Abstract image of a woman sitting on books and studying on a laptop

Benfield system

Download as PPT, PDF
Prem Baboo, profile picture
Prem Baboo

This document provides information on the Benfield process for removing carbon dioxide from gas streams. It discusses key aspects of the process including: - Absorption of CO2 into a potassium carbonate solution and regeneration of the solution by heating. - Use of an activator like DEA to improve CO2 absorption. - Comparison with other CO2 removal processes like Rectisol and considerations for process selection. - Parameters that affect the absorption and regeneration steps like pressure, temperature, and flow rates. - Causes and prevention of corrosion in the system through vanadium addition and factors that can cause foaming of the solution.

Engineering
1 of 22
Downloaded 274 times
1
2
3
4
5
6
7
Most read
8
Most read
9
10
11
Most read
12
13
14
15
16
17
18
19
20
21
22
AMMONIA PLANT CO2 ABSORPTION PROCESS Prem Baboo Sr. manager(Prod) National Fertilizers Ltd, India FIE ,Institution of Engineers( India) Technical Advisor & an Expert for www.ureaknowhow.com
CO2ABSORBER&REGENERATOR CO2 TO UREA PLANT .6 Kg/Cm2 43.2KNM3 9.14 P-1307 P1301 (A,B&C) E302 A&B 4 8 % 48% IN CO2-17.10% Ar-.75% N2-21.3% CH4-0.4% CO-0.11% H2-60.84% OUT CO2-.11% Ar—0.30% N2—25.65% CH4—0.5% CO--.13% H2—73.51% 13FIC 20 13-FIC-2 1 8.548.54 FLOW 1135M3 FLOW 345M3 104 M3 104M3 3.94M PALL RINGS 1.5” ..01M TOTAL 517M32”PALLRINGS L.P. STEAM 30 TON 13 FIC02 P.G.
BENFIELD PROCESS FLOW DIAGRAM 13 FIC02 13HIC101 DM WATER FROM TANK 307 MT/Hr. PROCESS GAS TO METHENATOR 600 C 345M3 FAN COOLER E 1303 ABSORBER F 1302 28.45MT/Hr 1100 C PROCESS CONDENSATE TX-1301 CICULATION PUMP BOOSTER PUMP REGENATOR F-1301 B-1305 E-1302 A/B B1306- TO FGR FLASH GAS 1590C PROCESS GAS CONDENSATE E1308 E1306 LP STEAM B1301 1130 C1162M3/ Hr B-1303 T0 DE-AERATOR C.W.
REMOVAL OF CO2:- PROCESS FOR REMOVAL OF CO2 ARE BASED UPON SCRUBBING OF GAS WITH SOME SOVENT (PHYSICAL OR CHEMICAL) THE SOLVENT SHOULD HAVE THE FOLLOWING PROPERTIES:- i. HIGH CO2 SOLUBILITY ii. LOW VISCOSITY iii. HIGH STABILITY UNDER OPERATING CONDITION iv. NO REACTIVITY UNDER OPERATING CONDITION v. VERY LOW VAPOUR PR UNDER OPERATING TEMP
GENERAL CONSIDERATION IN PROCESS SELECTION 1. PARTIAL PR OF CO2 IN FEED GAS AND TOTAL PR OF ABSORPTION 2. CO2 PURITY 3. GAS CONTAINING CO 4. AVAILABILITY OF UTILITY AND COST TWO TYPE OF PROCESSESS A. PHYSICAL PROCESS SOLVENT 1. WATER SCRUBBING WATER 2. LINDE’S RECTISOL METHANOL 3. ALLIED SELEXOL POLYPROPYLENE GLYCOL DIMETHYL EITHER 4. FLUOR’S PROCESS PROPYLENE CARBONATE 5. PURISOL N METHYL- 2 PYRROLIDINE 6. SULPHINOL TETRAHYDRO THIOPHENE 1, 1 DIOZIDE
B. CHEMICAL ABSORPTION BEST SUITED FOR LOW CO2 PARTIAL PRESSURE 1. MEA PROCESS:- MONO ETHANOL AMINE (REBOILER ENERGY IS HIGH 2NH2(CH2)2 OH + CO2+H2O=[HO(CH2)2NH3]2CO3 DISADVANTAGE:- (i)[HO(CH2)2NH3]2CO3+CO2+H2O= 2HO(CH2)2NH3HCO3 (ii) HO(CH2)2NH2+CO2= HO(CH2)2NHCOONH3(CH2)2OH CARBOMATE IS CORROSSIVE IN HOTER PARTS OF MEA • GV PROCESS • CATACARB PROCESS • BENFIELD PROCESS C. PHYSIOCHEMICAL PROCESS 1. MDEA PROCESS( METHYLDIETHANOAMINE
BENFIELD PROCESS OVER 700 BENFIELF PLANTS IN WORLD ENERGY 660 – 1140 KILO CALORIE PER NORMALM3CO2 45% FOR REGENERATION 55% FOR ABSORPTION K2CO3+CO2+H2O=2KHCO3+HEAT( MILD EXOTHERMIC) CO2+H2O=HCO3- +H+ CO3-- +H2O=HCO3- +OH- CO2+CO3-- H2O=2HCO3 1M3 30% K2CO3 SOLN ABSORBED 10M3 CO2 WITHOUT ANY ACTIVATOR ACTIVATOR ACTION:- DEA (R2NH) R=CH2CH2OH R2NH+CO2=R2NCOOH (INTERMIDIATE PRODUCT) R2NCOOH+K2CO3+H2O= R2NH+2KHCO3 K2CO3+CO2+H2O=2KHCO3
PROPERTIES OF DEA MW = 105.14, SP GR = 1.0966, MELTING PT = 28O C , BP = 10/100/760MMHG= 150/205/260 ANALYSIS OF LEAN SOLUTION / RICH SOLN K2CO3 KHCO3 EQ K2CO3 F/C TV V+5 DEA FE 17.22 15.32 27.80 .38 10.4 .4 2.42 42.1 10.67 25.52 28.30 .67 .85 .67 2.8 ---- CALCULATION OF F/C 1 _ _%AGE K2CO3 %EQ K2CO3 % EQ K2CO3 = % K2CO3+(MW KHCO3)100 % KHCO3 MW K2CO3)138 17.22+(0.69)X15.32=27.8016 1- FC 1_ (17.22) = 0.38 IN LEAN SOLN 27.8016 F/C IN RICH / LEAN SOLN = 0.858/0.352 (DESIGN VALUE) F/C = F/C RICH – F/C LEAN (ACTUAL) . F/C RICH – F/C LEAN (DESIGN)
COMPARISON BETWEEN PLANTS RECTISOL PHYSICAL ABSORPTION . LOWER ENERGY .REMOVAL OF ALL IMPURITIES SUCH AS ORGANICS, H2S, BENZENE, GUM FOAMING AND HYDROCARBON .PRODUCTION OF GAS WITH NEGLIGIBLE WATER GAS SOLVENT METHANOL . HIGH CO SLIP FROM CO SHIFT SECTION .FINAL REMOVAL OF CO,CO2 BY N2 WASH INI BENFIELD CHEMICAL ABSORPTION 612KCAL/NM3 CO2 B-1306 YES LP BOILER AFTER REBOILER NO REGN SINGLE ACTIVATOR SINGLE DEA HYDROLLIC TURB SINGLE( POWER GENERATION) AERATION OF SOLN NO FAVOURABLE CO2 BLOWER NO GV CHEMICAL ABSORPTION 713.5KCAL/NM3 CO2 B-1306 NO YES DOUBLE DUAL (DEA+GLYCINE) DUAL PUMP DRIVEN AVAILABLE CO2 BLOWER VENEZEULA CHEMICAL ABSORPTION 700KCAL/NM3 CO2 B 1306 YES YES YES DOUBLE DUAL DEA+GLYCINE) DUAL PUMP DRIVEN AVAILABLE CO2 BLOWER NO
contd CO2 BLOWER YES DISADVANTAGE NO PGR NO OF PUMP AND COLUMN MORE INITIAL COST HIGH CO2 EXCESS VENT NO CO2 EXCESS PGR AMMONIA PRODUCTION NO CO2 EXCESS UTILIZE CO2 EXCESS VENT PGR AVAILABLE
CORROSION CO2 ITSELF WEAKLY ACIDIC HOT POTASSIUM CARBONATE SOLN AGGRESSIVE FOR CORROSION COMPOUND MAY FORM WITH THE SCRUBBING SOLN CORROSIVE TO STEEL THEREFORE, A VANADIUM SALT V+5 IS USED IN THE SOLN AS A CORROSION INHIBITOR THE VANADIUM OXIDISES THE IRON ON MET AL SURFACES (VANADATION) BY ADDING V2O5 THE RESULTANT OXIDES FE3O4 MAGNETITE PRODUCE A TIGHT ADHERENT FILM ON THE SURFACE WHICH RESULTS IN ESSENTIALLY NO CORROSION DURING OPERATION UNLESS THE FILM IS DISTURBED V+5 +Fe2e = V+4 +Fe3e FERRIC Fe2O3 MOST STABLE FORM V2O5 CONVERTS Fe2O3 TO Fe3O4 2FeO +V2O5 = Fe2O3 + V2O4 FeO + Fe2O3 = Fe3O4 (MAGNETITE) MAINTAIN PENTAVALENT VANADIUM NOT LESS THAN 0.2 WT % INCREASE V+5 CONTENT BY ADDITION FRESH V2O5 (VANADIUM PENTAOXIDE) ADDITION OF KNO2 IS RECOMMENDED FOR OXIDATIION METHOD KNO2 +V2O4 = V2O5 +KNO
CORROSION AND PROBLEMS IN PLANTS • 1 – 1986 AND 1992 IN RCF ( HALDOR TOPSOE PLANT) • 2 – 1986 : PRECIPITATED BICARBONATE PEELS-OFF THE PASSIVATIION LAYER IRON • AND VANADIUM IN THE SOLN CO-PRECIPITATE WITH THE BICARBONATE FORMING • A SLURRY PLANT WAS SHUT DOWN 30 DAYS CIRCULATION PUMPS REPAIRED • NOV 1994 – HYDRO AGRI TRINIDAD’S TRINGEN II – 33 DAYS SHUT DOWN • PROTECTIVE MAGNETITE LAYER IN THE ABSORBER BOTTOM AND DISTRIBUTER BECOME DAMAGED FORMATION OF IRON CARBONATE CORROSION RATE INCREASED COMPLETE DEPLETION OF VANADIUM • 1992 – KRIBHCO HAZIRA – KELLOG’S DESIGN • FOLLOWING A NUMBER OF CRASH SHUT DOWN DUE TO NG AND MAINTENANCE JOB • THE CO2 PRODUCT PURITY OF BOTH UNITS CAME UP TO 97.96% DUE TO FAILURE OF FLOATING HEAD GASKET IN THE FLOATING HEAD TYPE EXCHANGER (REBOILERS) • SUSPECTABLE FAILURE AND THIS ALLOWED LEAKING PROCESS GAS TO ATTACK AND DESTROY THE PASSIVATION LAYER OF CS WALL OF REGENATOR • 2001 – VENEZUELA JOSE FERTILISERS . AFTER REDUCTION OF LT CO SHIFT CONV CATALYST – CATALYST DUST BEFORE LINE UP TO GV DID NOT BLOW / REMOVE PROPERLY Fe CONTENT IN GV SOLN -~ 5000 PPM VISCOSITY OF SOLN INCREASED FREQUENT CHOCKING OF STRAINERS AND DRAIN LINES OCCURS WHOLE SOLN FILTERS THROUGH Fe CONTENT CAME DOWN AND VISCOSITY NORMALISED
BENFIELD SYSTEM: START UP CHECK LIST :- 1. TRIP SYSTEM: IS-4, IS-5, IS-301A, B, C, IS 303, IS 304 ARE IN RESET CONDITION 2. STROKE CHECKING OF ALL CONTROL VALVES 3. CHECK a. 13 HV- 10 ------------CLOSE b. 13 HIC 101-------------CLOSE c. 13 FCV 02 -------------BY PASS & CV F/C d. ISOLATION VALVES OF 13 FIC -01, LIC -01, 13LIC-20- I/2, 13PV 28 13 LCV- - 26-1/2 CLOSE e. DM WATER CIRCULATIION – NORMAL f. CW TO E -1308 A/B – OPEN g. F 1302 PR NORMAL WITH NG > 15KG/CM2 h. N2 TO F 1301 OPEN j. PUMPS – P-1307/ P- 1301 PROPERLY LINED UP k. PUMPS ELECTRICALLY ENERGISED l. PUMPS L.O. CIRCULATION & SEALING WATER SYSTEM NORM
Contd. m. LEVEL IN B 1305 LESS THAN 100% n. O2 CONTENT IN THE SYSTEM LESS THAN 100PPM 4. START CIRCULATION KEEP E 1303 FANS IN STOPPED CONDITION 5. KEEP 13HV 10 CLOSE AND START INDIRECT HEATING BY SM STEAM PR LESS THAN 5 KG/ CM2 , TEMP LESS THAN 1800 C F 1301 PR 2 KG/CM2 (N2) OBTAIN BENFIELD SOLN TEMP 105O C PASSIVATION A. STATIC – E 1302 A/B FLOODED CONDITION TEMP=130O C DURATION 48 HRS B. DYNAMIC – CIRCULATION RATE 80% DURATION 36 HRS MAINTAIN V+5 EQUAL 0.5% K2CO3 KHCO3 EQ K2CO3 F/C V+5 DEA FE 20.96 6.37 25.33 0.172 0.47 2.18 66.74PPM LOCAL DRAINING B 1303 ON R1205 BY PASS MOV45 FULL CLOSED
FOR INDIRECT HEATING STOPPED CONDITION NG FLOW TO PRIMARY REF 6000NM3, STEAM FLOW 30 TE/HR RECYLE GAS FLOW ( 12FIC 02 +12 FIC 17) EQUAL 4000NM3 ( 800 +2200) 12TJR 1/12, 06 =5000 C / 7500 C 13 PI C11= 0.6KG/CM2 B 1305 STEAM EJECTORS , X 1301 A/B/C/D I/VS OF VAPOURS AND SL STEAM I/V MOTIVE STEAM TO BE OPENED FOR LINING UP SEQ 1. X 1301D 2. X 1301C 3. X 1301B 4. X 1301A FROM CCR 13 HIC O4, O5, O6, O7, INITIALLY TO BE CLOSED AND TO BE OPENED AFTERWARDS. 13 FIC O2 I/VS TO BE OPENED
contd 13 HIC 101 TO BE OPENED LINE UP 13 TIC O9 STOP NG TO F 1302 AND N2 TO F 1301 BLIND TO BE PROVIDED STOP LOCAL DRAINING OF 1303 AND LINE UP TO PC HEADER
BENFIELD THEORY a. FAVOURABLE PARAMETERS FOR ABSORPTION 1. HIGH PRESSURE ( LIMITATION REF PRESSURE) 2. BETTER ACTIVATOR ( DEA, IN LINE II GLYCINE ALSO) 3. LOWEST F/C 4. BETTER FILTERATION ( 10 MICRONS OR LESS) 5. OPTIMUM SPLIT STREAM TEMP 6. IMPROVED PACKED BEDS AND INTERNALS b. FAVOURABLE PARAMETERS FOR REGENERATION 1. LOW PRESSURE 2. PROPER DISTRIBUTION OF RICH SOLN 3. IMPROVED PACKED BED AND INTERNALS 4. REGN STEAM FLOW/ PR / TEMP OPTIMUM
FOAMING CAUSES: IMPURITIES i. SODIUM:- <1.0 % Na LIMITED NaHCO3 SOLUBILITY ii. CHLORIDE:- AS CL- >100PPM iii. INERTS SALTS:- FORMATE, THIOSULPHATE ETC. CAN JOLERATE UPTO MINIMUM INNNERTS IN SOLUTION DEENSITY AND ABSORPTION AFFECTED. iv. HEAVY METALS:- POTENTIAL FOR LOSS OF PASSIVATION. v. SOLUBLE Fe CONTEST:- CONTENT UPTO 150PPM (NORMAL) MAX SOLUBLE 200 – 250 PPM – CORROSION OCCURING. vi. SOLIDS IN SOLUTION:- ABRASIVE, LOSS CORROSION PROTECTION, FOAMING OF SOLUTION. vii. SOLUBLE INORGANIC CONTAMINATES:- - TOTAL SALTS HIGH - PROCESS TEMP INCREASES - LOSS OF ABSORPTION EFFICIENCY viii. SOLUBLE ORGANIC CONTAMINATES:- - FREQUENT CAUSE OF FOAMING OF SOLUTION - SOME LOSS OF ABSORPTION EFFICIENCY ix. GREASE AND OIL.. x. INTERNALS DISTURBES
FOAMING CAUSES i. DUST OF ACTIVATED CARBON ii. SUSPENDED METALLIC COMPOUNDS, WHICH MAY DISTURB SURFACE TENTION iii. DECOMPOSITION PRODUCTS iv. ORGANIC SUBSTANCES, GREASE, LUBEOIL, PAINT BITUMIN EPOXY RASINS. v. SULPHIDES FOAMING IS INDICATED BY :- 1. HIGH PDI OF ABSORBER, REGENERATOR 2. SOLUTION CARRY OVER 3. SOLUTION HOLD UP IN PACKINGS 4. LEVEL INSTABILITY 5. INCREASE IN CO2 SLIP
FOAMING CONTROL 1. SIDE STREAM FILTRATION – A) MECH FILTER~ 10 MICRONS FLOW – 5% TO 10% OF CIRCULATION RATE. (CONTINUOUS REMOVAL OF SOLIDS ) B) ACTIVATED CARBON FILTER:- TO REMOVE i. ORGANIC MATTER AND CONTEMINANTS ii. DECOMPOSED COMPOUNDS iii. IF COLOUR OF SOLN IS DARK, IMPROVE TRANSPARENCY 2. LIMITED USE ( 20ML) OF ANTIFOAM AGENT (UCON 50 HB 5100, POLYGLYCOLS , SILICONES. 3. DEMISTERS OF ABSORBER AND REGENERATOR FLUSHING BY BFW
FOAMING TEST 50 ML FILTERED BENFIELD SOLUTION AT 90OC SHAKEN VIGOROUSLY OR N2 IS BUBBLED FOR ONE MINUTE HIGHT OF FOAM > 40 MM COLLASPE TIME > 10SEC CAUSE OF INCREASE IN CO2 SLIP 1. INCORRECT SOLUTION FLOW RATE. 2. HIGH Fe OF HPC SOLUTION. 3. INCORRECT LEAN/ TOP SOLUTION TEMP. 4. INCORRECT SOLN COMPOSITION 5. FOAMING 6. INCORRECT SOLN / GAS – DISTRIBUTION IIN BEDS 7. DDISTURBANCE IN PACKING ARRANGEMENTS 8. DAMAGE / DISLOCATE INTERALS OF ABSORBER/ REGENERATOR
CAUSES OF BAD REGENERATION 1. LOW REGENERATION STEAM FLOW / TEMP / PR 2. HIGH SOLUTION FLOW RATE 3. ABSORBER GAS INLET TEMP LOW 4. REGENERATOR PR HIGH 5. INCORRECT STEAM / SOLUTION TEMP PROCESS FOR REMOVAL OF CO2 ARE BASED UPON SCRUBBING OF GAS WITH SOME SOVENT (PHYSICAL OR CHEMICAL) THE SOLVENT SHOULD HAVE THE FOLLOWING PROPERTIES:- i. HIGH CO2 SOLUBILITY ii. LOW VISCOSITY iii. HIGH STABILITY UNDER OPERATING CONDITION iv. NO REACTIVITY UNDER OPERATING CONDITION v. VERY LOW VAPOUR PR UNDER OPERATING TEMP *************************************************************************************

More Related Content

PDF
Ammonia CO2 Removal Systems
Gerard B. Hawkins
 
PDF
Ammonia converter
Dr.Mohamed Tarek,PhD
 
PDF
Ammonia Plant - Secondary Reforming
Gerard B. Hawkins
 
PDF
Ammonia Plant - Methanation Operations
Gerard B. Hawkins
 
PDF
Calculation of an Ammonia Plant Energy Consumption:
Gerard B. Hawkins
 
PDF
Ammonia synthesis converter
Prem Baboo
 
PDF
Brief desccription of ammonia & urea plants with revamp
Prem Baboo
 
PDF
Topsoe large scale_methanol_prod_paper
abodin
 
Ammonia CO2 Removal Systems
Gerard B. Hawkins
 
Ammonia converter
Dr.Mohamed Tarek,PhD
 
Ammonia Plant - Secondary Reforming
Gerard B. Hawkins
 
Ammonia Plant - Methanation Operations
Gerard B. Hawkins
 
Calculation of an Ammonia Plant Energy Consumption:
Gerard B. Hawkins
 
Ammonia synthesis converter
Prem Baboo
 
Brief desccription of ammonia & urea plants with revamp
Prem Baboo
 
Topsoe large scale_methanol_prod_paper
abodin
 

What's hot (20)

PPT
Activated MDEA solution(aMDEA)
National Fertilizers Limited
 
PDF
(HTS) High Temperature Shift Catalyst (VSG-F101) - Comprehensiev Overview
Gerard B. Hawkins
 
PPTX
Various ammonia technology
Prem Baboo
 
PDF
Steam Reforming - Catalyst Loading
Gerard B. Hawkins
 
PDF
Theory and Operation - Secondary Reformers -
Gerard B. Hawkins
 
PDF
Steam Reforming - A Comprehensive Review
Gerard B. Hawkins
 
PDF
Steam Reforming - Common Problems
Gerard B. Hawkins
 
PDF
Feedstock Purfication in Hydrogen Plants
Gerard B. Hawkins
 
PDF
Steam Reforming - (ATM) Approach to Equilibrium
Gerard B. Hawkins
 
PDF
(LTS) Low Temperature Shift Catalyst - Comprehensive Overview
Gerard B. Hawkins
 
PDF
Steam Reformer Surveys - Techniques for Optimization of Primary Reformer Oper...
Gerard B. Hawkins
 
PDF
Steam Reforming - Types of Reformer Design
Gerard B. Hawkins
 
PDF
Shift Conversion Catalysts - Operating Manual
Gerard B. Hawkins
 
PDF
Catalyst Catastrophes in Syngas Production - II
Gerard B. Hawkins
 
PDF
Amine Gas Treating Unit - Best Practices - Troubleshooting Guide
Gerard B. Hawkins
 
PDF
High Temperature Shift Catalyst Reduction Procedure
Gerard B. Hawkins
 
PDF
Steam Reforming - Tube Design
Gerard B. Hawkins
 
PDF
The Benefits and Disadvantages of Potash in Steam Reforming
Gerard B. Hawkins
 
PPT
A presentation on reformer new
Gowri Shankar
 
PDF
Steam Reforming - Practical Operations
Gerard B. Hawkins
 
Activated MDEA solution(aMDEA)
National Fertilizers Limited
 
(HTS) High Temperature Shift Catalyst (VSG-F101) - Comprehensiev Overview
Gerard B. Hawkins
 
Various ammonia technology
Prem Baboo
 
Steam Reforming - Catalyst Loading
Gerard B. Hawkins
 
Theory and Operation - Secondary Reformers -
Gerard B. Hawkins
 
Steam Reforming - A Comprehensive Review
Gerard B. Hawkins
 
Steam Reforming - Common Problems
Gerard B. Hawkins
 
Feedstock Purfication in Hydrogen Plants
Gerard B. Hawkins
 
Steam Reforming - (ATM) Approach to Equilibrium
Gerard B. Hawkins
 
(LTS) Low Temperature Shift Catalyst - Comprehensive Overview
Gerard B. Hawkins
 
Steam Reformer Surveys - Techniques for Optimization of Primary Reformer Oper...
Gerard B. Hawkins
 
Steam Reforming - Types of Reformer Design
Gerard B. Hawkins
 
Shift Conversion Catalysts - Operating Manual
Gerard B. Hawkins
 
Catalyst Catastrophes in Syngas Production - II
Gerard B. Hawkins
 
Amine Gas Treating Unit - Best Practices - Troubleshooting Guide
Gerard B. Hawkins
 
High Temperature Shift Catalyst Reduction Procedure
Gerard B. Hawkins
 
Steam Reforming - Tube Design
Gerard B. Hawkins
 
The Benefits and Disadvantages of Potash in Steam Reforming
Gerard B. Hawkins
 
A presentation on reformer new
Gowri Shankar
 
Steam Reforming - Practical Operations
Gerard B. Hawkins
 
Ad

Viewers also liked (20)

PDF
Ammonia Synthesis Flowsheet - Operator training
Gerard B. Hawkins
 
DOCX
Production of Ammonia
Brandon Hardwicke
 
PDF
Ammonia plant fundamentals
Prem Baboo
 
PPTX
Ammonia production from natural gas, haldor topsoe process
Gaurav Soni
 
PDF
Theory and Operation of Methanation Catalyst
Gerard B. Hawkins
 
PDF
Steam reforming - The Basics of Reforming
Gerard B. Hawkins
 
PDF
Theory and Practice of Steam Reforming
Gerard B. Hawkins
 
PDF
Barcelona refining summit 2014
BRONSWERK
 
PDF
CO2 Capture - Jon Gibbins, UKCCSRC, at the UKCCSRC ECR Winter School 2015
UK Carbon Capture and Storage Research Centre
 
PPT
boilers and_condensers
Arslan Abbas
 
PDF
Methanator Water Wash Procedures
Gerard B. Hawkins
 
DOCX
Silver Extraction From Hypo Fixer Solution
DEEPAK DODDAMANI
 
PDF
Syngas Catalyst Selection Criteria
Gerard B. Hawkins
 
PPTX
Extraction of silver from photographic waste
Dr. sreeremya S
 
PDF
Operation of urea fertilizers plant
Prem Baboo
 
PDF
Biogas from Food Waste: By Numbers
ENERGplc
 
PPTX
Extraction of Heavy Metals From Industrial Waste Water
Hashim Khan
 
PDF
Water Gas Shift & Hydrogen Purification Section Flowsheet
Gerard B. Hawkins
 
PDF
معالجة النفايات
Amir Alboukhari
 
PDF
Presentation wts plastic
Robinson Etseyatse
 
Ammonia Synthesis Flowsheet - Operator training
Gerard B. Hawkins
 
Production of Ammonia
Brandon Hardwicke
 
Ammonia plant fundamentals
Prem Baboo
 
Ammonia production from natural gas, haldor topsoe process
Gaurav Soni
 
Theory and Operation of Methanation Catalyst
Gerard B. Hawkins
 
Steam reforming - The Basics of Reforming
Gerard B. Hawkins
 
Theory and Practice of Steam Reforming
Gerard B. Hawkins
 
Barcelona refining summit 2014
BRONSWERK
 
CO2 Capture - Jon Gibbins, UKCCSRC, at the UKCCSRC ECR Winter School 2015
UK Carbon Capture and Storage Research Centre
 
boilers and_condensers
Arslan Abbas
 
Methanator Water Wash Procedures
Gerard B. Hawkins
 
Silver Extraction From Hypo Fixer Solution
DEEPAK DODDAMANI
 
Syngas Catalyst Selection Criteria
Gerard B. Hawkins
 
Extraction of silver from photographic waste
Dr. sreeremya S
 
Operation of urea fertilizers plant
Prem Baboo
 
Biogas from Food Waste: By Numbers
ENERGplc
 
Extraction of Heavy Metals From Industrial Waste Water
Hashim Khan
 
Water Gas Shift & Hydrogen Purification Section Flowsheet
Gerard B. Hawkins
 
معالجة النفايات
Amir Alboukhari
 
Presentation wts plastic
Robinson Etseyatse
 
Ad

Similar to Benfield system (20)

PPTX
Ammonia Refrigeration System Set up and Parameters
luxdam12
 
PPTX
Ammonia plant GSFC by Vishal Tapiawala
Vishal Tapiawala
 
PDF
SYNGAS Process Integration
Gerard B. Hawkins
 
PPTX
POWER PLANT CHEMISTRY( WATER TREATMENT FOR BOILERS)
Dilip Kumar
 
PPTX
Presentation on CO2 plant (Production Process & Quality Control).pptx
NSTU
 
PPTX
Presentation
Hafiz Muhammad Ali Ejaz
 
PPTX
Asset prospal
Sawak Maraj
 
PPTX
CUFL
Saga University
 
PDF
IRJET- Using DSFF Reactor Anaerobic Treatment of Sugar Industry Effluent
IRJET Journal
 
PPTX
IFFCO Industrial Training Evaluation.pptx
Abhay Rajput
 
PPTX
TECH PRESENTATION on Unloading Arrangements
skilldevloping
 
PDF
Catalytic Reforming Technology - Infographics
Gerard B. Hawkins
 
PPT
World Coal-to-Liquids Presentation
rcarpe
 
PPTX
Ammonia Process Presentation with proper pfd and description , optimisation
prsofficial005
 
DOCX
ammoniautility operator
Veeru Golla Palli
 
DOCX
ammonia&utility operator
Veeru Golla Palli
 
PPT
Ro For Boiler Pretreatment
meganshort
 
PPT
When Is Reverse Osmosis Right For Boiler Pre Treatment
SBWaterProfessionals
 
PPT
When Is Reverse Osmosis Right For Boiler Pre Treatment
Charles_Haynes
 
PPT
When Is Reverse Osmosis Right For Boiler Pre Treatment
Charles_Haynes
 
Ammonia Refrigeration System Set up and Parameters
luxdam12
 
Ammonia plant GSFC by Vishal Tapiawala
Vishal Tapiawala
 
SYNGAS Process Integration
Gerard B. Hawkins
 
POWER PLANT CHEMISTRY( WATER TREATMENT FOR BOILERS)
Dilip Kumar
 
Presentation on CO2 plant (Production Process & Quality Control).pptx
NSTU
 
Presentation
Hafiz Muhammad Ali Ejaz
 
Asset prospal
Sawak Maraj
 
CUFL
Saga University
 
IRJET- Using DSFF Reactor Anaerobic Treatment of Sugar Industry Effluent
IRJET Journal
 
IFFCO Industrial Training Evaluation.pptx
Abhay Rajput
 
TECH PRESENTATION on Unloading Arrangements
skilldevloping
 
Catalytic Reforming Technology - Infographics
Gerard B. Hawkins
 
World Coal-to-Liquids Presentation
rcarpe
 
Ammonia Process Presentation with proper pfd and description , optimisation
prsofficial005
 
ammoniautility operator
Veeru Golla Palli
 
ammonia&utility operator
Veeru Golla Palli
 
Ro For Boiler Pretreatment
meganshort
 
When Is Reverse Osmosis Right For Boiler Pre Treatment
SBWaterProfessionals
 
When Is Reverse Osmosis Right For Boiler Pre Treatment
Charles_Haynes
 
When Is Reverse Osmosis Right For Boiler Pre Treatment
Charles_Haynes
 

More from Prem Baboo (20)

PDF
The explosion hazard in urea process (1)
Prem Baboo
 
PDF
Urea process flow diagram
Prem Baboo
 
PDF
Materialtechnologyforfertilizersindustries
Prem Baboo
 
PDF
Neemcoatedureaaphilosophyforenvironment
Prem Baboo
 
PDF
Nano ureathephilosophyoffuture
Prem Baboo
 
PDF
Installation of s 50 in ammonia plants
Prem Baboo
 
PDF
Super conversion in urea reactors with super cup high efficiency trays
Prem Baboo
 
PDF
Ammonia plant material balance
Prem Baboo
 
PDF
Sswi april may-2021_lowres
Prem Baboo
 
PDF
Sweet and sour experience of commissioning 1
Prem Baboo
 
PDF
How to improve safety and reliability of the high pressure section of urea pl...
Prem Baboo
 
PDF
Experience of material in fertilizers industries
Prem Baboo
 
PDF
Fertilizers technology book
Prem Baboo
 
PDF
High pressure vessel_leakage_in_urea_plants (1)
Prem Baboo
 
PDF
High pressure vessel leakage in urea plants
Prem Baboo
 
PPT
Gas turbine
Prem Baboo
 
PPTX
P &amp; i diagram and tagging philosphy for
Prem Baboo
 
PDF
Ureaplantenergysavingbyselectionoflinermaterialandinernals
Prem Baboo
 
PDF
5000 tpd urea mega plants design
Prem Baboo
 
PPT
Inst maint practices
Prem Baboo
 
The explosion hazard in urea process (1)
Prem Baboo
 
Urea process flow diagram
Prem Baboo
 
Materialtechnologyforfertilizersindustries
Prem Baboo
 
Neemcoatedureaaphilosophyforenvironment
Prem Baboo
 
Nano ureathephilosophyoffuture
Prem Baboo
 
Installation of s 50 in ammonia plants
Prem Baboo
 
Super conversion in urea reactors with super cup high efficiency trays
Prem Baboo
 
Ammonia plant material balance
Prem Baboo
 
Sswi april may-2021_lowres
Prem Baboo
 
Sweet and sour experience of commissioning 1
Prem Baboo
 
How to improve safety and reliability of the high pressure section of urea pl...
Prem Baboo
 
Experience of material in fertilizers industries
Prem Baboo
 
Fertilizers technology book
Prem Baboo
 
High pressure vessel_leakage_in_urea_plants (1)
Prem Baboo
 
High pressure vessel leakage in urea plants
Prem Baboo
 
Gas turbine
Prem Baboo
 
P &amp; i diagram and tagging philosphy for
Prem Baboo
 
Ureaplantenergysavingbyselectionoflinermaterialandinernals
Prem Baboo
 
5000 tpd urea mega plants design
Prem Baboo
 
Inst maint practices
Prem Baboo
 

Recently uploaded (20)

PDF
UNIT no 1 INTRODUCTION TO DBMS NOTES.pdf
pawarbhaktiit
 
PDF
Abrasive, erosive and cavitation wear.pdf
nfandraden
 
PPTX
communication and presentation skills 01
CdtAfrazAttaullah
 
PDF
EXPLORING LEARNING ENGAGEMENT FACTORS INFLUENCING BEHAVIORAL, COGNITIVE, AND ...
johnmathew9417
 
PDF
Artificial Superintelligence (ASI) Alliance Vision Paper.pdf
SonaliPatil325517
 
PDF
22EC502-MICROCONTROLLER AND INTERFACING-8051 MICROCONTROLLER.pdf
RajalakshmiSermadura
 
PDF
August 2025 - Top 10 Read Articles in Network Security & Its Applications
IJNSA Journal
 
PDF
Design Guidelines and solutions for Plastics parts
ferdinand937933
 
PDF
SMART SIGNAL TIMING FOR URBAN INTERSECTIONS USING REAL-TIME VEHICLE DETECTI...
Niraj Aarya
 
PDF
ChapteR012372321DFGDSFGDFGDFSGDFGDFGDFGSDFGDFGFD
NotaProGamer
 
PDF
Visual Aids for Exploratory Data Analysis.pdf
Ashutosh Satapathy
 
PPTX
6ME3A-Unit-II-Sensors and Actuators_Handouts.pptx
anukaranugi
 
PDF
Level 2 – IBM Data and AI Fundamentals (1)_v1.1.PDF
KSRIHARISASANKA
 
PPTX
Fundamentals of Mechanical Engineering.pptx
MdMowdudAhmed
 
PDF
Accra-Kumasi Expressway - Prefeasibility Report Volume 1 of 7.11.2018.pdf
JeorgeWilsonKingson1
 
PPTX
AUTOMOTIVE ENGINE MANAGEMENT (MECHATRONICS).pptx
joanaabban6
 
PPTX
Module 8- Technological and Communication Skills.pptx
Ramya Nellutla
 
PDF
BIO-INSPIRED HORMONAL MODULATION AND ADAPTIVE ORCHESTRATION IN S-AI-GPT
ijaia
 
PPTX
Fundamentals of safety and accident prevention -final (1).pptx
Palani kumar
 
PPTX
Amdahl’s law is explained in the above power point presentations
sangeetha952248
 
UNIT no 1 INTRODUCTION TO DBMS NOTES.pdf
pawarbhaktiit
 
Abrasive, erosive and cavitation wear.pdf
nfandraden
 
communication and presentation skills 01
CdtAfrazAttaullah
 
EXPLORING LEARNING ENGAGEMENT FACTORS INFLUENCING BEHAVIORAL, COGNITIVE, AND ...
johnmathew9417
 
Artificial Superintelligence (ASI) Alliance Vision Paper.pdf
SonaliPatil325517
 
22EC502-MICROCONTROLLER AND INTERFACING-8051 MICROCONTROLLER.pdf
RajalakshmiSermadura
 
August 2025 - Top 10 Read Articles in Network Security & Its Applications
IJNSA Journal
 
Design Guidelines and solutions for Plastics parts
ferdinand937933
 
SMART SIGNAL TIMING FOR URBAN INTERSECTIONS USING REAL-TIME VEHICLE DETECTI...
Niraj Aarya
 
ChapteR012372321DFGDSFGDFGDFSGDFGDFGDFGSDFGDFGFD
NotaProGamer
 
Visual Aids for Exploratory Data Analysis.pdf
Ashutosh Satapathy
 
6ME3A-Unit-II-Sensors and Actuators_Handouts.pptx
anukaranugi
 
Level 2 – IBM Data and AI Fundamentals (1)_v1.1.PDF
KSRIHARISASANKA
 
Fundamentals of Mechanical Engineering.pptx
MdMowdudAhmed
 
Accra-Kumasi Expressway - Prefeasibility Report Volume 1 of 7.11.2018.pdf
JeorgeWilsonKingson1
 
AUTOMOTIVE ENGINE MANAGEMENT (MECHATRONICS).pptx
joanaabban6
 
Module 8- Technological and Communication Skills.pptx
Ramya Nellutla
 
BIO-INSPIRED HORMONAL MODULATION AND ADAPTIVE ORCHESTRATION IN S-AI-GPT
ijaia
 
Fundamentals of safety and accident prevention -final (1).pptx
Palani kumar
 
Amdahl’s law is explained in the above power point presentations
sangeetha952248
 

Benfield system

  • 1. AMMONIA PLANT CO2 ABSORPTION PROCESS Prem Baboo Sr. manager(Prod) National Fertilizers Ltd, India FIE ,Institution of Engineers( India) Technical Advisor & an Expert for www.ureaknowhow.com
  • 2. CO2ABSORBER&REGENERATOR CO2 TO UREA PLANT .6 Kg/Cm2 43.2KNM3 9.14 P-1307 P1301 (A,B&C) E302 A&B 4 8 % 48% IN CO2-17.10% Ar-.75% N2-21.3% CH4-0.4% CO-0.11% H2-60.84% OUT CO2-.11% Ar—0.30% N2—25.65% CH4—0.5% CO--.13% H2—73.51% 13FIC 20 13-FIC-2 1 8.548.54 FLOW 1135M3 FLOW 345M3 104 M3 104M3 3.94M PALL RINGS 1.5” ..01M TOTAL 517M32”PALLRINGS L.P. STEAM 30 TON 13 FIC02 P.G.
  • 3. BENFIELD PROCESS FLOW DIAGRAM 13 FIC02 13HIC101 DM WATER FROM TANK 307 MT/Hr. PROCESS GAS TO METHENATOR 600 C 345M3 FAN COOLER E 1303 ABSORBER F 1302 28.45MT/Hr 1100 C PROCESS CONDENSATE TX-1301 CICULATION PUMP BOOSTER PUMP REGENATOR F-1301 B-1305 E-1302 A/B B1306- TO FGR FLASH GAS 1590C PROCESS GAS CONDENSATE E1308 E1306 LP STEAM B1301 1130 C1162M3/ Hr B-1303 T0 DE-AERATOR C.W.
  • 4. REMOVAL OF CO2:- PROCESS FOR REMOVAL OF CO2 ARE BASED UPON SCRUBBING OF GAS WITH SOME SOVENT (PHYSICAL OR CHEMICAL) THE SOLVENT SHOULD HAVE THE FOLLOWING PROPERTIES:- i. HIGH CO2 SOLUBILITY ii. LOW VISCOSITY iii. HIGH STABILITY UNDER OPERATING CONDITION iv. NO REACTIVITY UNDER OPERATING CONDITION v. VERY LOW VAPOUR PR UNDER OPERATING TEMP
  • 5. GENERAL CONSIDERATION IN PROCESS SELECTION 1. PARTIAL PR OF CO2 IN FEED GAS AND TOTAL PR OF ABSORPTION 2. CO2 PURITY 3. GAS CONTAINING CO 4. AVAILABILITY OF UTILITY AND COST TWO TYPE OF PROCESSESS A. PHYSICAL PROCESS SOLVENT 1. WATER SCRUBBING WATER 2. LINDE’S RECTISOL METHANOL 3. ALLIED SELEXOL POLYPROPYLENE GLYCOL DIMETHYL EITHER 4. FLUOR’S PROCESS PROPYLENE CARBONATE 5. PURISOL N METHYL- 2 PYRROLIDINE 6. SULPHINOL TETRAHYDRO THIOPHENE 1, 1 DIOZIDE
  • 6. B. CHEMICAL ABSORPTION BEST SUITED FOR LOW CO2 PARTIAL PRESSURE 1. MEA PROCESS:- MONO ETHANOL AMINE (REBOILER ENERGY IS HIGH 2NH2(CH2)2 OH + CO2+H2O=[HO(CH2)2NH3]2CO3 DISADVANTAGE:- (i)[HO(CH2)2NH3]2CO3+CO2+H2O= 2HO(CH2)2NH3HCO3 (ii) HO(CH2)2NH2+CO2= HO(CH2)2NHCOONH3(CH2)2OH CARBOMATE IS CORROSSIVE IN HOTER PARTS OF MEA • GV PROCESS • CATACARB PROCESS • BENFIELD PROCESS C. PHYSIOCHEMICAL PROCESS 1. MDEA PROCESS( METHYLDIETHANOAMINE
  • 7. BENFIELD PROCESS OVER 700 BENFIELF PLANTS IN WORLD ENERGY 660 – 1140 KILO CALORIE PER NORMALM3CO2 45% FOR REGENERATION 55% FOR ABSORPTION K2CO3+CO2+H2O=2KHCO3+HEAT( MILD EXOTHERMIC) CO2+H2O=HCO3- +H+ CO3-- +H2O=HCO3- +OH- CO2+CO3-- H2O=2HCO3 1M3 30% K2CO3 SOLN ABSORBED 10M3 CO2 WITHOUT ANY ACTIVATOR ACTIVATOR ACTION:- DEA (R2NH) R=CH2CH2OH R2NH+CO2=R2NCOOH (INTERMIDIATE PRODUCT) R2NCOOH+K2CO3+H2O= R2NH+2KHCO3 K2CO3+CO2+H2O=2KHCO3
  • 8. PROPERTIES OF DEA MW = 105.14, SP GR = 1.0966, MELTING PT = 28O C , BP = 10/100/760MMHG= 150/205/260 ANALYSIS OF LEAN SOLUTION / RICH SOLN K2CO3 KHCO3 EQ K2CO3 F/C TV V+5 DEA FE 17.22 15.32 27.80 .38 10.4 .4 2.42 42.1 10.67 25.52 28.30 .67 .85 .67 2.8 ---- CALCULATION OF F/C 1 _ _%AGE K2CO3 %EQ K2CO3 % EQ K2CO3 = % K2CO3+(MW KHCO3)100 % KHCO3 MW K2CO3)138 17.22+(0.69)X15.32=27.8016 1- FC 1_ (17.22) = 0.38 IN LEAN SOLN 27.8016 F/C IN RICH / LEAN SOLN = 0.858/0.352 (DESIGN VALUE) F/C = F/C RICH – F/C LEAN (ACTUAL) . F/C RICH – F/C LEAN (DESIGN)
  • 9. COMPARISON BETWEEN PLANTS RECTISOL PHYSICAL ABSORPTION . LOWER ENERGY .REMOVAL OF ALL IMPURITIES SUCH AS ORGANICS, H2S, BENZENE, GUM FOAMING AND HYDROCARBON .PRODUCTION OF GAS WITH NEGLIGIBLE WATER GAS SOLVENT METHANOL . HIGH CO SLIP FROM CO SHIFT SECTION .FINAL REMOVAL OF CO,CO2 BY N2 WASH INI BENFIELD CHEMICAL ABSORPTION 612KCAL/NM3 CO2 B-1306 YES LP BOILER AFTER REBOILER NO REGN SINGLE ACTIVATOR SINGLE DEA HYDROLLIC TURB SINGLE( POWER GENERATION) AERATION OF SOLN NO FAVOURABLE CO2 BLOWER NO GV CHEMICAL ABSORPTION 713.5KCAL/NM3 CO2 B-1306 NO YES DOUBLE DUAL (DEA+GLYCINE) DUAL PUMP DRIVEN AVAILABLE CO2 BLOWER VENEZEULA CHEMICAL ABSORPTION 700KCAL/NM3 CO2 B 1306 YES YES YES DOUBLE DUAL DEA+GLYCINE) DUAL PUMP DRIVEN AVAILABLE CO2 BLOWER NO
  • 10. contd CO2 BLOWER YES DISADVANTAGE NO PGR NO OF PUMP AND COLUMN MORE INITIAL COST HIGH CO2 EXCESS VENT NO CO2 EXCESS PGR AMMONIA PRODUCTION NO CO2 EXCESS UTILIZE CO2 EXCESS VENT PGR AVAILABLE
  • 11. CORROSION CO2 ITSELF WEAKLY ACIDIC HOT POTASSIUM CARBONATE SOLN AGGRESSIVE FOR CORROSION COMPOUND MAY FORM WITH THE SCRUBBING SOLN CORROSIVE TO STEEL THEREFORE, A VANADIUM SALT V+5 IS USED IN THE SOLN AS A CORROSION INHIBITOR THE VANADIUM OXIDISES THE IRON ON MET AL SURFACES (VANADATION) BY ADDING V2O5 THE RESULTANT OXIDES FE3O4 MAGNETITE PRODUCE A TIGHT ADHERENT FILM ON THE SURFACE WHICH RESULTS IN ESSENTIALLY NO CORROSION DURING OPERATION UNLESS THE FILM IS DISTURBED V+5 +Fe2e = V+4 +Fe3e FERRIC Fe2O3 MOST STABLE FORM V2O5 CONVERTS Fe2O3 TO Fe3O4 2FeO +V2O5 = Fe2O3 + V2O4 FeO + Fe2O3 = Fe3O4 (MAGNETITE) MAINTAIN PENTAVALENT VANADIUM NOT LESS THAN 0.2 WT % INCREASE V+5 CONTENT BY ADDITION FRESH V2O5 (VANADIUM PENTAOXIDE) ADDITION OF KNO2 IS RECOMMENDED FOR OXIDATIION METHOD KNO2 +V2O4 = V2O5 +KNO
  • 12. CORROSION AND PROBLEMS IN PLANTS • 1 – 1986 AND 1992 IN RCF ( HALDOR TOPSOE PLANT) • 2 – 1986 : PRECIPITATED BICARBONATE PEELS-OFF THE PASSIVATIION LAYER IRON • AND VANADIUM IN THE SOLN CO-PRECIPITATE WITH THE BICARBONATE FORMING • A SLURRY PLANT WAS SHUT DOWN 30 DAYS CIRCULATION PUMPS REPAIRED • NOV 1994 – HYDRO AGRI TRINIDAD’S TRINGEN II – 33 DAYS SHUT DOWN • PROTECTIVE MAGNETITE LAYER IN THE ABSORBER BOTTOM AND DISTRIBUTER BECOME DAMAGED FORMATION OF IRON CARBONATE CORROSION RATE INCREASED COMPLETE DEPLETION OF VANADIUM • 1992 – KRIBHCO HAZIRA – KELLOG’S DESIGN • FOLLOWING A NUMBER OF CRASH SHUT DOWN DUE TO NG AND MAINTENANCE JOB • THE CO2 PRODUCT PURITY OF BOTH UNITS CAME UP TO 97.96% DUE TO FAILURE OF FLOATING HEAD GASKET IN THE FLOATING HEAD TYPE EXCHANGER (REBOILERS) • SUSPECTABLE FAILURE AND THIS ALLOWED LEAKING PROCESS GAS TO ATTACK AND DESTROY THE PASSIVATION LAYER OF CS WALL OF REGENATOR • 2001 – VENEZUELA JOSE FERTILISERS . AFTER REDUCTION OF LT CO SHIFT CONV CATALYST – CATALYST DUST BEFORE LINE UP TO GV DID NOT BLOW / REMOVE PROPERLY Fe CONTENT IN GV SOLN -~ 5000 PPM VISCOSITY OF SOLN INCREASED FREQUENT CHOCKING OF STRAINERS AND DRAIN LINES OCCURS WHOLE SOLN FILTERS THROUGH Fe CONTENT CAME DOWN AND VISCOSITY NORMALISED
  • 13. BENFIELD SYSTEM: START UP CHECK LIST :- 1. TRIP SYSTEM: IS-4, IS-5, IS-301A, B, C, IS 303, IS 304 ARE IN RESET CONDITION 2. STROKE CHECKING OF ALL CONTROL VALVES 3. CHECK a. 13 HV- 10 ------------CLOSE b. 13 HIC 101-------------CLOSE c. 13 FCV 02 -------------BY PASS & CV F/C d. ISOLATION VALVES OF 13 FIC -01, LIC -01, 13LIC-20- I/2, 13PV 28 13 LCV- - 26-1/2 CLOSE e. DM WATER CIRCULATIION – NORMAL f. CW TO E -1308 A/B – OPEN g. F 1302 PR NORMAL WITH NG > 15KG/CM2 h. N2 TO F 1301 OPEN j. PUMPS – P-1307/ P- 1301 PROPERLY LINED UP k. PUMPS ELECTRICALLY ENERGISED l. PUMPS L.O. CIRCULATION & SEALING WATER SYSTEM NORM
  • 14. Contd. m. LEVEL IN B 1305 LESS THAN 100% n. O2 CONTENT IN THE SYSTEM LESS THAN 100PPM 4. START CIRCULATION KEEP E 1303 FANS IN STOPPED CONDITION 5. KEEP 13HV 10 CLOSE AND START INDIRECT HEATING BY SM STEAM PR LESS THAN 5 KG/ CM2 , TEMP LESS THAN 1800 C F 1301 PR 2 KG/CM2 (N2) OBTAIN BENFIELD SOLN TEMP 105O C PASSIVATION A. STATIC – E 1302 A/B FLOODED CONDITION TEMP=130O C DURATION 48 HRS B. DYNAMIC – CIRCULATION RATE 80% DURATION 36 HRS MAINTAIN V+5 EQUAL 0.5% K2CO3 KHCO3 EQ K2CO3 F/C V+5 DEA FE 20.96 6.37 25.33 0.172 0.47 2.18 66.74PPM LOCAL DRAINING B 1303 ON R1205 BY PASS MOV45 FULL CLOSED
  • 15. FOR INDIRECT HEATING STOPPED CONDITION NG FLOW TO PRIMARY REF 6000NM3, STEAM FLOW 30 TE/HR RECYLE GAS FLOW ( 12FIC 02 +12 FIC 17) EQUAL 4000NM3 ( 800 +2200) 12TJR 1/12, 06 =5000 C / 7500 C 13 PI C11= 0.6KG/CM2 B 1305 STEAM EJECTORS , X 1301 A/B/C/D I/VS OF VAPOURS AND SL STEAM I/V MOTIVE STEAM TO BE OPENED FOR LINING UP SEQ 1. X 1301D 2. X 1301C 3. X 1301B 4. X 1301A FROM CCR 13 HIC O4, O5, O6, O7, INITIALLY TO BE CLOSED AND TO BE OPENED AFTERWARDS. 13 FIC O2 I/VS TO BE OPENED
  • 16. contd 13 HIC 101 TO BE OPENED LINE UP 13 TIC O9 STOP NG TO F 1302 AND N2 TO F 1301 BLIND TO BE PROVIDED STOP LOCAL DRAINING OF 1303 AND LINE UP TO PC HEADER
  • 17. BENFIELD THEORY a. FAVOURABLE PARAMETERS FOR ABSORPTION 1. HIGH PRESSURE ( LIMITATION REF PRESSURE) 2. BETTER ACTIVATOR ( DEA, IN LINE II GLYCINE ALSO) 3. LOWEST F/C 4. BETTER FILTERATION ( 10 MICRONS OR LESS) 5. OPTIMUM SPLIT STREAM TEMP 6. IMPROVED PACKED BEDS AND INTERNALS b. FAVOURABLE PARAMETERS FOR REGENERATION 1. LOW PRESSURE 2. PROPER DISTRIBUTION OF RICH SOLN 3. IMPROVED PACKED BED AND INTERNALS 4. REGN STEAM FLOW/ PR / TEMP OPTIMUM
  • 18. FOAMING CAUSES: IMPURITIES i. SODIUM:- <1.0 % Na LIMITED NaHCO3 SOLUBILITY ii. CHLORIDE:- AS CL- >100PPM iii. INERTS SALTS:- FORMATE, THIOSULPHATE ETC. CAN JOLERATE UPTO MINIMUM INNNERTS IN SOLUTION DEENSITY AND ABSORPTION AFFECTED. iv. HEAVY METALS:- POTENTIAL FOR LOSS OF PASSIVATION. v. SOLUBLE Fe CONTEST:- CONTENT UPTO 150PPM (NORMAL) MAX SOLUBLE 200 – 250 PPM – CORROSION OCCURING. vi. SOLIDS IN SOLUTION:- ABRASIVE, LOSS CORROSION PROTECTION, FOAMING OF SOLUTION. vii. SOLUBLE INORGANIC CONTAMINATES:- - TOTAL SALTS HIGH - PROCESS TEMP INCREASES - LOSS OF ABSORPTION EFFICIENCY viii. SOLUBLE ORGANIC CONTAMINATES:- - FREQUENT CAUSE OF FOAMING OF SOLUTION - SOME LOSS OF ABSORPTION EFFICIENCY ix. GREASE AND OIL.. x. INTERNALS DISTURBES
  • 19. FOAMING CAUSES i. DUST OF ACTIVATED CARBON ii. SUSPENDED METALLIC COMPOUNDS, WHICH MAY DISTURB SURFACE TENTION iii. DECOMPOSITION PRODUCTS iv. ORGANIC SUBSTANCES, GREASE, LUBEOIL, PAINT BITUMIN EPOXY RASINS. v. SULPHIDES FOAMING IS INDICATED BY :- 1. HIGH PDI OF ABSORBER, REGENERATOR 2. SOLUTION CARRY OVER 3. SOLUTION HOLD UP IN PACKINGS 4. LEVEL INSTABILITY 5. INCREASE IN CO2 SLIP
  • 20. FOAMING CONTROL 1. SIDE STREAM FILTRATION – A) MECH FILTER~ 10 MICRONS FLOW – 5% TO 10% OF CIRCULATION RATE. (CONTINUOUS REMOVAL OF SOLIDS ) B) ACTIVATED CARBON FILTER:- TO REMOVE i. ORGANIC MATTER AND CONTEMINANTS ii. DECOMPOSED COMPOUNDS iii. IF COLOUR OF SOLN IS DARK, IMPROVE TRANSPARENCY 2. LIMITED USE ( 20ML) OF ANTIFOAM AGENT (UCON 50 HB 5100, POLYGLYCOLS , SILICONES. 3. DEMISTERS OF ABSORBER AND REGENERATOR FLUSHING BY BFW
  • 21. FOAMING TEST 50 ML FILTERED BENFIELD SOLUTION AT 90OC SHAKEN VIGOROUSLY OR N2 IS BUBBLED FOR ONE MINUTE HIGHT OF FOAM > 40 MM COLLASPE TIME > 10SEC CAUSE OF INCREASE IN CO2 SLIP 1. INCORRECT SOLUTION FLOW RATE. 2. HIGH Fe OF HPC SOLUTION. 3. INCORRECT LEAN/ TOP SOLUTION TEMP. 4. INCORRECT SOLN COMPOSITION 5. FOAMING 6. INCORRECT SOLN / GAS – DISTRIBUTION IIN BEDS 7. DDISTURBANCE IN PACKING ARRANGEMENTS 8. DAMAGE / DISLOCATE INTERALS OF ABSORBER/ REGENERATOR
  • 22. CAUSES OF BAD REGENERATION 1. LOW REGENERATION STEAM FLOW / TEMP / PR 2. HIGH SOLUTION FLOW RATE 3. ABSORBER GAS INLET TEMP LOW 4. REGENERATOR PR HIGH 5. INCORRECT STEAM / SOLUTION TEMP PROCESS FOR REMOVAL OF CO2 ARE BASED UPON SCRUBBING OF GAS WITH SOME SOVENT (PHYSICAL OR CHEMICAL) THE SOLVENT SHOULD HAVE THE FOLLOWING PROPERTIES:- i. HIGH CO2 SOLUBILITY ii. LOW VISCOSITY iii. HIGH STABILITY UNDER OPERATING CONDITION iv. NO REACTIVITY UNDER OPERATING CONDITION v. VERY LOW VAPOUR PR UNDER OPERATING TEMP *************************************************************************************