3. PUBLIC STANDARDS OF CHAINS . . . . . . . . . . . . . . 31
4. HOW TO SELECT CHAINS . . . . . . . . . . . . . . . . . . . . . . . 32
4.1 TRANSMISSION CHAIN SELECTION . . . . . . . . . . . . . . . . . . . . . . . 32
4.1.1 Chain Selection Factors . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
4.1.2 Coefficients Used in Selection . . . . . . . . . . . . . . . . . . . . . . . 34
4.1.3 Drive Chain Selection (General Selection) . . . . . . . . . . . . . . 36
4.1.4 Power Transmission Chain Selection for Slow Speeds . . . . . 39
4.1.5 Hanging Transmission Chain Selection . . . . . . . . . . . . . . . . 41
4.2 CONVEYOR CHAIN SELECTION . . . . . . . . . . . . . . . . . . . . . . . . . . 47
4.2.1 Check of Conditions for Selection . . . . . . . . . . . . . . . . . . . . 47
4.2.2 Conveyor Type Selection . . . . . . . . . . . . . . . . . . . . . . . . . . 48
4.2.3 Selection of Chain Type and Specification . . . . . . . . . . . . . 50
4.2.4 Points of Notice About Roller Type . . . . . . . . . . . . . . . . . . 50
4.2.5 Chain Pitch Decision . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51
4.2.6 Deciding the Number of Sprocket Teeth . . . . . . . . . . . . . . . 51
4.2.7 Deciding the Attachment Type . . . . . . . . . . . . . . . . . . . . . . 52
4.2.8 Calculation of Tension . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52
4.2.8.1 Horizontal Conveyor . . . . . . . . . . . . . . . . . . . . . . . . 53
4.2.8.2 Free Flow Conveyor . . . . . . . . . . . . . . . . . . . . . . . . 53
4.2.9 Allowable Load of Roller and Standard A Attachment . . . . . 54
4.3 SELECTION EXAMPLE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55
5. CHAINS AND ENVIRONMENTS . . . . . . . . . . . . . . . . . 57
5.1 STEEL CHAINS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 57
5.1.1 Use of Steel Chains in High Temperatures . . . . . . . . . . . . . . 57
5.1.2 Use of Steel Chains in Low Temperatures . . . . . . . . . . . . . . 58
5.2 ENGINEERED PLASTIC CHAIN IN HIGH AND LOW TEMPERATURES . 58
5.3 OTHER CHAIN MATERIALS IN HIGH TEMPERATURES . . . . . . . . . . . 59
5.4 COPING WITH SPECIAL CONDITIONS . . . . . . . . . . . . . . . . . . . . . . 59
5.4.1 Use in Wet Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . 59
5.4.2 Use in Acidic, Alkaline, or Electrolytic Conditions . . . . . . . . 60
5.4.3 Use in Abrasive Conditions . . . . . . . . . . . . . . . . . . . . . . . . 60

vii
6. BASIC LAYOUTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63
6.1 BASIC LAYOUTS OF WRAPPING TRANSMISSION CHAINS . . . . . . . 63
6.1.1 General Arrangements . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63
6.1.2 Special Layouts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 64
6.1.3 Special Arrangements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65
6.2 BASIC CONVEYOR CHAIN LAYOUTS . . . . . . . . . . . . . . . . . . . . . . . 65
6.2.1 Horizontal Conveyor Arrangement . . . . . . . . . . . . . . . . . . . 65
6.2.2 Vertical Conveyor Arrangement . . . . . . . . . . . . . . . . . . . . . . 67
6.2.3 Inclined Conveyor Arrangement . . . . . . . . . . . . . . . . . . . . . 67
6.2.4 Horizontal Circulating Conveyor Arrangement . . . . . . . . . . . 67
6.3 SUPPORTING THE ROLLER OF A CONVEYOR CHAIN . . . . . . . . . . . 67
7. MANIPULATION OF CHAINS . . . . . . . . . . . . . . . . . . . . 69
7.1 TRANSMISSION CHAINS, SMALL PITCH CONVEYOR CHAINS . . . . 69
7.1.1 Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69
7.1.2 Installation Accuracy . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70
7.1.2.1 Chain Slack . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70
7.1.2.2 Horizontal Precision and Parallelism of the Shafts . . 71
7.1.3 Start-Up . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72
7.1.3.1 Prestart-Up Checklist . . . . . . . . . . . . . . . . . . . . . . . 72
7.1.3.2 Start-Up Test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72
7.1.4 Lubrication . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72
7.1.5 Inspection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73
7.1.6 Troubleshooting and Problem-Solving . . . . . . . . . . . . . . . . . 74
7.2 LARGE PITCH CONVEYOR CHAINS . . . . . . . . . . . . . . . . . . . . . . . . 79
7.2.1 Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 79
7.2.2 Installation Accuracy . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80
7.2.2.1 Chain Tension . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80
7.2.2.2 Horizontal Precision and Parallelism of the Shafts . . 80
7.2.2.3 Accuracy of the Rails . . . . . . . . . . . . . . . . . . . . . . . 80
7.2.3 Start-Up . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80
7.2.4 Lubrication . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81
7.2.5 Inspection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81
7.2.6 Troubleshooting and Problem-Solving . . . . . . . . . . . . . . . . . 81

APPLICATIONS SECTION
1. TRANSMISSION CHAINS . . . . . . . . . . . . . . . . . . . . . . . . 85
1.1 STANDARD ROLLER CHAINS . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86
1.1.1 ANSI Roller Chains (RS) . . . . . . . . . . . . . . . . . . . . . . . . . . . 86
1.1.2 BS/DIN Roller Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87
1.2 HIGH PERFORMANCE CHAINS . . . . . . . . . . . . . . . . . . . . . . . . . . . 88
1.2.1 Super Roller Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89
1.2.2 Super-H Roller Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 91
1.2.3 RS-HT Roller Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 92
1.2.4 Ultra Super Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93
1.3 LUBE-FREE CHAINS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94
1.3.1 LAMBDA® Roller Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . 94
1.3.2 Sealed Roller Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 96
1.4 ENVIRONMENTALLY RESISTANT CHAINS . . . . . . . . . . . . . . . . . . . 98
1.4.1 Nickel-Plated Roller Chain (NP) . . . . . . . . . . . . . . . . . . . . 100
1.4.2 WP®
Roller Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 102
1.4.3 Stainless Steel Roller Chain (SS) . . . . . . . . . . . . . . . . . . . . 103
1.4.4 Poly-Steel Chain (PC) . . . . . . . . . . . . . . . . . . . . . . . . . . . 107
1.5 SPECIALTY CHAINS, TYPE 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . 109
1.5.1 Bicycle Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 109
1.5.2 Motorcycle Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 112
1.5.3 Chains for Automotive Engines . . . . . . . . . . . . . . . . . . . . . 115
1.6 SPECIALTY CHAINS, TYPE 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117
1.6.1 Miniature Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117
1.6.2 Leaf Chains . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 118
1.6.3 Inverted Tooth Chain (Silent Chain) . . . . . . . . . . . . . . . . . 121
2. SMALL PITCH CONVEYOR CHAINS . . . . . . . . . . . 124
2.1 SMALL PITCH CONVEYOR CHAINS FOR GENERAL USE . . . . . . . . 126
2.1.1 RS Attachment Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . 126
2.1.2 Double Pitch Roller Chain . . . . . . . . . . . . . . . . . . . . . . . . 128
2.1.3 Plastic Roller Plus Plastic Sleeve Chain . . . . . . . . . . . . . . . 130
2.1.4 Hollow Pin Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 132
2.2 SPECIALTY CHAINS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 134
2.2.1 Step (Escalator) Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . 134
2.2.2 ATC Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 136
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ix
2.3 STANDARD ATTACHMENTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . 139
2.3.1 A Attachment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 139
2.3.2 K Attachment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 140
2.3.3 SA Attachment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 141
2.3.4 SK Attachment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 142
2.3.5 D Attachment (Extended Pin) . . . . . . . . . . . . . . . . . . . . . . 143
2.4 PLUS α ALPHA ATTACHMENTS . . . . . . . . . . . . . . . . . . . . . . . . . 144
2.5 SPECIAL ATTACHMENTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 146
3. PRECISION CONVEYOR CHAINS . . . . . . . . . . . . . . 149
3.1 BEARING BUSH CHAIN . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 150
3.2 INDEXING TABLE CHAIN . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 153
4. TOP CHAINS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 154
4.1 WHAT IS TOP CHAIN? . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 155
4.1.1 Plastic Materials for Top Chains . . . . . . . . . . . . . . . . . . . . . 155
4.1.2 Guide Rail Materials . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 156
4.1.3 Lubrication . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 157
4.1.4 Various Accessories . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 157
4.2 TYPES OF TOP CHAIN . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 158
4.2.1 TTP Top Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 158
4.2.2 TP Top Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 160
4.2.3 TTUP Top Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 162
4.2.4 TPU Top Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 164
4.2.5 TT Top Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 166
4.2.6 TS Top Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 168
4.2.7 TTU Top Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 169
4.2.8 TO Crescent Top Plate Chain . . . . . . . . . . . . . . . . . . . . . . . 170
4.2.9 TN Snap-On Top Plate Chain . . . . . . . . . . . . . . . . . . . . . . . 172
4.2.10 RS Plastic Top Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . 174
4.2.11 Bel-Top Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 175
5. FREE FLOW CHAINS . . . . . . . . . . . . . . . . . . . . . . . . . . . 177
5.1 WHAT IS FREE FLOW CHAIN? . . . . . . . . . . . . . . . . . . . . . . . . . . . 178
5.2 TYPES OF FREE FLOW CHAIN . . . . . . . . . . . . . . . . . . . . . . . . . . . 179
5.2.1 DOUBLE PLUS®
Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . 179
5.2.2 Outboard Roller Chain—Side Roller Type . . . . . . . . . . . . . 184
5.2.3 Outboard Roller Chain—Top Roller Type . . . . . . . . . . . . . . 187
5.2.4 Roller Table Chain (ST, RT) . . . . . . . . . . . . . . . . . . . . . . . . 189

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6. LARGE PITCH CONVEYOR CHAINS . . . . . . . . . . . 192
6.1 WHAT IS LARGE PITCH CONVEYOR CHAIN? . . . . . . . . . . . . . . . . 193
6.1.1 Standards . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 193
6.1.2 Nomenclature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 193
6.1.3 Construction and Features . . . . . . . . . . . . . . . . . . . . . . . . . 194
6.1.3.1 Shape Features . . . . . . . . . . . . . . . . . . . . . . . . . . . 194
6.1.3.2 Function Features . . . . . . . . . . . . . . . . . . . . . . . . . 194
6.1.3.3 Disadvantages . . . . . . . . . . . . . . . . . . . . . . . . . . . . 196
6.2 STANDARD CONVEYOR CHAINS . . . . . . . . . . . . . . . . . . . . . . . . 198
6.2.1 RF Conveyor Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 198
6.2.2 RF Bearing Roller Conveyor Chain . . . . . . . . . . . . . . . . . . . 200
6.2.3 RF Plastic Roller Plus Plastic Sleeve Conveyor Chain . . . . . . 204
6.3 SPECIALTY CONVEYOR CHAINS . . . . . . . . . . . . . . . . . . . . . . . . . 205
6.3.1 Bucket Elevator Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . 205
6.3.2 Flow Conveyor Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . 208
6.3.3 Parking Tower Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . 212
6.3.4 Continuous Bucket Unloader Chain . . . . . . . . . . . . . . . . . 214
6.3.5 Large Bulk Handling Conveyor Chain (CT) . . . . . . . . . . . . 216
6.3.6 Block Chain (Bar and Pin) . . . . . . . . . . . . . . . . . . . . . . . . . 218
6.3.7 Sewage Treatment Chain (Rectangular Sludge Collector) . . . 220
6.3.8 Sewage Treatment Chain (Bar Screen) . . . . . . . . . . . . . . . . 225
6.4 STANDARD ATTACHMENTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . 228
6.5 PLUS α ALPHA ATTACHMENTS . . . . . . . . . . . . . . . . . . . . . . . . . 229
6.6 SPECIAL ATTACHMENTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 233

xi
BIBLIOGRAPHY . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 234
AFTERWORD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 239
COFFEE BREAKS
Roller Chain Manufacturing Process . . . . . . . . . . . . . . . . . . . . . . . . . 191
A Brief History of Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 211
The Tools Developed from Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . 235
Sizing Up Chain . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 236
Speed Variation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 237

xiii
Preface
When most people hear the word “chain,” they imagine a short-link chain,
which consists of connected metal rings, or the type of chain used on a motor-
cycle or bicycle. However, chains of every size and description are used in
factories, even though they are rarely seen in daily life. In fact, most people
probably don’t notice that chain is being used all around them, in parking ele-
vators or escalators, for example.
Steel roller chain, which is the ultimate in chain design, and constitutes the
majority of chain produced today, is a relatively new invention. Its history is
only about 100 years old. It is newer as a machine part than gears and belts.
In Japan, the first chain was imported with bicycles during the Meiji-period
(1867~1912 A.D.). Domestic production started when the supply from the
United States and European countries was stopped during World War I.
There are two functions of chain: power transmission and conveyance. For
transmission roller chains, Japanese chain makers gradually changed the prior-
ity of production from bicycle chain to industrial chain. After World War II,
these chains challenged the advanced chain from the United States and
Europe. Now they have achieved the highest levels in the world for both qual-
ity and quantity. This holds true for conveyor chain, as well.
The industries that are the main users of the chain, including automobile,
electronics, steel, chemical, environmental, food, bicycle, and motorcycle
industries, have developed new technologies and production methods that
require various high performance chain. These industries are looking for
improvement in tensile strength, fatigue strength, abrasion resistance, environ-
mental resistance, and efficiency, as well as perfection of maintenance-free
chain products. To satisfy these many requirements, chain makers are making
every effort to improve chain’s basic performance step by step. In addition,
new chain technologies, including rolling bearing systems, super engineered
plastic, and free flow chains, are being developed. Because of these two fac-
tors, chains with special characteristics are now being produced.
During his lifetime of experience, the editor of this book has helped to
develop most of these new types of chain. He has also acquired a great deal
of practical knowledge through his contacts with end users. Accordingly, this
comprehensive book explains the points that readers may want to know,
including the most important point: determining the quality of the chain. I
hope this book can always be with you when you use chains.
I’m afraid some of the descriptions in this book may be either inadequate or
hard to understand; therefore, I hope that readers will point out any mistakes
and send me their comments and input. Furthermore, because this book is

xiv
based on a lot of technical data and specialized books, I would like to extend
many thanks to them all. I also thank Mr. Seihin Shibuya, vice-director of
Kogyo Chosakai Publishing Co., Ltd., for his whole-hearted efforts in publish-
ing this book.
March 1995
Kyosuke Otoshi
Director, Chain Products Division
Tsubakimoto Chain Co.

xv
David Doray
Director
Corporate Marketing Department
U.S. Tsubaki, Inc.
Lee Marcus
Marketing Communications Specialist
Corporate Marketing Department
U.S. Tsubaki, Inc.
James Lamoureux
Design & Application Engineer
Product Engineering
Roller Chain Division
U.S. Tsubaki, Inc.
Mokoto Kameda
Project Administrator
Customer Service and Materials
U.S. Tsubaki, Inc.
Katsuya Matsuda
Coordinator
Strategic Business Development
Department
U.S. Tsubaki, Inc.
Toshiharu Yamamoto
Quality Manager
Product Engineering
U.S. Tsubaki, Inc.
Jack Kane
Manager
Customer Service and Materials
U.S. Tsubaki, Inc.
Leszek Wawer
Senior Design & Application Engineer
Product Engineering
Atlanta Service Center
U.S. Tsubaki, Inc.
Editorial services provided by
Drake Creative, Inc., Chicago, IL
Design services provided by
Toomey Associates, Ltd., Hinsdale, IL
Acknowledgments
The following people contributed considerable time, talent, and energy
to ensure the accurate translation and timely publication of The Complete
Guide to Chain.

1. CHAIN BASICS
1.1 WHAT IS A CHAIN?
A chain is a reliable machine component, which transmits power by means
of tensile forces, and is used primarily for power transmission and conveyance
systems. The function and uses of chain are similar to a belt. There are many
kinds of chain. It is convenient to sort types of chain by either material of
composition or method of construction.
We can sort chains into five types:
1. Cast iron chain.
2. Cast steel chain.
3. Forged chain.
4. Steel chain.
5. Plastic chain.
Demand for the first three chain types is now decreasing; they are only used
in some special situations. For example, cast iron chain is part of water-treat-
ment equipment; forged chain is used in overhead conveyors for automobile
factories.
In this book, we are going to focus on the latter two: “steel chain,” especial-
ly the type called “roller chain,” which makes up the largest share of chains
being produced, and “plastic chain.”
For the most part, we will refer to “roller chain” simply as “chain.”
NOTE: Roller chain is a chain that has an inner plate, outer plate, pin,
bushing, and roller.
In the following section of this book, we will sort chains according to their
uses, which can be broadly divided into six types:
1. Power transmission chain.
2. Small pitch conveyor chain.
3. Precision conveyor chain.
4. Top chain.
5. Free flow chain.
6. Large pitch conveyor chain.
The first one is used for power transmission, the other five are used for con-
veyance. In the Applications Section of this book, we will describe the uses
and features of each chain type by following the above classification.
In the following section, we will explain the composition of power trans-
mission chain, small pitch chain, and large pitch conveyor chain. Because
there are special features in the composition of precision conveyor chain, top
chain, and free flow chain, check the appropriate pages in the Applications
Section about these features.
1

2
Basics
1.1.1 Basic Structure of Power Transmission Chain
A typical configuration for RS60-type chain is shown in Figure 1.1.
Connecting Link
This is the ordinary type of connecting link. The pin and link plate are slip
fit in the connecting link for ease of assembly. This type of connecting link is
20 percent lower in fatigue strength than the chain itself. There are also some
special connecting links which have the same strength as the chain itself. (See
Figure 1.2.)
Tap Fit Connecting Link
In this link, the pin and the tap fit connecting link plate are press fit. It has
fatigue strength almost equal to that of the chain itself. (See Figure 1.2.)
Offset Link
An offset link is used when an odd number of chain links is required. It is
35 percent lower in fatigue strength than the chain itself. The pin and two
plates are slip fit. There is also a two-pitch offset link available that has a
fatigue strength as great as the chain itself. (See Figure 1.3.)
Figure 1.1 The Basic Components of Transmission Chain
Offset Pin
Slip Fit
Slip Fit
Press Fit
Press Fit Press Fit
Bushing
Pin
Connecting
Link Plate
W
idth
Between
Roller Link
Plates
Cotter Pin
Offset Link
Connecting Link
Roller Chain
Pitch
Roller Diameter
Pin Link
Roller Link
Spring Clip
Roller Link Plate
Pin Link Plate
Roller

3
1. Chain Basics
Figure 1.2 Standard Connecting Link (top) and Tap Fit Connecting Link (bottom)
Figure 1.3 Offset Link
Pin Link Plate
Pin
Cotter Pin
Spring Clip
Connecting Link Plate
Cotter Connecting LinkSpring Clip Connecting Link
Spring Clip Connecting Link
Pin Link Plate
Pin
Cotter Pin
Cotter Pin
Offset Link Plate
Offset Pin
Spring Clip Tap Fit Connecting Link Plate
Cotter Connecting Link

1.1.2 Basic Structure of Small Pitch Conveyor Chain
The basic structure is the same as that of power transmission chain. Figure
1.4 shows a single pitch conveyor chain. The double pitch type in Figure 1.5
has an outer plate and an inner plate of the same height, but often has a roller
with a larger diameter. Usually, an attachment is used with this chain.
1.1.3 Basic Structure of Large Pitch Conveyor Chain—Engineering Class
Large pitch conveyor chain has the same basic structure as double pitch con-
veyor chain (Figure 1.5), but there are some differences. Large pitch conveyor
chain (Figure 1.6) has a headed pin, sometimes a flanged roller (F-roller), and
usually does not use a riveted pin. Large pitch conveyor chain is also called
engineering class chain.
1.1.4 Functions of Chain Parts
Plate
The plate is the component that bears the tension placed on the chain.
Usually this is a repeated loading, sometimes accompanied by shock.
Therefore, the plate must have not only great static tensile strength, but also
must hold up to the dynamic forces of load and shock. Furthermore, the plate
must meet environmental resistance requirements (for example, corrosion,
abrasion, etc.).
4
Basics
Figure 1.5 Basic Structure of Double Pitch Conveyor Chain with A-2 Attachment
Figure 1.4 Single Pitch Conveyor Chain with K-1 Attachment
Pin
Connecting Link Plate
Roller
Attachment Roller Link Plate
Attachment Pin Link Plate
Cotter Pin
Roller Link Plate
Pin Link Plate
Bushing

5
1. Chain Basics
Pin
The pin is subject to shearing and bending forces transmitted by the plate. At
the same time, it forms a load-bearing part, together with the bushing, when
the chain flexes during sprocket engagement. Therefore, the pin needs high
tensile and shear strength, resistance to bending, and also must have sufficient
endurance against shock and wear.
Bushing
The bushing is subject to shearing and bending stresses transmitted by
the plate and roller, and also gets shock loads when the chain engages the
sprocket.
In addition, when the chain articulates, the inner surface forms a load-bear-
ing part together with the pin. The outer surface also forms a load-bearing
part with the roller’s inner surface when the roller rotates on the rail or
engages the sprocket. Therefore, it must have great tensile strength against
shearing and be resistant to dynamic shock and wear.
Roller
The roller is subject to impact load as it strikes the sprocket teeth during the
chain engagement with the sprocket. After engagement, the roller changes its
point of contact and balance. It is held between the sprocket teeth and bush-
ing, and moves on the tooth face while receiving a compression load.
Figure 1.6 Basic Structure of Large Pitch Conveyor Chain
Pin
Pin Link Plate
Press Fit
Slip Fit
Bushing
Press Fit
Press Fit
Press Fit
Pin Link
Roller Link
Roller Link
Pin Link
Pitch
Roller Dia.
Width Between
Roller Link Plates
Roller Link
Plate
Pin Link
Plate
(Flat Hole)
T-Pin
Slip Fit
Attachment

6
Basics
Furthermore, the roller’s inner surface constitutes a bearing part together
with the bushing’s outer surface when the roller rotates on the rail. Therefore,
it must be resistant to wear and still have strength against shock, fatigue, and
compression.
Cotter Pin, Spring Clip, T-Pin
These are the parts that prevent the outer plate from falling off the pin at the
point of connection. They may wear out during high-speed operation, there-
fore, for this application, these parts require heat treatment.
1.2 ADVANTAGES AND DISADVANTAGES OF CHAIN
FOR POWER TRANSMISSION AND CONVEYORS
1.2.1 Power Transmission Uses
Power transmission machines use either chains, gears, or belts. Table 1.1
provides a comparison of typical applications.
Usually, chain is an economical part of power transmission machines for
low speeds and large loads. However, it is also possible to use chain in high-
speed conditions like automobile engine camshaft drives. This is accomplished
by devising a method of operation and lubrication.
Basically, there are lower limits of fatigue strength in the gear and the chain,
but not in the belt. Furthermore, if a gear tooth breaks, the gear will stop at
the next tooth. Therefore, the order is gear > chain > belt in the aspect of reli-
ability.
In most cases:
(1) An increase in gear noise indicates that the end of the service life is
near.
(2) You will know that the chain is almost at the end of its life by wear
elongation or an increase in vibration caused by wear elongation.
(3) It is difficult to detect toothed-belt life without stopping the machine
and inspecting the belt carefully.
It is possible to decrease gear noise by adjusting the gears precisely or by
adapting the drive to a helical or double helical gear. Both of these are expen-
sive, and thrust load may occur with the use of helical gears.
Chain is more suitable to long-term continuous running and power trans-
mission with limited torque fluctuation. Gears are more fit to reversing or
intermittent drives.
The greater the shaft center distance, the more practical the use of chain
and belt, rather than gears.

Table 1.1 Comparison Table
Type Roller Chain Tooth Belt V Belt Spur Gear
Sychronization
Transmission
Efficiency
Anti-Shock
Noise/Vibration
Surrounding
Condition Avoid Water, Dust Avoid Heat, Oil, Water, Dust Avoid Heat, Oil, Water, Dust Avoid Water, Dust
Space
Saving
Lubrication
Required No Lube No Lube Required
Layout Flexibilty
Excess Load
onto Bearing
High Speed
Low Load
Low Speed
High Load Compact Heavy Pulley Wider Pulley Less Durability Due to Less Engagement
Generally, under the same transmission conditions, the cost of toothed belts
and pulleys is much higher than the cost of chains and sprockets.
See the following features and points of notice about roller chain
transmission.
Features of Chain Drives:
1. Speed reduction/increase of up to seven to one can be easily
accommodated.
2. Chain can accommodate long shaft-center distances (less than 4 m),
and is more versatile.
3. It is possible to use chain with multiple shafts or drives with both sides
of the chain.
4. Standardization of chains under the American National Standards Institute
(ANSI), the International Standardization Organization (ISO), and the
Japanese Industrial Standards (JIS) allow ease of selection.
5. It is easy to cut and connect chains.
6. The sprocket diameter for a chain system may be smaller than a belt
pulley, while transmitting the same torque.
7. Sprockets are subject to less wear than gears because sprockets distribute
the loading over their many teeth.
Points of Notice:
1. Chain has a speed variation, called chordal action, which is caused by
the polygonal effect of the sprockets.
2. Chain needs lubrication.
3. Chain wears and elongates.
4. Chain is weak when subjected to loads from the side. It needs proper
alignment.
7
1. Chain Basics
Excellent Good Fair Poor

1.2.2 Conveyance Uses
Conveyor systems use either chains, belts, or rollers, depending on the
application. The general guidelines for suitability are shown in Table 1.2, and
discussed in Basics Section 1.2.1.
Belt conveyors are most suitable for large-volume movement of bulk materi-
als. Except for this situation, chains, belts, and rollers are generally difficult to
compare in terms of capacity, speed, or distance of conveyance of unit
materials.
NOTE: In this discussion, bulk materials refer to items like grain or
cement that may shift during conveyance. Unit materials, such as
automobiles or cardboard, are stable when conveyed.
1.3 SPROCKETS
The chain converts rotational power to pulling power, or pulling power to
rotational power, by engaging with the sprocket.
The sprocket looks like a gear but differs in three important ways:
1. Sprockets have many engaging teeth; gears usually have only one or
two.
2. The teeth of a gear touch and slip against each other; there is basically
no slippage in a sprocket.
3. The shape of the teeth are different in gears and sprockets.
Table 1.2
Conveyor Type Chain Belt Roller
Bulk Handling
Unit Handling
Only for light conveyor
Dust in Conveying
Bulky Goods ( for closed conveyor) ——
Space Required Small Large Large
8
Basics
Figure 1.7 Types of Sprockets
Excellent Good Poor

9
Figure 2.1 Typical Chain in Tensile Test Figure 2.2 Stress-Strain Graph
2. CHAIN DYNAMICS
A study of phenomena that occur during chain use.
2.1 CHAINS UNDER TENSION
A chain can transmit tension, but usually cannot transmit pushing forces.
There are actually a few special chains that can push, but this discussion
focuses on tension. In the following section we will explain how the chain
acts under tension.
2.1.1 Elastic Stretch, Plastic Deformation, and Breakage
Tensile Strength
How will the chain behave when it is subjected to tensile loading? There is
a standardized test to determine the tensile strength of a chain. Here’s how
it works: The manufacturer takes a new, five-link-or-longer power transmis-
sion chain and firmly affixes both ends to the jigs (Figure 2.1). Now a load
or tension is applied and measurements are taken until the chain breaks
(JIS B 1801-1990).
Chain Elongation
As a chain is subjected to increasing stress or load, it becomes longer.
This relationship can be graphed (Figure 2.2). The vertical axis shows increas-
ing stress or load, and the horizontal axis shows increasing strain or elonga-
tion. In this stress-strain graph, each point represents the following:
O-A: elastic region
A: limit of proportionality for chains; there is not an
obvious declining point, as in mild steel
A-C: plastic deformation
B: maximum tension point
C: actual breakage
Elongation
Load
O

10
Basics
Reporting Tensile Strength
Point B, shown in Figure 2.2, the maximum tension point, is also called the
ultimate tensile strength. In some cases, point B will come at the same time as
point C. After breaking a number of chains, a tensile strength graph shows a
normal distribution (Figure 2.3).
The average load in Figure 2.3 is called the average tensile strength, and the
lowest value, which is determined after statistically examining the results, is
called the minimum tensile strength. JIS (Japanese Industrial Standard) also
regulates minimum tensile strength, but it is much lower than any manufactur-
er’s tensile strength listed in their catalogs.
“Maximum allowable load,” shown in some manufacturer’s catalogs, is
based on the fatigue limit (see Basics Section 2.2.2). This value is much lower
than point A. Furthermore, in the case of power transmission chain, point A is
usually 70 percent of the ultimate tensile strength (point B). If the chain
receives greater tension than point A, plastic deformation will occur, and the
chain will be nonfunctional.
Using Tensile Strength Information
For the sake of safety, you should never subject chains to tension greater
than half the average tensile strength—not even once. If the chain is inadver-
tently loaded that high, you should change the whole chain set. If the chain is
repeatedly subjected to loads greater than the maximum allowable load,
fatigue failure may result.
When you see tensile strength graphs or stress-strain graphs, you should be
aware of the following facts:
1. Every manufacturer shows the average tensile strength in its catalog, but
it is not unusual to find that the value listed may have been developed
with sales in mind. Therefore, when comparing chains from different
manufacturers, check the minimum tensile strength.
Figure 2.3 Tensile Strength
JIS Tensile Strength
Min. Tensile Strength
Avg.Tensile Strength
Tensile Strength
Frequency

11
2. Chain Dynamics
2. In addition to the tensile strength, the most important fact about a stress-
strain graph is the value of stretch at the time of breakage. If the chain’s
tensile strength is higher and the capacity to stretch is greater, the chain
can absorb more energy before it breaks. This means the chain won’t be
easily broken even if it receives unexpected shock load. (In Figure 2.2,
the cross-hatched area is the value of energy that the chain can absorb
before it breaks.)
Elastic Elongation
Another important characteristic in practice is how much elastic elongation
the chain will undergo when it is subjected to tension. When you use chains
for elevators on stage, if there is a difference between the stage floor and the
elevator platform, the dancers will trip on it. In an elevator parking garage, it
is necessary to lower cars down to the entrance within a small difference in
the level. Therefore, it is important to anticipate how long the chain’s elastic
stretch will be. Figure 2.4 shows elasticity/stretch for power transmission roller
chains.
Please contact the individual manufacturers about small and large pitch con-
veyor chains.
Figure 2.4 Elastic Elongation on Roller Chain
Load
Max. Allowable Load
Elongation (mm/m) Elongation (mm/m)
Max. Allowable Load

12
Basics
2.1.2 Engagement with Sprockets
Although chains are sometimes pushed and pulled at either end by cylin-
ders, chains are usually driven by wrapping them on sprockets. In the follow-
ing section, we explain the relation between sprockets and chains when
power is transmitted by sprockets.
1. Back tension
First, let us explain the relationship between flat belts and pulleys. Figure
2.5 shows a rendition of a flat belt drive. The circle at the top is a pulley, and
the belt hangs down from each side. When the pulley is fixed and the left side
of the belt is loaded with tension (T0), the force needed to pull the belt down
to the right side will be:
T1 = T0 ϫ eµ␪
For example, T0 = 100 N: the coefficient of friction between the belt and
pulley, µ = 0.3; the wrap angle ␪ = π (180˚).
T1 = T0 ϫ 2.566 = 256.6 N
In brief, when you use a flat belt in this situation, you can get 256.6 N of
drive power only when there is 100 N of back tension. For elements without
teeth such as flat belts or ropes, the way to get more drive power is to
increase the coefficient of friction or wrapping angle. If a substance, like
grease or oil, which decreases the coefficient of friction, gets onto the contact
surface, the belt cannot deliver the required tension.
In the chain’s case, sprocket teeth hold the chain roller. If the sprocket tooth
configuration is square, as in Figure 2.6, the direction of the tooth’s reactive
force is opposite the chain’s tension, and only one tooth will receive all the
chain’s tension. Therefore, the chain will work without back tension.
Figure 2.5 Flat Belt Drive Figure 2.6 Simplified Roller/Tooth Forces
Chain Roller
Roller
Tooth Force
T0
T1

13
2. Chain Dynamics
But actually, sprocket teeth need some inclination so that the teeth can
engage and slip off of the roller. The balance of forces that exist around the
roller are shown in Figure 2.7, and it is easy to calculate the required back
tension.
For example, assume a coefficient of friction µ = 0, and you can calculate
the back tension (Tk) that is needed at sprocket tooth number k with this for-
mula:
Tk = T0 ϫ
sin ø k-1
sin(ø + 2␤)
Where:
Tk= back tension at tooth k
T0 = chain tension
ø = sprocket minimum pressure angle 17 – 64/N(˚)
N = number of teeth
2␤ = sprocket tooth angle (360/N)
k = the number of engaged teeth (angle of wrap ϫ N/360); round down
to the nearest whole number to be safe
By this formula, if the chain is wrapped halfway around the sprocket, the
back tension at sprocket tooth number six is only 0.96 N. This is 1 percent of
the amount of a flat belt. Using chains and sprockets, the required back tension
is much lower than a flat belt.
Now let’s compare chains and sprockets with a toothed-belt back tension.
Although in toothed belts the allowable tension can differ with the number
of pulley teeth and the revolutions per minute (rpm), the general recommen-
dation is to use 1/3.5 of the allowable tension as the back tension (F). This is
shown in Figure 2.8. Therefore, our 257 N force will require 257/3.5 = 73 N of
back tension.
Both toothed belts and chains engage by means of teeth, but chain’s back
tension is only 1/75 that of toothed belts.
Figure 2.7 The Balance of Forces Around the Roller
{ }
Tooth Force
Link Tension
Frictional
Tooth Force
Chain Tension
Pressure Angle

14
Basics
2. Chain wear and jumping sprocket teeth
The key factor causing chain to jump sprocket teeth is chain wear elongation
(see Basics Section 2.2.4). Because of wear elongation, the chain creeps up on
the sprocket teeth until it starts jumping sprocket teeth and can no longer
engage with the sprocket. Figure 2.9 shows sprocket tooth shape and posi-
tions of engagement. Figure 2.10 shows the engagement of a sprocket with an
elongated chain.
In Figure 2.9 there are three sections on the sprocket tooth face:
a: Bottom curve of tooth, where the roller falls into place;
b: Working curve, where the roller and the sprocket are working together;
c: Where the tooth can guide the roller but can’t transmit tension. If the
roller, which should transmit tension, only engages with C, it causes
jumped sprocket teeth.
The chain’s wear elongation limit varies according to the number of sprocket
teeth and their shape, as shown in Figure 2.11. Upon calculation, we see that
sprockets with large numbers of teeth are very limited in stretch percentage.
Smaller sprockets are limited by other harmful effects, such as high vibration
and decreasing strength; therefore, in the case of less than 60 teeth, the stretch
limit ratio is limited to 1.5 percent (in transmission chain).
Figure 2.8 Back Tension on a Toothed Belt
Figure 2.9 Sprocket Tooth Shape and Positions
of Engagement
Figure 2.10 The Engagement Between
a Sprocket and an Elongated
Chain

In conveyor chains, in which the number of working teeth in sprockets is
less than transmission chains, the stretch ratio is limited to 2 percent. Large
pitch conveyor chains use a straight line in place of curve B in the sprocket
tooth face.
2.2 CHAIN DRIVE IN ACTION
Let’s study the case of an endless chain rotating on two sprockets
(Figure 2.12).
2.2.1 Chordal Action
You will find that the position in which the chain and the sprockets engage
fluctuates, and the chain vibrates along with this fluctuation. Even with the
same chain, if you increase the number of teeth in the sprockets (change to
larger diameter), vibration will be reduced. Decrease the number of teeth in
the sprockets and vibration will increase.
This is because there is a pitch length in chains, and they can only bend at
the pitch point. In Figure 2.13, the height of engagement (the radius from the
center of the sprocket) differs when the chain engages in a tangent position
and when it engages in a chord.
15
2. Chain Dynamics
Figure 2.11 Elongation Versus the Number of Sprocket Teeth
Figure 2.12 An Endless Chain Rotating Around Two Sprockets
AllowableElongation(%)
Number of Teeth in Sprocket

16
Basics
Figure 2.13 The Height of Engagement
Figure 2.14 Speed Variation Versus the Number of Sprocket Teeth
Therefore, even when the sprockets rotate at the same speed, the chain
speed is not steady according to a ratio of the sprocket radius (with chordal
action). Chordal action is based on the number of teeth in the sprockets:
Ratio of speed change = (Vmax – Vmin) / Vmax = 1 – cos (180˚/N)
Figure 2.14 shows the result. In addition to the number of teeth, if the shaft
center distance is a common multiple of the chain pitch, chordal action is
small. On the other hand, if shaft center distance is a multiple of chain pitch +
0.5 pitch, chordal action increases. Manufacturing and alignment errors can
also impact chordal action.
In a flat-belt power transmission machine, if the thickness and bending elas-
ticity of the belt are regular, there is no chordal action. But in toothed-belt sys-
tems, chordal action occurs by circle and chord, the same as chains. Generally
this effect is less than 0.6 percent, but when combined with the deflection of
the pulley center and errors of belt pitch or pulley pitch, it can amount to 2 to
3 percent.
Number of Teeth in Sprocket
SpeedVariation(%)
Vmax – Vmin
Vmax
Maximum Chain Speed
Vmax = R␻
Chordal Rise
Minimum Chain Speed
Vmin = r␻

17
2. Chain Dynamics
Figure 2.16 Chain Load with the Addition of Resistance
Figure 2.15 A Typical Chain Drive with the Driving Side on the Left
2.2.2 Repeated Load Tension, Fatigue Failure
In Basics Section 2.2.1, we looked at the case of rotating chains without
load. In this section, we’ll examine rotating chains with load, a typical use
of chains.
In Figure 2.15, the left sprocket is the driving side (power input) and the
right sprocket is the driven side (power output). If we apply counterclockwise
rotation power to the driving sprocket while adding resistance to the driven
sprocket, then the chain is loaded in tension mainly at the D~A span, and ten-
sion is smaller in the other parts. Figure 2.16 shows this relation.
Time
Load
Chains in most applications are typically loaded by cyclical tension. Chain
fatigue is tested under pulsating tension via a fixture. The fatigue limit will
occur between 106 to 107 times. Figure 2.17 shows the concept of repeated
load tension, where Pa represents the amplitude.
NOTE: If the minimum force is zero, the chain is free to move during
testing. Therefore, JIS provides Pmin = Pmax ϫ 1/11, as in Figure 2.17.
When a chain that is more than five links and of linear configuration receives
repeated load, it can be shown as a solid line (as in Figure 2.17).
JIS B 1801-1990 defines the breakage load in 5 ϫ 106 times:
Pmax = Pm + Pa = 2.2 Pa

18
Basics
as the maximum allowable load. Figure 2.18 shows one result of fatigue exam-
ination in this way. In the figure, the vertical axis is Pmax and the horizontal
axis is the number of repetitions. When the repetitions are less than 104 times,
the test results fluctuate greatly. Therefore, these figures are practically useless,
and are not shown here.
In the previous paragraph, we need to be alert to what the JIS regulation is
really saying: “JIS B 1801-1990 defines...Pmax = 2.2 Pa as the maximum allow-
able load.” This is set up with wrapping transmission as a model (as shown in
Figure 2.15), and with the supposition that the smaller load side tension is 10
percent of the larger load side tension.
In actual practice, even if we use wrapping transmission, the smaller load
side tension may be almost zero; and in the case of hanging or lifting, the
chain’s slack side also doesn’t receive any load. In these cases, the conditions
can be shown as a dotted line (Figure 2.17); chain load = 2 Pa' and Pmin = 0;
therefore 2Pa' < Pmax.
Figure 2.18 Fatigue Strength
Range with Failure
Endurance Limit
Range without Failure
Tensile Strength
Load
Cycles
Figure 2.17 Repeated Load Tension
Time
Load

19
2. Chain Dynamics
If you follow the JIS definition of Pmax as maximum allowable load and you
choose a chain on the higher limits of the scale, the chain might not stand up
to those strength requirements. In some situations a fatigue failure might occur
even though it met the JIS requirement for maximum allowable load.
This is the reason that some manufacturers, such as Tsubaki, use 2Pa as
the maximum allowable load; or some manufacturers calculate 2Pa under the
situation of Pmin = 0 and show this in their catalog. In the latter method, the 2Pa'
value is larger than the value of the former method. The maximum allowable
load value of the JIS method is 10 percent greater than the former method of 2Pa.
In addition, some manufacturers, including Tsubaki, establish a fatigue limit
for strength at 107 cycles. JIS sets a fatigue strength at 5 ϫ 106 cycles.
Including the JIS scale, there are more than three ways of expressing the
same information in manufacturers’ catalogs. Therefore, you should not make
a final determination about a chain’s functions simply by depending on infor-
mation found in different catalogs. Consider a manufacturer’s reliability by
checking whether they have their own fatigue-testing equipment. Ask if they
show fatigue limit data in their catalogs. The quality guarantee system of ISO
9000 series is checked by third parties (instead of users) to gauge whether or
not their system of quality guarantee is adequate. It would be safe to choose
manufacturers who are ISO-9000-series certified.
2.2.3 Transmission Capability of Drive Chains
We have derived fatigue limits by testing. But just as you can’t judge a per-
son by examination alone, so we must also check whether the results of our
tests can be put to practical use. Some questions remain:
1. The chain’s fatigue limit (see Basics Section 2.2.2) is tested in a linear
configuration (Figure 2.1). But in wrapping transmission, the chain is
engaging with the sprocket. Is there any difference between these two?
2. A new roller chain is used. Is there any decrease in the strength of a used
chain?
3. Do connecting links or offset links have the same strength?
To answer these questions, a number of experiments and investigations
were done. The following are the findings.
2.2.3.1 Difference Between Linear Tension and Wrapping
When the chain engages the sprocket, the chain collides with the sprocket
tooth surfaces. The transmission capability is limited by the roller or bushing
breakage during collision.

20
Basics
As it wraps on the sprocket and rotates, the chain receives centrifugal force.
The faster the speed of rotation, the larger the centrifugal force becomes.
Additionally, the pin and the bushing are also subject to tension. There is a
limit to their bearing function.
2.2.3.2 Effect of Normal Chain Wear on Fatigue Strength
When a chain is operating, the outer surface of the pin and inner surface of
the bushing rub against one another, wearing little by little. (Proper lubrication
reduces the amount of wear but does not eliminate it.)
The problem is the wear of the pin. As the surface of the pin is reduced, the
rigidity of the pin decreases and eventually fatigue failure may result. The
question is how much wear is acceptable and at what point should you be
concerned.
Testing shows that when wear elongation is less than or equal to 1.5 percent
for transmission chain, or less than or equal to 2 percent for conveyor chain,
there is almost no risk of fatigue failure.
NOTE: This replacment limit applies to situations in which every pin
and bushing wears equally. If one part is subject to greater wear, the
system should be examined and repaired. Chains should be replaced
at the same time.
In practical terms, the most important consequence of deterioration is a
decrease in the fatigue strength by environmental factors. This problem will be
discussed in Basics Section 5.4.
2.2.3.3 Strength Differences Between Chain and the Connecting
Links and Offset Links
The individual connecting links and offset links have lower fatigue strength than
the chain itself. Therefore, you have to consider the strength-decrease ratio shown
in Table 2.1. The strength-decrease ratio differs from manufacturer to manufactur-
er, so it is important to get specific information from each manufacturer.
If you use chain with loads that are almost the same as the maximum allow-
able load, you should avoid using offset links. Use tap fit connecting links,
which are stronger than standard connecting links. In some cases, you can
order chains in an endless configuration (see NOTE on next page).
Table 2.1 Strength Reduction of Connecting Links and Offset Links
Reduction Ratio
Type Against Maximum Allowable Load
Standard Connecting Link 0 ~ 20%
Tap Fit Connecting Link No reduction
Offset Link 35%
Two-Pitch Offset Link 0 ~ 25%

21
2. Chain Dynamics
NOTE: Endless configuration: Manufacturers create connecting com-
ponents that are as strong as the chain’s other parts by riveting or other
factory processes. The chain is assembled and delivered as an endless
configuration.
The transmission-ability graph, which is sometimes called a “tent curve”
because of its shape, includes the result of the three points covered above.
This graph is an important tool when making chain decisions. Figure 2.19
illustrates the concept of a tent curve.
In Figure 2.19, Line O-A is decided according to the chain’s allowable ten-
sion, which includes the fatigue strength of the connecting or offset links, as
well as the centrifugal force in high-speed rotation. Line B-C is decided by
breakage limit of the bushing and roller. In this kind of breakage of the bush-
ing and roller, there is no fatigue limit as there is with the link plates.
Therefore, it is shown within 15,000 hours of strength-in-limited-duration. Line
D-E is decided by the bearing function of the pin and the bushing.
The range defined within these three lines (O-A, B-C, and D-E) is the usable
range. When the chain is used at low speeds, it is limited by line O-A, the
fatigue limit. The conditions of the tent curve shown are:
a. Two-shaft wrapping transmission with 100 links of chain.
b. Duration of 15,000 hours work.
c. Under the Additional Operating Conditions (1 through 5 shown below).
Additional Operating Conditions
1. The chain operates in an indoor environment of -10˚C to 60˚C,
and there is no abrasive dust.
2. There are no effects from corrosive gas or high humidity.
3. The two driving shafts are parallel with each other and adjusted properly.
4. Lubrication is applied as recommended in the catalog.
5. The transmission is subject to only small fluctuations in load.
Figure 2.19 A Transmission-Ability Graph (Tent Curve)
Roller-Bushing Impact
Link Plate Failure
Galling
Small Sprocket (rpm)
Horsepower(kW)
O

2.2.4 Wear of Working Parts
In Basics Section 2.2.3.2, we discussed the effects of pin wear. When a chain
is operating, the outer surface of the pin and inner surface of the bushing rub
against one another, wearing little by little.
When a chain is operating, obviously other parts are also moving and wear-
ing. For example, the outer surface of the bushing and inner surface of the
roller move against one another. In the case of transmission chain, the roller
and bushing wear is less than that of the pin and the inner surface of the
bushing because the chance of rubbing is generally smaller. Also, it is easier to
apply lubrication between the bushing and roller.
The progress of pin-bushing wear is shown in Figure 2.20, in which the hori-
zontal axis is the working hours and the vertical axis is the wear elongation
(percent of chain length).
In Figure 2.20, O-A is called “initial wear.” At first the wear progresses rapid-
ly, but its ratio is less than 0.1 percent and usually it will cease within 20 hours
of continuous operation. A-B is “normal wear.” Its progress is slow. B-C is
“extreme wear.” The limit of “allowable wear” (the end of its useful life) will
be reached during this stage (1.5 to 2.0 percent).
The solid line reflects a case of using chain with working parts that were
lubricated in the factory, but were not lubricated again. If you lubricate regu-
larly, the pin and the bushing continue to exhibit normal wear (reflected by
the dotted line), and eventually run out their useful life.
If you remove all the lubricants with solvents, the wear progresses along a
nearly straight line, and the life of the chain is shortened. This is shown by the
dashed line.
The factors that affect chain wear are very complicated. There are many con-
siderations, such as lubrication, assembly accuracy, condition of produced
parts, and the method of producing parts; therefore, wear value can’t be great-
ly improved by merely changing one factor.
22
Basics
Figure 2.20 Pin-Bushing Wear During Operation
Running Time
Elongation(%)
O
A
B
C

In transmission chain, JIS B 1801-1990 regulates the surface hardness of the
pin, the bushing, and the roller (as shown in Table 2.2) to meet the multiple
requirements for wear resistance and shock resistance.
2.2.5 Noise and Vibration
When the chain engages the sprockets, it will definitely make noise
(Figure 2.21). This is caused by several factors:
1. The chain roller strikes the sprocket tooth bottom.
2. There is space between the roller and the bushing; the roller makes noise
by its elastic vibration (in the case of thin rollers, like S-roller).
3. Sprockets vibrate.
4. The fluid held between each part (usually air or lubrication oil)
makes shock sounds.
Take for example, an RS80 transmission roller chain and a sprocket with 16
teeth operating at a speed of 123 rpm. (The chain speed is 50 m/min.) In this
case, the noise at a point 30 cm from the sprocket will be: with no lubrication,
65 dB (A); with lubrication, 57 dB (A).
According to the data given above, the noise made by the chain engaging
the sprocket can be predicted. Please contact the manufacturer.
There are some steps you can take to lessen the noise level.
a. Decrease striking energy:
• Use a sprocket with many teeth. This reduces the impact velocity
while maintaining the same chain speed.
• Operate the chain at slower speeds.
• Use smaller chain to decrease the chain’s weight.
23
2. Chain Dynamics
Figure 2.21 Noise Occurs when the Chain Engages the Sprocket
Table 2.2. Surface Hardness of Pin, Bushing, and Roller
Component HV HRC
Pin 450 or greater 45 or greater
Bushing 450 or greater 45 or greater
Roller 390 or greater 40 or greater

24
Basics
b. Buffer the effects of the impacting parts:
• Lubricate at the bottom of the sprocket tooth and the gap between
the bushing and the roller.
• Use specially engineered plastic rollers. (This will also decrease
transmission capability. There is virtually no decrease in sound if you
change to an engineered plastic sprocket.)
If we compare noise from chains and sprockets with other transmission
machine parts like belt and pulley or toothed belt and pulley, we find:
a. Belt noise is less than the other two. Compared to a flat belt, a toothed
belt makes a high frequency noise during high speed.
b. Usually, chain transmission is smoother than gear transmission. The
chain also differs in that there is no increase in noise level as it wears
and elongates during use.
2.3 CHARACTERISTIC PHENOMENA IN CONVEYOR CHAIN
Until now, we have primarily been explaining matters that apply specifically
to power transmission chains. However, there are some different problems that
occur when using conveyor chain.
2.3.1 Coefficient of Friction
The tension of transmission chain is calculated by dividing the transmitted
power (indicated as kW or horsepower) by the chain speed and multiplying by
an adequate coefficient. But in a fixed-speed, horizontal conveyor, tension is
decided by those factors shown below:
1. The coefficient of friction between the chain and the rail when conveyed
objects are placed on the chain.
2. The coefficient of friction between conveyed objects and the rail when
conveyed objects are held on the rail and pushed by the chain.
NOTE: There are two types of tension: the first occurs when conveyed
objects are moving at a fixed speed, and the second is inertial effects
that occur when starting and stopping the machine. We will only talk
about the former in this section, and the latter in Basics Section 2.3.2.
Figure 2.22 Tension on a Horizontal Conveyor

Table 2.3 Friction Coefficients for Top Plate and Guide Rails
Friction Coefficient
Top Plate Material Guide Rail Material Unlubricated Lubricated
Stainless Steel or Steel Stainless Steel or Steel 0.35 0.20
Stainless Steel or Steel UHMW 0.25 0.15
Engineered Plastic Stainless Steel or Steel 0.25 0.15
Engineered Plastic UHMW 0.25 0.12
Engineered Plastic (Low Friction) Stainless Steel or Steel 0.17 0.12
Engineered Plastic (Low Friction) UHMW 0.18 0.12
25
2. Chain Dynamics
The tension (T) in a horizontal conveyor, like that in Figure 2.22, is basically
calculated by this formula:
T = M1 ϫ g ϫ f1 ϫ 1.1 + M1 ϫ g ϫ f2 + M2 ϫ g ϫ f3
Where:
T = total chain tension
M1 = weight of the chain, etc.
M2 = weight of conveyed objects
f1 = coefficient of friction when chain, etc., are returning
f2 = coefficient of friction when chain, etc., are conveying
f3 = coefficient of friction when conveyed objects are moving
g = gravitational constant
1.1 = sprocket losses due to directional changes of the chain
NOTE: “chain, etc.,” in the above formula includes chain and the parts
moving with the chain, such as attachments and slats.
In this formula, a coefficient of friction is multiplied by every term in the
equation. Therefore, if the coefficient of friction is high, the tension increases
and larger chain is required. Also, the necessary motor power, which is calculat-
ed as tension ϫ speed ϫ coefficient, increases. A more powerful motor is need-
ed when the coefficient of friction is high.
Reduce the coefficient of friction and you can reduce the tension, too. This
allows you to choose a more economical chain and motor, and decrease the ini-
tial and running costs for conveyor equipment.
The chain’s coefficient of friction differs by type of chain, by material, and by
type of roller; it is shown in the manufacturer’s catalog. To illustrate this con-
cept, two examples are included. The coefficient of friction for different types of
top chain and guide rails is shown in Table 2.3. The coefficient of friction when
large R-roller chain rotates on rails (rail material: steel) is shown in Table 2.4.
Table 2.4 Friction Coefficients for Different Types of Rollers
Friction Coefficient
Chain Type Roller Type Unlubricated Lubricated
RF Double Pitch Chain Steel 0.12 0.08
Engineered Plastic 0.08 —
Large Pitch Conveyor Chain Steel 0.13 ~ 0.15 0.08
Engineered Plastic 0.08 —
Bearing Roller 0.03 —

26
Basics
Technology can help you reduce the coefficient of friction. Some of the
newest chains (for example, low-friction top chain, engineered plastic roller
chain, and bearing roller chain) can achieve low coefficients of friction with-
out lubrication. Other chains would have to be lubricated to achieve these
coefficients. In some instances, these new chains achieve dramatically lower
coefficients of friction. That means you can save maintenance time, money,
and energy at your facility.
2.3.2 Dynamic Tension of Starting and Stopping
Conveyor chain accelerates when it changes from stop mode to operational
speeds, and decelerates when it changes from operational speeds to stop
modes. Therefore, a dynamic tension resulting from inertia affects the convey-
or chain, and it is added to “the tension produced when conveyed objects are
moving at fixed speed,” which is discussed in Basics Section 2.3.1. You must
consider dynamic tension caused by inertia, especially in the following cases:
1. Starting and stopping chains frequently, such as intermittent use with
indexing equipment.
2. Starting and stopping in very short time spans.
3. When chains in motion suddenly receive stationary objects to convey.
The dynamic tension by inertia is calculated with this formula:
T1 = M ϫ α = M ϫ
dv
dt
Where:
M = total weight of conveying apparatus, including chain, attachments,
product, etc., (kg)
α = maximum acceleration (m/s2)
dv = change in speed (m/s)
dt = time in which speed change occurs (s)
For example:
M = 5,000 kg, the total weight of chain, attachment, product, etc.
f = 0.12, the dynamic coefficient of friction
T = 5,000 ϫ 9.8 ϫ 0.12 = 5,880 N
This assumes the conveyor is operating at constant speed. But when the
chain starts, if the speed is increased to 20 m/min. in 0.2 seconds, then:
dv = 20/60 = 0.33 m/s
dt = 0.2 s
T1 = 5,000 ϫ
0.33
= 8,250 N
0.2
Maximum tension = T + T1 = 14,130 N
If the chain is accelerated frequently in this manner, then select
chains using T + T1.

27
2. Chain Dynamics
2.3.3 Wear Between Rollers and Bushings
During the operation of conveyor chains, rollers receive some additional
forces, which are shown in Figure 2.23 and listed below:
1. The weight of conveyed objects when they are put directly on the chain.
2. The reaction forces when pushing conveyed objects with a dog.
3. Directional variation tension when the rail is set in a curved path.
These forces cause wear between rollers and bushings.
Some manufacturers publish an “allowable roller load”—a value at which the
wear rate of the roller is comparatively slow. For steel rollers, it is the value
with lubrication. For engineered plastic rollers and bearing rollers, the values
shown are without lubrication. Sometimes, engineered plastic rollers may be
affected by speed. Please check the catalogs.
If foreign objects, including conveyed objects, get into the working parts of
the chain, the catalog values are no longer applicable, even if you are using
lubrication.
There are many conveyed objects that work as lubricants; therefore, it is
hard to generalize about the allowable roller loads when there are any foreign
objects that might get into the working parts. Furthermore, the loads on the
rollers (as shown in points 1 through 3 above), are also applicable to the side
rollers and to the resulting wear of pins and side rollers. Make sure you con-
sider these factors when setting up a conveyor system.
Figure 2.23 Forces on Conveyor Rollers
Roller Load
Skid Line
Roller Load
Corner RailRoller Load
Roller Load
Load

28
Basics
2.3.4 Strength of Attachments
Bending and twisting forces can affect the attachments. For the A attach-
ment, which is a common type, the allowable load calculation indicated in cat-
alogs is based on the bending strength.
When a tall fixture is added onto the attachment, you must study the
strength of the entire configuration. When the attachment is subject to forces
other than those explained, you also must calculate the twisting forces. If the
attachment receives bending forces at the same time, make sure to combine
the bending forces with the twisting forces.
When calculating the strength of attachments such as A-type, K-type, SA-
type, and SK-type, which are extensions of a standard steel chain’s plate, use
the values shown below as their ultimate tensile strength, and choose a proper
safety factor.
Nonheat-treated plate: 490 MPa (50 kgf/mm2)
Heat-treated plate: 1,078 MPa (110 kgf/mm2)
2.3.5 Stick Slip
When using an extra-long conveyor system (more than 15 m) and slow
chain speed (less than 10 m/min.), you may notice longitudinal vibration in
the line, which is called stick slip, or jerking.
The basis for this phenomenon can be seen in Figure 2.24. Here the coeffi-
cient of friction is plotted against the speed of the chain. When operating a
long conveyor at slow speeds, the coefficient of friction for sliding surfaces (in
top chains, between top plates and rails; in R-rollers, between the outer sur-
face of the bushing and inner surface of the roller) decreases as speed increas-
es. This causes the chain to jerk or stick slip.
Usually, you can’t solve this problem by adding lubrication or by increasing
the number of sprocket teeth. There are, however, things you can do to pre-
vent or reduce stick slip:
1. Increase chain speed.
Figure 2.24 How Chain Speed Impacts the Friction Coefficient
Chain Speed
CoeffcientofFriction

29
2. Chain Dynamics
2. Eliminate or decrease the decline in the coefficient of friction by using a
bearing roller (please consult with manufacturer if the speed is less than 2
m/min.), or use a special kind of lubrication oil (Tsubaki special oil, or
others).
3. Increase chain rigidity (AE). A is the chain’s section area, and E is
Young’s modulus. To increase AE, use a larger chain. If there are several
chains with the same allowable tension, choose the one with the
thicker plate.
4. Separate the conveyor into sections and reduce the length
of each machine.
If stick slip continues to be a problem, consult the equipment manufacturer.
2.3.6 Relative Differences in Chain’s Total Length
If you want to achieve a precise positioning of more than two chain lines to
be used in parallel, you can order “matched and tagged” chain. Generally, if
the conveyor chains are made in the same lots, the relative differences in
length will vary only slightly. Table 2.5 shows the amount of variation for sev-
eral types of chain chosen at random from the same production run.
If your specific application requires less variation than those listed in Table
2.5, consider matched and tagged chains as an effective solution.
2.3.7 Take-Up
Conveyor chains need proper tension, which is why take-up is added to a sys-
tem. You have to position take-up where the chain’s tension will be minimal. If
you can remove two links from the chain, the adjusting length of take-up is:
L = chain pitch + spare length
If you can’t remove links from the chain, use this formula:
L = length of machine ϫ 0.02 + spare length
In this formula, 0.02 represents the allowable wear value (2 percent). There
are two portions of the spare length: one is the maximum and minimum range
of variation in length for new chains; the other portion is the length to loosen
the chain’s connecting link when the chain’s total length has been set as tight
as possible. For example: the machine length is 10 m, the length for maximum
and minimum range of variation is 0.25 percent, assuming the length needed
to connect chain is 25 mm, then:
L = 10,000 ϫ (0.02 + 0.0025) + 25 = 225 + 25 = 250 (mm)
Table 2.5 Conveyor Chains Chosen at Random from Same Production Lot
Center Distance Matched Tolerance
Less than 7 m Less than 3 mm
7 ~ 15 m Less than 4 mm
15 ~ 22 m Less than 5 mm

30
Basics
If the chain expands and contracts with temperature, the system needs
some means to absorb it. When you use a chain in a high-temperature envi-
ronment or to convey high-temperature objects, the chain becomes hotter
and the length increases at about the same ratio as its coefficient of linear
expansion. When the temperature is between 0˚ and 300˚C, and 1 m of chain
is heated by a value of 100˚C, the chain elongates by about 1 mm. If you
want to allow for this elongation with take-up, you must be careful about the
following points or the chain may fail:
• In the case of chain temperature increase, adjust take-up after the
temperature increase.
• In the case of chain temperature decrease, adjust take-up before
the decrease.
In the case of chain temperature change, the take-up should be designed to
absorb the elongation or the contraction of the chain.
If you don’t drive the chain in reverse, it is more convenient to design a
catenary section and collect the elongation in that part. In that case, it is also
beneficial to design a take-up. Figure 2.25 shows an example of a design
with catenary and take-up.
It is very annoying to continuously adjust take-up. Sometimes it is possible to
use self-adjusting take-ups by hanging a weight or using a hydraulic power
cylinder instead of adjusting the take-up. However, the chain receives addition-
al tension by doing this (sometimes the motor capacity is also influenced), so
don’t forget to check the chain strength as well as the motor capacity.
Another point about take-up is that if you drive the chain in reverse while
carrying objects, the take-up receives the load as if it were a driving part. In
this situation, you must select and design take-up with consideration for its
strength.
Figure 2.25 Catenary Take-Up
Driver Sprocket
Take-Up
Roller Catenary Support

31
Table 3.1. Standards for Major Types of Chains1
ANSI ISO JIS
Chain Category Standard Standard Standard
Power Transmission Roller Chain ANSI B 29.1M ISO 606 JIS B 1801
Power Transmission Bushed Chain ANSI B 29.1M ISO 1395 JIS B 1801
Power Transmission Sprocket ANSI B 29.1M ISO 606 JIS B 1802
Heavy-Duty Chain ANSI B 29.10M ISO 3512
Bicycle Chain ISO 9633 JIS D 9417
Motorcycle Chain ISO 10190 JCAS 12
Leaf Chain ANSI B 29.8M ISO 4347 JIS B 1804
Double Pitch Conveyor Chain & Sprocket ANSI B 29.4 ISO 1275 JIS B 1803
Power Transmission Roller Chain with Attachment ANSI B 29.5 JIS B 1801
Conveyor Chain ANSI B 29.15 ISO 1977/1~3 JCAS 22
1
The contents of each standard for a category may vary from group to group.
2
JCAS indicates the Japanese Chain Association Standard.
3. PUBLIC STANDARDS OF CHAINS
Because chain is widely used throughout the world, there are both interna-
tional and domestic standards to guarantee their interchangeability and func-
tions. Table 3.1 shows the primary standards.

32
4. HOW TO SELECT CHAINS
In this chapter, we outline the selection process. To choose the right chain,
follow the step-by-step procedure for the type of line you’re running. The first
thing you must determine is the type of application: power transmission or
conveyor. The selection process differs for the two applications; see Basics
Sections 4.1 and 4.2.
In addition to the procedures described in this book, chain manufacturers
usually provide comprehensive selection charts in their catalogs; refer to the
manufacturer’s catalog for detailed information.
4.1 TRANSMISSION CHAIN SELECTION
There are four main uses for transmission chains: power transmission, hang-
ing transmission, shuttle traction, and pin-gear driving.
1. Power transmission. The most frequent application, power transmission
involves an endless chain wrapped on two sprockets. There are two ways
to select chains for this use.
For general applications, you can select by power transmission capability
(tent curve). This is shown in Figure 4.1.
For slow-speed operation, you can make an economical selection using the
maximum allowable tension. Use this method when chain speed is less than
50 m/min. and starting frequency is less than five times/day (Figure 4.2).
Figure 4.1 Power Transmission Capability Figure 4.2 Maximum Allowable Load at Slow
Speeds (less than 50 m/min.)
Small Sprocket (rpm)
Number of Cycles
Tensile Strength
Power
Max. Allowable Load
Load
With Catenary
Without Catenary
kW
1 107

2. Hanging transmission. This design is increasing in popularity. It is used,
for example, in parking garage elevators. Sprockets rotate, and conveyed
objects can be lifted or suspended at the end of chains. (Figure 4.3).
3. Shuttle traction. (Figure 4.4).
4. Pin-gear drive. In this design, the chains are laid straight or in a large
diameter circle and are driven with special tooth form sprockets. This
design is more economical than using gears (Figure 4.5).
In this book, we will focus on items 1 and 2. Consult your manufacturer’s
catalog for information on items 3 and 4.
4.1.1 Chain Selection Factors
You must consider the following conditions:
1. Type of application.
2. Shock load.
3. Source of power: motor type; rated power (kW); moment of inertia,
I (kg • m2); rated torque at driving speed; starting torque; and
stopping torque.
4. Drive sprocket rpm and shaft diameter.
5. Driven sprocket rpm and shaft diameter.
33
4. How to Select Chains
Figure 4.3 Hanging Transmission Where
Conveyed Objects Are Lifted or
Suspended at the End of Chains
Figure 4.5 Pin-Gear Drive Transmission
Figure 4.4 Shuttle Traction

Table 4.1 Multiple Strand Factor
Number of Multiple
Roller Chain Strands Strand Factor
2 1.7
3 2.5
4 3.3
5 3.9
6 4.6
34
Basics
6. Center distance between sprockets.
7. Noise constraints.
8. Lubrication (possible or not).
4.1.2 Coefficients Used in Selection
1. Multiple strand factor
In multiple strand power transmission chains, the loading is unequal
across the width of the chain, therefore, the transmission capability is not
a direct multiple of the number of chains. You must use a “multiple strand
factor,” which is shown in Table 4.1, to determine the correct value.
2. Service factor, Ks
The chain transmission capability is reduced if there are frequent or
severe load fluctuations. You must apply the appropriate factor based on
the type of machine or motors (Table 4.2).
Table 4.2 Service Factor
Source of Power
Internal Combustion
Engine
Electric With Without
Motor or Hydraulic Hydraulic
Type of Impact Machines Turbine Drive Drive
Smooth Belt conveyors with small load fluctuation, 1.0 1.0 1.2
chain conveyors, centrifugal blowers, ordinary
textile machines, ordinary machines with small
load fluctuation.
Some impact Centrifugal compressors, marine engines, 1.3 1.2 1.4
conveyors with some load fluctuation,
automatic furnaces, dryers, pulverizers,
general machine tools, compressors, general
work machines, general paper mills.
High impact Press, construction or mining machines, 1.5 1.4 1.7
vibration machines, oil-well rigs, rubber mixers,
rolls, general machines with reverse or
high-impact loads.

35
3. Chain speed coefficient, Kv; sprocket tooth coefficient, Kc
Adjust the transmission capability according to the chain speed and
number of teeth in the small sprocket (Figure 4.6). The sprocket
coefficient is labeled Kc.
4. Impact coefficient, K
This coefficient (Figure 4.7) is based on the inertia ratio of the driving
machine and driven machine (ratio of I, ratio of GD2) and the amount of
play in transmission equipment. When the inertia ratio is less than 0.2 or
greater than 10, use the value of 0.2 or 10, respectively.
Figure 4.7 Shock Factor (K)
Figure 4.6 Speed Factor (Kv) and Sprocket Factor (Kc)
Small-Sprocket Teeth
Chain speed (m/min)
Kv,Kc
Sprocket teeth factor Kc
Speed factor Kv
Hoist work
Shockfactor(K)
Hoist
Conveyor Mill
gang roll
fly foilInertia ratio (R)
crane travel and shuttle
For no backlash in transmission equipment, etc.
For backlash in transmission equipment
Motor shaft converted
inertia of load
R = ———————
Inertia of motor

5. Unbalanced load coefficient; Ku
When you use two or four chains in a hanging application or shuttle
traction setup, the tension of each chain is not equal. This must be
accounted for by using the coefficient found in Table 4.3. The example
assumes an unbalanced load ratio between two chains of 60/40 (percent)
[i.e., 60 + 40 = 100 percent].
4.1.3 Drive Chain Selection (General Selection)
A suitable chain selection may be made according to the flow chart Figure 4.8.
EXAMPLE: Select a transmission chain for the conditions shown in Figure 4.9.
Step 1. Confirm the operating conditions.
Step 2. Determine the service factor Ks as shown in Table 4.2. In this
example, the service factor is Ks = 1.3.
Step 3. Calculate the corrected design power kW = 1.3 ϫ 7.5 = 9.75 kW.
Step 4. Consult the selection table (Figure 4.10). For n = 50 rpm and
corrected power = 9.75 kW, you should initially select RS140 chain
and a 15-tooth drive sprocket. These are not the final selections.
See manufacturer’s catalog for additional information.
36
Basics
Figure 4.9 Operating Conditions for Example 4.1.3
Table 4.3 Unbalanced Load Factor (Ku)
Lifting Strands Factor
2 0.6
4 0.36
(i=1/30)
Type of Application: Drive of Belt Conveyor
Source of Power: Electric Motor 7.5 kW
Drive Shaft: Diameter 66 mm. 50 rpm
Driven Shaft: Diameter 94 mm. 20 rpm
Center Distance of Shafts: 1,500 mm
Starting Frequency: 4 times/day
Type of Impact: Some Impact
Reducer Ratio: 1/30
Center Distance
Drive
Roller Chain
Reducer
1,500

37
Figure 4.8 Chain Selection Procedure (General Selection)
Make N > 15T
for small sprockets
and N < 120T
for large sprockets.
Multi-strand factor (Table 4.1)
Tentatively select the chain size and
number of teeth N' for the small sprocket
from the provisional selection table
Fits in the distance
between shafts
Same size
increase in
number of teeth
Data required for selection
Obtain the design kW
1 size up
Calculate the chain length L
(number of links)
From the kW rating
table, kW rating of the selected
chain > design kW
Determine the method of lubrication from
rpm of the small sprocket
End
1 size down
1 strand up
Procedure 1
Procedure 2
Procedure 3
Procedures 4-5
Yes
Procedure 6
Procedure 7
Procedure 8
Service factor Ks
Same size
increase in
number of teeth
1 size up
Fitting on the maximum
shaft diameter
Chain and sprocket determined
No
Yes
No
Yes
No
Determine the number of teeth N for
the large sprocket from the speed ratio
=

38
Basics
Figure 4.10 RS Roller Chain Provisional Selection Table
Step 4a. Calculate the size of the driven sprocket. Number of teeth in
driven sprocket = 15 ϫ (50/20) = 37.5. Therefore, select a 38-tooth
driven sprocket.
Step 4b. Confirm that the chain meets the power requirements. According to
the power transmission tables in the catalog, an RS140 chain with a
15-tooth sprocket is capable of transmitting 11.3 kW. Because 11.3
kW is greater than the design power of 9.75 kW, it is acceptable.
Triple Double Single
Strand Strand Strand
DesignkWValue
Speed of the Small Sprocket (rpm)

39
Step 5. Confirm that you can set a 15-tooth sprocket and a 38-tooth sprocket
within the 1,500-mm center distance and still maintain clearance.
The maximum hub bores of each sprocket are 89 and 110,
respectively. Therefore, these may be used.
Step 6. Calculate L, the number of chain pitches.
C =
center distance
chain pitch
C =
1,500
44.45
= 33.746 (sprocket center distance, in pitches)
(N - N') (38 - 15)
(N + N') 6.28 (38 + 15) 6.28
L = ——-— + 2C + —--—-- = ———- + 2 ϫ 33.746 + ———
2 C 2 33.746
= 94.39 links
Because you can’t have fractions of links, choose the next highest
even number. In this example, you would use 96 pitches. The center
distance of the sprockets will then be 1,536 mm.
Step 7. Check the catalog and decide the appropriate type of lubrication
(manual or drip).
4.1.4 Power Transmission Chain Selection for Slow Speeds
This selection procedure is based on the maximum allowable tension, which
is used when the chain speed is less than 50 m/min., and the starting frequen-
cy is less than 5 times/day. The selection is done following the flow chart in
Figure 4.11.
EXAMPLE: Recalculate the previous example from Basics Section 4.1.3 based
upon the selection for slow speed.
Step 1. Tentatively select RS120 chain, which is one size smaller than RS140,
and a 15-tooth sprocket. Then calculate the chain speed.
V = PNn / 1,000 = (38.1 ϫ 15 ϫ 50)/ 1,000 = 28.6 m/min. < 50
According to this speed and starting frequency, case selection for
slow speed may be used.
Step 2. From the rated power of the motor, calculate the tension Fm
on the chain.
Fm = 60 ϫ kW / V = 60 ϫ 7.5 / 28.6 = 15.7 kN
Step 3. Service factor Ks = 1.3, Chain speed coefficient Kv = 1.06
(from the chain speed 28.6 m/min.).
Step 4. Sprocket tooth coefficient Kc = 1.27 (from 15-tooth sprocket).
Step 5. Calculate the design chain tension F'm.
F'm = Fm ϫ 1.3 ϫ 1.06 ϫ 1.27 = 27.5 kN
Step 6. Decide on the chain size.
(——)2
(——)2

40
Basics
Figure 4.11 Chain Selection Procedure (Slow Speed)
Make N' > 15T
Provisional selection of one size smaller
than that selected for chain and sprocket
N' from the provisional selection table
Knowing
the load Ft (actual load)
on the chain
Calculate the static
chain tension Fm on
the chain from the
rated kW of the
prime motor
Service factor Ks
Speed factor Kv
Sprocket teeth factor Kc
Calculation for design
chain tension Ft, F'm
F't (or F'm) < Max.
allowable tension
Determine the chain size
Determine the number of teeth N for the
large sprocket from the speed ratio i
Determine the chain and sprocket
Calculate the chain length L
(number of links)
Decide the method of lubrication
from the rpm
of the small sprocket
End
Reconsider
chain size
Distance between shafts and max.
shaft diameters have been confirmed
by general selection method.
Procedure 1
Procedure 2
Procedure 3
Procedure 4
Procedure 5
No
Yes
Procedure 6
Procedure 7
Procedure 8
No
Yes
=
=

41
According to the catalog, the maximum allowable load of RS120 is 30.4 kN.
Because this value is higher than the chain design tension determined in Step
5, RS120 may be used in this application.
Select the number of teeth in the large sprocket according to the speed ratio,
using the same procedure as in the general selection.
Confirm the chain and the sprocket: driving sprocket is RS120-15T (maxi-
mum hub bore is 80 mm, and the shaft diameter is 66 mm; therefore, this may
be used), and driven sprocket is RS120-38T (maximum hub bore is not shown
in catalogs). Therefore, consult with the manufacturer and determine that the
38-tooth sprocket will accommodate a 94-mm shaft.
Step 7. Calculate the chain length (number of links).
C =
1,500
38.10
= 39.37 mm
(N - N') (38 - 15)
(N + N') 6.28 (38 + 15) 6.28
L = ——-— + 2C + ——- = ———- + 2 ϫ 39.37 + ———
2 C 2 39.37
= 105.58 links
Therefore, use 106 links. Center distance = 1,508 mm.
Step 8. Check the manufacturer’s catalog to determine the necessary type of
lubrication (manual or drip).
As you see, this selection allows you to choose a smaller and more
economical chain than the general selection. But, at the same time, consider
these facts:
• Do not use offset links or normal connecting links for slow speeds. Use
tap fit connecting links, which have a tight interference fit. If you
want to use offset links or normal connecting links, check the strength
derating shown in Basics Section 2.2.3 and recalculate.
• Cast-iron sprockets are not strong enough for slow speeds. Therefore,
use SS400, S35C, S45C, etc.
• Use a hardened-tooth sprocket for the high-speed sprocket.
• The bearing pressure on the chain will be very high, so lubricate the
chain well.
4.1.5 Hanging Transmission Chain Selection
Calculate the chain tension on both the load side and the driving side, and
select a chain with a suitable maximum allowable tension to satisfy the
requirements. The points of notice are shown below.
• If there are any laws or guidelines for chain selection, check and calculate
accordingly. Make sure to follow the manufacturer’s selections, and select
the safer one of the two selections.
( ——)2
( —--—)2

42
Basics
Figure 4.12 Typical Configurations for Hanging Chain
• The chain speed should be less than 50 m/min. If it is more than
50 m/min., consult the manufacturer.
• Use tap fit connecting links that have a tight interference fit.
When you want to use normal connecting links or offset links, you
must apply the appropriate derating value (Basics Section 2.2.3) to
the chain strength.
• Lubricate the chain joints as much as possible after you reduce the loads.
Lubrication is also required at terminal connections, etc.
• Make sure to follow proper safety procedures, including:
a. Be sure that no one is under the suspended objects.
b. Install a reliable safety guard to avoid damage in the event
of chain failure.
c. Examine chains regularly, and replace when necessary.
Figure 4.12 shows some common examples of hanging use. Selection is
done according to the flow chart in Figure 4.13.
Counterweight
Counterweight
End
Fittings
Roller Chains
Roller Chains
Roller Chains
End Fittings
End Fittings
End Fittings
Fork
End Fittings
Roller
Chains
Reducer
Reducer
Reducer

43
Figure 4.13 Chain Selection Procedure (Hanging Chain)
Starting torque: Ts Stalling torque: Tb
Calculate the
chain tension Fs
Calculate the
chain tension Fb
Time for
acceleration ts
Time for
deceleration tb
Choose larger value
Sprocket tooth factor: Kc
Speed factor: Kv
Calculate the design
chain tension F's (or F'b)
Calculate the
chain tension Fms
Calculate the
chain tension Fmb
Choose larger value
chain tension
F'ms (or F'mb)
Choose larger value
Determine the chain size where a large
tension for F'w, F'ms (or F'mb),
F's (or F'b), < Max. allowable.
Determine the small sprocket N',
large sprocket N
Confirm the distance between shafts
Confirm that the sprockets fit the shafts.
Determine the chain and sprocket
Calculate the chain length (number of links)
Determine the lubrication method from
the rpm of the small sprocket End
From the time for
acceleration, deceleration
From inertia ratio R
Shock factor: K
Calculate the chain tension from the motorCalculate the chain tension from the load
Confirm the mass M
(Weight W) of the load
chain tension F'w
Sprocket tooth factor: Kc
Speed factor: Kv
Service factor: Ks
Confirmation of the
motor characteristics
Frequency: 5 times/day,
(more than 8 hours)
No
Yes
Data required
Unbalance coefficient Ku
=

44
Basics
EXAMPLE: You are planning to use a hanging transmission machine like the
one shown in Figure 4.14. Determine if you can use SUPER120 for hanging
and SUPER100 for the drive chain. The power source is a 3.7-kW motor (with
brake). The motor shaft rotational speed is 1,500 rpm.
Step 1. Check the motor characteristics.
Rated torque: Tn = 0.038 kN • m
Starting torque: Ts = 0.083 kN • m
Braking torque: Tb = 0.096 kN • m
Motor moment of inertia: Im = 0.015 kN • m
Step 2. Calculate the chain tension based on load.
The chain tension Fw = M = 3,000 ϫ 9.80665 ϫ 10-3 = 29.4 kN
Service factor Ks = 1.3 (with some shock)
The chain speed coefficient Kv = 1.02 (from the chain speed 6.2 m/min.)
Coefficient for number of sprocket teeth Kc = 1.28 (14-tooth sprocket)
Coefficient of unbalanced load Ku = 0.6 (two sets of chains)
Determine the chain design tension
F'w = Fw ϫ Ks ϫ Kv ϫ Kc ϫ Ku
= 29.4 ϫ 1.3 ϫ 1.02 ϫ 1.28 ϫ 0.6 = 29.9 kN
Step 3. Calculate the chain tension based on the motor loading. Calculate
moment of inertia of motor shaft.
I = M ϫ
V
= 3,000 ϫ
6.2
= 0.0013 kg • m2
2πn1 2 ϫ π ϫ 1,500
Moment of inertia of motor Im = 0.015 kg • m2
Inertia ratio R = I / Im = 0.087
Figure 4.14 Example of a Hanging Chain Machine
( )
2
( )
2
Speed Reducer (i=1:60)
Motor with brake
Roller Chain: SUPER 1OO
Spocket: NT14
(PCD: 171.22)
Roller Chain: SUPER 120
(Chain Speed=6.2 m/min.)
Sprocket: NT14
(PCD: 171.22)
Sprocket: NT14
(PCD: 142.68)
Sprocket: NT30
(PCD: 303.75)
M=3,000kg
{W=3,000kgf}

45
When there is no play in the system, the coefficient of shock K = 0.23
(Figure 4.7). The chain tension from the starting torque:
Fms = Ts ϫi ϫ
30
ϫ 1,000 / (d /2)
14
= 0.083 ϫ 60 ϫ
30
ϫ 1,000 /(171.22 /2) = 124.7 kN
14
The chain tension calculated from the braking torque:
Fmb = Tb ϫi ϫ
30
ϫ1,000 ϫ1.2 /(d /2)
14
= 0.096 ϫ 60 ϫ
30
ϫ 1,000 ϫ 1.2 /(171.22 /2) = 173.0 kN
14
Use the larger value (in this case it is Fmb) to calculate chain tension.
F'mb = Fmb ϫ Kv ϫ Kc ϫ Ku ϫ K
= 173.0 ϫ 1.02 ϫ 1.28 ϫ 0.6 ϫ 0.23 = 31.2 kN
Step 4. Calculate the chain tension from motor acceleration and deceleration.
Working torque Tm =
(Ts + Tb)
=
(0.083 + 0.096)
= 0.0895 kN • m
2 2
Load torque TL =
M ϫ d
ϫ
g
(2 ϫ 1,000 ϫ i) 1,000
=
(3,000 ϫ 171.22)
ϫ
g
= 0.02 kN • m
2 ϫ 1,000 ϫ 60 ϫ
30 1,000
14
Motor acceleration time ts =
(Im + Il) ϫ n1
ϫ
g
ϫ 4
375 ϫ (Tm - Tl) 1,000
=
(0.015 + 0.00130) ϫ 1,500
ϫ
g
ϫ 4 = 0.037s
375 ϫ (0.0895 - 0.02) 1,000
Motor deceleration time tb =
(Im + Il) ϫ n1
ϫ
g
ϫ 4
375 ϫ (Tm + Tl) 1,000
=
(0.015 + 0.00130) ϫ 1,500
ϫ
g
ϫ 4 = 0.023s
375 ϫ (0.0895 + 0.02) 1,000
Because tb is smaller than ts, the chain tension due to motor deceleration Fb is
greater than that of the acceleration.
Fb =
M ϫ V
+ Fw =
3,000 ϫ 6.2
+ 29.4 = 42.9 kN
tb ϫ 60 ϫ 1,000 0.023 ϫ 60 ϫ 1,000

46
Basics
Therefore, the chain design tension:
F'b = Fb ϫ Kv ϫ Kc ϫ Ku = 42.9 ϫ 1.02 ϫ 1.28 ϫ 0.6 = 33.6 kN
When comparing the calculated chain tensions in Steps 2, 3, and 4, note that
F'b in Step 4 is the greatest. In this tension, Ku is already counted. Comparing
F’b with the maximum allowable tension of SUPER 120 chain, F'b < 39.2 kN.
Therefore, this chain may be selected.
The example shown above is for chain in hanging drives. The maximum ten-
sion on the wrapping transmission chains is:
F'b ϫ d / d' = 33.6 ϫ 171.22 / 303.75 = 18.9 kN
This value is less than the maximum allowable tension of SUPER 100 chain,
which is 30.4 kN. Therefore, this chain is acceptable.
Other Important Considerations
NOTE 1: If there are laws or regulations for chain selection, you must take
them into account. For example, if the safety guideline says, “Safety factor
must be greater than 10:1 compared with the minimum tensile strength,”
then you should design the equipment as shown above, and consider
the following:
For hanging drive chain:
Minimum tensile strength
= M ϫ g ϫ Ku ϫ 10 = 3,000 ϫ (9.80665 ϫ 10-3) ϫ 0.6 ϫ 10 = 176.5 kN
But the minimum tensile strength of SUPER 120 chain is only 124.6 kN,
which is not enough to meet this requirement. Instead, select SUPER 140
chain (213 kN).
Wrapping transmission chain requires more than 99.5 kN of minimum tensile
strength, therefore you may select SUPER 100 chain (111 kN).
Regulations are not always safer than manufacturer’s suggested selection pro-
cedure. Choose the safest system possible.
NOTE 2: If a load greater than the motor braking torque very 48 occasionally
occurs, the chains will be subjected to the following loads:
Wrapping transmission chain:
Fd =
0.096 ϫ 1,000 ϫ 60 ϫ 2
ϫ 0.6 = 48.4 kN
142.68
Hanging drive chain:
48.4 ϫ
303.75
= 85.9 kN
171.22
To avoid chain plastic deformation, the minimum tensile strength must be
more than twice these loads (see Basics Section 2.1.1), therefore, you should
select SUPER 100 chain and SUPER 160 chain.

47
Figure 4.15 Chain Selection Procedure (Conveyor)
4.2 CONVEYOR CHAIN SELECTION
There are five types of conveyor chains:
a. Small pitch conveyor chain.
b.Precision conveyor chain.
c. Top chain.
d.Free flow chain.
e. Large pitch conveyor chain.
To select any of these chains, use the
procedure outlined in the flow chart
(Figure 4.15). Chain tension is calculated
based on the load size.
In these five types, because often the
objects conveyed on small pitch conveyor
chains, precision conveyor chains, and
top chains are light, sometimes you don’t
have to check “allowable roller load.”
Also, attachments are not usually installed
on top chains and free flow chains, there-
fore, you don’t need to check the attach-
ment allowable load.
4.2.1 Check of Conditions for Selection
You should check the items shown
below:
1. Application conditions: application
environment, indoor or outdoor,
temperature, existence of foreign
objects.
2. Conveyed objects: type (unit
materials, bulk materials), abrasive,
corrosive, temperature (high or
low), dimension (for unit material),
weight (unit material kg/unit; bulk
material kg/m3).
3. Maximum conveyance volume
(unit materials, kg/conveyor length;
bulk materials, tons/hour).
4. Method of conveyance: pushing
with dog attachments, conveyed
objects placed directly on the
chains, etc.
Identify conveyor specifications
Conveyor types
Chain specifications
Roller type
Chain pitch
Number of sprocket teeth
Type of attachment
Calculate chain tension
Chain size
Check allowable load for roller
Check allowable load for attachment
Other special requirements, if any
END
No
No
Yes
Yes

48
Basics
5. Length of the conveyor, shaft center distance, vertical rise, general layout.
6. The chain speed (m/min.).
7. Number of the chain strands, interval length.
8. The chain pitch, attachment spacing and type.
9. The number of sprocket teeth, or pitch diameter.
10. Working hours (hours/day, hours/year).
11. Lubrication.
12. Motor: AC or DC, kW ϫ number of motors.
13. Noise: If there is any noise constraint, use a larger number of sprocket
teeth. Consult the manufacturer.
Some Additional Thoughts
You can make your decision on point 4 after reviewing the points in Basics
Section 4.2.2, Conveyor Type Selection. Make sure to follow the procedure
carefully.
Point 7 is more difficult to determine than it looks; the materials being con-
veyed impact the decision. Because the chain sizes and configuration may
change as the design is developed, you must consider this point carefully.
Consider these examples:
• If you convey fixed-sized pallets directly on chain, you usually need two
sets of chains. But if the pallet is not rigid enough, you should include a
third chain between the two outer chains.
• If you convey different-sized pipes or similar items directly on chain, you
must consider the shortest length so that at least two chains are supporting
the product on line, and determine the appropriate number of chains so
that the chains are equally loaded.
Points 8, 9, and 12 may be revised as you proceed with the selection process
since the chain sizes are usually determined by roller load, so make a prelimi-
nary selection first.
4.2.2 Conveyor Type Selection
According to conveyed object type (unit or bulk materials), typical chain
conveyor types are sorted as shown on the next page. Therefore, you should
choose the formation from among these.
In Figure 4.16, the available chain types are abbreviated below. These abbre-
viations mean:
RF: Double pitch roller chain, RF conveyor chain. Plastic roller and plastic
sleeve chain may be used to convey unit materials.
RS: RS attachment chain
RF-B: RF bearing roller conveyor chain
RFN: Bearing bush chain
RFD: Deep link chain
VR: DOUBLE PLUS®
chain

49
Figure 4.16 Types of Conveyor Chains
Material Conveyed
Unit
Conveyor
Types
Slat Conveyor Apron Conveyor
Pusher Conveyor, Tow
Conveyor, Roller Coaster
LoadingElevating
PushingorConveying
withFriction
Free Flow Conveyor
Plain Chain Conveyor
Trolley Conveyor
Tray Elevator
Tower Parking
Pusher Conveyor
Horizontal Circulating
Conveyor
Flow Conveyor
Scraper/Flight
Conveyor
Bucket Elevator
Bucket-Type
Continuous
Unloader
Type of
Chain
Bulk
Type of
Chain
RF-B
RFN
RF
(CT)
RF
RFN
NF
RF-SR
RF
RF-VR
RF-TR
RF-SR
RF
NF
EPC
RFD
RF RF
RFN
RF
NF Special
Chain
Special
Chain
RF
NF
RFD
RF
RF
RFN
RF
NFX

TR: Top roller chain
SR: Outboard roller chain
TP: Top chain
NF: Block chain (bar and pin)
NFX: Block chain—flow conveyor type
See Applications Section for details of these chains.
4.2.3 Selection of Chain Type and Specification
A conveyor design can use a variety of chains, depending on the type of
operation, conditions, and material conveyed. Here we present a few points of
notice about selection.
1. Consider RF, RS, or TP chain first. Typical applications are outlined in
Table 4.4.
2. If there are no special temperature or environment concerns, and if the
chain is not subject to rough usage, you can use plastic roller or RF-B
chain. This reduces the amount of friction.
3. When you require accurate stopping location or must avoid chain
elongation, select RFN.
4. NF is suitable for rough use and for conveyance of high-temperature
objects.
4.2.4 Points of Notice About Roller Type
Figure 4.17 shows the roller types and ways of guiding used in conveyor
chains.
1. First of all, consider if an R-roller will meet the operating conditions.
2. An S-roller is designed to relieve shock caused by sprocket engagement,
but when the conveyed objects are light and the conveyor length is short,
an S-roller may be used.
3. An F-roller is used primarily to prevent snaking in large pitch conveyor
chains. Because its flange operates and wears against the side rail, it is not
the roller of choice to convey heavy objects or bulk material or to operate
at high speeds.
50
Basics
Table 4.4 Determination by Usage
Roller Center Conveyed Material
Type of Chain Pitch Type Distance Weight Size Rigidity
RS Attachment Chain Short S Short Light Small Low
RF Double Pitch Chain Medium R • S Medium Light Small ~ Medium Mid
RF Conveyor Chain Long R• F • S Long Medium ~ Heavy Medium ~ Large High
Table Top Chain Medium N/A Medium Light Small ~ Medium Low

51
4.2.5 Chain Pitch Decision
There is only one pitch for any given small pitch conveyor chain, double
pitch roller chain, and RS attachment chain. Therefore, if you decide on the
chain size according to strength, you must also determine the chain pitch at
the same time. Chain pitch is measured in inches.
There are a couple of chain pitches for each size of large pitch RF conveyor
chain. You must first choose the right size, then select the chain pitch. Large
pitch chain is measured in millimeters.
The spacing of conveyed objects and the relationship between the sprocket
diameter and amount of available space can impact the chain-pitch decision.
For example, when pushing unit materials with a pusher at intervals of 2 m,
you must select a chain pitch that is a multiple: 50, 100, 200, 250, 500 mm.
In general, here is how larger pitch chain compares to smaller pitch chain:
1. Larger pitch chain costs less.
2. Attachments on larger pitch chain are stronger.
3. Because of the decrease in the number of teeth in the sprockets,
chordal action is greater.
4. Larger pitch chain systems tend to be noisier.
5. The pin and the bushings of larger pitch chain wear faster.
4.2.6 Deciding the Number of Sprocket Teeth
The number of sprocket teeth is limited by the chain pitch and the chain
speed (Figure 4.18). If noise is a consideration, consult the manufacturer.
Figure 4.17 Conveyor Rollers and Guiding Mechanisms
R-Roller
S-M-N-Roller
F-Roller
Flange
T-Pin

4.2.7 Deciding the Attachment Type
See the chapters on standard, Plus α Alpha, and special attachments in the
Applications Section.
4.2.8 Calculation of Tension
Here we have an example to determine the tension in a horizontal conveyor
and free flow conveyor.
Terms
Tmax: Maximum chain tension (kN).
T: Static chain tension at each part of conveyor (kN).
Q: Maximum weight of conveyed objects (t/h).
V: Conveying speed (the chain speed). (m/min.).
H: Vertical center distance between sprockets (m).
L: Horizontal center distance between sprockets (m).
C: Center distance between sprockets (m).
m: Mass of the working portion of the chain (kg/m). The mass of the
chain ϫ number of the chain strands, bucket, apron, etc.
52
Basics
Figure 4.18 Chain Pitch Versus Allowable Speed
AllowableSpeed(m/min.)
N: Number
of Teeth
Chain Pitch (mm)

M: Mass of the conveyed object in conveying section (kg/m).
f1: Coefficient of friction between the chain and the guide rail
when conveying.
f2: Coefficient of friction between the chain and the conveyed objects
in the accumulating section.
4.2.8.1 Horizontal Conveyor
T1 = 1.35 ϫ m ϫ L1 ϫ
g
(kN)
1,000
T2 = (L - L1) ϫ m ϫ f1 ϫ
g
+ T1 (kN)
1,000
T3 = 1.1 ϫ T2 (kN)
Tmax = (M + m) ϫ L ϫ f1 ϫ
g
+ T3 (kN)
1,000
4.2.8.2 Free Flow Conveyor
Tmax = 2.1 ϫ m ϫ (L1 + L2) ϫ f1 ϫ
g
+ M ϫ L1 ϫ f1
1,000
ϫ
g
+ M1 ϫ L2 ϫ f2 ϫ
g
(kN)
1,000 1,000
L1: Length of conveying portion (m).
L2: Length of accumulating portion (m).
M1: Weight of conveyed objects in accumulating portion (kg/m).
Table 4.5 shows the allowable carrying load for each size of large pitch
conveyor chain when it is used in horizontal conveyance.
53
Figure 4.19 Horizontal Conveyor
Figure 4.20 Free Flow Conveyor
Accumulating PortionConveying Portion

54
Basics
4.2.9 Allowable Load of Roller and Standard A Attachment
There are two kinds of allowable roller load: one is caused by load weight
(Figure 4.21); the other by corner rail (Figure 4.22).
Figure 4.21 Allowable Load Caused by
Load Weight
Figure 4.22 Allowable Load Caused by Corner Rail
Table 4.5 Allowable Conveyed Loads for Selected Conveyor Chains
units: kg/strand of chain
Allowable Conveyed Load
Conveyor Chain Size RF Conveyor Chain Bearing Roller Chain
RF03 5,400 14,000
RF05 12,500 33,300
RF08 • 450 14,300 36,700
RF10 20,500 53,300
RF12 33,900 90,000
RF17 44,600 116,700
RF26 57,100 150,000
RF36 86,600 230,000
RF60 91,100 -
RF90 143,800 -
RF120 201,800 -
NOTE: Calculated for horizontal conveyor. Safety factor = 7; Coefficient of rolling friction for RF type = 0.08, for
bearing roller type = 0.03
Load
Roller Load
Corner Rail
Roller Load
Roller Load

55
Each manufacturer’s catalog shows the allowable roller load, according to
each roller type and design. Check the appropriate catalogs.
NOTE: The values listed for bearing roller chain and plastic roller
chain are for unlubricated operation; the values for other types of
chain are for lubricated conditions.
On the standard A attachment, bending load occurs from the carried load.
Twisting forces may also occur, depending on the direction of the load. The
manufacturer’s catalog shows the allowable load for bending load.
4.3 SELECTION EXAMPLE
Now that we’ve covered the procedures you need to follow to choose a
conveyor chain, let’s complete an example.
Your assignment: Select a suitable chain for the conditions shown
in Figure 4.23.
1. Operating conditions (Figure 4.23). In addition, note the following:
• The conveyed object is steel pipe supported on a plate.
• The system operates in a clean environment.
• The environment and conveyed objects are at ambient temperature.
• The chain can be lubricated.
2. The chain conveyor type: loading on slat conveyor.
3. The chain type: check both RF and RF-B types.
4. The roller type: R-roller.
5. The chain pitch: 250 mm.
6. The number of sprocket teeth: based on the chain pitch and the
chain speed, select six teeth.
7. The attachment type: A-2.
8. Determine the chain size from the tension.
In this example, two sets of chain convey 80,000 kg. Therefore, each of the
selected chains must be able to carry more than 40,000 kg per one set.
Table 4.5 shows you that either RF17 (general series) or RF10-B are acceptable.
NOTE: We are ignoring the dynamic tension of starting and stopping to
make the example easier to understand.
9. The allowable roller load.
Chain pitch is 250 mm and the length of the conveyed object is 1,000 mm.
Object length /pitch = the number of rollers under the conveyed object.
1,000 /250 = 4 rollers
If we use two sets of chain, there are eight rollers under one conveyed
object. If the steel pipes on the plate are not carried equally, uneven load
occurs on the roller. In this process, we presume that only four rollers share
the load.
The roller’s load = (2,000 ϫ g) / 4 = 4,900 N = 4.9 kN
According to the catalog, either RF26 (standard series) or RF12-B (roller bear-
ing) may be selected.

56
Basics
10. The allowable load of standard A attachment.
There are eight A attachments under each pallet. Assume that four
attachments receive the load equally. The load on the A attachments
= 4,900 N. According to the catalogs, RF12 (basic series) or stronger
is acceptable.
11. Taking into account the tension, the allowable roller load, and the
allowable load for standard A attachments, RF26250-R (general series)
or RF12250-BR (roller bearing) may be selected.
12. Motor size.
Motor (kW) =
T ϫ V
ϫ
1
(␩ = 0.85 motor efficiency)
54.5 ␩
When using bearing roller conveyor chain, f1 = 0.03.
T = 2,000 kg ϫ
g
ϫ 40 pieces ϫ 0.03 = 23.5 kN {2,400 kgf}
1,000
kW =
23.5 ϫ 10
ϫ
1
= 5.1 kW
54.5 0.85
When using RF series conveyor chain, f1 = 0.08.
T = 2,000 kg ϫ
g
ϫ 40 pieces ϫ 0.08 = 62.8 kN {6,400 kgf}
1,000
kW =
62.8 ϫ 10
ϫ
1
= 13.6 kW
54.5 0.85
The process is straightforward and logical. And you can see that a bear-
ing roller conveyor chain, because it has lower friction, allows you to use a
smaller chain and a smaller motor.
Figure 4.23 Parameters for Example Selection Process
Double Strand Conveyor
Conveyor Length: 50m Chain Speed: 10m/min.
Weight of Conveyed Material: 2,000kg/pc x 40pcs
Chain: P=250mm R–Roller A-2 Attachment
1,000
50m

85
1. TRANSMISSION CHAINS
Power transmission chains are classified into six major groups.
1.1 Standard Roller Chains. These chains are designed for
general usage.
1.2 High Performance Chains. These chains have higher tensile
strength and greater fatigue strength.
1.3 Lube-Free Chains. These chains have longer wear life than
standard chains without lubrication.
1.4 Environmentally Resistant Chains. Chains with special
corrosion resistance.
1.5 Specialty Chains, Type 1. For specific applications.
1.6 Specialty Chains, Type 2. For general designs.
Within these six groups, there are many types of chains available
(Figure 1.1). In the following sections, we will discuss the various types.
Figure 1.1 Power Transmission Chains

86
Applications
1.1 STANDARD ROLLER CHAINS
1.1.1 ANSI Roller Chains (RS)
Transmission: General usage
Application Example
Power transmission chains are widely used throughout the world in a variety
of applications, including drive, tension, shuttle traction, and transmission
reduction operations. Because of this widespread usage, certain international
standards are set to ensure that pitch, width, and other key characteristics of
chains and sprockets are standardized. In the United States, power transmis-
sion chains must meet ANSI B29.1, thus earning the name ANSI chains. In
other countries, the chains must meet JIS B1801, ISO 606A, or ISO 1395C.
Construction and Features
(1) ANSI Roller Chains have the same shape and construction as the chain
shown in Basics Section 1.1.1. There are 14 sizes of roller chains regulat-
ed by ANSI. For easy reference, these are numbered 25, 35, 41, 40, 50,
60, 80, 100, 120, 140, 160, 180, 200, and 240. Some manufacturers
include chain numbers 320 and 400 to the list of standardized chains.
(2) Chains with a “5” on the right-hand digit of the chain number are
bushing chains. Bushing chains do not have rollers.
(3) Number 41 chain is a narrow variation of number 40.
(4) This chain number indicates the chain pitch. Here’s how to decipher the
pitch from the chain number. The numbers to the left of the right-hand
digit refer to the chain pitch in eighths of an inch. To calculate the pitch,
multiply the number by 3.175 mm. For example: 140 = 14 ϫ 3.175
= 44.45 mm pitch, or 14/8 = 1.75 inches.
(5) Each manufacturer adds its own identification stamp prior to the chain
number. For Tsubaki, “RS” is the identifier (for example, RS80, RS100).
The use of “RS” as an identifier has spread widely; it has become
the standard symbol for power transmission roller chains.
(6) There are smaller chains available. Refer to the “Miniature Chain” Section
in this book for information on sizes smaller than number 25.
Sprockets
Various sprockets are produced for each size of RS Roller Chain. Sprockets
are identified by the type of base material used in manufacture and by the
bore. Here are some basic types:

87
1. Transmission Chains
(1) Carbon steel sprockets with plain bores. (Sintered metal or cast iron are
sometimes used.)
(2) Carbon steel sprockets with finished bores, keyway, and setscrews.
TAPER-LOCK®
and QD®
bores are also available.
(3) 304 stainless steel sprockets with plain bores.
(4) Engineered plastic sprockets with plain bores.
(5) POWER-LOCK®
sprockets, which do not require a keyway or setscrew.
Selection and Handling
See Chapters 4 through 7 in the Basics Section.
1.1.2 BS/DIN Roller Chain
Transmission: General usage
Application Example
BS/DIN power transmission chains are regulated by international standards
(ISO 606B) and are used primarily in Europe. In Japan and the United States,
BS/DIN chains are used in transmission equipment imported from European
countries or for licensed production.
Compared to the same-sized ANSI Roller Chains, the power ratings of
BS/DIN chains in drive applications (tent curve) are a little lower (Table 1.1).
Table 1.1 Power Ratings for Standard ANSI and BS/DIN Roller Chains
Pitch Number of RPM Power
Chain No. (mm) Sprocket Teeth (rev./min.) Rating (kW)
RS80 25.4 19 500 24.1
RS16B 25.4 19 500 22.0
RS160 50.8 19 500 76.1
RS32B 50.8 19 500 70.0
TAPER-LOCK ®
is a registered trademark of Reliance Electric Company. QD®
is a registered trademark of and is used under
license from Emerson Electric Company.

88
Applications
1.2 HIGH PERFORMANCE CHAINS
These are enhanced types of ANSI Roller Chain (RS) in average tensile
strength and/or fatigue resistance. Each chain has different features. Figure 1.2
shows the general relationship of high performance chains to ANSI Standard
Roller Chain.
NOTE: The multipliers shown in Figure 1.2 compare high performance
chain to RS Roller Chain. The comparisons are between products of
Tsubaki. You may find the ratio varies by chain size or manufacturer.
Refer to a specific manufacturer’s catalog for details.
Figure 1.2 Increasing Fatigue Strength and Tensile Strength of Roller Chains
ANSI RS ROLLER CHAINS
FATIGUE STRENGTH
x 1.1
x 1.2 x 1.2
x 1.1
x 1.3
▼
▼
x 1.4
x 1.55
x 1.45
AVERAGE
TENSILE
STRENGTH
RS-HT ROLLER CHAINS
SUPER ROLLER CHAINS
SUPER-H ROLLER CHAINS
ULTRA SUPER ROLLER CHAINS

89
1.2.1 Super Roller Chain
High performance: General uses
Application Example
Super Roller Chains are generally used in compact drives because they have
high maximum allowable tension. (See Figure 1.3.)
Super Roller Chains are constructed for added fatigue strength (Table 1.2).
In addition, there are several characteristics that distinguish Super Roller
Chains.
(1) Appearance
• The plate shape is almost flat.
• Quad-staked riveting on the pin helps hold the link plate.
• The roller is seamless, not curled.
(2) Construction
• The pins are made of through hardened steel, which provides
toughness rather than surface hardness.
• The link plate holes are ball drifted. This process involves pressing a
steel ball through the hole of the link plate. The steel ball is slightly
larger than the diameter of the hole, which creates residual
compressive stress.
Figure 1.3 Super Roller Chain
Table 1.2 Super Roller Chain Compared to ANSI Standard Roller Chain
Average Maximum
Tensile Strength Allowable Load
RS100 118 kN 22.6 kN
SUPER 100 127 kN 30.4 kN
Ratio 1.08 1.35

90
Applications
• Connecting link plates are press fit to maintain the higher fatigue
resistance.
• The middle link plates of multiple strand chain’s connecting link are
not press fit. They are specially constructed for higher fatigue strength.
• Connecting links are fitted with high-strength spring pins.
Because of these features, Super Roller Chains offer higher maximum allow-
able tension, greater tensile strength, and increased shock resistance. Table 1.2
shows a comparison between Number 100 Super Roller Chain and Standard
Roller Chain. Number 100 Super Roller Chain performs at the same level as
RS120. Both have a maximum allowable tension of 30.4 kN.
Sprockets
High performance chain usually requires carbon steel sprockets. Cast iron
sprockets with few teeth may lack adequate strength. Steel sprockets are avail-
able for single or multiple strand. Check the keyway strength of the sprockets
before ordering to make sure they provide enough strength.
Super Roller Chains are available in sizes 80 through 240. Smaller
chains (≤60), stainless steel chains, and offset links are not available in Super
Roller Chain.
When installing Super Roller Chain, do not use the connecting link from
Standard Roller Chain. Only special press fit connecting links should be used
with Super Roller Chains.
Super Roller Chains are susceptible to wear and elongation. Therefore, it is
very important to provide proper lubrication. (Refer to manufacturer’s catalog
for details.)

91
1.2.2 Super-H Roller Chain
Heavy transmission
Application Example
Super-H Roller Chains are used in compact and heavy drives. (See Figure 1.4.)
They have greater maximum allowable load, increased tensile strength, and
smaller elastic elongation compared to the same-sized RS Roller Chain.
The link plates on Super-H Roller Chain are thicker. In fact, the thickness of
the link plate is the same as the next-larger-sized Super Roller Chains.
Table 1.3 compares data on number 100 chains.
Figure 1.4 Super-H Roller Chain
Table 1.3 Super-H Roller Chain Compared to ANSI Standard Roller Chain
Average Maximum
Tensile Strength Allowable Load
RS100 118 kN 22.6 kN
SUPER 100-H 145 kN 32.4 kN
Ratio 1.23 1.43

1.2.3 RS-HT Roller Chain
Heavy transmission: Construction machines, agriculture machines, and ten-
sion applications
Application Example
RS-HT Roller Chains have higher tensile strength and less elastic elongation
in comparison with RS Roller Chains. These characteristics are good for “lift-
ing” applications (at low cycles), construction machines, and agriculture equip-
ment (Figure 1.5).
Compared with RS Roller Chains, RS-HT Roller Chains have the features
shown below and in Table 1.4.
Appearance
(1) Link plate thickness is equal to the next-larger chain.
(2) Quad-staked riveting on the pin head helps hold the link plate
on the pin.
(3) Rollers are seamless, not curled.
92
Applications
Figure 1.5 RS-HT Roller Chain
Table 1.4 RS-HT Roller Chain Compared to ANSI Standard Roller Chain
Average Maximum
Tensile Allowable
Strength Load
RS100 118 kN 22.6 kN
RS100-HT 142 kN 24.5 kN
Ratio 1.20 1.08

1.2.4 Ultra Super Chain
Super-heavy transmission
Application Example
Ultra Super Chain has the highest tensile strength and greatest allowable ten-
sion of any chain that can mate with a standard sprocket. These features also
allow the drive train of the equipment to be smaller. (See Figure 1.6.)
Ultra Super Chains have the same chain pitch, roller diameter, and width
between inner link plates as ANSI Standard Chain. However, the link plate
thickness is the same as the next-larger chain. The pin diameter is larger than
ANSI Standard Chains. Table 1.5 compares RS100 Roller Chain and 100 Ultra
Super Chain. In this chain series, both the average tensile strength and maxi-
mum allowable tension are increased, even over Super-H Chains. Number 100
Ultra Super Chains have the same maximum tension as RS140, which is two
sizes larger.
Sprockets
See “Super Roller Chain” Section.
(1) Choose these chains using the guidelines for low-speed selection.
(2) Ultra Super Chain is available in sizes 100 through 240.
(Number 180 is not available.)
93
Figure 1.6 Ultra Super Roller Chain
Table 1.5 Comparison of ANSI Standard Chain (RS) with Ultra Super Chain (US)
Average Maximum
Tensile Allowable
Strength Load
RS100 118 kN 22.6 kN
US100 172 kN 39.2 kN
Ratio 1.45 1.73

94
Applications
(3) Ultra Super Chain is not available in multiple strand.
(4) Due to the hardness of plates being higher than other carbon steel roller
chains, Ultra Super Chains have a greater risk of hydrogen embrittlement.
Other points of notice are the same as Super-H Roller Chain.
1.3 LUBE-FREE CHAINS
1.3.1 LAMBDA®
Roller Chain
Transmission and conveyor: Lube-free type, drive transmission
Application Example
LAMBDA Roller Chains do not require additional lubrication. This makes
them ideal for “clean” applications like final assembly areas, paper production,
and other operations where lubrication could affect the product on line.
LAMBDA Roller Chains are available in drive or conveyor styles.
(See Figure 1.7.)
LAMBDA Roller Chains are designed for long wear life without additional
lubrication. The bushings are made of oil-impregnated sintered metal, and the
pins are specially coated. LAMBDA Roller Chains also have rollers, which
make them different from other lube-free chains. (The SL series, for example,
does not have rollers.)
The features of LAMBDA Roller Chains are as follows:
(1) LAMBDA Roller Chains outlast Standard Roller Chains without lubrication
up to 30 times longer at low speed (about 25 m/min.) and seven times longer
at medium speed (about 127 m/min.). (See Figure 1.8.)
Figure 1.7 LAMBDA®
Lube-Free Chain
Specially coated pin
Oil impregnated sintered bushing
Roller

95
Figure 1.8 Comparison of LAMBDA®
Chains and Other Chains
Lub
e-FreeChain
fosdnarBrehtO
SteelRollerChain
Steel R
ollerChain
Other Brands of Sealed
Chain
Lube-Free Chain
Λ (LAMBDA Chain)
Λ(LAMBDA Chain)
LowWear Elongation LAMBDA®
Chain
0.5%
0
Wear
Elongation
0.5%
0
25
m/min.
Low
Speed
127
m/min.
Medium
Speed
Wear
Elongation
SealedChain
(2) The rollers on LAMBDA®
Roller Chain engage the sprocket more
smoothly, reducing power loss.
(3) LAMBDA Roller Chains have the same transmission capacity as
equivalently sized ANSI Roller Chains at speeds of 150 m/min. or less.
(4) Because additional lubrication is not required, LAMBDA Roller Chains
help prevent contamination of equipment and conveyed objects.
This promotes a clean working environment.
(5) LAMBDA Roller Chains are designed to operate in temperatures
from -10˚ to 60˚C.
Sprockets
Single strands of LAMBDA Roller Chain run on standard sprockets. Multiple
strand chains require special sprockets that have a wider transverse pitch.
(1) Drive LAMBDA Roller Chains have thicker roller link plates than RS
Roller Chains. The chains are also wider. Check to make sure that the
wider chains will run correctly on your equipment.
(2) When the chain is used in a dusty environment, the dust will absorb
the lubrication oil in the bushings, and the bushings may wear in a short
time. If conditions are dusty, test the chain in the environment.
(3) If LAMBDA Roller Chain is used in water, the chain will wear faster.
(4) When the lubricating oil contained in the bushing is depleted, the chain
should be replaced.
Application Series
(1) Nickel-plated LAMBDA Roller Chain is available for higher corrosion
resistance.
(2) LAMBDA II lasts twice as long as LAMBDA in temperatures up to 150˚C.

96
Applications
1.3.2 Sealed Roller Chain
Lube-free type: High-speed transmission, in dusty conditions
Application Example
Sealed Roller Chain may be useful for general industrial applications that run
at high speeds or in dusty conditions. (See Figure 1.9.)
Sealed Roller Chains have O-ring seals between the pin link and the roller
link plates. These seals keep the lubricant in and contaminants out. The inner
width of the chain is the same as ANSI specifications. The total width of the
chain is larger than the ANSI measurement because the bushings usually
extend beyond the roller link plates to protect the O-rings.
Sealed Roller Chains are available in sizes 40 through 100. The average
tensile strength is slightly lower than ANSI Roller Chain.
Sprockets
Standard sprockets are used for single strand chain.
Figure 1.9 Sealed Roller Chain

97
(1) O-ring seals are usually made of acrylonitrile-butadiene rubber, which is
highly resistant to oil, heat, and abrasion. Fluorine rubber O-ring seals
are available for high heat operations (greater than 120˚C).
(2) The link plates holding the O-rings are under compression. This means
greater force is required to articulate the chain, and the transmitted
power is decreased. At places where the chain tension is low (such as
the return side) the strand will retain the bend. The manufacturing
tolerances of the O-rings are generally large, therefore, it is difficult to
make the bending resistance of O-ring chain smaller and stable.
(3) When the oil film between the O-ring and the link plate is gone, the
O-ring will wear and deteriorate. Rubber has a “creeping” property, and
it tries to make the contacting surface flat. Therefore, it becomes more
difficult to get the lubricant into the working parts.
(4) During long-term operation, the O-rings may start to fall off the chain.
Then, the elongation at that spot will progress very rapidly. If this occurs,
it is time to replace the chain, even if the total chain has not reached the
elongation limit (1.5 percent).
(5) The cost of Sealed Roller Chain is higher than ANSI Standard Roller
Chain. The higher cost is because of the additional and special parts (O-
ring seals, longer pins and bushings). Unfortunately, less expensive stan-
dard components cannot be used for Sealed Roller Chain.
Technical Trend
Chain manufacturers are constantly striving to improve the quality and wear
life of chains in general, including Sealed Roller Chain.
In the area of seal research, a variety of shapes of seals has been tested. The
goal is to reduce the bending resistance and yet keep the lubricant in the
working parts. Currently, O-rings are the most practical alternative.

98
Applications
1.4 ENVIRONMENTALLY RESISTANT CHAINS
These are chains that offer high resistance to corrosion or heat due to special
coatings or materials. The approximate relationship between these chains is
shown in Figure 1.10.
Table 1.6 shows a variety of environmentally resistant chains and materials.
NOTE: The chains surrounded with a thick line have a temperature
range of -20˚ to 400˚C. Before using these chains in temperatures out-
side this range, contact the manufacturer.
In this Figure, the left-to-right direction shows the relative corrosion
resistance (right is more resistant than left). The average tensile
strength or maximum allowable tension may differ even between
chains of the same size.
Figure 1.10 Environmentally Resistant Chains
ANSI RS
ROLLER CHAINS
NP ROLLER
CHAINS
Plating
Special Nickel Plating
For Corrosive
Environments
Special Double
Surface Treatment
304SS
Stainless Steel
WP®
ROLLER
CHAINS
SS ROLLER
CHAINS
304SS +
Engineered Plastic
PC ROLLER
CHAINS
Titanium + Special
Engineered Plastic
High Grade
Material
PC-SY CHAINS
304SS +
630SS
AS ROLLER
CHAINS
316SS
Stainless Steel
NS ROLLER
CHAINS
TITANIUM
TI ROLLER
CHAINS
▼

Table 1.6 Chains for Special Environments
Conditions
Chemicals,
Sea Acid, Alkalis, Low/High Non-
Series Treatment Special Features and Applications Water Water Sanitary Corrosives Temperatures Magnetic Lube-Free
NP Nickel-plated 1. Maximum allowable load about 10% less than RS Chain. •
2. Use SS in applications that contact food.
WP®
Special coating 1. Maximum allowable load same as RS Chain. • •
2. Better than NP in wet applications.
3. Use SS in applications that contact food.
SS 304SS 1. Typical anti-corrosion chain. • • • • •
2. Food, chemical, and pharmaceutical environments.
NS 316SS 1. Very corrosion resistant. • • • • • •
2. Maximum allowable load same as SS Chain.
AS Precipitation-hardened 1. Maximum allowable load 50% higher than SS Chain. • • • • •
stainless + 304SS 2. A little less anti-corrosive than SS.
PC 304SS + engineered plastic 1. Low noise (5 dB less than steel chain). • • •
bushing link (white) 2. Light weight (50% less than steel chain).
PC-SY Titanium + special engineered 1. Resists chemicals, including hydrochloric and sulfuric acids. • • • •
plastic bushing link (glossless) 2. Suitable when stainless steel cannot be used.
TI Titanium 1. Nonmagnetic and high resistance to corrosion. • • • • • •
2. Light weight (50% less than steel chain).
99
1.TransmissionChains

100
Applications
1.4.1 Nickel-Plated Roller Chain (NP)
Transmission, conveyor: Mild corrosive environment
Application Example
Nickel-Plated Roller Chains combine strength close to ANSI Roller Chain with
the corrosion resistance that comes from the nickel plating. These chains are
used in applications where you want light corrosion resistance. For example,
NP chain might be used in an application that has limited contact with water.
(See Figure 1.11.)
Plated Roller Chains have corrosion resistance and the attractive appearance
of nickel plating for a low cost. The strength and wear resistance are almost
the same as standard chains. These chains are a good buy if they are selected
correctly. Numbers 25 through 120 are standard.
Generally, small pitch chains are plated before assembling, and large pitch
chains are plated after assembling. Either way, the interior surfaces of the
components may not receive complete coverage.
Sprockets
Standard sprockets are used. When the application requires no rust, use
stainless steel or engineered plastic sprockets. With engineered plastic
sprockets, the strength and speed (less than 70 m/min.) are limited.
(1) Plated Roller Chains, however well plated, will experience flaking of
the plating from the interior surfaces and the roller surface that rotates
on the roller guide and impacts the sprocket. If this flaking presents a
problem (for example, danger of flakes getting mixed into foods), use
stainless steel chains.
(2) Nickel has a higher electrical potential than the base metal. If the nickel
plating flakes off, corrosion will progress faster at that point. Zinc plating
has a lower electrical potential than the base metal, therefore, the
corrosion will progress more slowly. But frequent exposure to acid
during the zinc-plating process increases the likelihood of hydrogen
embrittlement in the hardened plates. Therefore, zinc plating is not
available for some chains.

101
(3) Nickel plating may also create hydrogen embrittlement. In an application
where a broken chain may create serious damage, WP®
series chain
may be a better choice. Of course, safety guards must be installed.
(4) Link plates are shot peened for greater fatigue strength. The plating
process reduces the effects of shot peening, therefore, the fatigue
strength of plated chain is 10 percent less than that of standard chains.
(5) Plated Roller Chains are prelubricated with mineral oil after assembly.
If the prelubrication is unwanted, advise the manufacturer when
ordering.
Figure 1.11 Nickel-Plated Chain

102
Applications
1.4.2 WP®
Roller Chain
Transmission: Corrosion-resistant type
Application Example
WP Roller Chains offer the strength and durability of ANSI Roller Chains plus
a special surface treatment that stands up to water, and even sea water.
WP Roller Chains are mechanically coated to resist rust. Mechanical coating
is different than applying electroplating, or chemically plating the components.
Some manufacturers produce chemically plated chains. To chemically plate
chains, zinc and chrome are used in a high-temperature process. The chains
resist rusting when the chlorine ion is present. However, if the chains are
chemically plated after assembly, press-fit parts will lose some of the interfer-
ence due to exposure to high temperatures. This decreases the maximum
allowable tension. Also the hardness of the working parts is decreased, which
reduces the wear resistance.
In WP Roller Chains, zinc and chrome are used, and the rust resistance to
chlorine ions is the same as that of chemically plated chains. But, because WP
Roller Chains are not exposed to high temperatures during the mechanical
plating process, they have higher maximum allowable tension. The surface of
WP Roller Chain is olive-gray.
(1) The tensile strength and maximum allowable tension of WP Roller
Chains are the same as those of Standard Roller Chains.
(2) Working temperature range is -10˚ to 60˚C.
(3) Avoid using these chains if they will have direct contact with foods.
The foods may become contaminated.

103
1.4.3 Stainless Steel Roller Chain (SS)
Transmission: Corrosive environment. Manufacture of foods, chemicals,
and medicines
Application Example
All parts are made of austenitic 304 stainless steel.
The material composition is:
Carbon (C): less than 0.08%
Chromium (Cr): 18.00 to 20.00%
Nickel (Ni): 8.00 to 10.50%
SS Roller Chains are the most commonly used environmentally resistant
chains for the manufacture of foods, chemicals, medicines, or transmission in
water. They are also used in indoor conditions where rust is a problem.
(See Figure 1.12.)
The construction and sizes of SS Roller Chains are the same as ANSI Roller
Chains. Each part is formed from 304 stainless steel by cold working process-
es, such as press processing and machining. The pins are assembled to the
outer plates and the bushings to the inner plates. Neither solution annealing
nor passivating treatment are done on SS Roller Chains.
SS Roller Chains have the following features:
• Attractive appearance of glossy stainless steel.
• Exceptional corrosion resistance. But in certain highly corrosive
conditions, stress-corrosion cracking may occur.
Figure 1.12 Stainless Steel Chain

104
Applications
• Exceptional corrosion resistance and strength at high temperatures. These
chains can operate in high temperatures, but the manufacturer should be
contacted for applications above 400˚C.
• These chains may be used in extremely low temperatures, because low
temperature brittleness does not occur.
• There is slight magnetism, due to the cold working processes.
• Due to the cold working processes, the surface of the chains may rust
in some conditions.
• The tensile strength of SS chain is almost half that of RS Roller Chains.
• The chain parts are not heat-treated (such as quenching and tempering).
The tensile strength and hardness of these parts are lower than that of RS
Roller Chains.
• Because the surface hardness of the working parts (pins, bushings and
rollers) is low, the wear resistance is also less than that of RS Roller
Chains. Due to the lower thermal conductivity of stainless steel, the
working parts retain more heat, which also lowers the allowable tension
of SS Roller Chains. The allowable tension of the chain is determined by
the wear resistance.
• Numbers 11 through 240 are available. (Number 15 is not available.) Only
sizes smaller than number 80 are usually stocked. Nonhardened materials
with low thermal conductivity must be designed with smaller press fits.
This fact also makes the allowable tension of these chains lower than RS
Roller Chains.
Sprockets
SS Roller Chains run on standard-sized sprockets. In corrosive conditions,
stainless steel or engineered plastic (less than 70 m/min.) sprockets should be
used. Carbon steel sprockets may corrode and contaminate the chain and the
environment.
If SS Roller Chain is used in water within the allowable load published by
the manufacturer, the water acts as a lubricant, and the chain has additional
wear resistance. (See Figure 1.13.)
Check the manufacturer’s catalog for the conditions when SS Roller Chain
is appropriate.
When determining the allowable tension, do not consider the safety factor
and/or the tensile strength of SS Roller Chains shown in manufacturers’ cata-
logs. The tensile strength of SS Roller Chain has no practical meaning.
Surface treatment of the working parts, such as platings or nitriding, may
improve the wear resistance of SS Roller Chains, but the coating may peel off
and contaminate the environment. Nitriding usually reduces the corrosion
resistance of the chains. Contact the manufacturer for additional information.

105
When chains are cycled between the freezer and room temperature, dew
forms and freezes on the chains. This may cause noise, difficult articulation,
and chain breakage. Silicon grease applied to the gaps of the chain helps to
prevent this.
When SS Roller Chains are used at temperatures greater than 400˚C, extra
clearance in the chain joints is required. The thermal expansion may cause the
joints to seize and the chain to break. Advise the manufacturer of the operat-
ing temperature(s) in which the chain will be used.
You can extend the working life of SS Roller Chains with proper lubrication.
The chains should be lubricated as much as possible when the application
allows it.
Application Series
Other corrosion-resistant stainless steel chains are shown below. For condi-
tions and size availability, check the manufacturer’s catalog.
NS Series
All parts are made of austenitic stainless steel SS316.
The composition of this material is:
Carbon (C): less than 0.08%
Chromium (Cr): 16.00 to 18.00%
Nickel (Ni): 10.00 to 14.00%
Molybdenum (Mo): 2.00 to 3.00%
NS series chains cost more than SS Roller Chains but have greater resistance
to corrosion and heat. When the chains are used in temperatures above 400˚C,
contact the manufacturer. The allowable tension is the same as SS Roller
Chains. These chains are considered almost nonmagnetic.
Figure 1.13 Use of Stainless and Standard Chain in Water
Stainless Steel Dry
Stainless Steel in Water
RS Carbon Steel Chain

106
Applications
AS Series
Pins, bushings, and rollers (double pitch oversized rollers are SS304) are
made of precipitation-hardened stainless steel. The plates are made of the
same material as SS Roller Chains. Due to the hardened pins and bushings,
this series has higher wear resistance. The maximum allowable tension is 1.5
times that of SS Roller Chains. That means you can use a smaller chain and
get equivalent performance. The corrosion resistance is less than SS Roller
Chains. These chains are somewhat magnetic.
Other Precipitation-Hardened Series
There are other types of stainless steel chains that have case-hardened or all
precipitation-hardened stainless steel components, including the link plates. The
tensile strength is higher than SS Roller Chains, however, the wear resistance
and the maximum allowable tension are the same. Talk with the manufacturer
about the availability and applications of these chains.
SS Engineered Plastic Sleeve Series
The engineered plastic sleeve between the pins and bushings make this a
lube-free variation of SS Roller Chains. These chains cannot typically work in
water or other liquids with some exception, such as Tsubaki LS series, but are
good for indoor conditions where rust should be avoided. The allowable ten-
sion is the same as SS Roller Chains.
TI Series
All parts are made of titanium or titanium alloy. These chains have greater
corrosion resistance in chloric conditions and no magnetism. The chain’s
weight is very light (about half of the same-sized steel chain). The allowable
tension is the same as SS Roller Chains.
Technical Trends
In stainless steel chain design, corrosion resistance is the most important fac-
tor. The allowable tension is much lower than RS Roller Chains. For example,
the maximum allowable tension for RS80SS is 1.77 kN versus 14.7 kN for RS80.
The allowable tension for SS Roller Chain is about one-eighth that of RS Roller
Chain. In the AS series, the ratio is 1 to 5.5. Researchers continue to study
ways of increasing wear resistance and allowable press fit at assembly.

107
1.4.4 Poly-Steel Chain (PC)
Transmission, conveyance: Lube-free type. Food or medicine production
Application Example
Poly-Steel (PC) Chains are lube-free chains used in food or medicine produc-
tion. PC Chains can be used in power-transmission applications, and, with the
addition of attachments on the outer plates, as conveyors. (See Figure 1.14.)
The chains are a construction of outer links (outer plates and pins) made of
SS304, and inner links made of engineered plastic. There are no rollers.
Features are shown below.
(1) Inner links are made of a self-lubricating material; therefore, the chains
do not require lubrication. The wear resistance of these chains is higher
than that of Stainless Steel Roller Chains without lubrication
(Figure 1.15).
(2) Because the inner link is made of plastic, the noise caused by
engagement with the sprocket is lower (about 5 dB lower than Standard
Roller Chain).
(3) PC Chain is very light; about half that of Standard Roller Chains.
(4) There are five sizes for this series: Numbers 25, 35, 40, 50, and 60.
The maximum allowable tension varies from 0.08 to 0.88 kN.
Sprockets
Standard sprockets are used. The three major sizes have the same dimen-
sions as ANSI Roller Chain; Numbers 25 and 35 are slightly wider. In corrosive
conditions, carbon steel sprockets may corrode and contaminate the applica-
tion. Use stainless steel or, at slow speeds (less than 70 m/min.), use engi-
neered plastic sprockets.
Figure 1.14 Poly-Steel Chain
304 Stainless Steel
Engineered Plastic

108
Applications
(1) One of the advantages of Stainless Steel Drive Chain is its high ratio
between tensile strength and maximum allowable tension. Even if
tension is high at the moment of starting, it will not break if the
start-up is infrequent. The ratio between tensile strength and maximum
allowable tension for Poly-Steel Chain, however, is low. There is a huge
difference in the Young’s ratio between steel and plastic. Almost all of
the shock load is absorbed by the engineered plastic inner link.
This means you need to take care when selecting Poly-Steel Chain. If
Poly-Steel Chain is selected the same way as standard chain, breakage
may occur. When selecting Poly-Steel Chain, the maximum tension—
including inertia shock—must be considered to get satisfactory results.
(2) These chains are suitable for splash applications, but they should not be
submerged in water or other liquids. The ideal environment is indoors
where rusting must be avoided.
(3) The allowable tension of this series is almost the same as Stainless Steel
Roller Chains (SS series.)
(4) An offset link is not available for Poly-Steel Chain. An even number of
links must be used.
Application Series: PC-SY
Because of the titanium outer links and special engineered plastic inner
links, SY series chains do not corrode in most chemicals, including hydrochlo-
ric and sulfuric acid. The allowable tension is about half that of Poly-Steel
Chains. This is a nonmagnetic type of chain.
Technical Trend
Manufacturers are working to increase both the tensile strength and the
maximum allowable tension.
Figure 1.15 Stainless Steel Chain Versus Poly-Steel Chain
WearElongation
Operation Time
Poly-Steel Chain
Prelubricated
Stainless Steel Chain
Completely Dry
Stainless Steel Chain

109
Figure 1.16 Most Bicycles Use Chain
1.5 SPECIALTY CHAINS, TYPE 1
1.5.1 Bicycle Chain
Transmission
Application Example
These chains transmit the power of pedaling to the back wheel (Figure 1.16).
Most bikes use chain; a few styles use cog belts, but these are the exceptions.
In the early stages of chain development, chain design grew in response to
development in bicycles. Bicycles are categorized as shown in Table 1.7.
In addition to bicycles, these chains may be used in low-speed, light-load
transmission operations, for example, in agriculture machines or with electric
garage door openers.
Table 1.7 Categories of Bicycles
Category Models of Bicycles
General Sports, small-tire, general-purpose, child’s
Infant Infant’s
Special Purpose Road racing, heavy-duty carriage, track racing, mountain, tricycle, tandem

110
Applications
Bicycle Chains are generally categorized into two types: 1/2 ϫ 1/8 and
1/2 ϫ 3/32. The first number (1/2) is the chain pitch; the latter numbers (1/8
and 3/32, respectively) indicate the inner width in inches.
Number 1/2 ϫ 1/8 chain is used for simple transmission without speed shift-
ing; it has the same construction as Standard Roller Chain.
Number 1/2 ϫ 3/32 chain is used with a derailleur. There are two types of
construction—standard roller and bushingless (Table 1.8). In the bushingless
chain, the inner link plates are extruded so that the inner plates also serve as
the bushings (Figures 1.17 and 1.18). In most derailleur transmission chains,
the link plates are bent or cut so that the chains can change smoothly on the
front or rear sprockets.
Figure 1.17 Bushingless Bicycle Chain Components
Figure 1.18 Schematic Diagram of Bushingless Bicycle Chain
Table 1.8 Applications of Bicycle Chains
Nominal Inner Link
Number Pitch Width Construction Application
1/2 X 1/8 12.7 3.30 Roller Chain Simple drive
General purpose
1/2 X 3/32 12.7 2.38 Roller Chain With derailleur
Bushingless Chain Sports
Racing
Outer Plate Inner Plate
Pin Roller

111
Sprockets
The basic sizes of the sprockets (front and rear) are common to all manufac-
turers; however, the tooth shape is different. This is especially true for the
sprockets for 1/2 ϫ 3/32 chains. Each manufacturer designs its own tooth
shapes for better shifting. Exercise care when changing sprockets.
(1) Manufacturers usually offer a selection system for derailleur transmission,
which includes the chain and sprockets. Check the manufacturer’s
catalog for information.
(2) The chain’s performance is usually influenced by wear. Select a chain
with specially coated pins, which increase wear resistance.
(3) You must connect the chains carefully, or they may break during
operation. Use special connecting pins (sold separately) to connect
chains, especially those used with derailleurs.
(4) These chains are frequently exposed to rain, dirt, or mud, which can
lead to elongation or rust. The chains need regular cleaning
and lubrication.
(5) Do not use weak-acid rust remover (such as phosphatic rust remover) on
these chains. These chemicals can cause hydrogen embrittlement and
chain breakage.
Technical Trend
To keep up with the design enhancements of bicycles, chains are being
developed in several ways:
(1) Lighter weight.
(2) Higher rust and weather resistance.
(3) Attractive appearance.
(4) Nonstaining to clothes.
(5) Lower noise at engagement.

112
Applications
1.5.2 Motorcycle Chain
Transmission
Application Examples
Motorcycles are high-speed applications that operate in tough conditions—
rain, dirt, sand, and high shock loads. These specially developed chains are
used as the part of the drive train to transmit the motor power to the back
wheel (Figure 1.19).
Motorcycle Chains are superior to gears, which are in the crank cases, by the
ease in adjusting the shaft center distance and the number of teeth of the
sprocket. Therefore, you can freely design the motorcycle’s reduction ratio
taking into account the specifications and the working conditions. In the case
of a racing motorcycle, for example, the engine power may be 180 hp, and
the chain speed is 1,500 m/min.
Motorcycle Chains have the same basic construction and sizes (numbers 40,
50, and 60, Table 1.9) as Standard Roller Chains. But they have a special width
of inner links. Because of the very demanding working conditions, some
Figure 1.19 Motorcycle Chain in Action

113
Motorcycle Chains have the following special features:
(1) Strength
Quad-staked riveting on the pin head helps to retain the link plate on
the pin. Connecting links are press fit. (Riveted connecting links are also
available.) Link plates are thicker (heavy) and the rollers are seamless.
(2) Wear life
Special coated pins, sintered bushings that are oil impregnated, and seam-
less bushings with O-rings are used to extend the wear life of the chain.
(3) Resistance to dirt, sand, or mud
To prevent debris from getting into tight joints, the bushings are extend-
ed beyond the inner link plates, and often O-rings are used to seal the
chains. This extension and O-rings prevent abrasive material from
getting into the chain.
(4) Appearance
These chains may have special coloring, plating, (gold or silver), or
glossy finish on the plates.
Sprockets
Special sprockets are used for these chains. Numbers 425 and 530 sprockets
have the same tooth shapes as standard types.
(1) Usually the specifications differ for each motorcycle or application, even
with the same-sized chains. Do not select the chain just by size of the
sprocket; take into account the application. For example, an off-road
motorcycle travels through dirt and sand, which will get on the chain.
You should avoid the use of oil-impregnated sintered bushings
for this application.
(2) Failure of Motorcycle Chains may result in injury or death. Care must be
exercised when connecting or aligning the chains.
(3) Both O-ring chains and oil-impregnated sintered bushing chains wear
rapidly if the O-rings fall off or if the oil in the sintered bushings is
depleted. If either of these situations occur, the chain must be replaced
—even if it has not elongated to the limit.
Table 1.9 Motorcycle Chains
40 Class 50 Class 60 Class
Chain Inside Chain Inside Chain Inside
Number Width (mm) Number Width (mm) Number Width (mm)
420 6.35 520 6.35 630 9.53
425 7.95* 525 7.95
428** 7.95* 530 9.53*
* Same inside width as ANSI Standard Roller Chain.
** Roller diameter differs from ANSI Standard Roller Chain.

114
Applications
(4) The life of O-ring chain is usually determined by the durability of the
O-ring. To improve the durability, there should be an oil film on the
O-ring at all times. Even though it is a sealed chain, lubrication is
required to extend the working life of the O-ring. Cleaning sprays may
cause deterioration of the O-rings. Do not allow chains to air dry after
washing, or to rust.
Technical Trend
Motorcycles are getting faster and more powerful. Therefore, Motorcycle
Chains must have greater durability. At the same time, motorcycles are getting
lighter and smaller. Manufacturers are working on new materials, sizes, and
heat treatments to improve the performance of the chain.

1.5.3 Chains for Automotive Engines
Transmission: Camshaft driving, balancer driving
Automotive Chains are used for driving the camshafts in engines, counterbal-
ance shafts, or oil pumps. Some manufacturers use cog belts instead of chains
in this application. (See Figure 1.20.)
Camshaft drives transmit the crankshaft rotation to the camshaft of the over-
head cam (OHC) engine at a ratio of 2:1. The counterbalance shaft and oil
pump are also driven by the crankshaft. Both of these drives are installed
inside the engine and are not visible from the outside.
These chains work at the temperature range of -30˚ to 130˚C, and rotate at
about 600 to 7,000 rpm. Counterbalance drive sprockets rotate at 1,200 to
14,000 rpm, which is equivalent to a speed of 1,800 m/min.! This is twice the
speed of engine drive chain. Motorcycles also use camshaft drives, but this dis-
cussion is limited to automobiles that use roller chains, which are usually
offered by Japanese or European manufacturers. In the United States, Silent
Chains are usually used for camshaft drives in automobiles, but roller chains
are being increasingly used.
(1) Single strand chain with a pitch of 9.525 mm or 8.0 mm is usually used.
(See Figure 1.21.) In diesel engines or other high-load engines, double
strand chains may be used.
(2) The chains are used at high speed. Therefore, the wear between the pins
and bushings is the main concern. The surface of the pin is usually
hardened with Hmv 1,600 or more.
115
Figure 1.20 Engine Cutaway to Show Chain Drive

116
Applications
Sprockets
(1) Tooth shapes are either ANSI- or BS-type. Currently the BS-type is used
more frequently.
(2) Automotive engines are produced on a large scale. The sprockets for
both the crankshaft and the camshaft are mass-produced from
sintered metal.
(1) These chains are used with chain guides, levers, and tensioners to
reduce chain elongation, vibration, and noise.
(2) Generally, the chains are selected according to the transmission torque,
small-sprocket speed, and the layout. In mid- to high-speed transmission,
vibration and lubrication must also be considered.
(3) These chains need forced lubrication.
Technical Trend
Manufacturers are focusing attention on the following issues:
(1) Making lighter-weight, smaller-sized chains.
(2) Improving reliability of the entire transmission system, including
sprockets, guides, levers, and tensioners.
(3) Decreasing noise from the chain, and throughout the entire drive system.
Figure 1.21 Automotive Drive Chain and Sintered Metal Sprockets

1.6 SPECIALTY CHAINS, TYPE 2
1.6.1 Miniature Chain
Transmission: Office machines and general uses
Application Example
Many users require “smaller, lighter” equipment. The transmission chains for
this equipment must also be smaller. Miniature Chains RS11SS (3.7465 mm
pitch) and RS15 (4.7625 mm pitch) are designed to fill this request. (See the
lower part of Figure 1.22.)
This is a bushing chain series, which means it does not have rollers. RS11SS
is made from 304 stainless steel; RS15 is made from carbon steel. Offset links
are not available for Miniature Chains.
Sprockets
There are special sprockets for RS11SS (tooth sizes of 12 through 48) and
RS15 (tooth sizes of 11 through 35). Sprockets for RS11SS are made of 304
stainless steel; for RS15 they are carbon steel.
Technical Trend
In the case of small transmissions, toothed belts seem to have advantages
over chains.
117
Figure 1.22 Miniature Chain Versus Other Chains

118
Applications
1.6.2 Leaf Chains
Lifting, counterbalance, forklifts, machine tools
Leaf Chains are used for fork lift masts, as balancers between head and
counterweight in machine tools, or for low-speed pulling (tension linkage).
This type of chain is also called “Balance Chain,” and is regulated by ANSI
B29.8M, JIS B 1804, and ISO 4347. (See Figure 1.23.)
These steel chains have a very simple construction: link plates and pins. The
chain number indicates the pitch and the lacing of the links. (See Figure 1.24.)
The chains also have the features shown below.
(1) High tensile strength per section area. This allows the design of
smaller equipment.
(2) There are A- and B-type chains in this series. Both AL6 Series and BL6
Series have the same chain pitch as RS60 (19.05 mm), but they differ, as
shown in Table 1.10.
(3) These chains cannot be driven with sprockets.
Sprockets
Sheaves, not sprockets, are used to change the direction of these chains
(Figure 1.25).
Figure 1.23 Leaf Chain and a Leaf Chain Application

119
Table 1.10 Difference Between AL6 Series and BL6 Series
AL6 Series BL6 Series
Pin Diameter 5.94 7.90
Plate Thickness 2.4 3.2
Plate Height 15.6 18.1
Plate Lacing 2X2, 4X4 2X3, 3X4
Even lacing is standard. Odd lacing is standard.
(1) In roller chains, all the link plates have higher fatigue resistance due to
the compressive stress of press fits. In Leaf Chains, only two outer plates
are press fit. Therefore, the tensile strength of Leaf Chains is high, but
the maximum allowable tension is low. Use safety guards at all times,
and be particularly alert to assure that the safety factor is in the
manufacturer’s catalog. Use extra safety factors where consequences of
chain failure are severe.
(2) The more plates used in the lacing, the higher the tensile strength. But
this does not improve the maximum allowable tension directly; the
number of plates used may be limited.
Figure 1.24 Leaf Chain Lacing Patterns
2 x 2
2 x 3
AL622 AL644 AL666
BL623
LACING
LACING
CHAIN SIZE
CHAIN SIZE BL634 BL646
3 x 4 4 x 6
4 x 4 6 x 6

120
Applications
Figure 1.27 Leaf ChainFigure 1.25 Leaf Chain Sheave
Figure 1.26 Leaf Chain
(3) The pins articulate directly on the plates, and the bearing pressure is
very high. The chains need regular lubrication. The use of SAE 30 or 40
machine oil is suggested for most applications.
(4) When the chain speed is greater than 30 m/min., or if the chain is cycled
more than 1,000 times in a day, it will wear very quickly, even with
lubrication. In either of these cases, use RS Roller Chains.
(5) AL-type should be used only under conditions in which:
• There are no shock loads.
• Wear is not a big problem.
• Number of cycles is less than 100 a day.
Under other conditions, BL-type should be considered.
(6) If you select a chain using a low safety factor, the stress in parts becomes
higher. In this situation, if the chain is used in corrosive conditions, it
may fatigue and break very quickly. If you’re operating under these
conditions, perform maintenance frequently.
(7) The shape of the clevis depends on the type of end link of the chain
(outer link or inner link). Manufacturers produce clevis pins or clevis
connectors, but typically, the user supplies the clevis (Figures 1.26 and
1.27). The strands should be furnished to length by the manufacturer.
An incorrectly made clevis may reduce the working life of the chain.
Contact the manufacturer or refer to the ANSI standard.
(8) The sheaves are usually supplied by the user.
Clevis Connector
Clevis for Outer Link
Clevis Pin
Clevis for Inner Link

1.6.3 Inverted Tooth Chain (Silent Chain)
Transmission
Application Example
Silent Chains are used for the camshaft drive of the mid- to large-size
motorcycle engines and automobile engines in the United States, the
transfer-case drive in four-wheel-drive vehicles, and the primary drive
between the engine and transmission, as well as in other high-speed
applications (Figure 1.28).
(1) Silent Chains have a very simple construction: only plates and pins.
Today’s Silent Chains are actually an update of a 19th-century design.
ANSI B29.2M-1982 regulates the standard pitch, width, and kilowatt
ratings of the chains and sprockets.
(2) There are eight different pitches from 9.52 mm to 50.8 mm.
(3) The link plate receives tension and has a notch for engaging the
sprockets. There is no notch on the guide plate. These plates act as
guides for the sprockets.
(4) Pins may be round or have other shapes, such as D-shape (Figure 1.29).
(5) All of the chain components share the tension. Silent Chains have higher
capacity than roller chains of the same width.
121
Figure 1.28 Silent Chain

122
Applications
(6) Because the link plates of Silent Chain strike the sprocket at an angle,
the impact and the noise are reduced (Figure 1.30). This is why these
chains are called “silent.” The higher the chain speed, the greater the
difference from roller chains.
Sprockets
The sprocket for Silent Chain is shaped like a gear. In the ANSI
standard, the tooth working face is a straight line. But in HY-VO®
Chains
(see Applications Series below), an involute tooth is used for the sprocket.
(1) Silent Chains are good for high-speed transmission.
(2) If single- or multiple-strand roller chains are an option, they are less
expensive. Wider Silent Chain becomes relatively competitive in price.
(3) Silent Chains must be lubricated during operation. Use an oil bath if the
speed is less than 600 m/min. If the speed is more than 600 m/min., or
if the shaft center distance is short, use a pump or forced lubrication.
Silent Chains wear rapidly without lubrication.
(4) The notch on the plates can engage with the sprockets from only one
direction. The chain is not for reversing applications.
(5) To select the right Silent Chain for your operation, refer to the
manufacturer’s catalog.
Figure 1.29 Silent Chain Components Figure 1.30 Silent Chain Strikes the Sprocket at an
Angle, Reducing Noise
LINK PLATE
GUIDE PLATE
PIN

123
Application Series
HY-VO®
Chain is a unique type of Silent Chain. HY-VO stands for HIGH
CAPACITY, HIGH VELOCITY, and INVOLUTE TOOTH, and it is a registered
trademark of Borg-Warner Automotive, Inc.
In Silent Chain, the pin and the plate rotate against each other. In HY-VO
Chains, the pin is comprised of two pieces that have rotational contact. Due to
the rotational contact of the pins, the wear life of the chain is increased. Also
in HY-VO Chains, the contact point between the pins moves up when the
chain engages the sprocket (Figure 1.31). This construction decreases chordal
action (which was discussed in Basics Section 2.2.1), vibration, and noise.
Figure 1.31 HY-VO Chain
CONTACT POINT
PITCH LINE
PITCH LINE

124
2 . SMALL PITCH CONVEYOR CHAINS
Small pitch conveyor chain is based on ANSI Roller Chains with attachments
added to make them suitable for conveyor uses (Figure 2.1). There are many
types of small pitch conveyor chains. Figure 2.2 shows the relationship
between these chains and available options, such as lubrication free or envi-
ronmentally resistant.
Figure 2.1 Attachment Chains

NOTE: 1) , Available.
2) Heat resistant from -20°~400°C. Consult chain manufacturer in case
temperature exceeds these limits.
3) AS Pins and bushings are precipitation-hardened. All others are
304 stainless.
125
2. Small Pitch Conveyor Chains
Figure 2.2 The Relationship Among Chains and Their Availability
Anti-Corrosive
Nickel
Plating Stainless
NP
LAMBDA®
LAMBDA®
Lube-Free
between
Bushing and
Roller
LAMBDA®
Lube-Free
RS Attachment
Chain
RS Roller
Chain
Hollow Pin
Chain
RF Double
Pitch
Plastic Roller
Plastic
Sleeve
Hollow
Pin
Double Pitch
Attachment
Lube-Free
Standard
Standard
or Y/SY
SS AS
Hollow
Pin
Hollow
Pin
Engineered Plastic
Inner Link
Attachment
Poly-Steel
Chain
LAMBDA®

126
Applications
2.1 SMALL PITCH CONVEYOR CHAINS FOR GENERAL USE
2.1.1 RS Attachment Chain
Light conveyance: General uses
Application Example
RS Attachment Chain is used for short conveyors (usually less than 10 m) of
small products. This chain is also suitable for conditions under which noise
should be avoided (Figure 2.3).
Table 2.1 Standard Dimensions for RS Attachment Chain1
Maximum
Pitch Allowable
Chain No. (mm) Tension (kN) Note2
25 6.35 0.64 Bushed
35 9.525 1.52 Bushed
40 12.70 2.65
50 15.875 4.31
60 19.05 6.27
80 25.40 10.6
100 31.75 17.1
120 38.10 23.9
140 44.45 32.3
160 50.80 40.9
1
These dimensions are from Tsubaki. Other manufacturers’ products may vary.
2
Bushed chain is designed without a roller.
Figure 2.3 RS Attachment Chains

127
This chain is based on Standard RS Roller Chain with added attachments for
conveyance, as indicated in ANSI B29.1 for reference.
Table 2.1 shows the chain size, pitch, and maximum allowable tension for
standard products from Tsubaki. Among these chains, Numbers 40, 50, 60, and
80 are used most frequently.
The features are shown below:
(1) Due to the small pitch of these chains, the drive design is smaller.
(2) Usually sprockets with a large number of teeth are used. Therefore,
the chain speed does not vary significantly, and the chain engages with
sprockets with less noise.
(3) These chains may be used for high-speed conveyors.
(4) A wide variety of standard attachments and special attachments
(Plus α Alpha series) are available for this chain series.
(5) Slip-fit, spring-clip type connecting links are provided for RS40, RS50,
and RS60 chains. RS80 has cottered connecting links.
Sprockets
Standard RS Roller Chain sprockets are used with these chains.
(1) If the attachments receive large bending or twisting forces, make sure the
chain has adequate strength. In these conditions, Double Pitch Roller
Chain or a chain with larger pitch will be more effective; both have
larger attachments.
(2) Due to light weight, the chain inertia is smaller.
(3) The tolerance of the overall chain length is -0.05 to 0.25 percent
(JIS Standard) of the standard length. This is greater than that of
RS Roller Chain.
(4) In these chains, the clearance between the parts is small. Chain
articulation is easily affected by dirt or contamination in the joints.
Application Series
(1) Lubrication free: LAMBDA®
series (operating temperature of
-10˚ to 60˚C).
(2) Environmentally resistant: Special coatings or base materials may be
used to add extra resistance. These include:
• Coating: Nickel plating, WP®
specification.
• Material: 304 stainless steel SS-type, AS-type with the pins, bushings,
and rollers made of precipitation-hardened stainless steel and the other
components the same material as SS-type.

2.1.2 Double Pitch Roller Chain
Light conveyance: General uses
Application Example
This is the most commonly used conveyor chain and is utilized widely in
the auto parts, electric, electronic, and precision machinery industries
(Figure 2.4).
Double Pitch Roller Chain has the same basic construction as Standard Roller
Chain, but double pitch means the chain pitch is twice as long, has flat-shaped
link plates, and longer attachments. This series is regulated by ANSI B29.4,
ISO 1275-A, and JIS B 1803. Table 2.2 shows the size, pitch, and maximum
allowable tension for standard specification Double Pitch Roller Chain.
Among these, four sizes—Numbers 2040, 2050, 2060, and 2080—are most
commonly used. The features are shown below:
(1) Double Pitch Roller Chains have the smallest tolerances for overall length
compared to all other types of conveyor chains.
Without attachments: 0 to +0.15 percent of the nominal chain length.
With attachments: 0 to +0.25 percent of the nominal chain length.
128
Applications
Figure 2.4 Double Pitch Roller Chain
Table 2.2 Dimensions of Double Pitch Roller Chain1
Maximum
Pitch Allowable
Chain No. (mm) Load (kN)
2040 25.40 2.65
2050 31.75 4.31
2060 38.10 6.27
2080 50.80 10.6
2100 63.50 17.1
2120 76.20 23.9
2160 101.60 40.9
1

129
(2) There are two types of rollers, R-roller (oversized) and S-roller
(standard). The S-rollers are used in short-length and slow-speed
conveyance. The R-rollers are most commonly used, especially for
longer conveyors.
(3) There are many standard attachments and special attachments (Plus α
Alpha series) available for this series.
(4) Chains sized 2060 and larger have greater rigidity than Standard RS
Attachment Chains because the link plates are one size thicker (heavy).
(5) Due to its light weight, the chain’s inertia is smaller.
(6) Slip-fit, spring-clip-type connecting links are provided for Numbers 2040,
2050, and 2060. Number 2080 has cottered connecting links.
Sprockets
Special sprockets are required for these chains. For the S-rollers, standard
sprockets exceeding 30 teeth are used (30-tooth sprocket has 15 effective
teeth). The chain engages every second tooth.
(1) Double Pitch Roller Chains are selected according to the allowable roller
load and maximum allowable tension.
(2) When the attachments receive a large bending or twisting force, make
sure the chain has adequate strength. In these cases, a larger-pitch roller
chain is frequently used because it has a thicker plate and longer
attachment.
(3) In these chains, clearance between the components is small. Chain
articulation is easily affected by dirt or contamination in the joints.
Application Series
(1) Lubrication-free: LAMBDA®
series (operating temperature of -10˚ to
150˚C). O-ring chains are also lubrication-free chains, however, they have
bending resistance and sometimes, after engaging the sprockets, the
chains retain the articulated position. This may occur at the return side
of the chain loop. Therefore, O-ring chains are not suitable for
conveyance.
(2) Environmentally resistant: Special coatings or base materials may
be used to add extra resistance.
•Coating: Nickel plating, WP®
specification.
•Material: 304 stainless steel SS-type and AS-type with pins, bushings,
and small rollers are made of precipitation-hardened stainless steel.

130
Applications
2.1.3 Plastic Roller Plus Plastic Sleeve Chain
Transmission, conveyance: Maintenance-free type, general uses
Application Example
Plastic Sleeve Chain is used for general purpose with small loads, and under
conditions that require maintenance-free or low-noise applications.
In Plastic Sleeve Chains, the pins and bushings are separated by a sleeve
made of self-lubricating engineered plastic. This feature makes the chains
maintenance free (Figures 2.5 and 2.6).
This chain has the features shown below:
(1) A small coefficient of friction (R-Roller): 0.08 versus 0.12 for all-steel chain.
(2) Light weight: 30 percent less than the weight of all-steel chain
with R-rollers.
Figure 2.5 Plastic Sleeve Chain
Figure 2.6 Plastic Sleeve Chain Versus Other Chains
Engineered Plastic S-
or R-Roller
Engineered Plastic
Sleeve
CarbonSteelChain
Operating Hours
WearElongation
Lube-FreeChain
StainlessSteelChain
Plastic Sleeve Chain

131
(3) Low noise: the noise made from engaging the sprockets is 5 to
7 dB lower.
(4) In Plastic Sleeve Chain, the maximum allowable tension is one-sixth,
and the allowable load of the R-roller is about one-third that of the
same-sized all-steel chain (with lubrication).
Sprockets
Use the same sprockets as for Double Pitch Roller Chain.
Application Series
There are special low-noise engineered plastic R-rollers, which can reduce
the noise from the standard engineered plastic type by 7 dB. The allowable
roller load for low-noise R-rollers is about 30 percent less than standard engi-
neered plastic R-rollers.

132
Applications
2.1.4 Hollow Pin Chain
Conveyance, simplified attachment installation, general uses
In Hollow Pin Chain, the pin has a hole, allowing for the installation of
various attachments (Figure 2.7). Usually these chains are used for conveyors
(Figure 2.8). Sizes are shown in Tables 2.3 and 2.4.
The advantages of installing attachments into the hollow pin include
the following:
(1) The hollow pin is at the center of articulation, and always keeps the
pitch length. Regardless of whether the chain is straight or wrapping
around the sprocket, the center distance of attachments is always the
same. Figure 2.8 shows an example of installing a mesh net. Even
when the chains bend, the mesh net does not expand or contract.
Figure 2.7 Hollow Pin Chain
Figure 2.8 Installing Attachments
Can-dryer Rod
Crossrod with Mesh

133
(2) With a crossrod over two chains, the load from the attachments is
distributed to both sides of plates equally. The chain can fully use
its strength and not twist.
(3) It is easy to change, maintain, and adjust attachments.
Sprockets
Standard sprockets are used for the small pitch series. For double pitch
series, standard sprockets for Double Pitch Roller Chain are used.
(1) These chains are selected using the same methods as other conveyor
chains. Care must be taken since the maximum allowable tension
of hollow pin chains is less than that of the same-sized standard chains.
(2) Retaining rings are used on the pin head for connecting links. When an
attachment link is to be added to an HP connecting link, the attachment
link pin must be longer than those used in the rest of the chain.
(3) The pin is not riveted in this chain. The lower maximum allowable load
and the high rigidity of the pin make it difficult for the link plates to
come off.
(4) The small pitch series and the S-roller (standard) types in the double
pitch series are bushing chains, which do not have rollers.
Table 2.3 Sizes for Hollow Pin Chain1
Pin Minimum Maximum
Inner Allowable
Chain No. Pitch Diameter (mm) Load (kN)
RS40HP 12.70 4.00 1.76
RS50HP 15.875 5.12 3.14
RS60HP 19.05 5.99 4.21
RS80HP 25.40 8.02 7.64
1
Table 2.4 Sizes for Double Pitch Hollow Pin Chain1
Pin Minimum Maximum
Inner Allowable
Chain No. Pitch Diameter (mm) Load (kN)
RF2040HP 25.40 4.00 1.76
RF2050HP 31.75 5.12 3.14
RF2060HP 38.10 5.99 4.21
RF2080HP 50.80 8.02 7.64
1

2.2 SPECIALTY CHAINS
2.2.1 Step (Escalator) Chain
Small size conveyance: Escalator
Application Example
Step Chain, which is also called Escalator Chain, moves the steps on escala-
tors or drives moving sidewalks (Figure 2.9).
In escalators, the steps are installed about every 400 mm, however, widths
and heights are different. The tensile strength of step chains ranges from 6 to
30 tons. The 9-ton type and 15-ton type are most common.
The chain pitch should be as small as possible to reduce the effects of
chordal action, which is caused by the chain/sprocket engagement. Using the
smallest size possible allows the chain to operate more smoothly (Table 2.5).
The way steps are installed on chains differs from country to country. In
Japan, the bearing part is in the center of the chain plate, so the step shaft is
installed there. In other countries, extended pins are used as the shaft for the
step (Figure 2.10).
134
Applications
Figure 2.9 Step (Escalator) Chain

135
Figure 2.10 Bearing Hole and Extended Pin on Step (Escalator) Chain
Usually rollers on the step side carry the weight of steps and passengers, but
in some types the chain rollers carry the weight.
The features of step chain are:
(1) Greater wear resistance. The pin diameter is larger than standard chains.
(2) Length from step to step and from chain to chain is strictly controlled.
Sprockets
Special sprockets are required for step chains.
Technical Trends
The chains shown above are being adapted for the following:
(1) Lubrication-free type. (However, lubrication is mandated at regular
intervals.)
(2) Low-noise type (for quiet environments).
Table 2.5 Pitch and Attachment Spacing for Step (Elevator) Chain
Attachment
Pitch (mm) Spacing
Small Size 67.7 6th
Medium Size 81.3 5th
Large Size 101.6 4th

Figure 2.11 ATC Chain Can Accomodate
Many Tools
Figure 2.12 ATC Chain
HP-Type
SK-Type
136
Applications
2.2.2 ATC Chain
Small conveyance: Machine tools
Application Example
ATC Chain is used to organize tools in the automatic tool changer, which is a
device on Computer Numeric Control (CNC) machine tools.
When fewer than 30 tools are used, the tool pots are mounted on a disc.
Tools are changed by controlling the disc. When more than 30 tools are used,
tool pots are mounted directly on the chain. (See Figures 2.11 through 2.13.)
Comparing the disc and chain set-ups, differences include the
following points:
(1) Using the same area, the chain type can have as much as 1.5 times as
many tools as that of the disc (Figure 2.13).
(2) To add tools to the disc type, you must change to a larger-diameter disc
and redesign the changer. But with the chain type, you simply add chain
strands. The changer location remains the same, allowing standardization.
(See Figure 2.14.)
Figure 2.13 Chain-Type ATC Can Have 1.5 Times that of Disc-Type ATC
Disc-Type ATC
Chain-Type ATC

137
Figure 2.14 Ways to Add Tools
There are two types of ATC Chains: SK and HP. Note the following features:
SK series has two strands of chain in which the pitch of the outer link and
inner link is different. SK attachments are placed on every other link. There
are three standard tool pitches: 95.25, 114.30, and 133.35 mm, which are based
on RS100, 120, and 140 transmission chains, respectively. The SK series can
bend in only one direction.
HP series has large-diameter hollow pins. There are five standard tool pitches:
90, 100, 130, 140, and 160 mm. HP series can bend in both directions, which
permits more freedom in design.
Both types of chain are available for any shank number, including 40 and 50
in MAS, ANSI, and ISO types. Special ATC Chains are also available for 25, 30,
35, 45, and 60; check with the manufacturer.
Sprockets
The SK series ATC Chain uses the sprockets that are used for duplex power
transmission roller chain. (The tooth range is limited.) HP series ATC Chain
requires special sprockets.
(1) ATC Chains must be lubricated.
(2) When there is excessive tool overhang, use a tool guide to keep
the chain straight.
(3) Change tools at the position shown in Figure 2.15.
(4) Positioning pins and grippers help to maintain accurate placement.
For Expansion of Number of Tools
Chain-Type ATC
Disc-Type ATC Tool Replacement Position

138
Applications
Figure 2.15 Positions for ATC Tool Changers
Gripper
Positioning Pin
Gripper
Positioning Pin
Gripper
Positioning Pin
Sprocket
ATC Chain
ATC Chain
ATC Chain

139
2.3 Standard Attachments
Most applications use small pitch conveyor chains with attachments in
one of these ways:
• Convey materials directly on chain attachments.
• Convey materials on jigs installed on the attachments.
The characteristics of the conveyed materials and the working environment
are different for each application. Many types of attachments with and without
jigs are available.
There are many different types of attachments; it would be difficult for chain
manufacturers to satisfy all customer requirements for quality, price, and deliv-
ery if every type of special attachment chain were made. There are too many
variations. Chain manufacturers need mass production to maintain high quali-
ty, reasonable prices, and quick delivery, not small production lots of many
different items.
Current standard attachments are established and selected based upon the
long history of attachment chain use and demand, and they provide high qual-
ity, economy, and quick delivery to meet the majority of customers’ require-
ments. For small pitch conveyor chains, standard attachments include: A, K,
SA, SK, D-1, and D-3 types.
Standard attachments are available for a wide variety of chains:
• With special surface treatments (nickel-plated or WP®).
• Made of 304 stainless steel or other metals.
• For lube-free operations (LAMBDA®
series, etc.).
In the following sections, we will explain each standard attachment.
2.3.1 A Attachment
An A attachment is most commonly used. It has a bent link plate that
extends out on one side of the chain, forming an L-shape. It comes with one
or two bolt holes, which are referenced A-1 or A-2, respectively (Figure 2.16).
The attachment interval can vary (for example, on each chain link, every five
links, or two attachments in a series with intervals every four links, etc.).
Generally two strands of chains with slats are used (Figure 2.17).

140
Applications
Attachments are subjected to bending force. If they convey heavy objects,
have long jigs installed, or receive side loads, twisting force is added to the
bending force. Depending on the application, make sure you consider these
forces in your calculations.
The shape of the attachment influences the design of the equipment. If slats
do not cover the chain rollers, guide rails may be used to support the chain
rollers on the return side.
2.3.2 K Attachment
This is an attachment made by installing A attachments on both sides of the
chain. The attachment is called K-1 or K-2 based on the number of bolt holes
on one side. The attachment interval can vary the same as the A attachment
(Figure 2.18).
Figure 2.16 A-2 Attachment Figure 2.17 A-2 Attachment with Slat
Figure 2.18 K-1 Attachment
Installation of Slat

The top of the attachment is higher than the R-rollers, so slats or jigs can be
installed over the chains (Figure 2.19). Objects can also be conveyed directly
on the K attachments.
NOTE: When the bushings and rollers wear extensively, the upper side
of the rollers may touch the slats or jigs. Larger than standard over-
sized rollers or flanged F-rollers may cause interference with the slat or
jigs. Please check with the chain manufacturer.
When a wide slat is installed on two A attachment chains, the slats may not
be able to support the weight. A chain with K attachments is installed between
the A attachment chains to help support the load (Figure 2.20).
When the slats are rigid enough and are fastened well to the attachments,
there is almost no effect from bending force to the strength of the attachment.
But if the slat is not fastened well, make sure to consider the bending force in
your calculation.
If long jigs are installed, or the attachment receives side loads, it is exposed
to twisting forces.
The return side of the K attachment chain cannot be supported with guide
rails on the rollers. The return may be slack or supported in some other way
(Figure 2.21).
2.3.3 SA Attachment
For the SA attachment, the link plate is extended on one side of the chain,
and one or two bolt holes are installed. These are called SA-1 or SA-2 depend-
ing on the number of the bolt holes (Figure 2.22). The attachment interval can
vary the same as the A attachment. These attachments may be adapted for use
with hooks or slats (Figure 2.23).
The SA attachment is simpler and stronger than the A attachment, and may
receive bending and twisting force depending on the direction of the loads.
The return side of the chains can be supported by guide rails on the rollers
unless bolts extend into the attachment.
141
Figure 2.20 Using A and K Attachments Figure 2.21 K Attachment Configuration
(Note return side.)
Take-up
Drive
Figure 2.19 K Attachment with Jigs
Installation of Bucket Installation of L-angle

142
Applications
2.3.4 SK Attachment
SK attachments are made by installing SA attachments on both sides of the
chain. They are called SK-1 or SK-2, depending on the number of bolt holes
on one side. The attachment interval can vary the same as the A attachment
(Figure 2.24).
Usually SK attachments are used with dogs or jigs (Figure 2.25). SK attach-
ments are strong enough to stand up to bending or twisting forces.
The return side of SK attachment chains cannot be supported by guide rails
on the rollers like A or SA attachment chains. The return must be slack or sup-
ported in some other manner.
Figure 2.22 SA-2 Attachment
Figure 2.24 SK-1 Attachments Figure 2.25 SK Attachments May Be Used
with Dogs or Jigs
Figure 2.23 SA Attachments Are Adaptable for Use
with Hooks or Slats
Double Strands Convey Long Materials
Installation of Hook
Installation of Pusher
Installation of V-block

143
Figure 2.26 D-3 Attachment (Extended Pin)
Figure 2.27 D Attachments with Crossrods and Jigs
2.3.5 D Attachment (Extended Pin)
In this form, the one end of the pin is extended. The attachment interval
can vary the same as the A attachment (Figure 2.26).
As shown in Figure 2.27, two sets of D attachment chains can be connected
to crossrods, or jigs (such as blocks) may be installed.
The extended pins are subjected to bending and shearing forces. The allow-
able load of D attachment that is shown in a manufacturer’s catalog is based
on a bending force concentrated at the center of the extended pin.
The return side of the D attachment chain can be supported by guide rails
on the rollers.

144
Applications
2.4 Plus α Alpha Attachments
Plus α Alpha attachments are the second most frequently used type of
modified attachments. These attachments are sorted into three types:
(1) Hole diameter in an A or K attachment or the length
of the pin in a D attachment (Figures 2.28 and 2.29).
(2) Installing a nut in the hole of an A or K attachment (Figure 2.30).
(3) Using a different type of attachment (Figures 2.31 (i) and (ii)).
Types (1) and (2) are easy-to-order products. Type (3) includes special
designs that are available for the convenience of equipment designers. These
designs can be used whenever possible for equipment.
Plus α Alpha attachments are available in the following types of chains:
(1) Special surface treatment (nickel-plated, WP®
).
(2) Made of 304 stainless steel or other metals.
(3) Lube-free (LAMBDA®
series or other type).
Figure 2.29 Changing the Pin Length in
D Attachments
Figure 2.30 Installing a Nut in an A or K Attachment
Figure 2.28 Changing the Hole Diameter in A or K Attachments
A Attachment
D Attachment
K Attachment
A Attachment K Attachment

Spec Rubber pads Improved wear Easy lateral Smaller gap For bottling Excellent
prevent resistance. transfer of between the and canning for
damage to conveyed plates. industries. conveying
the conveyed objects. relatively
materials. heavy
goods.
Spec Conveying Sharp-top Press-fitted Gripping The chain Rubber
bar-type attachment bushing is attachment bends in one pads
objects. is ideal for ideal for for thin direction only. hold the
conveying bearing. objects, such conveyed
board-type as film. material
objects. from above
and below.
Spec The upper Attachment Side plate is Inner bent HP chain with Curved
surface of the for larger sizes higher than attachments attachment. chain with
link plate has over RS180. the top of are chamfered attachment
been ground the roller. to protect and guide
to provide a conveyed plate.
smooth con- materials.
veying surface.
145
Figure 2.31 (i) Other Types of Attachments
Type Ground Large chain Double pitch Internally bent Hollow Curved
attachment. attachment with deep attachment. pin with attachment
(over RS180). link. attachment. with guide
plate.
Type Triangle Sticker Bushing Grip No-bend Rubber
attachment. attachment. attachment. attachment. attachment. attachment.
Type Rubber pad. Heat-treated Bent-end Inclined Crescent plate. Slat
top plate. top plate. top plate. attachment.
Symbol PG RS RFD UM HP GP
Attachment Series (1)
Attachment Series (2)
Top Plate, Slat Attachment
Symbol RE FS AB KU NB RSG
Symbol PSG YP SM CT CL SLT

Spec Thread Install tool Suitable for
for tool attachment conveying
attachment with clips. on the pins.
with nuts.
146
Applications
Figure 2.31 (ii) Other Types of Attachments
2.5 Special Attachments
These made-to-order products require careful consideration. Should a
manufacturer supply them, or should you make them in house? Here are
some points to weigh:
High Accuracy
The most common requirement is the height from the guide rail to the upper
edge of the A or K attachment. The “ground upper surface” type of Plus α
Alpha attachments has high accuracy. The tolerance is approximately 0.2 mm,
depending on the chain size and manufacturer. For standard attachments,
the tolerance range is wider: about two to three times that of the Plus α Alpha
attachments. During normal service, the chain will wear, and the height
will change.
Type Guide HP with guide Curved chain Threaded Extended pin Stay-pin.
roller. roller. with guide extended with clip.
roller. pin.
Type Double Top roller OBR with
strand with guide attachment
top roller. attachment. guide.
Spec Wide-top For longer For longer
roller width. conveyor line. conveyor line.
Symbol GR HP-GR CU-GR EN EC ST
Guide Roller Attachment
Free Flow Chain
Symbol TR TG SG
Guide roller prevents meandering.

147
If you require greater accuracy than is available from Plus α Alpha
attachments, make a shuttle that supports the conveyed objects, and use
chains only for tracking.
When you need high accuracy in other dimensions besides height, contact
the chain manufacturer.
Cost
The reason chain manufacturers can produce attachments at low cost is that
they use a punch-press process, which is efficient but takes time to set up.
To absorb the cost of set-up, parts need to be produced in large quantity: hun-
dreds of pieces. (The smaller the part, the more parts needed to offset
the set-up costs.)
If you need a special attachment in low quantities, the chain manufacturer
can help work out a design that can be produced at lower cost.
Turnaround Time
Chain manufacturers can supply almost all the standard attachments from
stock. Special order attachments require lead times. The lead time for specialty
attachments runs from several weeks to several months. To prevent a crisis sit-
uation, in the event of normal wear or catastrophic failure, you should stock
replacement chain and re-order well in advance. Figure 2.32 shows several
examples of specialty attachment chains that can be made.

148
Applications
Figure 2.32 Specialty Attachments

149
Figure 3.1 A Turntable and Pushing
Transfer Set-Up
Figure 3.2 Precision Conveyor Chain Set-Up
3. PRECISION CONVEYOR CHAINS
Times have changed. In the old days, most accurate indexing drives used a
turntable or pushing transfer. But these designs have limits on the number of
station installations and starting and stopping cycles (Figure 3.1).
In the 1980s, Precision Conveyor Chains were developed for this application.
These chains do not wear or elongate, which were the major obstacles to
chains in accurate indexing drives. In addition, the number of stations is
limited only by the practical length of the chain. And there is more freedom
in the starting and stopping cycle, because the chain can be connected
in a series (Figure 3.2).
Indexing Table
Chain
Pusher Transfer

3.1 Bearing Bush Chain
Light to heavy conveyance: No elongation, electric, electronic, precision
machinery industries
Bearing Bush Chain (Figure 3.3) is used in automatic assembling, packaging,
filling, and parts installation for a variety of industries, including electric, elec-
tronic, semiconductor, automobile, and food as well as in other precision
machinery. It includes the following features:
(1) High accuracy and no elongation.
(2) Interchangeability with other double pitch roller chains and
large pitch conveyor chains.
(3) Low cost.
Constructions and Features
Usually chains are designed with gaps between the pins and bushings for
proper operation. With Bearing Bush Chain, needle bearings are installed
between the pins and bushings. These add rolling elements between these
components and eliminate the sliding friction (Figure 3.4).
The advantages of this design include:
(1) Immediately after installation, the chain stretches a little (less than 0.03
percent) to fit the contacting surface of chain parts. After that, it doesn’t
stretch (Figure 3.5). The results include the following points:
150
Applications
Figure 3.3 Bearing Bush Chain
Figure 3.4 Needle Bearings in Precision Chain
Profile of Bearing Portion
Bushing
Needle
Bearing
Roller
Pin
Lubricated Between Pin and Bushing

151
3. Precision Conveyor Chains
Figure 3.5 After Installation, Precision Chain
Has No Elongation
ii) No annoying position-adjustment maintenance.
iii) No take-up adjustment or lubrication.
(2) The main dimensions are the same as double pitch roller chain and
large pitch conveyor chain (R-rollers). That gives you the following
benefits:
i) Change from standard chains to Bearing Bush Chains with
minimal redesign of the equipment.
ii) Low-cost standard sprockets can be used (special made-to-order
sprockets are required for high accuracy).
iii) Available with a variety of attachments.
(3) Relatively low cost.
Bearing Bush Chain has many sizes from small to large (Table 3.1).
Sprockets
For double pitch roller chain type, standard sprockets are used for general
applications. When the application requires high accuracy, special-order
sprockets are needed.
For Engineering Class conveyor chains, machined-tooth sprockets (made to
order) are used instead of standard flame-cut sprockets.
Table 3.1 Precision Conveyor Chain
Double Pitch Chain Maximum Engineering Class Chain Maximum
Allowable Allowable
Chain No. Load (kN) Chain No. Load (kN)
RFN2040R 0.78 RFN03075R 2.45
RFN2050R 1.27 RFN05100R 4.90
RFN2060R 1.76 RFN10150R 7.85
RFN2080R 2.94 RFN12200R 9.81
RFN17200R 12.70
RFN26250R 19.60
RFN36300R 24.50
ChainWearElongation(%)
Number of Cycles
Standard Type and High-Precision Type
i) Accurate positioning in a high-speed or indexing drive. For example,
in an application of automatic installation of electronic parts with 30
stations, a conveying speed of 10 m/min., and an index of 0.6 sec-
onds, the positioning accuracy is ± 0.2 mm (using a positioning pin).

152
Applications
Points of Selection and Handling
(1) In Bearing Bush Chain, the contacting surfaces between pins and
needles or needles and bushings are small. If these parts are subjected
to a load larger than the allowable static load of the needle bearing,
permanent deformation will occur, and the chain will not operate
correctly. The chain tension, including inertia, should be lower than
the rated allowable load.
(2) Due to the low bending resistance, the chains will vibrate at the
low-tension return side. Guide rails or guide rollers help to
prevent vibration.
(3) A “high-precision type,” which is more accurate in the overall chain
length and the dimension of attachments, is available.
(4) The double pitch chain type is basically an inch-pitch series,
but there are some metric pitches available.
Application Series
Link plates of Bearing Bush Chain are nickel-plated to avoid rusting
in indoor use.
Stainless steel Bearing Bush Chain is available for corrosive conditions.
However, the allowable load is limited because of the low hardness of the
contacting parts. In addition, the chain will elongate gradually (Figure 3.6).
Heat-resistant Bearing Bush Chain is available for temperatures up to 150°C.
Figure 3.6 Elongation of Stainless Steel Precision Chain
ChainWearElongation(%)
Number of Cycles
Stainless Steel Bearing Bush Chain

153
3. Precision Conveyor Chains
3.2 Indexing Table Chain
Precision conveyance: High accuracy, no elongation
Electric, electronic, and precision machinery industries
Indexing Table Chain is used when you need a more accurate conveyance
than Bearing Bush Chain, for example, in an assembling machine with
46 stations, a speed of 10 m/min., an index of 1.0 second, and a stopping
accuracy of ± 0.15 mm.
Indexing Table Chain is expensive because each link has seven needle
bearings (Figure 3.7). This chain includes the following features:
(1) No elongation.
(2) Each part is measured with precision; the installing accuracy is ± 0.1 mm.
(3) The chain pitch is indicated in millimeters.
(4) Four sizes are standard: 50 to 150 mm with a maximum allowable
tension between 0.49 and 1.27 kN.
Sprockets
Special sprockets with 8 or 12 teeth are required.
Figure 3.7 Indexing Table Chain
Positioning Line for Attachment
Direction of Travel

154154
Figure 4.1 Top Chains
4. TOP CHAINS

4.1 What Is Top Chain?
Top Chain has a plate to hold conveyed objects on its upper side. These
chains were originally used for bottling and canning in the food industries.
Today you will find them in a variety of applications, because they are conve-
nient and economical (Figure 4.1).
Top Chains are divided into two categories based on the type of movement:
linear or curved. The chain may be constructed of engineered plastic, carbon
steel, or stainless steel. Usually steel chains have stainless steel top plates;
however, engineered plastic snap-on tops are sometimes used.
There are several forms of Top Chains. Figure 4.2 shows the correlation
between these chains. There are additional types of chains that are not illus-
trated in Figure 4.2. These include the following:
• TO type: Steel chains for horizontal circular conveyance.
• TU type: Steel for universal movement.
• TN type (linear conveyance) and TNU type (curved conveyance):
Steel chains with snap-on top plates made of engineered plastic.
• RS40P type, RS60P type: Small pitch chains made of engineered plastic.
• RS60P-2 type, RS60PU-2 type: Double strand plastic chains.
• Bel-Top Chain type: Small pitch, wide chain, which is closer in form
to a belt than to standard-type chain.
In the following section, we will look at the features and characteristics
of Top Chains.
4.1.1 Plastic Materials for Top Chains
Most Engineered Plastic Top Chains have molded parts; the pins are made of
304 stainless steel. They offer quiet operation, do not require additional lubri-
cation, and do not scratch conveyed objects. Engineered Plastic Top Chains
are divided into several types as follows:
(1) Standard series.
(2) Low-friction, wear-resistant series. In the low-friction series, the
coefficient of friction (against guide rails or conveyed objects) is 15 to 45
percent lower, and wear life is 1.2 to 2 times longer than standard series.
155
4. Top Chains
Figure 4.2 Relationship Between Different Types of Top Chains
Carbon Steel, Stainless SteelEngineered Plastic
TTP, TP
TTUP, TPU
TT, TS
TTU
Straight Conveyor
Curved Conveyor

156
Applications
(3) Heat-resistant, high-speed series. When constructed of super engineered
plastic, this series can work continuously in temperatures up to 250°
C,
and the chains can convey objects with speeds up to 200 m/min.
(4) Anti-chemical series. These chains are made of super engineered
plastic and resist most organic solvents, inorganic salts, acids,
alkalines, and oxidizers. There is a “super anti-chemical” series
with pins made of titanium.
(5) Electroconductive series. This series has electric resistivity of 106
Ω•cm.
These chains are suitable where dust collection, electronoise, and elec-
trosparks should be avoided.
(6) Plastic pin series. In this series, chains and pins are made of engineered
plastic. Compared to the standard series, these chains are 15 to 25
percent lighter in weight and are easy to disassemble for recycling.
A larger-diameter pin and unique design make this a very strong series.
In fact, it has almost the same allowable tension as the standard series.
Table 4.1 shows the features of each type of TPU 836 chain. Coefficient of fric-
tion and maximum allowable load are under the following conditions: room
temperature, non-lubricated, chain speed 10 m/min., and stainless steel rail.
4.1.2 Guide Rail Materials
The guide rails for engineered plastic chains are usually made of 304 stain-
less steel with a good finish, MC nylon, or ultra-high molecular-weight poly-
ethylene (UHMW). For steel chains, guide rails are made of plastic.
For heat-resistant and high-speed applications, make sure you consider the
following points:
(1) When the chain operates within normal temperatures at high speeds,
choose a guide rail that is made of carbon steel or stainless steel with
polished, hard chrome-plating.
(2) When the chain operates in high temperatures, consider a polished
stainless steel guide rail. Remember to allow for heat expansion, and fix
only one end of the guide rail.
Table 4.1 Types of Engineered Top Chains
Maximum Maximum Coefficient Maximum
Chain Speed Ambient of Allowable
Material (m/min.) Temp. (°C) Friction Load (kN)
Standard Polyacetal 50 80 0.25 0.98
Low-Friction Special Polyacetal 50 80 0.17 0.98
Heat-Resistant Super Engineered Plastic 200 250 0.20 0.98
Anti-Chemical Super Engineered Plastic 40 80 0.30 0.50
Electroconductive Special Polyacetal 50 80 0.25 0.70
Plastic Pin Special Polyacetal 50 80 0.17 0.88

157
4. Top Chains
4.1.3 Lubrication
Soapy water used to be applied as a lubricant in food industries, but now a
water-based lubricant is more frequently utilized. For general applications that
allow oil, use oil to lubricate Top Plate Chains.
4.1.4 Various Accessories
In addition to the chains and sprockets explained in this book, there are a
variety of accessories, including guide rails, chain guides, and feet (Figure 4.3).
Figure 4.3 Chain Accessories

158
Applications
4.2 TYPES OF TOP CHAIN
4.2.1 TTP Top Chain
Top Chain: Engineered plastic for linear performance
Application Example
Bottling and canning
TTP Top Chains are used in linear conveyors to transport or accumulate
materials that could be easily scratched, such as bottles or cans. Set-ups may
use one or more strands of chain.
(1) In TTP Top Chain, individual top plates made of molded polyacetal are
connected using 304 stainless steel pins (Figure 4.4). Due to its simple
construction, the chain can be easily washed and cleaned. The basic
information is shown in Table 4.2.
(2) Table 4.3 shows the dimensions and function availability for selected
TTP Top Chains. In addition to the ones shown in the table, TTP Top
Chains are produced in the following widths: 63.5, 76.2, 101.6, 114.3,
127.0, 152.4, and 165.1 mm. Check with the manufacturer about the
types of chains available.
(3) Double-hinged TTP Top Chains have wider hinges than standard chains,
and are available in Top widths of 190.5, 254, and 304.8 mm. Use 25-
tooth sprockets (12.5 effective teeth) for these chains.
Figure 4.4 TTP Top Chain
Travel
Liner
Frame

Table 4.3 Top Plate Dimensions
Top Plate Low- Heat- Anti-
Width (mm) Standard Friction Resistant Chemical Electroconductive Plastic Pin
82.6 N/A
Consult
114.3 N/A Manufacturer
Consult
190.1 N/A Manufacturer
Table 4.2 Profile of TTP Top Chain
Sprocket
Bushing Maximum
Chain Pitch Diameter Allowable Number Outer Diameter
(mm) (mm) Load (kN) of Teeth P.C.D. Steel Plastic of Idler Wheel
9.5 117.33 N/A
38.1 12.7 0.83 10.5 129.26 130
11.5 141.22 142.5
12.5 153.20 154.5
(Segmented)
159
4. Top Chains
Sprockets
Use special sprockets for TTP Top Chain. Chains may slide off the steel
sprocket due to uneven load distribution or misalignment. There are optional
guide rings for steel sprockets to prevent this. Engineered plastic sprockets
have integral guides at every tooth, or every second tooth.
An engineered plastic idler pulley may be substituted for the sprocket at
the tail shaft. The idler pulley rotates freely, without bearings, on the fixed
steel shaft.
NOTE: Excessive chain tension can damage the idler pulley.
: Available

160
Applications
4.2.2 TP Top Chain
Top Chain: Engineered plastic for linear conveyance
Application Example
TP Top Chains are used for linear conveying. Applications are similar to the
TTP series (Figure 4.5).
(1) There are two specifications of TP Top Chain: Type I and Type II.
If you are developing a new application, consider Type II Chain
(Figure 4.5). It offers higher wear resistance than Type I.
(2) Tables 4.4 and 4.5 show the main characteristics and available top-plate
widths for different chain series.
Figure 4.5 TP Top Chain (Type II)
Travel

161
4. Top Chains
Sprockets
For TP Type II Top Chains, use spockets for TTU type. Twelve-tooth split
sprockets made of engineered plastic (P.D. 147.21) are also available.
An engineered plastic idler pulley may be substituted for the sprocket at the
tail shaft. The idler pulley rotates freely, without bearings, on the fixed steel
shaft.
When operating in high temperatures, use steel sprockets. If the temperature
is higher than 150°C, contact the manufacturer.
Chains for Special Applications
RS2040P chain series, with a top plate width of 50 mm, has a pitch of 25.4 mm.
This is smaller than standard Top Plate Chain, which has a pitch of 38.1 mm.
With RS2040P, you can use smaller sprockets with 19 teeth (9.5 effective teeth,
P.D. 78.23) and select a base material that meets the specific operating conditions,
for example, electroconductive, chemical-resistant, super chemical-resistant, or
heat-resistant.
Table 4.4 TP Top Chain and Sprockets
Bushing Maximum Sprocket
Chain Pitch Diameter Allowable Number
(mm) (mm) Load (kN) of Teeth P.C.D. Steel Plastic
10 123.29 N/A
12.7 (Type I) 10.5 129.26
38.1 15.2 (Type II) 1.181
11 135.23 N/A
12 147.21
13 159.20 N/A
1
Refer to manufacturer’s catalog for Heat-Resistant series data.
Table 4.5 TP Top Chain Special Feature Availability
Top Plate
Width (mm) Standard Low-Friction Heat-Resistant Anti-Chemical Plastic Pin
76.2 N/A N/A
82.6 N/A / N/A /
N/A / Consult
101.6 N/A / N/A / N/A Manufacturer N/A
N/A / Consult
N/A / Consult
Note: Two symbols in one cell stand for Type I / Type II. : Available

162
Applications
4.2.3 TTUP Top Chain
Top Chain: Engineered plastic for curved conveyance
Application Example
Bottling, canning, and general uses
One or more strands of TTUP Top Chains are used for conveying or accu-
mulating objects that are easily scratched, for example, bottles, cans, and fine-
ly machined parts.
(1) TTUP Top Chain is based on engineered plastic TP Top Chain, Type II,
but it has extra side-flexing capability. It can curve around corners with
minimum radius (R) of 600 mm. This is accomplished with tapered
knuckles.
(2) There are no float-prevention tabs on links of TTUP Top Chain
(Figure 4.6).
(3) Tables 4.6 and 4.7 show the main functions and available top plate
widths for different chain series.
Figure 4.6 TTUP Top Chain
Travel

Table 4.7 TTUP Top Chain Special Feature Availability
82.6 N/A
Consult N/A
114.3 N/A Manufacturer N/A
Consult
190.1 N/A Manufacturer N/A
163
4. Top Chains
Sprockets
steel shaft.
The main difference between TTUP and TPU Top Chain is that TTUP does
not have float-prevention tabs. Therefore, TTUP may be more easily detached
from guide rails.
Table 4.6 TTUP Top Chain and Sprockets
Chain Bushing Maximum Sprocket
Pitch Diameter Allowable Number Outer Diameter of
(mm) (mm) Load (kN) of Teeth P.C.D. Steel Plastic Plastic Idler Wheel
10 123.29 N/A N/A
10.5 129.26 130
38.1 15.2 1.08 11 135.23 N/A 142.5
12 147.21 154.5
(Split is available)
13 159.20 N/A N/A
: Available

164
Applications
4.2.4 TPU Top Chain
Engineered Plastic Top Chain for curved conveyance
Application Example
Bottling, canning, and general uses
TPU Top Chain (Figure 4.7) is used in similar applications as TTUP Top Chain.
(1) TPU Top Chain has side-flexing capability with a minimum radius (R) of
500 mm accomplished by taper-shaped knuckles, and is equipped with
float-prevention tabs on plates. A smaller minimum radius of TPU than
on TTUP, and the presence of float-prevention tabs, enables this chain to
follow complicated layouts.
(2) Tables 4.8 and 4.9 show the main functions and available widths
for various TPU Top Chains.
Figure 4.7 TPU Top Chain
Table 4.8 TPU Top Chain and Sprockets
Pitch Diameter Allowable Number Outer Diameter
(mm) (mm) Load (kN) of Teeth P.C.D. Steel Plastic of Plastic Idler Wheel
10 123.29 N/A N/A
10.5 129.26 N/A
38.1 15.2 0.98 11 135.23 N/A N/A
12 147.21 N/A
13 159.20 N/A N/A
: Available

Sprockets
steel shaft.
In high temperatures, use steel sprockets. If the operating temperature
exceeds 150°C, contact the manufacturer.
TPU is similar to TTUP except for the following points:
(1) TPU Top Chain has float-prevention tabs.
(2) It is difficult to detach the chain from guide rails.
(3) Float-prevention tabs allow the chain to easily follow any changes in rail
direction, from horizontal to vertical (Figure 4.8).
165
4. Top Chains
Figure 4.8 TPU Float-Prevention Tabs Allow the Chain to Follow the Direction of the System
Table 4.9 TPU Top Chain Special Feature Availability
82.6
Drive Sprocket
Driven Sprocket
: Available

166
Applications
Figure 4.9 TT Top Chain
4.2.5 TT Top Chain
Steel Top Chain: For linear conveyance, including bottling, paper containers,
general uses
Application Example
TT Top Chain is used for linear conveyance of beer and cosmetic bottles,
paper containers, or general products.
(1) TT Top Chain consists of stainless steel top plates with rolled hinges and
connecting pins. Due to its simple construction, the chain is easy to
clean, and it meets the requirements of sanitary environments.
(Figure 4.9).
(2) There are two standard types of TT Top Chain: N-type has 304 stainless
steel pins and 430 stainless steel plates; SS-type is made entirely
of 304 stainless steel.
(3) Table 4.10 shows the main functions of this chain.
(4) There are eight widths of top plates: 63.5, 76.2, 82.6, 101.6, 114.3, 127.0,
152.4, and 190.5 mm. The top plates have beveled (or chamfered) edges,
which permit smooth loading or accumulating of conveyed objects,
such as bottles.
Travel
Liner
Frame

Sprockets
Use special sprockets for this chain.
If you use steel sprockets, make sure to install guide rings to prevent the
chain from sliding off. This can happen if materials are unevenly distributed
on the chain, or if the chain is misaligned.
Split engineered plastic sprockets come with guides on every tooth or every
other tooth. Therefore, guide rings are not necessary. Maintenance on split
sprockets is quite simple. They are easy to install and remove from the shaft.
An engineered plastic idler pulley may be substituted for the sprocket at the
tail shaft. The idler pulley rotates freely, without bearings, on the fixed steel
shaft.
Special finishes on the upper part of the plate are available. The ground
type has a fine finish to allow for extra-smooth sliding of conveyed
bottles. The anti-abrasion finish has hard chrome plating on the upper
side of the top plate.
Table 4.10 TT Top Chain Characteristics
10.5 129.26 130
1.47 (N-type) 11.5 141.22 142.5
38.1 12.7 2.16 (SS-type) 12.5 153.20 154.5
167
4. Top Chains
: Available

Table 4.11 TS Top Chain and Sprockets
Chain Roller Maximum Sprocket
Pitch Diameter Allowable Number
(mm) (mm) Load (kN) of Teeth P.C.D. Steel Plastic
9.5 117.34
2.94 (P, NP-type) 10.5 129.26
38.1 11.91 1.03 (SS-type) 11.5 141.22
12.5 153.20
168
Applications
4.2.6 TS Top Chain
Steel Top Chain: For linear conveyance. General uses
Application Example
TS Top Chain is used for linear conveyance. TS-P type allows on-loading and
unloading objects along direction of chain movement, when a single strand of
chain is used. When objects are conveyed or moved across several strands of
chains, TS-PA type works effectively. (Figure 4.10 shows TS-P type.)
(1) In TS Top Chain, top plates are projection-welded onto RS Double Pitch
Roller Chain (RS2060-S).
(2) Table 4.11 shows the main functions of the chain.
(1) Nickel-plated and 304 stainless steel are available.
(2) The lubrication-free LAMBDA®
series (NP-P-LAMBDA, NP-PA-LAMBDA)
offers extended chain wear life without additional lubrication (not suit-
able for wet or dusty conditions).
Figure 4.10 TS Top Chain (P-Type)
: Available

Table 4.12 Characteristics of TTU Top Plate Chain
10.5 129.26 130
38.1 12.7 2.16 11.5 141.22 142.5
12.5 153.20 154.5
169
4. Top Chains
4.2.7 TTU Top Chain
Steel Top Chain: For curved conveyance. Bottles, paper containers,
or general materials
Application Example
TTU Top Chain is used for curved conveyance of beer bottles, cosmetic
bottles, paper containers, or general materials (Figure 4.11).
(1) To accomplish curved movement, TTU Top Chain has oval-shaped
hinges and float-prevention tabs for curved guide rails. These two
features differentiate TTU chain from the TT series.
(2) Table 4.12 shows the main characteristics of TTU Top Chain.
(3) There are four widths of top plates: 63.5, 82.6, 114.3, and 190.5 mm.
Figure 4.11 TTU Top Chain
: Available

4.2.8 TO Crescent Top Plate Chain
Steel Top Chain: For curved movement
Application Example
TO Crescent Top Plate Chain is available for general uses.
(1) Based on RS80 Roller Chain, TO Top Plate Chain is triple pitch
(76.2 mm). It can follow any horizontal direction because the top
plates installed on each chain link are crescent shaped (Figure 4.12).
(2) You can connect or disconnect this chain at each chain link.
(3) There are three widths of top plates: 82.6, 114.3, and 117.8 mm.
(4) Standard (S) or large (R) rollers are available.
(5) Standard type has carbon steel base chain and top plates made of
430 stainless steel. The SS-type is entirely made of 304 stainless steel.
(6) When the chain is used horizontally, pay special attention to prevent the
chain from hanging down. Support top plates with a top plate guide near
the sprocket. Use guide rails in other sections of the conveyor.
170
Applications
Figure 4.12 TO Crescent Top Plate Chain

171
4. Top Chains
Figure 4.13 TU Crescent Top Chain Can Operate in Three Directions
Sprockets
Use special sprockets. For TOS Chain (S-rollers), use 31 teeth (effective
teeth: 10 1/3, P.D. 254.59 mm), for TOR Chain (R-rollers), use 11 teeth
(P.D. 270.47 mm).
(1) Guiding at the curve: With R-rollers, you can guide the chain with
sprockets or guide rails. With S-rollers, you can guide with sprockets,
but not with guide rails.
(2) TO Chain is available with nickel plating or all 304 stainless steel.
Contact the manufacturer for information.
(1) TO Top Chains with engineered plastic top plates, plates with bushings,
and rollers are available for low-noise, light-weight applications (width:
114.3 mm). Check with the manufacturer.
(2) TU series is designed to operate in any of three directions.
(See Figure 4.13.)

172
Applications
Figure 4.14 TN Top Chain Figure 4.15 TN Top Chain Has Level Top Plates
4.2.9 TN Snap-On Top Plate Chain
Top Chain: Engineered plastic top plates. Linear conveyance, general uses
Application Example
TN Snap-On Top Plate Chain is used for conveying and accumulating objects
that are easily scratched (Figures 4.14 and 4.15), and can be used alone or sev-
eral strands in parallel.
(1) This linear conveyance chain consists of engineered plastic top plates
snapped onto outer links of RS60 Roller Chain (chain pitch: 19.05 mm,
with nonriveted pin ends). It is easy to install or exchange top plates
in this chain. When snap-on top plates of two or more separate chains
are guided by the liners, it is possible to move conveyed objects
across chains.
(2) Table 4.13 shows the maximum allowable tension and available widths
of top plates for base chains made of different materials. Notice the
higher maximum allowable loads for carbon steel and plated
carbon steel chains.
TN826PC
Liner
Frame
RS60 Special Base Chain

173
4. Top Chains
Sprockets
Usually, standard sprockets for RS60 Roller Chain with 19 teeth (P.D. 115.74
mm) through 25 teeth (P.D. 151.99 mm) are used with this chain. Stainless
steel and engineered plastic sprockets are also available.
(1) Snap-on top plates will not separate from the base chain under normal
use. Excessive loads may cause snap-on top plates to separate.
(2) An idler pulley should not be used for this chain.
(3) The back portion of the top plate rises slightly above the level of the
conveying surface in the area where the chain engages with the
sprocket. This should be considered when designing a system.
(1) Lube-free LAMBDA®
carbon steel or plated chains can be used for clean
applications. These chains are most effective if they are not exposed to
water, liquid, or dust.
(2) MW top plates are low-friction and abrasion resistant.
(3) TNU Snap-On Top Plate Chain series are used in curved movement.
Table 4.13 Maximum Allowable Loads for Top Plate Chains
Maximum Allowable Top Plate Width
Chain Spec. Load (kN) 82.6 101.6 114.3 127 190.5
Carbon Steel 6.28
NP 6.28
SS 1.03
Poly-Steel 0.88 N/A N/A N/A N/A
: Available

4.2.10 RS Plastic Top Chain
Top Chain: Engineered plastic. General uses, food industries
Application Example
RS Plastic Top Chain is used in electric, electronic, food (such as bakeries),
and other industries (Figure 4.16).
(1) Due to the small chain pitch, the transition area between conveyors is
minimal. This ensures smooth loading.
(2) Double strand chain can be used in long conveyors due to increased
allowable load.
(3) Table 4.14 shows chain sizes, availability, functions, and specifications.
Sprockets
Standard sprockets will not work with double strand chains, RS60P-2 and
RS60PU-2 chain. Special sprockets must be used.
Table 4.14 RS Plastic Top Chain
Maximum
Chain Pitch Top Plate Allowable Low- Heat- Anti- Plastic
Number (mm) Width (mm) Load (kN) Standard Friction Resistant* Chemical Electroconductive Pin
RS40P 12.70 20 0.44 N/A
RS60P 19.05 30 0.88 N/A
RS60P-2 19.05 60 1.27 N/A N/A N/A N/A
RS60PU-2 19.05 60 1.08 N/A N/A N/A N/A
* Up to 140° C.
174
Applications
Figure 4.16 RS Plastic Top Chain
RS60P-2 (Top)
RS60PU-2 (Bottom)
Curved Conveyor
: Available

175
4. Top Chains
4.2.11 Bel-Top Chain
Top Chain: Engineered plastic belt-shaped chain. Bottling, canning,
and general uses
Application Example
Bel-Top Chain offers the power and reliability of a chain system with the
smooth operation of a belt. The chain is used for linear conveyance, accumu-
lation, side loading, and movement of cans, bottles, or other materials that are
easily scratched (Figure 4.17).
Accumulation and movement with Bel-Top Chain is smoother than a system
with several strands of Engineered Plastic Top Chains. In addition, the Bel-Top
Chain system, including guide rails and other parts, costs less.
(1) The chain consists of engineered plastic modular links with small pitch
(19.05 mm) and pins. It combines the functions of a chain and
belt (Figure 4.18).
Figure 4.17 Bel-Top Chain Figure 4.18 Bel-Top Chain Combines the
Features of Chains and Belts

176
Applications
(2) There are two types of Bel-Top Chain; MWB type has low-friction and
anti-abrasion, KV-type has heat resistance (endures continuous
temperatures of up to 250°C) and high-speed resistance. Each type
uses different engineered plastic.
(3) Pins are made of engineered plastic in MWB-type and stainless steel in
KV-type. There are specially shaped snap rings installed on both ends
of the pin to prevent it from falling out.
Special features include the following:
(1) Large conveying width (up to 3 m).
(2) No slippage due to positive engagement with sprockets.
(3) Easy to maintain. The chain consists of only three parts; therefore, it is
easy to assemble, connect, and disconnect. If a single link breaks,
only the broken parts need to be replaced.
(4) Considering small chain pitch, small sprockets may be used to ensure
smooth transfer between conveyors.
(5) Sprockets prevent tracking problems. This condition is difficult to
prevent when using a conventional belt.
(6) It is easy to maintain a clean and sanitary operation. Therefore,
the chain is widely used in the food industry.
Sprockets
Use special engineered plastic sprockets with 10 teeth (P.D. 61.65 mm) for a
hexagonal steel shaft, or 24 teeth (P.D. 145.95 mm) with a square steel shaft.
When 10-tooth sprockets are used, the area between conveyors can be mini-
mized. On the other hand, 24-tooth sprockets offer smoother engagement with
the chain, and chordal action is reduced.
When conveying light products, the lateral distance between sprockets may
be extended. Refer to the manufacturer’s catalog for details.
(1) Maximum allowable load of both MWB-type and KV-type is 1.96 kN for
1,524-mm-wide chain. However, this value is affected by temperature
and speed. When the chain width is greater than 1,524 mm, check the
manufacturer’s catalog for maximum allowable load.
(2) “Open type” of MWB-type has holes in the upper panel. These can be
used in a variety of applications. For example, you can drain liquid or
allow air flow through the chain during the operation.
(3) It is important to allow for catenary, and to install take-up on the return
side. Special consideration needs to be given to the heat expansion
of KV-type.

177
5. FREE FLOW CHAINS
Figure 5.1 Free Flow Conveyor Chains

178
Applications
5.1 WHAT IS FREE FLOW CHAIN?
A free flow conveyor system allows you to stop conveyed objects (with a
stopper), while the chain (Figure 5.1) runs continuously underneath. After
the stopper is released, conveying resumes (Figure 5.2).
It is possible to get free flow function even with standard RS (figure-eight
side plates) roller chains by placing conveyed objects directly on the chains.
However, during the accumulating mode, the chain will slide underneath,
which may leave marks on the bottom of conveyed objects, and eventually
leading to excessive wear.
Free flow chains were developed to eliminate the possibility of damaging
conveyed objects during the accumulating mode. These chains are equipped
with rollers that support conveyed objects. When accumulating, freely rotating
rollers are in contact with the bottom side of goods conveyed, which ensures
smooth and damage-free operation.
There are several types of free flow chains. Figure 5.3 shows the relation
among various types of free flow chains.
Figure 5.3 Types of Free Flow Chains
Figure 5.2 Free Flow Conveyor System
Direction of Travel
Accumulation Transfer Accumulation Transfer
RS Roller
Chain
Outboard Roller
Chain
Duplex Top
Roller Chain
Top Roller
Chain
DOUBLE PLUS®
Chain
New Type
Available with
Attachments
Narrow
Space
Chains to be two strands, located at
both sides of a conveyor. Stoppers
and sorting devices may be installed
between two chains.
Roller Table

179
5. Free Flow Chains
5.2 TYPES OF FREE FLOW CHAIN
5.2.1 DOUBLE PLUS®
Chain
Free flow conveyance: Light conveyance. Electric, electronic industries
Application Example
DOUBLE PLUS Chain is a new type that meets low noise requirements and
high safety standards. It was invented in Japan in the 1980s, and it is now
being used around the world for electronics assembly lines as well as in the
auto parts, beverage, and medical equipment industries.
The chain is widely used in electric or electronic industries on the assembly
lines, where objects (for example, VCRs) are conveyed on pallets. Usually two
chains are used as a set (Figure 5.4).
Pallets are usually made of aluminum with steel or plastic (polypropylene)
liners at the chain-pallet contact point.
The common pallet type is:
Size: 500 mm ϫ 500 mm.
Weight: 20 to 30 kg (including the weight of conveyed objects).
Pallet speed: 10 to 15 m/min.
DOUBLE PLUS Chain has large center rollers with small rollers on both sides.
During conveyance, large center rollers and small rollers rotate at the same
rpm. Chain tension, while conveying objects, is relatively low, as it is affected
primarily by rolling friction.
Figure 5.4 DOUBLE PLUS®
Chain

Due to the difference in diameter between large and small rollers, the pallets
move faster than the chains. The speed ratio (K) is calculated by the following
formula:
K = 1 + (large roller diameter/small roller diameter).
The value of K is usually between 2.5 and 3.0.
During the accumulating mode, the large rollers that support the pallet rotate
in the opposite direction from the small rollers. Due to this relative motion,
friction results between the two rollers, and chain tension increases.
After the accumulator stop is released, the friction between large and small
rollers will gradually increase the pallet speed, and eventually the pallet will
resume full conveying speed (Figure 5.5).
Features of DOUBLE PLUS®
Chain include the following:
(1) Safe design, due to only large rollers being exposed when the chain
cover is installed.
(2) Low operational noise, due to low chain speed.
(3) High wear resistance, because the large and small rollers are made
of engineered plastic.
180
Applications
Figure 5.5 Basic Operation of DOUBLE PLUS®
Chain
Figure 5.6 Two Types of DOUBLE PLUS®
Chain
Small Roller
Guide Rail
Guide Rail Guide Rail
Small Roller
Small Roller Small Roller
Small Roller
Large Roller
Large Roller
Large Roller Large Roller
Why is Free Flow possible in this structure?
Pallet
Pallet Pallet
Safety Cover
Safety Cover Safety Cover
Steel Base
Chain
Steel Base
Chain
Steel Base
Chain
Small rollers are
installed in both sides
of large rollers
• When Conveying-Friction
between the large center roller and
the small roller allows them to rotate
in unison.
• When Accumulating-The larger
roller rotates freely in the opposite
direction of the small roller allowing
conveyed objects to accumulate. We
call this free flow conveying.

181
5. Free Flow Chains
There are two design types of DOUBLE PLUS®
Chain. These are shown in
Figure 5.6. In Figure 5.6 (left), the large roller is positioned between two small
rollers equipped with a step. The step portions of each small roller face each
other and are inserted in the ID of the large rollers, thus holding them in posi-
tion. In the right-hand illustration, the large roller is equipped with steps on
both sides. The small roller is positioned over each step.
Although the designs are different, the performances are practically the
same. In Figure 5.6, the left-hand chain has a K speed ratio close to 3, which
is slightly higher than the other type.
In the design shown in Figure 5.6 (left) when the chain engages with the
sprockets, the large rollers don’t lock; therefore, the pallets travel at the nor-
mal conveying speed (three times the speed of chain) at the exit or entrance
of the conveyor.
In the right-hand illustration, the large rollers lock when the chain engages
with the sprockets. Therefore, the pallet speed is reduced to the chain speed
at the conveyor exit or entrance. This is convenient if you want to transfer a
pallet to another conveyor moving at a slower speed. If sprockets are lowered
slightly, constant conveying speed at the exit from the conveyor is maintained.
The sizes of DOUBLE PLUS Chain are shown in Table 5.1.
Table 5.1 DOUBLE PLUS®
Chain Sizes
Chain Chain Large Roller Small Roller Allowable
No. Pitch Diameter Width Diameter Width Load kN*
RF2030VRP 19.05 18.3 8.0 11.91 4.0 0.55
RF2040VRP 25.40 24.6 10.3 15.88 5.7 0.88
RF2050RFP 31.75 30.6 13.0 19.05 7.1 1.37
RF2060VRP 38.10 36.0 15.5 22.23 8.5 2.06
RF2080RFP 50.80 48.0 20.0 28.58 15.0 5.29
* Regular Type (A)

182
Applications
Sprockets
Use special 10-tooth sprockets that engage with small rollers (Figure 5.7).
(1) There are two types of DOUBLE PLUS®
base chain: with or without
bushings. The bearing area on the type with bushings is larger, creating
a contact surface between the pin and bushing. The bearing area on the
type without bushings is limited to the contact surface between the side
plate and the pin. Chain with bushings has much better wear
characteristics.
(2) The guide rail and bottom surface of the pallet should be smooth and
straight in a DOUBLE PLUS Chain system for proper operation.
Therefore, check and compare that the chain has a flexible construction
that can accommodate irregularities.
(3) Large and small rollers are available in different types of materials:
standard, electroconductive, and high friction (for increased pallet
acceleration). These specifications may be combined to suit your needs.
(4) Aluminum extrusions are usually available through the manufacturer.
If the weight on the pallets is very heavy, or you want to extend the
working life of the system, steel rails should be used.
(5) If you lubricate between the pins and bushings to reduce the noise and
wear elongation, do not allow oil to get on the contacting surface of the
large rollers and small rollers or on the outer surface of small rollers.
If these parts are contaminated with oil, the pallets will not accelerate
fast enough or they won’t reach the operating speed because of roller
slip. You should buy prelubricated chains.
(6) The rigidity of the chain depends on its structure. The greater the
rigidity, the less likely that stick slip will occur (see Basics Section
2.3.5). If the conveyor is less than 15 m long, the possibility of stick slip
is greatly reduced.
Specialized Sprocket
Figure 5.7 Specialized 10-Tooth Sprocket for Use with DOUBLE PLUS®
Chain

(7) There will be a gap between head and tail sprockets of two separate
DOUBLE PLUS®
conveyors when they are positioned in one line. Install
a pallet-supporting roller in the transition area (Figure 5.8).
Technical Trends
(1) Small objects, such as screws, may fall between exposed chain compo-
nents, which can jam the system. Snap covers have been developed to
prevent small objects from jamming the line (Figure 5.9).
(2) Besides chain, sprockets, and guide rails, many conveyor components,
such as pallet guides (to control side-to-side motion) and brackets,
have been designed for DOUBLE PLUS®
Chain and guide rails. They are
available as kits. Manufacturers are also expected to develop software
packages to aid the conveyor designer in selecting the proper chains
and components.
(3) There are DOUBLE PLUS®
Chains with steel rollers for heavy loads.
183
5. Free Flow Chains
Figure 5.8 Placement of Pallet-Supporting Rollers
Conveying Surface
Conveying Surface
Pallet-Supporting Roller
Pallet-Supporting Roller
Sprocket
Sprocket
Direction of Travel
Direction of Travel
Figure 5.9 Snap Covers on DOUBLE PLUS®
Chain
Snap Cover

184
Applications
5.2.2 Outboard Roller Chain—Side Roller Type
Free Flow Chain: Electric, electronic and precision machinery conveyance
Application Example
Outboard Roller Chain with Side Rollers (Side Roller Chain) is used for free
flow conveyance, like DOUBLE PLUS®
Chain, in the electric, electronic equip-
ment, and auto parts industries. Usually two strands are used on the equip-
ment (Figure 5.10). Please refer to DOUBLE PLUS Chain, in Applications
Section 5.1.1, for typical pallet size and weight guidelines.
Side Roller Chain is based on standard roller chain with side rollers installed
on extended pins. There are three types of base chain:
(1) RF-type (double pitch roller chain) with S-rollers (straight side plates,
small rollers).
(2) RF-type (double pitch roller chain) with R-rollers (straight side plates,
oversized rollers).
(3) RS-type (figure-eight side plates, small rollers; oversized rollers are
not available).
Figure 5.10 Outboard Roller Chain with Side Rollers
Conveyed Material
Pallet
Chain
You can select various combinations of chain materials; carbon steel, plated
carbon steel, various stainless steel materials, and/or engineered plastic. The
relation between roller material availability and applicable chain sizes is
shown in Table 5.2.
Small sprockets can be used with the RS-type to minimize conveyor height.
Because the side roller diameter is larger than the chain pitch for the RS-

185
5. Free Flow Chains
type, side rollers cannot be installed on every pitch on the same side of
the chain. They can be installed on every pitch in alternating positions
(Figure 5.11).
In RF-type, the diameter and width of the side roller are different for
S-rollers and R-rollers.
When the stopper in a free flow conveyor is released, pallets accelerate to
the chain speed. This acceleration is determined by the coefficient of friction
between the side roller and the pin. The smaller the coefficient of friction, the
longer it takes for the pallets to reach the speed of the chain. Faster accelera-
tion can be accomplished by installing brake rollers. The construction and
coefficient of friction of the brake rollers are different for each chain manufac-
turer. In engineered plastic side roller products from Tsubaki, the coefficients
of friction of chain are: with brake, 0.10; without brake, about 0.06.
Outboard Roller Chain has the following characteristics compared to
DOUBLE PLUS®
Chain:
(1) Greater allowable tension for the carbon steel chain (Table 5.3).
(2) More economical. RF2050 chain costs about half as much, and sprockets
cost about two-thirds that of the equivalent size of DOUBLE PLUS Chain.
(3) More noise. Comparing systems with the same pallet speed and sprock-
ets with the same number of teeth, Side Roller Chain emits about 10 to
15 dB(A) more noise than DOUBLE PLUS Chain.
(4) Because the body of Side Roller Chain is exposed over the guide rail,
this chain does not have the same safety features as DOUBLE PLUS.
(5) Snap covers are not available for Side Roller Chain. It is difficult to
prevent small objects from falling in between chain components.
(6) Complete kits for Outboard Roller Chain, including the guide rails and
other components, are not available. Therefore, you have to create your
own system.
Table 5.2 Outboard Roller Chain (Side Roller)
RS Attachment Type RF Double Pitch Type
Engineered Plastic Roller RS40~100 RF2040~RF2100
Electroconductive
Plastic Roller RS40~60 RF2040~RF2060
Steel Roller RS40~160 RF2040~RF2160
Table 5.3 Allowable Tension of DOUBLE PLUS®
and Outboard Roller Chains
Chain Type Roller Type RF2040 RF2050 RF2060 RF2080
DOUBLE PLUS®
Regular Series 0.88 1.37 2.06 5.29
Chain High Friction Series 0.44 0.69 1.03 2.65
Outboard Roller Steel Roller 2.65 4.31 6.27 10.7
Chain Plastic Roller 0.44 0.69 1.03 1.76
(Allowable load kN)

186
Applications
Figure 5.11 Installation of Side Rollers
Sprockets
Standard sprockets may be used. In some cases, side rollers may interfere
with the sprocket hub. Additional machining of the hub might be required.
(1) Although both R-rollers and S-rollers are commonly used in Side Roller
Chains, R-rollers should be considered if either of the following condi-
tions exist:
• The overall length of the machine is more than 10 m.
• The chain speed is more than 20 m/min.
(2) R-rollers have lower coefficient of friction (without lubrication, R-roller:
0.12; S-roller: 0.21).
(3) Select Side Roller Chain according to the chain tension and allowable
roller load. Make sure to consider the tension due to the accumulating
mode when you calculate total chain tension.
(4) Side rollers can be installed in alternating positions, staggered
or parallel. Staggered rollers tend to allow pallets to run smoother.
(5) Side Roller Chain requires lubrication to reduce wear elongation
and to reduce noise level.
NOTE: Lubrication may affect (delay) acceleration; therefore, please
apply carefully.
Side Roller Chain is available in LAMBDA®
construction for lube-free
operations.
Technical Trends
Chain manufacturers are working on new chain designs that quiet
operation noise.
Chain kits, including chain, guides, sprockets, and other components are
a focus of chain manufacturer development plans.
Large pitch side roller conveyor chains are available to handle heavier loads.
Connecting Link
Staggered Installation Parallel Installation

187
5. Free Flow Chains
5.2.3 Outboard Roller Chain—Top Roller Type
Free Flow Chain: Automotive industry, precision equipment industry,
general uses
Application Example
Outboard Roller Chain with Top Rollers (Top Roller Chain) is used primarily
in the automotive and precision equipment industries for free flow conveyance
(Figure 5.12).
Top Roller Chain is based on the standard chain with extended side plates
(SK-1 attachments). Top rollers are installed on the pins that connect SK-1
extended plates. Pallets with conveyed objects are loaded on the top rollers.
Table 5.4 shows some of the base chains that are available.
Table 5.4 Outboard Roller Chain (Top Roller)
Base Chain Top Roller Spacing Top Roller Material Chain Pitch *Max. Allowable Load (kN)
RS Roller Chain Every Pitch, 2nd Pitch Steel, Plastic 12.7~31.75 2.65~17.1
Double Pitch Chain Every Pitch Steel, Plastic 25.4~63.5 2.65~17.1
Engineering Chain Every Pitch Steel 75~200 4.2~35
*Maximum allowable load listed in this table for RS Roller Chain and Double Pitch Chain is the same as that of
standard carbon steel chains. For the Engineering Chain, it is one-seventh of the average tensile strength of
standard chains.
Plastic Top Roller
Steel Top Roller
Regular Series
Figure 5.12 Outboard Roller Chain with Top Rollers

188
Applications
RS (single pitch) Top Roller Chain can only be equipped with an S-roller. R-
rollers and S-rollers are available for RF (double pitch) Top Roller Chain.
The features of Top Roller Chain include the following points:
(1) High maximum allowable tension.
(2) Economical cost.
(3) Lower stability than Side Roller Chain, because Top Roller Chain
is narrower.
(4) Snap covers are not available for Top Roller Chain. It is difficult to
prevent small objects from falling in between chain components.
(5) Noise levels during operation are higher than those for DOUBLE PLUS®
Chain. (Noise is about equal to Side Roller Chain.)
(6) Top Roller Chain installation kits, including the guide rails and other
components, are not commonly available.
Sprockets
Standard sprockets can be used with RS (single pitch) chain and with RF
(double pitch) chain with S-rollers. Other types of Top Roller Chain require
special sprockets.
Top Roller Chains are available with R-rollers and with S-rollers. The use of
R-rollers is preferred, especially if either of the following conditions exists:
• The overall length of the equipment is more than 10 m.
• The chain speed is more than 20 m/min.
R-rollers have lower coefficient of friction (without lubrication,
R-roller: 0.12; S-roller: 0.21).
Top Roller Chains can be made of stainless steel, carbon steel, or plated
carbon steel.
LAMBDA®
Top Roller Chain is available for lube-free operations. Engineered
plastic top rollers should be used in this construction because they are
lube-free.
Two types of Top Roller Chains have higher stability than standard Top
Roller Chains (Figure 5.13). They are:
• TG-form with SK attachments that point downward.
• Double Strand Top Roller Chain.
Please refer to Plus α Alpha catalog for additional information.
Figure 5.13 Types of Higher Stability Top Roller Chain
Double Strand Top Roller
TR TG
Special Attachment
for Prevention of Turnover

189
5. Free Flow Chains
5.2.4 Roller Table Chain (ST, RT)
Free flow: Bottling, canning
Application Example
Roller Table Chain lets you convey and accumulate groups of small, separate
objects, such as bottles, boxes, or cans. With Roller Table Chain, pallets are
usually not used; the conveyed materials are placed directly on engineered
plastic rollers. (See Figure 5.14.)
Roller Table Chain is constructed from two strands of chains, which are
connected with stay-pins and engineered plastic rollers that rotate freely.
Conveyed objects are placed directly on the engineered plastic rollers.
Conveyed goods are accumulated on the Roller Table Chain with
low friction.
Figure 5.14 Roller Table Chain

190
Applications
There are two types of Roller Table Chain: ST and RT.
(1) ST-type has special attachments that cover the upper side of the chain.
These attachments are level with the engineered plastic rollers, which
permits low resistance as conveyed objects move across the chain and
onto the engineered plastic rollers.
(2) RT-type does not have special attachments that cover the chain.
Therefore, side guides are required to prevent smaller conveyed objects
from crossing the chain part of the assembly. If the conveyed objects
are large (for example, pallets), they can cross the RT-type chain
(Figure 5.15).
(3) ST-type is made of 304 stainless steel or nickel-plated carbon steel;
RT-type is made of stainless steel.
Features:
(1) The resistance during accumulating (line pressure) is low; the coefficient
of rolling friction of engineered plastic roller is 0.06 ~ 0.10.
(2) ST-type is available in pitches ranging from 9.525 to 15.875 mm; RT-type
from 9.525 to 19.05 mm. Because the pitch is small, Roller Table Chain
is very effective at conveying small objects.
Engineered plastic rollers for Roller Table Chain are available in a wide
range of effective widths: from 50 to 601.2 mm. Chain width is limited by the
conveying capacity, which is usually expressed in kg/m2
.
Figure 5.15 Two Types of Roller Table Chain
Stay-
pin (with
rotation stop)
Stay-
pin (with
rotation stop)
Same Height
Plastic Roller (Gray)
Plastic Roller (Gray)
Special Attachment
ST-Type RT-Type

191
5.FreeFlowChains
Coffee Break
• Roller Chain Manufacturing Process

192
6. LARGE PITCH CONVEYOR CHAINS
Figure 6.1 Large Pitch Conveyor Chain

193
6. Large Pitch Conveyor Chains
6.1 WHAT IS LARGE PITCH CONVEYOR CHAIN?
Large pitch conveyor chains (Figure 6.1) are big pitch chains with rollers,
originally based on cast iron chains. The base material was changed to steel,
and they incorporated some of the features of drive chains and small pitch
conveyor chains.
They were standardized by Tsubaki in the 1920s. They were developed in
Japan as millimeter-unit pitch chains, available in a variety of pitches for a
given capacity. Similar chains are available in the United States, but are usually
measured in inch-unit pitch.
6.1.1 Standards
ISO 1977/1 ~ 3 includes standards for large pitch conveyor chains. These
standards are for European-type chains, which have larger diameter bushings,
pins, and rollers, and thinner, taller side plates than comparable sizes of chains
made in the United States or in Japan.
Japan Chain Industry Association Standard JCAS 2-1982 governs seven cate-
gories of large pitch conveyor chains. The major characteristics of these cate-
gories are shown in Table 6.1.
RF 12 200 - R
Average tensile strength,
in tons, of the chain when it
was originally designed
Chain pitch
Roller type
Table 6.1 Major Characteristics of Large Pitch Conveyor Chain
There are larger sizes than those shown in Table 6.1; in fact, tensile strength
can exceed 4,460 kN! If you need extra-high performance chain, discuss the
options with the manufacturer.
6.1.2 Nomenclature
Some chain manufacturers use their own nomenclature. In the case of
Tsubaki, for example, chain size 16 with 200 mm pitch, is listed as RF12200-R.
Here’s what that name means.
Chain Tensile Side Plate Inner Link Roller Diameter
Number Strength Pitch
(Pin Dia.) (kN) (mm) Height Thickness Width Small Large
08 29.4 75ϳ150 23 3.2 15.7 15.9 32
11 68.6 75ϳ150 33 4.7 20.7 22.2 40
14 107.9 100ϳ200 39 6.3 28.7 29.0 50
16 176.5 150ϳ300 46 8.0 35.8 34.9 65
19 205.9 150ϳ300 52 9.5 50.1 40.1 80
22 274.6 200ϳ450 66 9.5 55.9 44.5 100
25 470.7 250ϳ600 81 12.7 65.4 50.8 125

194
Applications
6.1.3 Construction and Features
The structure of large pitch conveyor chain is shown in Basics Section 1.1.
6.1.3.1 Shape Features
(1) Side plates are straight.
(2) Because the radius of the side plate end is greater than half of
the side plate height, the corner of the engaging side plate will rise
slightly when the chain joint engages the sprocket. This may cause
interference with objects conveyed directly on a chain equipped with
an S-roller. (The roller diameter is less than the height of the side plate.)
(3) The end of the pin (opposite to the head of the pin) is equipped with
a cotter hole for a T-pin. This arrangement allows easy assembly or
disassembly of chain links.
(4) The pin has a swell neck at one end, and the cotter side can either be
double flat or have a D-shape. Accordingly, side plates have full round
pin holes, and D-shaped or double-flat pin holes.
(5) There are three types of rollers available: R, F, and S (M, N).
The F-roller is a feature of large pitch conveyor chains, since they are
useful in guiding the chain on the rail. However, the flange wears against
the rail, and therefore, should only be used when the chain is lubricated,
or when the conveyed material acts as a lubricant. Additionally, F-rollers
should be avoided where heavy loads are conveyed, otherwise the flange
may wear quickly or break. As a rule, S-rollers are used to reduce sprocket
tooth wear due to smooth engagement with the sprocket, but are not suit-
able for rolling conveyance.
(6) R- and F-rollers have small-diameter hubs on their sides.
6.1.3.2 Function Features
(1) High rigidity.
Large pitch conveyor chains are designed to carry heavy loads and endure
rough loading. Of course, there are limits to the chain’s integrity, and it is
important to consult the manufacturer for details.
Let us check the chain’s resistance to bending. The following formula shows
the relationship between bending moment, M, and stress:
M = ␴Z = 1/6 ϫ ␴ ϫ H ϫ t2
␴: stress on side plate
H: side plate height
t: side plate thickness
Using the equation, let’s compare the effects of side plate thickness (t) on
chain rigidity when tensile strength, side plate height (H), pin diameter, and
bushing diameter are held constant.

195
Here are two examples. Case 1 reflects design considerations for a large
pitch conveyor chain; Case 2 is for a small pitch conveyor chain.
Case 1.
Bending moment: M1 = 1/6 ϫ ␴ ϫ H ϫ t2
Case 2.
t2 = t/2
␴2 = 2␴ (in order to maintain the same tensile strength)
M2 = 1/6 ϫ ␴2 ϫ H2 ϫ (t2)2 = 1/6 ϫ 2␴ ϫ H ϫ (t/2)2
Bending moment: M2 = 1/12 ϫ ␴ ϫ H ϫ t2
Therefore, the large pitch conveyor chain (Case 1) can withstand twice the
moment (M) of small pitch conveyor chain (Case 2).
(2) Large pitch conveyor chain is designed to operate in harsh conditions.
However, certain environments may affect the side plates, which can
lead to stress-corrosion cracking, for example. This is a rare occurrence
even for heat-treated side plates of this series.
(3) The chain is designed with relatively large clearances between
components. Typically, even if foreign material gets between the chain
parts, the rollers will continue rotating, and articulation of the links is not
easily impaired.
(4) In Table 6.2, different materials are listed for each chain part of
frequently used series. This lets you create a chain specifically for your
operating environment at an economical cost. In Table 6.2, the “O” mark
designates available materials for the chain parts. Table 6.3 shows the
relation of materials and the chain parts.
(5) Attachments have high strength. Take the commonly used A attachment
as an example. During operation, it is subjected to bending and twisting
forces. Bending moment and twisting moment are calculated according
to formulas shown below.
Bending moment (M) = 1/6 ϫ ␴ ϫ H ϫ t2
Twisting moment (T) = A ϫ ␶ ϫ N ϫ t2
The allowable values of M and T are quite high for large pitch conveyor
chain compared with small pitch conveyor chains. Attachments have higher
resistance to breakage during operation, but verify the bending and twisting
moments. Manufacturers can help you determine the appropriate chain size
and attachment for an application.

: Available : Not Typically Used
196
Applications
(6) It is relatively easy for users to modify chain attachments, by machining
or welding, to fit specific applications. Consult with the chain manufac-
turer in advance to avoid damaging the chain.
6.1.3.3 Disadvantages
(1) Larger pitch chain increases the size of the equipment, which may be
considered an obstacle.
(2) To keep the size of the equipment small when using large pitch chain,
sprockets with small numbers of teeth are commonly used. This
contributes to greater speed variation of the chain.
(3) Although applications can run as fast as 330 m/min., normally large
pitch chains should be used at low speeds.
Large pitch conveyor chains are generally more costly than smaller pitch
roller chains, and in the case that the system or the chain does not function
as designed, it may be more difficult to resolve these issues than with
smaller chains.
You are ultimately responsible for selecting the proper chain, so follow all
the steps in the selection process, and consider what effects the system or
the conveyed materials have on the chain, in strength, wear, corrosion, etc.
As stipulated in previous sections of this book, the calculations of bending and
twisting strength of chain attachments, large or small, are the same as with
other machine elements.
Work with a chain manufacturer who has a good reputation for quality and
safety; who offers knowledge, expertise, and superior service; and who manufac-
tures quality product. Remember, not all chains and attachments are listed in the
catalog, as it would be impractical to publish all specifications and information.
Table 6.2 Typical Material of Commonly Used Chain Series
Non-
Heat-Treated 400 Series 304
Steel Heat-Treated Steel Stainless Steel Stainless Steel Cast Iron
Side Plate
Pin
Bushing
Roller

DT
GT
Application
Greater
Function
Features
Basic Series • Most Popular and
Economical
• Greater Wear Life Between
Bushing and Roller
• Compact Design
• Popular Series
• Greater Wear Life Between
Pin and Bushing
• For Cement Conveyor
• For Bulk Conveyor
• Good For Directly Conveying
on the Chain
• For Compact Design
(Power and Space Saving)
• For Unit Conveyor
• For High Accuracy
• Positioning with Indexing
Drive on Unit Conveyor
• Low Noise, Clean, and
Light Weight
• No-Lube
• Corrosion Resistance,
Heat Resistance, and Cold
Resistance
• Corrosion Resistance,
Heat Resistance, and Cold
Resistance
• Incidental Water Contact
• Incidental Water Contact
• Good For Conveying
Abrasive Bulk Materials
• Clean, Low Noise, Corrosion
Resistance
• Light Weight
• No-Lube
Wear Resistance
Between Bushing
and Roller
Reinforced Series
Wear Resistance
Between Pin and
Bushing
Reinforced Series
Bearing Roller Series
Bearing Bush Series
Plastic Roller Series
Plastic Roller and
Plastic Sleeve Series
400 Stainless Steel
Series
Reinforced 400
Stainless Steel
Series
300 Stainless Steel
Series
Corrosion and Wear
Resistance Between
Pin and Bushing
Corrosion and Wear
Resistance Between
Pin, Bushing, and
Roller
Reinforced Series
300 Stainless Steel
Series Plastic Roller
Series
300 Stainless Steel
Series and Plastic
Sleeve Series
For Regular
NormalEnvironmentCorrosiveandHigh-Temperature
Environment
LightCorrosiveEnvironment
For Wear
Resistance
For Heavy-Weight
Objects
For High-Accuracy
Positioning
For Low Noise and
No-Lube
For Corrosion
Resistance and Heat
Resistance
For Partial Corrosion
Resistance
For Low Noise and
No-Lube
AT
CT
BT
B-DT, B-AT
RFN
DTP
RFS-DTP
NT
PT
ST
MT
RT
YT
STP
RFS-STP
NOTE: 400 Stainless Steel Series Chain May Rust Depending on Environmental Conditions
197
Table 6.3 Relationship of Materials and Components

198
Applications
6.2 STANDARD CONVEYOR CHAINS
6.2.1 RF Conveyor Chain
Large conveyance: Basic type, general uses
Application Example
This is the basic chain series of large pitch conveyor chains (Figure 6.2).
See Basics Section 1.1.
Sprockets
Standard sprockets with 6, 8, 10, and 12 teeth are available for RF Conveyor
Chains with R-rollers. For S-rollers, sprockets with 15 and 25 teeth (7.5 and
12.5 effective teeth, respectively) are also available.
Figure 6.2 Large Pitch Conveyor Chain

199
The sprockets are sorted into four types according to size, usage, and budget:
(1) Plain bore.
(2) Finished bore with keyway.
(3) Equipped with POWER-LOCK®
, a keyless locking device (Figure 6.3).
(4) Detachable tooth.
Although connecting links are easy to use, the rigidity and strength of the
connecting links is less than the other links. If strength is an issue, consider
the use of outer links instead of connecting links. Special tools are available to
assemble outer links. Check with the manufacturer.
(1) Bearing-roller series: Lower coefficient of friction and larger allowable
roller load.
(2) Plastic roller series: Bushings and rollers are maintenance free.
(3) Plastic sleeve series: Pins and bushings are maintenance free.
Figure 6.3 RF Conveyor Sprocket with POWER-LOCK®
Keyless Locking Device

200
Applications
6.2.2 RF Bearing Roller Conveyor Chain
Large conveyance: High performance chain. General uses
Application Example
RF Bearing Roller Conveyor Chain is used in automobile, steel, electric, and
other industries.
In this large conveyor chain, cylindrical roller bearings are installed between
the bushing and roller of the RF Conveyor Chain (Figures 6.4 and 6.5).
Compared to basic RF Conveyor Chain, RF Bearing Roller Conveyor Chain
has the following features:
(1) The coefficient of rolling friction for RF Bearing Roller Conveyor Chain
is one-third to one-sixth that for RF Conveyor Chain.
Basic RF Conveyor Chain: without lubrication, 0.13 to 0.18; with
lubrication, 0.08 to 0.12.
RF Bearing Roller Conveyor Chain: 0.03.
This means the chain tension is reduced, and, frequently, a smaller chain
size can be used. The conveyor will also require less energy to operate,
making it more economical.
(2) The initial cost of equipment is reduced. Because the coefficient of
rolling friction is lower, you can use smaller sprockets, motors, reducers,
shafts, bearings, and frames.
Figure 6.4 RF Bearing Roller Conveyor Chain
Figure 6.5 RF Bearing Roller Conveyor Chain
Includes Cylindrical Roller Bearings
Bushing
Spacer
Cylindrical Roller Bearing
Roller

201
(3) The allowable load of the roller is increased. The allowable roller load
for RF12000-R Bearing Roller Conveyor Chain is 8.35 kN, which is 1.6 to
3.3 times greater than the equivalent size of a basic type with lubrication
(2.50 kN for nonheat-treated roller; 4.17 kN for heat-treated roller).
Capacity of the roller for RF12000-R Bearing Roller Conveyor Chain is
equivalent to RF26200-R Conveyor Chain with heat-treated rollers. This is
two sizes larger. In horizontal and slightly inclined conveying, usually the
chain size is determined by the allowable load of the roller. Because of
the reasons we have discussed, you can select a chain two to three sizes
smaller. Rollers are also exposed to high load when they engage with
sprockets. Even though this load may be several times greater than the
vertical load on rollers during conveying, it is within the capacity range
of bearing rollers.
(4) Lower maintenance. RF Bearing Roller Conveyor Chain has grease
pockets on both its sides. Although we have received reports that these
chains have been operated for five years without any maintenance, we
suggest that you lubricate the bearing roller occasionally.
(5) Longevity of the bearing roller. The bearing roller is large in diameter
and short in length; therefore, failure due to foreign material getting
inside it is rare. Some types of roller bearings are prone to failure due
to foreign objects causing misalignment.
(6) Accepting thrust load. A self-lubricating spacer is installed on both sides
of the roller to accept thrust load. The spacer prevents a direct contact
between the rotating roller and the side plate; therefore, wear particles
getting inside the bearing is minimized.
(7) Stick-slip resistance. Stick slip is virtually eliminated because of the low
coefficient of friction in a wide range of speeds. Consult the manufactur-
er when conveyor speed is less than 2 m/min.
(8) Wide range of chain sizes is available. The ball bearings commonly avail-
able on the market cannot be adapted for the needs of chains due to
their limited load capacity. It is difficult to adapt ball bearings to rollers
with diameters less than 45 mm, but roller bearings can be adapted for
use by using the bushing and roller as bearing races.

202
Applications
Sprockets
The standard sprockets used for RF Conveyor Chain are used for RF Bearing
Roller Conveyor Chain.
(1) The design of standard bearing-roller spacers is similar to spacers used
in ordinary ball bearings. They are not water- and dust-proof. Oil- or
labyrinth-seals can be installed (on a made-to-order basis) if the chain
is going to be exposed to water or dust. Please consult the chain
manufacturer.
(2) A grease nipple can be installed on the pin head to provide grease to
bearing parts (only certain sizes are available).
(3) The working temperature is limited to -20° to 80°C. The limiting factor is
the spacer. When a temperature-resistant material is used for the spacer,
operating temperatures may be expanded. Contact the manufacturer for
additional information.
(4) To reduce the impact of the bearing roller as it engages the sprocket, use
sprockets with greater numbers of teeth. For example, if the chain speed
is 30 m/min., use a 10-tooth sprocket. Consult with the manufacturer if
the chain speed is greater than 30 m/min.
(5) Do not select Bearing Roller Chain based on roller allowable load alone.
In some applications, you also need to verify the strength of attachments
to prevent breakage. Refer to the manufacturer’s catalog for additional
information.
(1) Outboard Bearing Roller Conveyor Chain is used on assembly lines
(Figure 6.6). In this type of chain, bearing rollers are installed on the
outside of the chain, making it ideal on long assembly lines, like auto
lines, where work is performed on the conveyed products along the
line. Outboard Bearing Roller Conveyor Chain is easy to support on the
return side. If you combine the design features of Outboard Bearing
Roller Conveyor Chain and Bearing Bush Chain, you can create a chain
with very, very low elongation (practically nonexistent) and minimal
rolling friction.
(2) Waterproof-bearing Roller Conveyor Chain (Figure 6.7) has heat-treated
bearings made of 403 stainless steel, and includes oil-seals and grease
nipples. Originally this chain was developed for the “shower test,”
which checks the leakage in automobile manufacturing. It can be
used in any application where the chain is exposed to water spray.
NOTE: Charge with grease regularly.

203
(3) Plastic sleeve type. Installation of plastic sleeves between the pins and
bushings makes Bearing Roller Chain maintenance free. It also reduces
the allowable tension. It is available in the following sizes: RF03, RF05,
RF450, and RF10.
(4) A variety of attachments, including special attachments, can be installed
on RF Bearing Roller Conveyor Chain.
Technical Trends
Because of the lower initial cost of the entire installation, RF Bearing Roller
Conveyor Chain has gained acceptance in a wide range of applications. Further
series development is required to respond to various applications.
Figure 6.6 Outboard Bearing Roller
Conveyor Chain
Figure 6.7 Waterproof-bearing Roller
Conveyor Chain
Outboard Bearing Roller
Guide Rail Sprocket
Grease Nipple
Spacer
Cylindrical Roller Bearing
Oil Seal
Roller
S-Roller

204
Applications
6.2.3 RF Plastic Roller Plus Plastic Sleeve
Conveyor Chain
Large Pitch Conveyor Chain: Maintenance-free type for light load
Application Example
RF Plastic Roller Plus Plastic Sleeve Conveyor Chain is ideal for maintenance-
free, light-load applications. It is not suitable for conveying bulk materials
(such as grains) or when the application exposes it to rough handling
(Figure 6.8).
See the section on Plastic Sleeve Chain in Small Pitch Conveyor Chains
(Figure 6.9).
Sprockets
Standard RF Conveyor Chain sprockets may be used.
The maximum allowable load of this chain is smaller than the standard
series. For example, maximum allowable load of RF05100-R with plastic sleeve
is 5.20 kN (with 8-tooth sprocket), while for the standard type it is 9.80 kN.
This represents 47 percent reduction in the maximum allowable load. The
coefficient of rolling friction is also 47 percent lower (0.08 versus 0.15 for stan-
dard type without lubrication). Therefore, it is important to note that while the
maximum allowable chain tension is reduced, the coefficient of friction is also
reduced commensurately. The result is that the allowable conveyed object
weight on the conveyor remains the same.
Figure 6.8 RF Plastic Roller Plus Plastic
Sleeve Conveyor Chain
Figure 6.9 Wear Comparison
ChainWearElongation
Operation Time without Lubrication
Carbon Steel Chain
Plastic Sleeve Chain
Engineered Plastic Roller
Engineered Plastic Sleeve

205
6.3 SPECIALTY CONVEYOR CHAINS
6.3.1 Bucket Elevator Chain
Large conveyance: Vertical conveyance of grain and other bulk materials for
the cement, chemical, and food industries
Application Example
Bucket Elevator Chains convey bulk materials vertically. You might see this
type of chain used to move cement, coal, or grain, for example. Buckets are
installed at regular intervals, and the chain moves continuously, scooping and
conveying the product. Because they are effective and economical, Bucket
Elevator Chains are widely used (Figure 6.10).
When the chain engages the upper sprocket, the buckets are tipped, and
conveyed objects are discharged. Discharging occurs either with centrifugal
force or continuously, which uses the bottom side of the bucket as a guide
for the next bucket.
The trend has been for bucket elevator equipment to become smaller, to
economize on installation costs. To reduce the operating costs, the chain must
travel faster (more than 80 m/min.). Therefore, the centrifugal discharge buck-
et elevator has become more common (Figure 6.11). Usually, the capacity of
the conveyed material is within the range of 300 ton/h.
Figure 6.10 Bucket Elevator Figure 6.11 Discharging of Buckets Occurs with
Centrifugal Force or Continuously
Continuous
Discharge
Centrifugal
Discharge

206
Applications
In large-bucket elevators, two chains are installed, one on each side of the
bucket. Small-bucket elevators use only one strand of chain. The two-strand
arrangement is a preferable design, ensuring safer operation.
Bucket Elevator Chain is based on standard large pitch conveyor chain with
K-2 or G-4 attachments. Buckets are spaced evenly (usually every two links)
over the length of chain.
Three important construction features include the following:
(1) Superior wear resistance of pins and bushings, which reduces chain
elongation. This has become increasingly important as cement makers
have increased the amount of slag in concrete.
(2) High fatigue resistance.
(3) Easy connecting and disconnecting. This is very important because of
the limited space in the elevator housing. Chain must be easy to handle.
Sprockets
Usually, sprockets with 12 teeth are used in low-speed bucket elevators
(chain speed less than 45 m/min.). High-speed bucket elevators normally
require 24-tooth sprockets. It is important to choose a sprocket with suitable
pitch-line clearance.
Excess conveyed material may accumulate in the bottom of the casing,
which can cause accelerated wear. Worn chain and sprockets will not engage
correctly; the sprockets may have to be replaced. Sometimes, welding material
onto the tooth at the point of excessive wear will restore the sprocket, but it is
not recommended. Additionally, this procedure is extremely difficult with the
sprocket that is located at the top of the bucket elevator.
Even sprockets with hardened teeth are subject to excessive wear in bucket
elevators, due to the abrasive nature of conveyed materials. For example, in
cement conveyors, there is a point of sprocket hardness at which wear is virtu-
ally eliminated. However, it is impractical and expensive to make such hard
teeth in standard sprockets. In the 1980s, detachable-tooth sprockets were
developed, which permit the replacement of the tooth part only (Figure 6.12).
The body of the sprocket remains on the shaft, which reduces repair time and
costs. By using special materials in the tooth insert, high tooth hardness is
achievable, and therefore, wear life is increased. Use of detachable-tooth
sprockets is increasing, especially in the cement industry.

207
(1) Choose Bucket Elevator Chain carefully. If the chain breaks, it is
extremely difficult and time consuming to remove broken chain from the
bottom of the casing. Re-installation is also very demanding. Rely on
chain from manufacturers with proven records for quality and reliability.
(2) Use special tools to connect and disconnect chain links.
(3) Avoid grinding the pins, heating the plates, or increasing the size of side
plate holes during chain assembly. These procedures, sometimes used at
facilities, allow easier assembly of links; however, it compromises the
strength of chain, which can lead to ultimate failure.
(4) Consider using detachable-tooth sprockets.
(5) For safety reasons, inspect chain and sprockets frequently, since chains
and sprockets have a limited useful life.
Figure 6.12 Detachable-Tooth Sprocket
Sprocket
Body
Nut Tooth Insert
Bolt

208
Applications
6.3.2 Flow Conveyor Chain
Large conveyance: Conveyance of bulk materials in a closed case; cement,
chemical, and food industries
Application Example
Flow Conveyor Chain moves bulk materials in a closed case. It conveys
the particles horizontally, on a slight incline, or vertically in an arrangement
shaped like the letter L. This conveyor is sometimes called a Redler Conveyor
(Figure 6.13).
Generally, a flow conveyor is used widely in the conveyance of bulk materi-
als such as cement and fertilizer in chemical industries, and grain in food
industries. Because it is enclosed, dust from the conveyed materials is con-
tained, and will not pollute the surrounding area. A flow conveyor is not usu-
ally used to move sticky, dusty, or low-density products.
A flow conveyor set up to move cement has an average capacity of 300
ton/h and a speed of 35 m/min. Usually one strand of chain is used.
Specially shaped attachments with large clearances (Figure 6.13) are installed
on small pitch or large pitch conveyor chains. The chain operates in a casing
filled with conveyed material, such as grain, flour, or ash.
Figure 6.13 Flow Conveyor Chain

209
This is based on a phenomenon used in a basic science experiment; when
you put sand in a long cylinder, closed at one end with paper, and push the
sand with all your strength, the paper cannot be broken if the cylinder is long
enough. This is because the friction between the sand and the cylinder
absorbs all of the pushing force. Conversely, in the flow conveyor, the attach-
ments work as moving walls, and the sand moves along with it. To lift con-
veyed objects, the friction at the bottom wall of the conveyor must support the
weight of the vertical portion, therefore, the conveyor must have a bottom line
“L” shape.
Because there is very little relative movement among the conveyed materials
in this application, breakage is rare. The case width is determined by the
attachment dimensions; usually it is less than 750 mm.
Chains for flow conveyors include: RF03075 (average tensile strength, 29 kN)
through RF26200 (314 kN) for grain conveyance; RF450W (108 kN) through
RF36300N (868 kN) for other applications.
Sprockets
Standard sprockets for RF-type conveyor chain are used for flow conveyors.
Detachable tooth sprockets are beginning to be used these days.
(1) There are several types of attachments available, depending on design
and arrangement of the conveyor and whether material is pushed against
the bottom of the casing or its side walls.
Figure 6.14 shows several types of attachments (L, B, U2
V, and W).
The set-up on the right-hand side has more pushing power than the one
on the left-hand side. The specific properties of the material conveyed
determine the type of attachments that should be used. Discuss your
application with the manufacturer.
Figure 6.14 Examples of Attachments for Flow Conveyor Chain
L B U2V W

Figure 6.15 Installation of a Cleaner on a Flow Conveyor Chain
Figure 6.16 NFX-Type Block Chain
Direction
Cleaner
Sweeping Board
210
Applications
(2) KL-type attachment is an inclined version of an L attachment. This attach-
ment can convey low-density and sticky materials.
(3) In grain applications, installation of a cleaner prevents mixing of differ-
ent types of grains, and the cleaner removes any particles in the casing
that could go bad. Usually the cleaner is installed at intervals of 6 m
(Figure 6.15).
(4) An M-roller, which rotates more smoothly than an S-roller, is typically
used in the base chain.
(5) If the conveyed materials are highly abrasive materials, special block
chain provides longer wear life. (Figure 6.16 shows a set-up with NFX-
type block chain.)

211
Coffee Break
A Brief History of Chain
The word meaning “chain” can be traced back to an ancient word in the
Indo-European language family. As early as 225 BC, chain was used to draw
a bucket of water up from a well. This very early bucket chain was composed
of connected metal rings.
In the 16th century, Leonardo da Vinci made sketches of what appears to be
the first steel chain. These chains were probably designed to transmit pulling,
not wrapping, power because they consist only of plates and pins and have
metal fittings. However, da Vinci’s sketch does show a roller bearing.
It took some time for the technology to catch up with the concept. Problems
in the manufacturing and processing of steel prevented chain growth until the
19th century, when new technologies made steel chain and bearings realities.
In the 1800s, a Frenchman named Gull obtained a patent for a similar chain
for use on a bicycle. This chain, called “Gull Chain,” is still used today in
hanging applications.
When molded chain was invented in the 19th century, things began to move
rather quickly. First came the cast detachable chain, which is composed of
identical cast links. Next, the pintle chain, which has a separate pin, appeared.
The cast detachable chain and the pintle chain have been improved over the
years, and they are still in use today in some special applications. They are
being replaced—gradually—by large pitch steel conveyor chain.
In the late 1800s, a new development—the
bushing—revolutionized steel chain. Chains
with bushings had greater wear resistance
than Gull Chain because the bushing acted
as a bearing, protecting the pin. At this point,
the chain story moves into superspeed. Steel
bushing chain was used on bicycles, in the
rear-wheel drive of early automobiles, and,
in 1903, as the propeller drive in the Wright
brothers’ airplane.
Airplane built by the Wright brothers First drawing of chain during the
Renaissance by Leonardo da Vinci

212
Applications
6.3.3 Parking Tower Chain
Large conveyance
Application Example
Shortage of parking in large cities created a demand for carousel-type (verti-
cal-rotation) multilevel parking, that first appeared in Japan in 1962 (Figure
6.17). Tower parking lots permit the storage of many vehicles (usually more
than 30 cars) in a small space. Over the years, tower parking has become
increasingly popular. Currently there are more than 10,000 of them in Japan.
Parking Tower Chain supports and rotates the cage containing the vehicle.
As an interesting note: Elevator parking garages, which use transmission roller
chains or wire ropes to raise and lower the vehicles, are increasing in number.
But vertical-rotation garages are still the majority.
There are only a few manufacturers producing parking tower systems.
However, each manufacturer produces a specific design.
Figure 6.18 shows an example of Parking Tower Chain.
The entire assembly consists of chain, attachments, and side rollers. The
chain receives tension, which can be summarized as follows:
Chain tension = weight of automobiles and cages + weight of the chain
+ friction on the side roller + tension from take-up.
Figure 6.17 Vertical Rotation Parking Elevator Figure 6.18 Example of Parking Tower Chain

213
Each attachment must support the weight of an automobile and a cage. The
side rollers prevent the attachments from tilting. Spacing of each cage is
between 1,600 and 2,000 mm, and attachments are installed on every fourth
chain link. Therefore, the chain pitch is 400 to 500 mm. Tensile strength varies
between 1,333 and 1,500 kN, depending on the type of chain that is used (the
largest one is 2,940 kN). Standard chain speed is 16 m/min., but in some
applications speeds reach 25 m/min.
Sprockets
The special shape sprocket with 12 teeth is used with this chain. Usually the
sprocket is made by the original equipment manufacturer.
(1) Safety is a major concern with this application. The technical standards
developed by the Japan Parking Industry Association require a safety
factor of more than seven.
(2) It is very important that the original equipment manufacturer (OEM) and
the chain manufacturer work closely to select the design and size of the
chain for the application. Only manufacturers with experience in this
type of application should be considered.
(3) Make sure to include the weight of the chain itself in calculations. It is
an important factor, since the number of cars that can be stored may be
affected by the weight of the chain.
(4) Pins, bushings, and side rollers must be lubricated regularly, and all com-
ponents must be inspected frequently. These should be included in the
maintenance contract from the OEM.
Technical Trends
Desirable characteristics for Parking Tower Chain include low noise, high-
speed stability, light weight, and maintenance free.

214
Applications
6.3.4 Continuous Bucket Unloader Chain
Large conveyance: For conveyance of iron, stone, coal, and rock salt
Application Example
Continuous Bucket Unloader Chain is used to remove large quantities
of material, like iron, stone, coal, or rock salt from a ship’s cargo hold
(Figure 6.19). This application originally used a cable-driven bucket on
a crane rather than chains. However, there were several problems with the
original design—contamination of the environment by conveyed material,
difficulty with automation, inability to scoop material in hard-to-reach
areas, and short working life of wire rope. Because of these problems,
chain has become the design of choice in current applications.
Figure 6.19 Continuous Bucket Unloader Chain

215
In this conveyor form, buckets that scoop conveyed objects are installed
between two chains. Mobility and flexibility make this equipment different
from the conventional bucket elevator. The conveyor system can be moved to
different locations, and the equipment can be transformed from an L-shape to
an I-shape to get to hard-to-reach areas.
The maximum conveyance capacity: 3,000 ton/h.
The maximum chain speed: about 100 m/min.
Some types of flow conveyors are used for unloaders.
Chains used in continuous bucket unloaders are exceptionally large,
even when compared to other large pitch conveyor chains. Average tensile
strengths are 3,040 kN, 3,630 kN, and 4,460 kN for some of the heaviest
chains. Usually N-rollers are used in the chain.
Sprockets
The sprockets are exposed to high speeds, heavy shock loads, and corrosive
and abrasive materials. Special sprockets with more than 12 teeth and with a
noise-reduction factor should be used. Wear-resistant, detachable-tooth sprock-
ets are frequently used.
(1) The chain must have exceptional wear resistance because it is exposed
to high speeds, heavy shock loads, and conveyed materials that are
corrosive and abrasive. For example, in the case of coal, the corrosive-
ness varies with each coal mine.
(2) Chain attachments should have high strength to support large bucket loads.
(3) Noise and abrasion of sprockets are important considerations.
(4) Choose chain from a manufacturer with a lot of experience and known
to produce a high-quality product. Select the chain only after communi-
cating application requirements to the manufacturer.
(5) Assembly of large pitch conveyor chain on the equipment can be an
enormous task. There are special tools available that can assist in con-
necting the chain.
Technical Trends
Manufacturers are working to develop relatively light-weight chain for the
load it carries, and sprockets that can provide long-term performance with low
noise levels.

216
Applications
6.3.5 Large Bulk Handling Conveyor Chain (CT)
Large conveyance: The steel industry, container conveyance
Application Example
Large Bulk Handling Conveyor Chain (CT) is used in the steel industry to
convey hot steel coils (up to 700°C) as well as slabs or other heavy objects,
such as containers. This chain is very strong. It can convey several coils, which
can weigh up to 45 ton/coil.
CT Chain is used in pairs, and heavy objects are conveyed directly on them.
Standard large pitch chains do not have enough capacity to support the
extremely heavy loads (the limiting factor is the roller). For that reason, special
cylindrical bearing rollers have been developed. They combine a high allow-
able load for the roller with low coefficient of friction. The coefficient of fric-
tion is 0.03, which is one-third to one-fourth the coefficient of friction of
standard large pitch conveyor chain in normal temperatures.
Figure 6.20 and Table 6.4 show the structure, dimensions, and functions of
this chain.
A coil can be conveyed on its side or straight up. When the coil is on its
side, you can use the chain as shown in Figure 6.20. Special attachments need
to be used when conveying a coil straight up. Figure 6.21 shows examples of
Large Bulk Handling Conveyor Chains with attachments for conveying round
objects, and one for curved conveyance.
Figure 6.20 Large Bulk Handling Conveyor Chain (CT)
Grease Nipple

Roller Link Plate Max. Allowable Max Allowable
Chain No. Pitch (mm) Dia. (R) Height (H) Roller Load (kN) Load (kN)
CT 60 300 400 500 125 171 29.4 83.3
CT 90 300 400 500 135 182.5 35.3 126
CT 130 300 400 500 150 195 42.2 181
CT 160 400 500 600 175 227 55.9 224
217
Sprockets
Large Bulk Handling Conveyor Chain requires special sprockets. They must
operate at low speeds (less than 15 m/min.) and usually have six to eight
teeth, which keeps the diameter small, and cost down.
Technical Trends
The coils are sometimes very hot, and are frequently transported through a
heat chamber. For these applications, the chain must be heat-resistant. In one
specific case, steel slabs were placed directly on the chain in five piles. Each
pile weighed 80 ton, and the surrounding temperature was 900°C. In extreme
situations like this, consult the manufacturer.
Figure 6.21 Large Bulk Handling Conveyor Chain (CT) with Special Attachments
Table 6.4 Dimensions and Functions of Large Bulk Handling Conveyor Chain (CT)

218
Applications
6.3.6 Block Chain (Bar and Pin)
Large conveyance: The steel industry, conveyance of sand and earth, shuttle
traction
Application Example
Block Chain is used for cooling high-temperature steel bars, seamless pipes,
or for pushing red-hot slabs and billets, for example (Figure 6.22). In addition
to the steel industry, Block Chain is used for vertical conveyance of sand and
earth, and for shuttle traction.
This chain is usually composed of three parts: two outer plates and one (or
sometimes two) inner plate (block) that are connected with pins. The tensile
strength ranges from 309 to 2,720 kN.
In comparison to roller chain, Block Chain has the following features:
(1) Greater impact resistance due to the strong construction and high rigidity.
(2) Higher strength considering chain weight.
(3) All the main parts are heat-treated for greater wear resistance against the
guide rails.
(4) Usually the bottom side of the plate slides on the guide rail; the chain
does not have rollers. It’s possible to push and carry conveyed objects
on the guide rails using special pushers (dogs) attached to the chain
(Figure 6.23).
Figure 6.22 Block Chain

219
Sprockets
Sprocket teeth engage the inside plate of the chain, entering the area
between outer links. The sprocket skips every second tooth to allow for the
solid block.
(1) Select a sprocket with more than 12 teeth.
(2) Use a sprocket with an outer plate support piece (Figure 6.24).
(3) Install hardened bushings in the inner link for improved wear elongation
resistance (Figure 6.25).
Figure 6.23 Installation of Pushers
on Block Chain
Figure 6.24 Sprocket with Outer
Plate Support Piece
Figure 6.25 Hardened Bushings
Improve Wear Resistance
Bushing
1. Solid Pusher
Inner or outer pusher
link to push material.
2. Tilting Dog
When material on the
conveyor runs relatively
faster than the chain,
the dog is pushed down
from behind to enable
material to pass over.
The dog then resumes
its original position.
3. Ducking Dog
The dog is supported on
the guide rail to convey
material. When the
guide rail is interrupted,
the dog ducks down,
leaves the material, and
passes beneath it.
4. Tilting and Ducking Dog
Both tilting and ducking
functions are combined.
When the dog comes in
contact with the table
surface, it lets the material
pass over. When the guide
rail is discontinued, the
dog leaves the material,
and passes beneath it.

220
Applications
6.3.7 Sewage Treatment Chain
(Rectangular Sludge Collector)
Large conveyance: Sewage treatment equipment
Application Example
One of main uses of large pitch conveyor chain is in water treatment facili-
ties. In a large sewage treatment facility, sewage goes through several tanks in
which solid wastes are eliminated by deposition and flotation.
In the silt tank, sand and dirt are removed using vacuum or V-buckets. In the
settling tank, sludge in the water, or on its surface, is scraped to the exit with
“flights” (boards) installed between two strands of chains at intervals of 3 m
(Figure 6.26). Sewage Treatment Chain (ACS Chain) is used in this process
(Figure 6.27). Accumulated dirt is removed with pumps.
Cast iron chains were once used in sewage treatment facilities. In such a cor-
rosive environment, chain deterioration could not be avoided. As the volume
of chain material decreased due to corrosion, wear was accelerated. To offset
the loss of material due to corrosion, cast iron chains became quite heavy, yet
the tension required in water-treatment applications did not justify the use of a
chain with such high tensile strength.
In the mid-1960s, ACS stainless steel chains were developed in Japan espe-
cially for water treatment facilities. The stainless steel construction assured
excellent corrosion resistance, so there was no need for extra-heavy cast iron
chains. Because of their superior functions, ACS chains have gained wide
acceptance.
This chain is also used to convey corrosive objects in general scraper conveyors.
Figure 6.26 Sewage Treatment Chain with Flights Installed

221
ACS Chain has large-diameter bushings. It does not have rollers.
Plates, pins, and bushings are made of 403 stainless steel. The T-head cotter
key is made of 304 stainless steel, which ensures high corrosion resistance.
SF-4 attachments are used for installing flights, and extended pins or LA-1
attachments for installing buckets in the dredger. Both of these attachments
are placed on the outer plates. LA-1 attachments are made of heat-treated car-
bon steel.
Figure 6.28 compares the strength of cast iron chain and stainless steel chain
in a long-term test.
Figure 6.27 Sewage Treatment Chain

Figure 6.28 Comparison of Cast Iron and Stainless Steel
Sewage Treatment Chain
222
Applications
Sprockets
Use special sprockets. Refer to the manufacturer’s catalog.
When cast iron chain was used, cast iron sprockets were also required. Due
to corrosion, the area of the sprocket tooth engaging with the chain would
lose its original form and round off (Figure 6.29). Upon engagement with the
chain, additional stresses would appear that would accelerate wear on the
chain and the sprocket even further. As a result, the working life of cast iron
chains and sprockets was short.
In an ideal situation, stainless steel sprockets are used with stainless steel
chain to ensure the optimum performance. Cast iron sprockets will wear in a
similar fashion even if stainless steel chain is used, resulting in increased wear
on the chain bushings and shortened chain life. It is a basic point that you
must use stainless steel chain and sprockets together. However, stainless steel
sprockets are expensive. Chain manufacturers have designed the insert-tooth
sprocket to reduce the cost. Only the part of the tooth that engages the chain
is stainless steel; the sprocket body is carbon steel (Figure 6.30).
19
10
0
0 5 10
Tsubaki ACR 810
Tsubaki ACS 19152W
Malleable
Cast Iron Chain
Time (Years)
TensileStrength(Tons)
Figure 6.29 Rounding of Cast Iron Sprocket Figure 6.30 Insert-Tooth Sprocket
Sprocket
Rounding
Due to
Corrosion
Tooth Insert
Insulator
Sprocket Body

223
(1) The chain speed of a scraper application is slow, 0.3 to 0.6 m/min., and
3 m/min. in the bucket application. The chain tension is the highest dur-
ing the test period, before water is poured into the tank. Before water is
poured into a 40-m tank, one chain is exposed to tension of 10 kN.
(2) 403 stainless steel chain has sufficient corrosion resistance for most
sewage facilities. If there is a high concentration of chlorine (as found in
sea water, for example), if there are high levels of sulfur from hot
springs, or if the tanks are contaminated, 304 stainless steel should be
used, at least for side plates.
Chains used in water treatment applications are operated at low speeds and
not subjected to any heavy shock loads. It is not necessary in this application
to consider chains with tensile strength greater than 19 tonf.
For that reason the following chains were developed:
(1) ACR 810 Chain is a small chain made of 403 stainless steel. It has a ten-
sile strength of 10 tonf. This was the first chain to be used in scraper
applications to be equipped with rollers. The rollers reduce wear on the
sprocket and the chain. Insert-tooth sprockets have been developed for
this chain as well. (See Figure 6.30.)
(2) Engineered plastic chain (ACP Chain, Figure 6.31), developed in the
United States, is a light-weight chain with high corrosion resistance. It
does not have rollers (similar to cast iron chain). Due to its light weight
(one-half to one-fourth the weight of stainless steel chain), installation is
relatively simple.
One of the problems with this chain is that engineered plastic expands
and contracts as the water temperature changes. Therefore, it is difficult
to keep the chain under constant tension. Tensile strength (25 to 40 kN)
is much lower than either cast iron or stainless steel chain.

Figure 6.32 Sprocket for Engineered Plastic Chain
224
Applications
The material, strength, and dimensions of engineered plastic chains
differ from one manufacturer to another. Compare these points when
you select the chain.
For engineered plastic chains, there are plastic kits, which include
sprockets, flights, and shoes (see Figure 6.32). Use them together. Never
use cast iron sprockets with engineered plastic chain.
Figure 6.31 Engineered Plastic Chain (ACP Chain)

225
6.3.8 Sewage Treatment Chain (Bar Screen)
Large conveyance: Sewage treatment equipment
Application Example
At the water gate of sewage treatment plants, there are gratings—called bar
screens—arranged lengthwise to catch floating objects. In addition to water
treatment plants, bar screens may be installed at the mouths of rivers. In some
bar screen setups, chains are set on guide rails and used as wide gratings or
screens. (See Figures 6.33 and 6.34.)
Eventually gratings fill up with contaminants, and they have to be cleaned.
A comb-shaped rake installed between two strands of chain is used for this
purpose.
Figure 6.33 Bar Screen Chain Set-up Figure 6.34 Bar Screen Chain
Sprocket
Bar Screen Chain for
Sewage Removal

Table 6.5 Specifications for Bar Screen Chain
Side Plate Pin, Bushing, Roller
Standard Series Heat-Treated Steel Heat-Treated 400 Series Stainless Steel
PJ Series Heat-Treated 400 Series Stainless Steel Heat-Treated 400 Series Stainless Steel
SJ Series 304 Stainless Steel 304 Stainless Steel
Figure 6.35 PJW-Specification Bar
Screen Chain
Figure 6.36 Y Attachment
Figure 6.37 A-2 (Type I) Attachment
226
Applications
(1) Bar Screen Chain is constructed like roller chain. There are three specifi-
cations in this kind of chain. Select the appropriate type based on the
corrosiveness of the operating environment (Table 6.5).
(2) Available attachments—Y and A-2 (Type I)—are made of heat-treated
steel.
(3) S-rollers and F-rollers may be used with this chain. The difference
between the two include the following points:
S-roller: Adapted to a rake with wheels. The rake rotates and sweeps out
the waste. (This is sometimes called a rotating-rake design.)
F-roller: Adapted to the rake without wheels. The rake is fixed on the
chain. The F-rollers support the weight of the rake. In an F-roller set-up,
the flange may alternate sides every one or two rollers. This arrangement
prevents derailment. Because the inside width (W) of the chain is larger
with the F-roller, the chain is called PJW specification to distinguish it
from others (Figure 6.35). Each chain attachment is exposed to high
load, because there are only two or three rakes installed on the chain.
Y attachments are used in the rotating-rake design (Figure 6.36), and A-2
(Type I) attachments are used in the fixed rake type (Figure 6.37). Both
attachments have additional features that increase their strength: the end
of the connecting pin is threaded and equipped with a nut to prevent
falling off.

227
(4) F-rollers are exposed to extremely high load from the rakes attached
to the chain. To extend the working life, bushings usually have a
larger bearing area, which reduces bearing pressure.
(5) Common chain sizes have tensile strength within the range of 68 to 490 kN.
Sprockets
Although these chains are based on RF conveyor chain, they require special
sprockets because of the pitch (152.4mm = 6 inches). For S-roller type, insert-
tooth sprockets are available.
(1) To select this chain, verify the chain tension required, and make sure to
confirm the roller load and attachment strength (twisting moment and
bending moment).
(2) Allow for a safety factor to withstand peak loads during jam-ups.
(3) Chain rollers might be exposed to high loads when following the curves
of the guide rail. Make sure you take this load into consideration when
selecting the chain. Minimize tension from the take-up (Figure 6.38).
(4) Of course, you should avoid contaminating the water with oil, but when
the test run of the equipment is performed without water, the chain’s
moving parts should be lubricated.
Technical Trends
Bar Screen Chain is required to perform with low noise levels, because it is
now commonly used near populated areas.
Figure 6.38 High Roller Load Due to Curved Rail
Corner Rail
Roller Load

228
Applications
6.4 STANDARD ATTACHMENTS
Large pitch conveyor chains are usually used with attachments. These attach-
ments are divided into the following categories:
• Standard
• Industry-specific (Plus α Alpha)
• Special
Attachment styles and nomenclature for large pitch chains are the same as
for small pitch chain. (See Applications Sections 2.3 to 2.5.)
The standard attachments for large pitch conveyor chains are A, K, SA, SK,
G, and RFD type. These attachments are available on the following types of
chains:
• Treated surface, such as plated chain.
• 304 stainless steel or other special materials.
• Bearing roller or bearing bush specification.
1. A attachment
2. K attachment
3. SA attachment
4. SK attachment
5. G attachment
One plate in a pair has bolt holes. These are used to install buckets on two
sets of chains (Figure 6.39).
} Refer to Applications Section 2.3 for
descriptions of these types of attachments.
Figure 6.39 G-4 Attachments

229
6. RFD attachments
The upper side of the link plate is tall; it actually sticks above the R-roller
(Figure 6.40). Therefore, conveyed objects can be placed directly on the chain.
This is a very economical design.
6.5 PLUS αα ALPHA ATTACHMENTS
Although these are not standard attachments, tooling is available. They have
been used in a variety of applications, and they have proven to be effective.
Please try to incorporate them in your designs.
These attachments are also available with the chains shown below:
• Treated-surface type, such as plated chain.
• 304 stainless steel or other special materials.
• Bearing roller or bearing bush specification.
Tables 6.6, 6.7, and 6.8 show the major types of industry-specific attachments.
Figure 6.40 RFD Attachments

230
Applications
Table 6.6 Plus αα Alpha Attachments
Usage or
Chain Name Attachment Appearance Application
With CA2 CA2
With AA3 AA3
With Reinforced Rib A2R
With MG2 MG2
With AS2 AS2
With AF2 AF2
With Centered Bushing CB
With WS WS
EP1
With Extended Pin EP2
EP3
With Stay-Pin TN
With KY KY1
KY2
For a net conveyor that has
limited clearance between
slats next to each other at
sprocket engagement.
To have a reinforced attach-
ment, inserting conveyed
jigs into it.
To have high flexural rigidity
of A attachment.
The same size bucket can
be installed.
For installing scrapers or
flights.
For installing deep scrapers
or flights.
Bars penetrating a chain to
be installed.
For prevention of conveyed
materials leakage.
A hollow pipe or something
to be installed on edge of
the pin.
Material to be put directly
on stay-pins or wire mesh
laced around pins.
For storage of cyclindrical
materials.
Type 2Type 1
There are two types depending on open and closed position of the attachment.

With Top Plate TP1
TP2
With Trolley Roller TRO
Resists Stick Slip RFL
OR1
With Outboard Roller OR2
OR3
With Stud Bushings RFB
With Center Roller CRR
CRF
With Guide Shoe GSA
GSK
With Guide Roller GR
With Solid Pusher KD1
KD2
KD1: Dog not attached to plate.
KD2: Dog attached to plate.
With Dog Roller RD
When cylindrical materials are conveyed,
material surface is not damaged, and rotating
friction is reduced by using this attachment.
231
Not to damage conveyed
materials.
For long-distance and hori-
zontal conveying.
For smooth conveying with-
out stick slipping.
For supporting heavy loads.
For longer wear life of bush-
ing.
For easy replacement of
roller when it is worn.
For prevention of chain’s
winding travel.
For horizontal conveying.
To push materials with the
pusher.
To convey cylindrical
materials by pushing.
Table Surface
Table Surface
Direction of Travel

232
Applications
With Tilting Dog CD
With Roller Tilting Dog RCD
With Ducking Dog DD
With Teeth Dog TD
With ID ID
When material on the conveyor runs relatively faster
than the chain, the dog is pushed down from behind to
enable material to pass over. The dog then resumes its
original position.
When the conveyor runs on descent, the dog prevents
the cylindrical material from excessive run. When the
material is in front of the dog, the dog is pushed down
and can store the material.
The dog is supported on the guide rail to convey materi-
al. When the guide rail is interrupted, the dog ducks
down, leaves the material, and passes beneath it.
The dog functions best when the chain conveys the
material on descent, preventing it from excessive run
and storing it. As the dog resumes its original position at
the engagement of a sprocket tooth, it does not damage
the material and makes little noise.
At the time that the dog pushes the material, if unex-
pected load operates the dog, it ducks down, leaving the
material as it passes beneath it.
For storage of materials on
the table surface.
For storage of cylindrical
materials.
For leaving materials at the
designated station.
For storage of cylindrical
materials without noise.
For both storage and
pushing.
Table Surface
Table Surface
Table Surface
Table Surface
Table Surface
Stopper
Stopper
Stopper
Direction of Travel (in case of storage)
Direction of Travel (in case of storage)
Direction of Travel
Direction of Travel
Direction of Travel
Materials

233
6.6 SPECIAL ATTACHMENTS
Special attachments are designed for specific applications and are used infre-
quently. In Applications Section 2.5, we discussed who should make special
attachment—the chain manufacturer or the user. Please refer to the section for
details.
For large pitch conveyor chain, the tolerance of the height of a ground A
or K attachment from the guide rail to the upper side of the “Precision
Ground” attachment is ± 0.4 mm. This value is larger than the tolerance for RS
conveyor chains.
Figure 6.41 shows examples of special attachments.
Figure 6.41 Examples of Special Attachments

234
BIBLIOGRAPHY
1. Atsushi Okoshi, Roller Chain, Korona-sha, Japan (1960).
2. Masataka Nakakomi, Safety Design of Roller Chain, Yoken-do,
Japan (1989).
3. Shizuo Aoi, Chain Conveyor, Yakumo-shoten, Japan (1958).
4. Utaro Majima, Chain-Conveyor, Kogaku Tosho, Japan (1967).
5. R. C. Binder, Mechanics of the Roller Chain Drive, Prentice-Hall, Inc.,
NJ (1956).
6. L. Jones (Ed.), Mechanical Handling with Precision Conveyor Chain,
Hutchinson & Co., London (1971).
7. L. L. Faulkner, S. B. Menkes (Ed.), Chains for Power Transmission and
Material Handling, Marcel Dekker (1982).
8. Hans-Guenter Rachner, Stahlgelenkketten und Kettentriebe, Springer-
Verlag, Berlin (1962).
9. Catalog, Tsubakimoto Chain Co.
10. Catalog, Daido Kogyo.
11. Catalog, Izumi Chain.
12. Catalog, Borg-Warner Automotive.
13. Catalog, Rexnord.
14. Catalog, Renold.

235
Coffee Break
Coffee Break
The Tools Developed from Chain
Here we show three unique tools developed from chains.
1. Tough Roller (Figure 1)
This tool consists of a frame and an endless assembly of rollers wrapping
around a center plate in the frame.
Comparing Tough Roller design to general roller bearing, the center plate in
the frame works as an inner ring, and the surface on which the Tough Roller
travels acts as an outer ring. Rollers function like cylindrical roller bearings,
and the plate, together with the pin, act as a retainer. Due to its features, like
high capacity (maximum allowable load = 100 tons) for its small body size,
small running friction and low center of gravity, this tool is used in low-fre-
quency conveyance of heavy objects.
2. Shafted Bearing Roller (Figure 2)
In this bearing roller, the roller has a shaft installed on it, which permits use
as a support or guide wheel.
There are a variety of sizes and options available in this construction. Roller
diameters range from 31.8 to 125 mm; maximum allowable load from 1.27 to
27.5 kN. The roller can be an R-type or F-type. There are various options, such
as a urethane coating applied to the outer surface, or there can be a 5-degree
taper in the channel.
3. Attachment with Shafted Bearing Roller
In this bearing roller, the roller is attached to the K-1 attachment of the
chain. It can be used as support or a guiding wheel. Capacity and specifica-
tions are the same as for the shafted bearing roller.
Figure 1 Tough Roller Figure 2 Shafted Bearing Roller
Top Plate
Center
Plate
Side
Plate

236
Coffee Break
Coffee Break
Sizing Up Chain
1. Teeny Tiny
The smallest standard transmission chain is Number 25. The chain pitch is
6.35 mm and minimum tensile strength is 3.50 kN. The smallest chain current-
ly manufactured, although it is not standard, is Number 10, which is used in
office equipment. It has a pitch of 3.175 mm and minimum tensile strength of
0.98 kN. There are a lot of micromachines (less than 1 mm) being made, but
the chain to fit them is not currently available.
2. Stupendous
The largest standard transmission chain is Number 240, which has a pitch of
76.2 mm and average tensile strength of 500.4 kN. There are larger chains, but
they are not standard. A Number 400, for example, has a pitch of 127 mm and
average tensile strength of 1,730 kN. Multistrand versions of this chain are
available, as well, from some manufacturers. Their tensile strengths are the
multiplication of a single strand. Check with your manufacturer for availability.
The largest chain ever used had a pitch of 1,400 mm. It was created for hori-
zontal rotating parking equipment.
The highest average tensile strength for a single chain—900 tonf—was a
block chain. It was used in the production of steel tubing. If this chain were to
be used in a multistrand configuration, its average tensile strength would be
multiplied.
However, considering the cost, tensile strength of 500 tonf is the limit for a
single roller chain.

237
Coffee Break
Coffee Break
Speed Variation
Chains are usually used at low speeds with large loads. Some common chain
types and speeds include the following:
Transmission roller chain: less than 150 m/min.
Small pitch conveyor chain: 10 to 30 m/min.
Precision conveyor chain: less than 50 m/min.
Top chain: 10 to 30 m/min.
Free flow chain: 5 to 10 m/min.
Large pitch conveyor chain: 10 to 30 m/min.
There are chains that are designed for high-speed operations. Here are some
examples:
• The chain used in balancer drives in automotive engines can run at
1,800 m/min., which is the same speed as a cog belt. Chain pitch is less
than 8 mm.
• Chain that drives the rear wheels of racing motorcycles operates at 1,500
m/min.
• The chain for the camshaft drives in marine diesel engines operates at
about 600 m/min. Chain pitch is greater than 100 mm.
• The top chain that moves beer cans in breweries runs at 200 m/min.
• Large pitch conveyor chains and block chains in steel processing plants
can run at speeds of 330 m/min. The chain pitch is 150 mm.
In each of these high-speed operations, the chain must be selected carefully.
It’s important to consider not only the strength and wear resistance, but the
type of lubrication required. When you set up a high-speed chain system,
make sure you work with a reliable supplier, and ask to see some actual per-
formance results for the chain you are considering.

239
AFTERWORD
For designers and users of equipment, the most important points to consider
for power transmission and conveyor operations are how well they stand up
to and satisfy the following:
Power Transmission Operations
1. Quality: The features of the transmitted power, maintenance, length
of working life.
2. Cost: Initial cost, running cost.
3. Delivery: Availability.
Conveyor Operations
1. Quality: Speed, accuracy, flexibility, maintenance, length of working life.
2. Cost: Initial cost, running cost.
3. Delivery: Availability.
Of course, these points can be applied to much more than just chain.
You also have to compare belts, gears, and even other tools.
Power transmission and conveyors are rarely treated scientifically. At colleges
and universities, chains are often ignored in lectures about technology. Many
people think that chain is simply an old machine element.
But chain is more than that. Used correctly, chain can have a major impact
on the entire operation. Here’s an example: By replacing steel rollers with
engineered plastic rollers on conveyor chains and moving from plastic rollers
to bearing rollers, the coefficient of friction was reduced to one-fourth or one-
fifth of the original. This results in lower costs for driving parts and frames,
and saves energy. Progress in chains has a direct connection to economizing
energy.
I have worked with many customers in many different fields during my
career. I noticed that there was no handbook to explain the different types of
chains, nor a book that describes the ease and convenience of using chain.
This book is designed to solve these problems. First, I explained the main
ideas about chain. Then, I picked 50 types of chain in current use and gave
practical points—application examples, construction and features, sprockets,
selection and handling, technical trends—so that readers can work the chain’s
ability fully into their equipment. There is no denying the fact that most of the
chain names and types are products of Tsubaki. Although other manufacturers
also produce most of the chain types shown in this book, the lack of materials
and the wide variation in products make comparisons very difficult.

240
I wish to express my sincere thanks to Mr. Toshiharu Yamamoto, the late Mr.
Katsumi Kotegawa, and other senior experts who developed the company’s
technology, Mr. Keichi Sawata, Mr. Sumio Watanabe, Mr. Shinobu Takeda, Mr.
Susumu Saijo (who provided good materials), and Mr. Tadahisa Yoshida for
valuable advice.
May 1995
Makoto Kanehira

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