Dave Stropky, VP Research
Process Simulations Ltd.206-2386 East Mall, Vancouver, BC, Canada
www.psl.bc.ca
Industrial Process Modeling
Contents
Introduction to PSL
3D Process Modeling
Process Modeling Information
Industrial Applications
Process Simulations Ltd.1986 UBC modeling group (pulp and paper)1993 PSL Incorporated, Recovery Boiler Model1995 Bark boilers, Hydrocyclones1998 Headboxes, Lime kilns, Wood Kilns1999 Digesters2000 Gasifiers, Clarifiers2001 Cement Kilns, Coal Fired Boilers2002 Precipitators, BFB Boilers2003 Lagoons2004 Calciners2006 Multiphase fluidized beds
PSL INTRODUCTIONIndustrial Projects Since 1997
89 Recovery Boilers 25 Bark/Biomass/Power Boilers 13 Lime Kilns 3 Headboxes 4 Precipitators 5 Cement Kilns 4 Gasifiers 1 Precalciner 2 Wastewater Lagoons 10 Others
PSL INTRODUCTIONPSL Advantages
Independent Analysis
Advanced & Validated Computer Models. UBC connection.
Equipment equipment-specific submodels to predict the behavior of complex processes
Combustion and Flow Analysis Expertise
Advanced, Intuitive, Interactive 3-D display and analysis technologies
Broad Industrial Application Experience
3D ProcessModeling
Principle of Conservation
MassMomentum
Energy…….
IN = OUT
ININ
OUTOUT
OUTOUT
PROCESS MODELING 3D CFD
PROCESS MODELING
Buildings Jet enginesWeather
Harrier jet
Industrial Equipment
3D CFD Modeling Examples
IndustrialApplications
Recovery BoilersINDUSTRIAL APPLICATONS
• Air System Design• Liquor Injection• Carryover/Plugging• Wall Corrosion• Tube Cracking• Steam Production• Boiler load• Burner Design• NCG Injection• Emissions
Bark BoilersINDUSTRIAL APPLICATONS
• Air System Design• Fuel Injection• Carryover• Wall Corrosion• Steam Production• Boiler load• Grate Design• NCG Injection• Emissions
PreCalcinersINDUSTRIAL APPLICATONS
• Meal Injection• NOx Reduction• Gas Flow Distributions• Fuel combustion• Emissions• Temperature Profiles• Operational Optimization
DigestersINDUSTRIAL APPLICATONS
• Chip injection• Flow uniformity• Chip uniformity• Wash/screen
effects
KappaNumber
LigninMass Fraction
CarbohydratesMass Fraction
Chip Compaction
Wastewater LagoonsINDUSTRIAL APPLICATONS
• Flow patterns• Residence Time
Distributions• Biological Models
PrecipitatorsINDUSTRIAL APPLICATONS
• Flow Distribution• Efficiency• Baffle Design• Inlet/outlet ducting• Screen Design• Egg Crates
CyclonesINDUSTRIAL APPLICATONS
• Flow Distribution• Particle Distribution• Efficiency• Inlet ducting
KilnsINDUSTRIAL APPLICATONS
• Flame Profile• Calcination• Brick Failure/
Heat Load• Alternate Fuels• Air/Fuel Ratios• Burner Design• NCG Injection• Emissions
Distance from Kiln Hood [m]
Tem
pera
ture
ofG
asan
dLi
me
[K]
Volu
me
Frac
tion
ofO
2,C
O2,
H2O
inFl
usG
as[v
ol%
]
Em
issi
onof
NO
inFl
ueG
as[p
pmv]
Mas
sFr
actio
nof
Lim
eC
ompo
nent
s[w
t%]
0 20 40 60 80 100
500
1000
1500
2000
0
5
10
15
20
25
30
35
40
010
020
030
040
050
0
0
10
20
30
40
50
60
70
80
90
100
Feed
End
Fire
End
Tgas
CaCO3
CaO
Tck
NO
CO2
O2
H2O
Predicted Axial Profile Data
KilnsINDUSTRIAL APPLICATONS
Multi-layer refractory heat transfer model Heat transfer and lime calcination
CaCO3 = CaO + CO2
Heat absorbed 1.679 MJ/kg CaCO3 @1089K
Kilns: Input DataINDUSTRIAL APPLICATONS
10' 6" Dia.
Barrel Tilt = 1.7899 = 3/8" per 12"o
Burner
4' 2 3/4"
24" 24"
9"
5' 6"
2' 9"
17 3/4"
kiln c L
Z
X
Barrel Start(non rotated)
GEOMETRY
Primary AirSwirl Angle: 45o
Direction same as kiln rotation
Primary AirSwirl Angle = 0o
Oil Channel8 holes at 1/8" Dia.
Swirl Angle = 0o
Oil Channel12 holes at 3/16" Dia.
Swirl Angle = 0o
R1 R3R2
R4
r2
r1
TOP VIEW
SIDE VIEW
BED_ANGLE 31 deg
BARREL_ANGLE 1.79 deg
BURNER_ANGLE_BETA 0.16 deg
BURNER_ANGLE_ALPHA 1.5 deg
SPIN_AIR_ANGLE 45 deg
R1 0.1138 m
R2 0.1626 m
R3 0.1869 m
R4 0.2154 m
Kilns: Input DataINDUSTRIAL APPLICATONS
BURNER GEOMETRY
Kilns: Input DataINDUSTRIAL APPLICATONS
9"70% Alumina
9"Magnel RSV
9"70% Alumina
2-1/2"Greenlite HS
6"Clipper DP
3-1/2"Mix Refratherm
Greenlite
3"Greenlite HS
6"Castable
6"Castable
0' 0m
2'0.
6096
m
9.5'
2.89
56m
19.5
'5.
9436
m
39.5
'12
.039
8
84.5
'25
.755
6m
134.
5'40
.995
6m
216'
65.8
368m
221'
67.3
608m
226.
5'69
.037
2m
Burner
3'0.9144m
6"0.1524m
18"0.4572m
39"0.9906m
102"
2.59
08m
10'
3.04
8m
6' 7
"2.
0066
m
97"
2.46
38m
102"
2.59
08m
108"
2.74
32m
54'16.4592m
ChainSystem
101"
2.56
54m
012
23
34
4
4
0
aTaTaTaTaTaj
jj
thermal conductivity, W/mkT temperature, K
Material4a 3a 2a 1a 0a
Greenlite -2.554e-7 7.878e-4 5.248e-2Refratherm 150 -3.571e-7 8.021e-4 0.1576Magnel RSV 2.394e-12 -1.332e-8 2.771e-5 -0.02586 12.54Kruzite - 70 5.908e-7 -0.0013 2.301Clipper DP -3.571e-7 8.021e-4 0.1576
REFRACTORY
Selected Data Window
Kilns: Operational DataINDUSTRIAL APPLICATONS
DCS Data Analysis
Kilns: Operational DataINDUSTRIAL APPLICATONS
Fuel/Feed/Air Data Analysis
Production rate 274.42 tpd 3.1761 kg/sTotal feed rate 663.12 tpd 7.6750 kg/sSolids content 80% 80%CaCO3 462.23 tpd 5.3498 kg/sDust 57.29 tpd 0.6631 kg/sInerts 10.98 tpd 0.1270 kg/sMoisture 132.62 tpd 1.54 kg/s
663.12 tpd 7.6750 kg/s
Oil flow rate 0.4440 kg/sOil composition 100.00% Carbon 78.30% 0.3477 kg/s Hydrogen 9.88% 0.0439 kg/s Oxygen 11.57% 0.0514 kg/s Nitrogen 0.00% 0.0000 kg/s Sulphur 0.14% 0.0006 kg/s Ash 0.11% 0.0005 kg/s High heat value 44.7040 MJ/kg Density 935.0 kg/m3Oil temperature 230 oF 383 KStoichiometric air ratio for oil combustion 12.0178 kgAir/kgOilStoichiometric air for oil combustion 5.3359 kg/sAtomizing steam flow rate lb/hr 0.08 kg/sMixture flow rate 0.5240Mass fraction of oil in mixture 0.8473Total heat input 19.8 MW
LIME
FUEL
Excess air ratio 8.51%Stochiometric air flow rate*(1+excess air ratio) 5.7900 kg/s
PRIMARY AIRPrimary air flow rate 1.2800 kg/sPrimary air temperature 298.15 KPrimary air density 1.1835 kg/m^3Primary Axial Air 25.0% 0.3200 kg/sPrimary Spin Air 75.0% 0.9600 kg/s
SECONDARY AIRSecondary air temperature 298.15 KSecondary air density 1.1835 kg/m^3Left side flow area 0.2027 m*mRight side flow area 0.2027 m*mLeft side open area ratio 5.00%Right side open area ratio 5.00%Left side flow velocity 13.0334 m/sRight side flow velocity 13.0334 m/sLeft side flow rate 0.1563 kg/sRight side flow rate 0.1563 kg/s
BURNER/HOOD GAP AIRBurner/Hood gap air temperature 298.15 KBurner/Hood gap air density 1.1835 kg/m^3Burner/Hood gap area 0.0488 m*mBurner/Hood gap open area ratio 80.00%Burner/Hood gap velocity 13.0334 m/sBurner/Hood flow rate 0.6018 kg/s
DISCHARGE GRATE AIRDischarge grate air temperature 450 KDischarge grate air density 0.7841 kg/m^3Discharge grate area 0.5226 m*mDischarge grate open area ratio 54.80%Discharge grate velocity 16.0120 m/sDischarge grate flow rate 3.5956 kg/sTotal air flow rate 5.7901 kg/sTotal air flow rate - stochiometric air flow rate 0.0001 kg/s
Air
Kilns: Balance SheetsINDUSTRIAL APPLICATONS
Energy/Mass Balance
Heat Loss (shell) 3.3000 MWFuel Mass Flow Rate 0.5693 kg/sFuel high heating value 57.76 MJ/kgChemical enthalpy from Fuel 32.88 MW Product temperature (into cooler) 991.5 KFuel composition by wt% Product CaCO3 flowrate 0.157 kg/sN2 0.0439% Product CaO flowrate 4.681 kg/sCO2 0.0395% Product Inerts flowrate 0.564 kg/sCH4 99.9166% Physical enthalpy from product 4.22 MWFuel temperature 310.9 K Energy absorbed by calcination 14.90 MWPhysical enthalpy from fuel 0.047 MW Physical enthalpy of H2O released from mud 0.2626 MWTotal enthalpy from fuel 32.93 MW Evaporation heat of H2O released from mud 5.4454 MW
Physical enthalpy of CO2 released from mud 3.5689 MWLime Mud In Total enthalpy from product 28.39 MW
CaCO3 flow to kiln 8.516 kg/s net heat absorbed 27.78 MWCaO flow to kiln 0.000 kg/sFeed moisture flow to kiln 2.414 kg/s Enthapy of H2O vapour into gas phase 6.457692 MWInerts flow to kiln 0.564 kg/s Enthapy of CO2 into gas phase 3.631979 MWMaterial temperature to kiln 322.0 K Total 10.08967 MWPhysical enthalpy from feed 0.61 MWRecycle dust in 0.000 kg/s Total Energy In 45.59 MWRecycle dust temperature 322.0 K Product Energy Out + Heat Loss 31.69 MWPhysical enthalpy from recycle in 0.00 MW Energy taken away by flue gas 13.90 MWTotal enthalpy feed 0.61 MW
Flue Gas Temperature 475.2 K 395.7 FAir Flue gas CO2 mass flowrate 5.242 kg/s
Air composition by wt% Flue gas N2 mass flowrate 10.080 kg/sO2 23.00% Flue gas H2O mass flowrate 3.694 kg/sN2 77.00% Flue gas O2 mass flowrate 0.736 kg/sH2O 0.00% Physical enthalpy from flue gas 13.84 MWPrimary air flowrate 1.956 kg/s Dust Loss 0.000 kg/sPrimary air temperature 338.7 K Dust Loss in flue gas Enthalpy 0.00 MWPrimary air physical enthalpy 0.13 MW Total Enthalpy from flue gas and dust 13.84 MWCooler air flowrate 11.135 kg/sCooler outlet air temperature 434.5 K Flue gas energy balance check -0.06 MWCooler air physical enthalpy 1.83 MWTotal enthalpy air 1.96 MW CO2 from calcination 3.6780 kg/s
Lime Mud Out
FuelDust Loss 0.0% of dry solids MT to ton 1.1023113
Residual Carbonate 2.90% of total product TPD to kg/s 0.0104998
mud feed solids 79.0%wet feed flowrate 1094.7 TPD 11.494 kg/s 91,224 Lb/hr
CaCO3 in dry feed 93.78%CaO in dry feed 0.00%
Inerts in dry feed 6.216% of dry solids
100.00%
dry solids 864.8 TPD 9.080 kg/s 72,067 Lb/hrdust recycle 0.0 TPD 0.000 kg/s
moisture to kiln 229.9 TPD 2.414 kg/s
1094.7 TPD 11.494 kg/s 91,224 Lb/hr
CaCO3 input to kiln 811.0 TPD 8.516 kg/s
CaO input to kiln 0.0 TPD 0.000 kg/s
Inerts input to kiln 53.8 TPD 0.564 kg/s
Estimated material temperature into kiln 120 F 322.0 K
Uncalcined CaCO3 0.1567 kg/sCaO 4.6811 kg/s 404.5 MT/day 445.8 T/day
CaCO3 input to kiln - uncalcined CaCO3 8.3592 kg/s
CaO from above line (check) 4.6811 kg/sResidual Carbonate % check 2.900% 0.000% error
Inerts in product 10.45%
Total Product 5.402 kg/s 466.8 MT/day 514.50 T/dayMaximum Product Availability 86.65%
Maximum Availability with Measured Residual Carbonate
Contour/Vector Planes3D MODEL INFORMATION
Surface Plots3D MODEL INFORMATION
Integrated Information3D MODEL INFORMATION
Distance from Kiln Hood [m]
Tem
pera
ture
ofG
asan
dLi
me
[K]
Vol
ume
Frac
tion
ofO
2,C
O2,
H2O
inFl
usG
as[v
ol%
]
Em
issi
onof
NO
inFl
ueG
as[p
pmv]
Mas
sFr
actio
nof
Lim
eC
ompo
nent
s[w
t%]
0 20 40 60 80 100
500
1000
1500
2000
0
5
10
15
20
25
30
35
40
010
020
030
040
050
0
0
10
20
30
40
50
60
70
80
90
100
Feed
End
Fire
End
Tgas
CaCO3
CaO
Tck
NO
CO2
O2
H2O
Predicted Axial Profile Data
Process Modeling Advantages3D MODEL INFORMATION
Advanced, intuitive, interactive visual representation of industrial processes based on basic laws of physics
Software can be used to rapidly analyze and rectify process problems, or to create virtual equipment for operator training
Provides engineers and operators with significantly more information for analyzing equipment operations than is currently available
Reduced risk on retrofits and large capital expenditures Allows for more informed recommendations for operational
and design changes Better equipment performance and reliability Increased knowledge for operators, engineers, and
managers leads to optimized equipment design and operation and ultimately to reduced operational and maintenance costs