petrosim training course-1
DESCRIPTION
petrosim training courseTRANSCRIPT
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PETRO-SIM
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Petrosim
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Simplified Preheat Train 2 Assay Synthesis 6 Naphtha Stabilizer 10 Stream Properties 14 Tray to Tray Crude Column 24 Tray to Tray Vaccum Column 28 DISTOP Crude Column 32 DISTOP Vacuum Column 37 DISTOP Calibration 41 The Meter Unit Operation 52 Heat Integration 55 Using the Optimizer 59 Sub Flowsheeting 62 Excel Integration 66 CCR Reformer 69 REF-SIM 81 KBC Reactor Models 99 REF-SIM CALIBRATION DATA REQUIREMENTS 105
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Simplified Preheat Train
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:1 : Arabian Light
: PFD
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: Load Refinery Assay in to Composition
Stream Assay Initialize Assay Properties Only . . Mixer
. Set %3
. Light Gas . Adjust
03/0 Light Gas To Separator .
Spread Sheet H2 C2 C3 i-C4 n-C4 i-C5 n-C5 . Light Gas
Adjust Adjust To Separator H2 C2 C3 i-C4 n-C4 i-C5 n-C5 3/0
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Assay Synthesis
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:2 refinery Components
default Peng Robinson . Assay Crude Back Blending Plant Data Group Naphtha Kerosene LGO
Lights HGO FUEL OIL RESIDUEE Heavies :
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Assay (Properties) 32 :
SG, Aromatics, Naphthenes, Olefins, Iso-paraffins, RON Clear, RON Pb, MON Clear, MON Pb, Visc 50C, Visc 100C, Total Sulfur, Mercaptan Sulfur, Pour, Cloud, Freeze, Mol Wt, Aniline Point, TVP , RI, Total N2, Con Carbon, Ni, Va, Cu/Fe, Na, C to H, Sat Rings, Fap 1, Fap 2
. Assay ... . Assay TBP
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Contiguous
. (Contiguous) .
Overlapping
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Minus
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Naphtha Components . GC
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Exclude .
. Assay .
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Plant Data Group Gas :
. Crude Back Blending TBP : Tower Feed
(C) 40 (Bar) 5
(Tonnes/hr) 100Crude Back Blending Assay:
Straight Cuts Component Splitter :
. 15
. Synthesis
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Naphtha Stabilizer
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:3 : Naphtha Stabilizer
refinery default Components
Refinery Plant To Crude . Peng Robinson :
API Gravity=68
Light Ends Volume %
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: Naphtha Stabilizer
22 8 (Bar) 7/8 (Bar) 4/0 (Bar) 3/9
(C) 54 (C) 93 1 (m3/hr) 12
. Naphtha Stabilizer
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(D86 5% stab naphtha, C4s in Bottoms, vol) .
Distillaate Rate C4s in Bottoms, vol Distillate Rate D86 5% . 01/0
stab naphtha . C 43 . Tray Sizing Design
Valve Tray . Tray Sizing Rating
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Secion 2 Section 1 2 1 Flow Path 7 3 Diameter (ft)
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Stream Properties
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Stream Type Petrosim (General, Water, Sour Water, Light Gas, Gasoline, Kerosene, Distillate, Fuel Oil, Crude)
Properties .
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Properties : Property Picker .
LPG Distillation D86 Vol-90 : LPG Properties
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Petrosim :
Distillation ASTM D86 Plot -1
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Attachments\Utilities\BP Curves -2
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. Tools\ Stream Properties
. % 80 % 20 D86
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Distillation D86 Vol_20 Distillation ASTM D86_20 Display Name . Distillation D86 Vol_80 Distillation ASTM D86_80
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Petrosim
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Stab Naphtha Properties
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Assay Adjuster Naphtha Stablizer
. Assay Adjuster . Plant to Crude
Oil . Assay Manager ARABIAN LIGHT Assay Adjuster
: Stab Naphtha
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Aromatics Content by Volume Specification\Properties Naphthenes Content by Volume Specification\ Properties\
Stream ARABIAN LIGHT :
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Stab in Adjusted ARABIAN LIGHT Properties Composition .
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Feed Model database Assay Assay
ARABIAN LIGHT Oil Manager . :
: Product Stream
: TBP Plot
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Tray to Tray Crude Column
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:4 (1 )
(CDU SSteam) :
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39 34
Partial (bar) 5/1
(bar) 0 (bar) 2 (C) 40 (C) 120 (C) 400
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: Initialize Assay Properties Only Steam
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. ( . )
Pump Around . .
Sub Flowsheet .
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Tray to Tray Vaccum Column
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:5
Bttms E-103 :
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10 10
(bar) 03/0 (bar) 04/0
(C) 46 (C) 400
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Pump Around :
46 . LVGO HVGO
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Pump Around :
. HVGO TBP Cut Point on Feed Spec
. HVGO
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: Petrosim Tray-to-tray DISTOP
Tray-to-tray . (rigorous)
Distop . section by section
Distop . .
Distop . Assay .
. Distop
Tray-to-tray . TBP Distop
Overflash Pumpback Reflux Flow . : .
Reflux rates Overflash Rates
Pumparound Duties
Stripping Steam Rates
Reboiler Heat Duties
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DISTOP Crude Column
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:6 . Distop 1
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: Simplified Preheat Train with Tray to Tray Column.
. Distop Solver Parameter
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Column Environment Monitor Tray to Tray General Distop .
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Overflash on feed: 1 vol%
Drum T: 75 C, 167 F
Efficiencies :
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: % 100 .
. % 60 Pump Around
. : Product Spec
. . Result Distop .
. Open PFD
(Fractions) Distop .
. Adjust . Diesel HGO
C7- F19 :
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Adjusted Variable: Column subflowsheets\CDU\Distop TBP cut point\HGO\Accept
Target Variable: Material Streams\Diesel\Calculator \Cloud Point\Accept
:Adjust
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DISTOP Vacuum Column
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:7 Distop 6
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: Bttms
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Distop : Distop Vacuum Tower (K-Value) . Heat Balance Closure Feed Conditions . LVGO 100 %
. % 50 Pump Around Percent Maximum Heat Removal
. % 80 HVGO % 100
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.% 100
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DISTOP Calibration
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Distop Distop
Yield) . Stream Data) .
. . Distop
(Back Blending)
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Distop section by section Distop
: 4 (Flash Zone) . . . .
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Distop .
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(Stripper efficiency) .1 .
( ) .
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1 - Volume Interchange (VI)
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(Section efficiency) .2
. X
( ) ( )
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3. Front Shape Factor
Front Shape ( )
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4. Back Shape Factor
Back Shape . X ( )
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:8 . 6 Distop
Distop Calibration :
Petro-Sim Calibration Naphtha Kerosene Diesel . Cond-Vet
D86 HGO Bttms D1160 .
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: Add Set Input Data
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Accept meter :
: . meter
. DISTOP Calibration_Values.xls
. input data
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Cut Name Naphtha Kerosene Diesel Naphtha Kerosene Diesel
Mass flow 107 56 84
Specific gravity 0.723 0.793 0.835
Distillation ASTM D86_1 vol % [C] 35 175 226 Distillation ASTM D86_1 vol % [F] 95 347 439
Distillation ASTM D86_5 vol % [C] 61 179 242 Distillation ASTM D86_5 vol % [F] 142 354 468
Distillation ASTM D86_10 vol % [C] 77 181 247 Distillation ASTM D86_10 vol % [F] 171 358 477
Distillation ASTM D86_20 vol % [C] 94 184 255 Distillation ASTM D86_20 vol % [F] 201 363 491
Distillation ASTM D86_30 vol % [C] 105 187 262 Distillation ASTM D86_30 vol % [F] 221 369 504
Distillation ASTM D86_50 vol % [C] 120 194 275 Distillation ASTM D86_50 vol % [F] 248 381 527
Distillation ASTM D86_70 vol % [C] 132 203 289 Distillation ASTM D86_70 vol % [F] 270 397 552
Distillation ASTM D86_80 vol % [C] 139 210 298 Distillation ASTM D86_80 vol % [F] 282 410 568
Distillation ASTM D86_90 vol % [C] 146 220 310 Distillation ASTM D86_90 vol % [F] 295 428 590
Distillation ASTM D86_95 vol % [C] 152 227 318 Distillation ASTM D86_95 vol % [F] 306 441 604
Distillation ASTM D86_99 vol % [C] 161 239 327 Distillation ASTM D86_99 vol % [F] 322 462 621
Cut Name HGO Residue HGO Residue
Mass flow 31 260
Specific gravity 0.882 0.981
Distillation ASTM D1160_1 vol % [C] 280 314 Distillation ASTM D1160_1 vol % [F] 536 597
Distillation ASTM D1160_5 vol % [C] 310 376 Distillation ASTM D1160_5 vol % [F] 590 709
Distillation ASTM D1160_10 vol % [C] 355 406 Distillation ASTM D1160_10 vol % [F] 671 763
Distillation ASTM D1160_20 vol % [C] 365 449 Distillation ASTM D1160_20 vol % [F] 689 840
Distillation ASTM D1160_30 vol % [C] 374 477 Distillation ASTM D1160_30 vol % [F] 705 891
Distillation ASTM D1160_50 vol % [C] 390 541 Distillation ASTM D1160_50 vol % [F] 734 1006
Distillation ASTM D1160_70 vol % [C] 409 Distillation ASTM D1160_70 vol % [F] 768
Distillation ASTM D1160_80 vol % [C] 425 Distillation ASTM D1160_80 vol % [F] 797
Distillation ASTM D1160_90 vol % [C] 445 Distillation ASTM D1160_90 vol % [F] 833
Distillation ASTM D1160_95 vol % [C] 450 Distillation ASTM D1160_95 vol % [F] 842
Distillation ASTM D1160_99 vol % [C] 482 Distillation ASTM D1160_99 vol % [F] 900
Cut Name Gas
Mass flow 10.4
Component Mole Composition
Nitrogen [mol %] 0.37
Methane [mol %] 3.35
Ethane [mol %] 18.65
Carbon dioxide [mol %] 0.70
Hydrogen Sulphide [mol %] 1.17
Propane [mol %] 25.62
Iso butane [mol %] 13.93
N butane [mol %] 26.60
Iso pentane [mol %] 4.48
N pentane [mol %] 4.05
Hexane + [mol %] 1.08
TOTAL 100.00
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: . Run Independent variables Constraints Objective function
. % 5 % 0 Constraint
. Objective
. Cutter Synthesize . Synthesize
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. 1 . DISTOP column solver
Diagnostics . . Synthesize
. synthesis Calibrate Cutter Synthesize
. Objective
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Distop Accept Cutter
Reset . . Cutter .
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1 - Section efficiencies 2 - volume interchange values
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The Meter Unit Operation
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historian meter Petrosim .
. Petrosim meter
:9 Petrosim 1 . (Stream Type) Gasoline . Palette meter 1 . Dataset ).
(. Calculator
Solve Control Send Data on Solve Send All Variables For Selected Objects .
1 . synthesize
Plant to Crude unit operation synthesize .
Plant to Crude unit operation meter
. 1
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Assay Synthesis Default set Data set . Plant to Crude unit operation meter .
: Corrections meter
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. Corrections .
API 2540 . Active Set . Active Set
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meter .
. Calculate Mole Wt
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API 2540 meter .
Corrections Liquid Flow C24 API 75 .
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: Screened Override Data set
. Min Max
Screened . Default .
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Heat Integration
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:11 Simplified Preheat Train with Tray to Tray Column.ksc . Pump Around Export Diesel PA .
. PFD Diesel PA
HC Liquid E-101 .
HC Liquid . Diesel PA_Draw Diesel PA_Return .
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Design End Point 5/0 . .
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:11 Rating E-103 6 .
Recycle Diesel PA_Draw .
hold . E-103 Steady State Rating
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Open PFD . Sub flowsheet Diesel_PA cooler .
No .
Monitor Diesel PA .
. m3/hr 250 Diesel PA_Draw
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Using the Optimizer
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:12
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OilStabilizationOpt. Ksc Optimizer .
Optimizer Simulation F5 Palette
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: Steam 1 Heat Flow
Steam 2 Heat Flow
Steam 3 Heat Flow
Stage 2 Vap Pressure
Stage 3 Vap Pressure
Upper Lower Variable 1E6 kJ/hr 0 Steam 1 Heat Flow 1E6 kJ/hr 0 Steam 2 Heat Flow 1E6 kJ/hr 0 Steam 3 Heat Flow
35 bar 6.5 bar Stage 2 Vap Pressure 10 bar 0.7 bar Stage 3 Vap Pressure
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Cold Properties-1: Reid VP of Liq Prod
Upper Lower Constraint 0.965 bar 0.5 bar Reid VP Limits
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-2.78e-5 cost/kJ Heat Flow Comp 1 hp -2.78e-5 cost/kJ Heat Flow Comp 2 hp -1.894e-4 cost/kJ Heat Flow Steam 1 -1.894e-4 cost/kJ Heat Flow Steam 2 -1.894e-4 cost/kJ Heat Flow Steam 3 14.94 cost/bbl Liq Vol Flow@Std Cond Liq Product 2.508 cost/kgmole Molar Flow Gas Product
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Sub Flowsheeting
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Sub Flowsheet . Sub Flowsheet Sub Flowsheet Case Study
Sub . Sub Flowsheet Flowsheet .
:13 CDU VDU HDS.ksc . T-100 .
Cut/PasteObjects Combine into
Sub Flowsheet .
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-Flow Sub Flowsheet . 1
Sub Flowsheet .
Sub Flowsheet ExternalStream
. Sub-Flowsheet Environment :
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Sub Flowsheet .
Sub Flowsheet Sub Flowsheet
Sub Flowsheet . Open PFD . Sub Flowsheet
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. Excel Petrosim
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Excel Integration
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:14
Excel Simplified Preheat Train.ksc . Raw Crude Properties . Properties Ctrl+Shift+C
. Lable . Excel Ctrl+V Paste . Properties
: Excel
Export New Table to Excel . Create Excel
Link Export New Table .
Excel Petrosim Excel
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Excel . macro .
Petrosim Excel Excel Toolbars Petrosim Toolbar For Excel .
Excel Toolbar Push All Send to Petro-Sim Excel Petrosim . Petrosim
Get All Update From Petrosim ( )Toolbar .
Refresh Sheet Petrosim Excel .
Excel . Send to Excel
Custom Table . help .
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CCR Reformer
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. 90-104 60-40 :
(1) Semiregenerative (2) Cyclic regeneration (3) Continuous Catalyst Regeneration (CCR)
Shutdown
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Semiregenerative ( ) .
6 Semiregenerative .
. . ( psig 300-200)
. . Shutdown
. 10 5 . Cyclic Regeneration
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psig . Semiregenerative . 200
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. psig 50 Continuous Catalyst Regeneration
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REF-SIM 1 Petrosim .
1 -Stand alone program
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) REF-SIM . Petrosim (
:15 REF-SIM REF-SIM CCR A Example . Calibration Input Option1
Petrosim .
. REF-SIM Export Calibration to Petro-Sim
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Add New .
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. Add Operation Reformer
. All Data Export to Petro-SIM . 1 Export Case Number
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. Petrosim REF-SIM
. : Feed .
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Feed C 10 bar 45/3 .
Unstab Reformate bar 7/0 C . 66
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20 10 (bar) 44/3 (bar) 44/3
(C) 49 (C) 177 1
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Condenser Temperature: 43 C
Column Stream Properties Spec.\ 3.5 volume% Benzene in the bottoms product stream
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REF-SIM
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REF-SIM REF-SIM
. 3 . mode .
Calibration Predict Optimization . Test Run Calibration REF-BAL (
Test Run REF-BAL . ( REF-SIM REF-BAL . Calibration
PLANO . RON RVP REF-BAL .
PLANO P N A ( ( . Calibration REF-BAL Test Run
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. Predict Calibration .
Predict . Predict ( )
(Yields) .
(CCR, semi-regenerative, cyclic or pilot plant) Design (CCR )
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1. Calibration Input Data
Calibration input includes process data and specific targets for the calibration run to meet.
1.1 Feed Enter the feed rate, D86, TBP, or D2887 analysis, overall PNA, a full gas chromatographic (GC)
breakdown of the feed by carbon number and type, or a combination of these.
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1.2 Operating Conditions
Reactor temperatures
Reactor pressures
Recycle rates and composition
Reformate flow
Net gas flows and analysis
Separator pressures and temperatures
Compressor pressures
1.2.1 For CCR
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1.2.3 For Semi-Regen or Cyclic
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1.3 Yields and properties
Yields and properties, based on a normalized product and straight cuts, are targets calculated by REF-
BAL and copied into the Calibration Input worksheet. The REF-SIM model tries to match these targets
with Calibration Factors when a Calibration case is run. These targets are calculated by REF-BAL:
1. C5+ yield
2. C5+ RON
3. C5+ RVP
4. Hydrogen (weight percent of feed)
5. Naphthenes (volume percent in C5+)
6. Light ends yields (as weight percent of feed)
7. BTX yields (weight percent of feed) if applicable: benzene, toluene, xylenes, C9 aromatics, C5 paraffins, C6 paraffins,C7 paraffins, C8 paraffins and MCP
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1.4 Ecinomics
Pricing can be added to the Calibration Input sheet if desired. Although these values are not used in
calibration, they are available for consistency and for comparison with cases in the other modes.
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2. Predict Input Data
Process input information includes:
Feed rate
Feed quality (overall PNA and Distillation or Composition (GC analysis))
Reactor conditions
Separator and recontactor conditions
Catalyst information
Pricing In addition to the process information, you select options in the following categories: 1. Closure option: inlet temperature, C5+ RON or C6+ RON 2. Recycle rate 3. Catalyst activity 4. Pressure calculation 2.1 Operating Conditions
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2.2 Reactors
2.2.1 For Semi-Regen or Cyclic
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2.2.2. CCR
2.3 Furnaces
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2.4 Recycle
2.5 Blended Reformate
2.6 Supplemental Pressure Drop
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2.7 Pilot Plant Operation
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3. Results Worksheets
REF-SIM has Results worksheets corresponding to Calibration, Predict and Optimizer Input worksheets.
3.1 Calibration Results worksheet The Calibration Results worksheet lets you average the Calibration Factors and calculate the standard deviation factors. Select the Calibration cases to include by entering non-blank characters in cells on row 1 to the right of the title, Statistics. The averaged Calibration Factors and standard deviations are displayed in columns BN through BP at the right end of the Calibration Factor section. To use the average Calibration Factors in Predict cases, select the Copy function to copy the factors over to the Predict Input worksheet.
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The Result worksheets for the Predict and Optimize Modes are the same as the Calibration Result worksheet except:
The Predict and Optimizer worksheets do not have the Calibration Factor averaging section
The Predict Result worksheet contains indices and text material used by the Optimizer Input and various dialog boxes
The Optimizer worksheet does not contain output for Calibration Factors because they are the same for all Optimization cases
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3.2 Comparison worksheet The Comparison worksheet compares two cases from the Calibration, Predict, and Optimizer Results worksheets. After you select the worksheet and case, the program calculates both absolute and relative differences between the values in each case. These differences are displayed as Delta and % of 1st in columns G and H.
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3.3 Summary Worksheet
The Summary worksheet displays summary data for a specified Calibration, Predict, or Optimizer Results case so you can quickly review and evaluate the data. This worksheet is formatted to be suitable for printing on one page. Select the case to be displayed using the list box and spinner.
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4. Calibration Case Checklist Before running the model in Calibration Mode, check these items:
1. Check REF-BAL results to make sure model balance closure is within 1% and hydrogen closure is within 0.5%, and copy into Calibration. Remember to add additional process information on the Calibration Input worksheet and static unit configuration data on the Design worksheet.
2. Run the model using the RUN button or choose Run, Calibration Case, from the REF-SIM menu. Turn off Auto Tune for the first run. If it runs successfully, turn on Auto-Tune and run after each new target is added.
3. If the model fails, view the Error Log. The cause of the failure is listed at the bottom of the file. The message should provide enough information for you to correct the problem. After correction run the model again.
4. If the model runs successfully, the results are loaded into the Calibration Result worksheet. Check the Error Log to ensure there are no abnormal warnings.
5. Use the Summary worksheet to check input data quality.
5. Predict Case Checklist To run the model in Predict Mode:
1. Select the Predict Input worksheet. 2. If running a Primed Predict, select a successful Calibration case. 3. Select a catalyst activity option for the Predict case.
Option 0 is specific to cyclic units and computes activity from start of run.
Option 1 is for all types of reformers and uses previous calculated activity.
Option 2 is specific to semi-regen units and integrates activity decay.
Options 3 and 4 are specific to CCR units; they compute catalyst activity for the regenerator that is down or starting up, respectively.
Note: If Option 3 or 4 is selected, the regenerator on or off time must be given. Also, if Option 4 is selected, the catalyst decay rate is required.
4. Select the reactor closure option:
Option 0 closes on specified reactor inlet temperatures. Note: If Option 0 is selected, you can also specify fixed reactor inlet temperatures.
Option 1 closes on specified C5+ RON.
Option 2 closes on specified C6+ RON.
Option 3 closes on specified volume percent aromatics in C5+.
Option 4 closes on methylcyclopentane.
5. Enter the new process target values and change options (such as feed rate, feed components, H2/HC ratio, etc.) If a target or option cell is left blank, the value from the previous case is used.
6. Run the Predict Mode using the Run button on the worksheet or the Run option on the REF-SIM menu.If the model fails, look at the Error Log. The cause of the failure is listed at the bottom of the file. The message should provide enough information for you to correct the problem. Correct the problem and run the model again.If the model runs successfully, the results are loaded into the Predict Result worksheet. Check the Error Log to ensure there are no abnormal warnings.
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KBC Reactor Models
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KBC Reactor Models
Fcc-sim for Fluid Catalytic Cracking
Carbon Number-based Feed Characterisation by Detailed Hydrocarbon Type.
Integrates Cracking Reaction Kinetics Up the Riser/Reactor.
Heat Balanced Model with Rigorous Coke Burning Kinetics.
Ref-sim for Reformers
Models CCR, Semi-regen, and Cyclic Units.
Detailed Kinetic Reactions by Carbon Number and Type.
Hcr-sim for Hydrocrackers
Rigorous Kinetic Representation of All Key Reactions: HDS, HDN, Aromatic Saturation, and
Cracking.
Calculates Reactor Bed Temperature Rise with Detailed Heat Balance.
Accurate Predictions of Yields and Hydrogen Consumption.
N Htr-sim, D Htr-sim, Vgo Htr-sim, Rhd s-sim for Hydrotreaters
Rigorous Kinetic Representation of All Key Reactions: HDS, HDN, Aromatic Saturation, and
Cracking.
Calculates Reactor Bed Temperature Rise with Detailed Heat Balance.
Accurate Representations of Desulfurisations to Ultra-low Sulfur (
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REF-SIM CALIBRATION DATA
REQUIREMENTS
REF-SIM CALIBRATAION DATA REQUIREMENTS
The following information is required for successful calibration and delivery of the REF-SIM or REF-SIMOPT model. 1. Unit description
Please provide a brief description of the unit including the following information.
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Description
Unit Licensor:
Year Build:
Design Capacity:
Rated Capacity:
Present catalyst type:
Date of last regeneration:
Frequency of regenerations:
Catalyst loaded density: #/CU.FT. KG/KL
Type of recycle compressor:
Driver type:
Source of feed:
End use of reformate: Gasoline: BTX: Both:
End use of hydrogen:
Type moisture analyzer:
Method of measuring chlorides in recycle gas:
Target Level of chloride on Catalyst:
Measured Chloride on catalyst: When:
Method of taking catalyst sample:
2. Economics
Please provide a set of prices for all feeds, products and utilities.
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:
This data is not mandatory. It is used only for demonstration purposes.
Hydrogen (as pure H2):
$/MSCF ($KNM3)
Fuel Gas:
$/MMBTU (/GCAL)
Propane:
$/BBL ($M3)
Iso-butane:
$/BBL ($M3)
Normal butane:
$/BBL ($M3)
Reformate:
$/BBL ($M3)
RONC of reformate:
Incremental octane value:
$/Octane-BBL (M3)
Compressor operating cost:
$/HP-HR ($KWH)
Semi-regen units only:
$/Regeneration
BTX operations only
Benzene:
$/BBL ($M3)
Toluene:
$/BBL ($M3)
Xylene:
$/BBL ($M3)
Feed Price:
Feed #1
$/BBL ($M3)
Feed #2
$/BBL ($M3)
Feed #3
$/BBL ($M3)
HTR convection section heat:
$/MMBTU ($/GCAL)
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Petrosim
:
3. Feed analysis
Feed 1 Feed 2 Feed 3
Flow Rate:
Flow Units:
Gravity:
Spec: or OPI:
D-86 TBP Other
Distillation Type:
Feed 1 Feed 2 Feed 3
IBP:
10% Point:
30% Point:
50% Point:
70% Point:
90% Point:
End Point:
Has distillation been corrected for pressure:
Yes: No:
PONA VOL%: or WT%:
Feed 1 Feed 2 Feed 3
Paraffins:
Naphthenes:
Aromatics:
For BTX operations VOL%: or WT%:
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Petrosim
:
Feed 1 Feed 2 Feed 3
Paraffins
IC4:
NC4:
C5:
C6:
C7:
C8:
C9:
C10:
C11+:
Naphthenes
MCP:
CH:
N7:
N8:
N9:
N10:
N11+:
Aromatics
Benzene:
Toluene:
Xylene:
A9:
A10:
A11+:
Totals:
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Petrosim
:
4. Reformate analysis
Flow rate:
Flow units:
Percent Isobutane:
Vol%:
Wt%:
Mole%:
Percent N-butane:
Vol%:
Wt%:
Mole%:
RONC:
RVP:
Engineering Units:
Spec Gravity:
API:
Distillation type
TBP:
D-86:
Other:
10% Point:
30% Point:
50% Point:
70% Point:
90% Point:
End Point:
Has distillation been corrected for Pressure?
Yes:
No:
PONA: Vol%:
or Wt%:
Paraffins:
Naphtenes:
Aromatics:
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Petrosim
:
Composition VOL%: or WT%:
Paraffins
Olefins
C3: C4:
iC4: C5:
NC4 C6:
C5 C7:
C6: C8:
C7: C9:
C8: C10:
C9: Total:
C10:
C11+:
Naphthenes
MCP:
CH:
N7:
N8:
N9:
N10:
N11+:
Aromatics
Benzene:
Toluene:
Xylene:
A9:
A10:
A11+:
Totals:
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Petrosim
:
Light Ends Stream Rates and Compositions:
Net hydrogen gas:
Rate:
Flow Units
Stabilizer O/H Liq:
Rate:
Flow Units
Vent Gas (1):
Rate:
Flow Units
Other:
Rate:
Flow Units
Other:
Rate:
Flow Units
Note
The vent gas stream is the second net hydrogen product stream taken off of the low pressure separator when the majority of the net hydrogen is going to a recontactor.
Recycle
Net
Hydrogen
Stab
Gas
Stab
Liquid
Other
Other
Volume percent:
Weight percent:
Mole percent:
Hydrogen
Methane
Ethane
Propane
Isobutane
Normal butane
IC5
NC5
C6+
Totals
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Petrosim
:
5a operating data and time of the test run
Product Separator
Temperature: Pressure: H2 Purity:
Hydrogen Recontactor (if applicable)
Temperature: Pressure: H2 Purity:
Recycle Compressor
Discharge pressure:
Recycle gas: Rate: Flow Units
Moisture in recycle gas:
Chlorides in recycle gas:
Fresh feed plus recycle gas temperature to feed/effluent exchanger
Temperature:
Temperature of feed and hydrogen to first heater
Temperature:
For CCRs provide catalyst circulation rate
Flow rate: Units of flow:
Carbon-on-catalyst:
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Petrosim
:
5b Reactor data at time of test run
Reactor
#1
Reactor
#2
Reactor
#3
Reactor
#4
Reactor
#5
Catalyst Weight:
Time since (1) (2)
last regeneration:
Inlet Temperature:
Delta Temperature:
Inlet Pressure:
Notes
(1) Time is in days for semi-regen units and in hours for regenerative units.
(2) Not needed for CCR units.
6a For CCR units provide one of the following estimates
If the catalyst circulation is changed and the octane and feed rate are held constant:
a. What is the change in the catalyst
circulation?
b. How much of the carbon-on-catalyst
change?
OR
If the feed rate is changed and the catalyst circulation rate and octane are held constant:
a. What is the change in the feed rate?
b. How much of the carbon-on-catalyst
change?
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115
:
Petrosim
OR
If the octane rate is changed and the catalyst circulation rate and feed rate are held constant:
a. What is the change in the feed rate?
b. How much of the carbon-on-catalyst
change?
6b For semi-regen units provide one of the following estimates
Typical octane over a run:
Typical run length:
Typical feed rate over a run:
Typical reactor temperatures one month into run:
Reactor
#1
Reactor
#2
Reactor
#3
Reactor
#4
Reactor
#5
Inlet:
Delta:
Typical reactor temperature at the end of run:
Reactor
#1
Reactor
#2
Reactor
#3
Reactor
#4
Reactor
#5
Inlet:
Delta:
Typical C5+ yield loss over a Wt% Vol%
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Petrosim
:
run:
Typical recycle rate: Rate Flow Units
Typical RON:
What limits run
length:
5c For regenerative units provide the following estimates
Reactor
#1
Reactor
#2
Reactor
#3
Reactor
#4
Cycle length in hours:
Net octane loss over cycle:
Net yield loss over cycle:
Note
To tune the model, it is necessary to know how each reactor affects the system during its cycle.
Theoretically, we want to know how each reactors operation changes over a cycle,
independent of the other reactors. The easiest way to estimate this is by looking at the
difference in operation between the time the reactor is taken off-line for regeneration and then
put back on-line.
6. Octane/temperature response data
Temperature to raise octane one point:
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:
Petrosim
7. Fuel oil equivalents
MmBTU/FOE BBL HHV LHV
OR
Default Lbs/Gal
Hydrogen: 2.016
Methane: 16.043
Ethane: 30.070
8. Utility information
Total heater efficiency: % Actual % Design
Radiant Section
Measured Duty
Design Duty
Heater 1
Heater 2
Heater 3
Heater 4
Heater 5
Recycle
Compressor
Measured
Power:
HP (KW)
Design Power: HP (KW)
Booster Compressor Measured
Power:
HP (KW)
Design Power: HP (KW)
JELDpetrosim