MA1.ppt

Flowlines: The prevailing layout
for High Volume Manufacturing

Topics
• Production Flow in High Volume Discrete
Part Manufacturing
• Manufacturing System Layouts
• Manufacturing Flowlines and their
variations
– Synchronous Transfer Lines
– Asynchronous Flowlines and the Push vs. Pull
dilemma
– Asynchronous Transfer Lines
– KANBAN-based Lines
– CONWIP-based Lines

Discrete Part Manufacturing Systems
The end product is the
assemblage of a
number of
components
and sub-assemblies,
either produced in-
house or procured
from outside.
Frame
Building
Frame
Machining
Frame
Painting
Engines and
Transmissions
Oil Tank
Cell
Shocks
Cell
Steering
Wheel Cell
Wheels
Cell
Doors
Cell
Seats
Cell
TESTING
“Packaging”

Production Flow in
discrete part manufacturing
A-1
A-2
A-3
A-4
I-1
A-5
O-1-1 O-1-2 O-1-3 O-1-4
O-2-1 O-2-2 O-2-3
O-4-1 O-4-2 O-4-3
O-5-1 O-5-2
Part 1
Process
Plan
Part 2
Process
Plan
Part 4
Process
Plann
Part 5
Process
Plan
End Product
Part 3
(Procured externally)
Main Frame

A typical Organization of the
Production Activity in
High Volume Discrete Part Manufacturing
Raw
Material
& Comp.
Inventory
Finished
Item
Inventory
S1,2
S1,1 S1,n
S2,1 S2,2 S2,m
Assembly Line 1: Product Family 1
Assembly Line 2: Product Family 2
Fabrication (or Backend Operations)
Dept. 1 Dept. 2 Dept. k
S1,i
S2,i
Dept. j

Organizing the Workflow for Backend
Operations: Major Layout Types
Workspace
Drill Mill
Grind End
Product
Store
Assembly
Paint
Weld
Saw
Lathe
Raw
Material
Store
(a) Fixed Product Layout
Lathe
E.P.
Store
Assembly
Saw Lathe Mill Drill
Saw Mill Drill Paint
Grind Mill Drill Paint
Weld Grind Lathe Drill
(b) Product Layout
R.M.
Store
E.P.
Store
Saw Drill Paint
Weld Grind Paint
Mill
Lathe Mill
Lathe
Drill
(c) Group or Cellular Layout
R.M.
Store
E.P.
Store
Assembly
Paint
Saw
Grind
Weld
Lathe
Lathe
Mill
Mill
Drill Drill
(d) Process or Functional Layout
Adjusted
from
Francis
et. al.

Fixed Product Layout
• Workpiece remains fixed and the various
processes are brought to it
• Used primarily in ship-building.
• Sometimes can be the preferred layout when high
levels of precision are in order.
• Production activity is controlled through project
management related practices.

Product Layout or Flowline
• Each part has its own dedicated production line.
• The line for each part is organized in a way that
facilitates the corresponding production flow.
• Easy to manage and supervise
• However, a capital-intensive proposition
• Production volumes must be sufficiently large

Process Layout or Job Shop
• Facility is organized into departments supporting
different functions
• Production lots are visiting these departments
according to their processing needs (process plans)
• Can result in high equipment utilization and
operational flexibility
• But it also incurs extensive material handling and
long production times
• Necessitates involved production planning and
scheduling
• Appropriate for low-volume production of a large,
volatile portfolio of parts

Group or Cellular Layout
• Parts are grouped into families based on the
similarity of their processing requirements.
• Each family gets a dedicated production facility,
known as production cell.
• Typically cells operate as switching flowlines,
with switching taking place between the
production of batches of different part types.
• Frequently switching can involve substantial effort
and time, known as setup time.
• Provide a “middle ground” between a product and
a process layout, in terms of operational efficiency
and investment

Re-entrant Lines
• Flowlines in which certain processing stages share
the same type of equipment, and therefore, they
present “re-entrance”.
• The motivation for re-entrance and the resulting
operational complexities are similar to those
underlying the deployment and operation of a
cellular layout.
• Re-entrant lines is a typical layout for
semiconductor manufacturing.

The product-process matrix
Production
volume
& mix
Jumbled
flow (job
Shop)
Disconnected
line flow
(cellular)
Connected
line flow
(assembly
Line)
Continuous
flow
(chemical
plants)
Process
type
Low volume,
low standardi-
zation
Multiple products,
low volume
Few major products,
high volume
High volume, high
standardization,
commodities
Commercial
printer
Heavy
Equipment
Auto
assembly
Sugar
refinery
Void
Void
(Figure borrowed from Hayes and Wheelright)

Manufacturing Flowlines:
A working abstraction
• Flow line: A sequence of workstations supporting the
production of a single part type.
• Each workstation consists of one or more identical
servers executing one particular stage of the entire
production process.
• processing time at each workstation variable due to
inherent process variability but also due to operational
detractors, like
– machine downtime,
– operator unavailability,
– experienced set-up times,
– preventive maintenance, etc.

Flowline Performance Measures
• Production rate or throughput, i.e., the number of parts
produced per unit time
• Line capacity, i.e., the maximum sustainable
production rate
• Line (expected) cycle time, i.e., the average time that
is spend by any part into the line (this quantity
includes both, processing and waiting time).
• Average Work-In-Porcess (WIP) accumulated at
different stations
• Expected utilization of the station servers.
Remark: The above performance measures provide a link between the directly quantifiable and
manageable aspects and attributes of the line and the primary strategic concerns of the
company, especially those of responsiveness and cost efficiency.

A flowline classification
Flowline
Synchronous Asynchronous
Push
e.g.,
Asynchronous
Transfer
Line
Pull
e.g.,
KANBAN or
CONWIP lines

Synchronous Transfer Lines
• Production is paced by an
interconnecting conveyor system
•No WIP accumulation at the
different stations
• Production control logic is
hardwired in the supporting
conveyor system
• Line expensive and inflexible
• Typically used for high-
throughput final assembly
• c.f. the module on scheduling
for further coverage of these lines

Asynchronous Flowlines and the
Push vs. Pull dilemma
• Part advancement between the different stations is
not synchronized.
• Need for buffering capacity at the different
stations to accommodate the resulting WIP.
• Two primary control mechanisms
– Push:
• Lots are released into the line according to an externally
specified production plan.
• A lot that has completed processing at its current station will
immediately advance to the next one.
– Pull:
• Target WIP levels are specified for different line segments.
• Lot advancements that can cause the exceeding of some target
WIP levels are blocked.
• A drop from the target WIP level is a signal for replenishment.

Push vs. Pull dilemma (cont.)
• Push properties
– Directly connected to production planning
– Can easily accommodate changes in target
production
– (In its basic definition), it lacks a feedback
mechanism that can facilitate reaction to
operational contingencies
– As a result, congestion is possible

Push vs. Pull dilemma (cont.)
• Pull properties
– Main control variable is WIP
– The enforced WIP caps make the line reactive
to contingencies and prevent congestion
– Need for some (analytical) machinery to
translate target production plans to target WIP
levels
– Need considerable stability of the production
plans, since frequent changes of the target WIP
levels can lead to chaotic behavior.

Asynchronous Transfer Lines
W1 W2 W3
TH TH
TH TH
B1 B2 B3
M1 M2 M3
Some important issues:
• What is the maximum throughput that is sustainable through this
line?
• What is the expected cycle time through the line?
• What is the expected WIP at the different stations of the line?
• What is the expected utilization of the different machines?
• How does the adopted batch size affect the performance of the
line?
• How do different detractors, like machine breakdowns, setups,
and maintenance, affect the performance of the line?

KANBAN-based production lines
Station 1 Station 2 Station 3
• What is the throughput attainable by a certain selection of
KANBAN levels?
• What is the resulting cycle time?
• How do we select the KANBAN levels that will attain a desired
production rate?
• How do we introduce the various operational detractors into the
model?

CONWIP-based production lines
Station 1 Station 2 Station 3 FGI
• Same as those for the KANBAN model, plus
• How can we compare the performance of such a system to that
of an asynchronous transfer line and/or a KANBAN-based
system?

The remaining part of the module
• Modeling and Performance Analysis of Asynchronous
Transfer Lines as a Series of G/G/m queues
• Modeling the impact of operational detractors
• Employing the above results in line diagnostics
• Design of Asynchronous Transfer Lines
• Modeling and Performance Analysis of CONWIP-
based production lines through Closed Queueing
Networks
• An integrating framework for bounding and shaping
the performance of a production line
• Analyzing the impact of batching on the system
performance and designing optimized batching policies

MA1.ppt

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