CO2 Capture Simulation in HYSYS Platform

CO2 Capture

From Power Plant Flue Gas - A Simulation case study in Hysis Platform

Subhasish Mitra M.Tech Department of Chemical Engineering IIT Kanpur

Motivation:


Global warming triggers environmental concern over reduction of greenhouse gas emissions from industrial sources.




CO2 is major contributor to the global warming phenomenon due its abundance comparing to other green house gases.




Huge quantity of CO2 in flue gases released from power plants can be separated and utilized for various industrial uses.




Gas absorption process with amine based chemical reaction is recognized as most cost effective solution with proven track records.

Application of CO2:


Carbonated soft drinks & soda water, Leavening agents e.g. Baker’s yeast, Baking powder used in dough.




Used in pneumatic system for portable pressure tools. Good fire extinguisher.




Supercritical CO2 is a good industrial solvent, e.g. extraction of lipophilic organic compounds, extraction of caffeine from coffee etc.




In chemical industry for production of Urea, carbonates & bicarbonates and sodium salicylate.




Liquid CO2 as refrigerant (R774).




Oil recovery & coal bed methane recovery.

Combined power cycle:

Rankine cycle

Brayton cycle

Combined Power Cycle Effciency: ήcc= ή GT + ή ST - (ή GT )(ή ST )

Amine plant – simplified PFD:

Amine package introduction: •Two different amine packages are available in Hysis – Amine Package, DBR Amine Package. •Based on extensive experimental data on equilibrium acid gas (CO2, H2S, COS, CS2) solubility and kinetic parameters for the aq. alkanolamine solutions.

•Important! The package works only under specified set of operating conditions e.g. amine conc., temperature & acid gas partial pressure.

Amine package operating conditions: Alkanolamine

Amine conc.(wt%)

Acid gas partial pr (psia)

Temp (F)

MEA

0 – 30

1e-4 – 300

77 – 260

DEA,TEA, MDEA

0 – 30

1e-4 – 300

77 – 260

DGA

50 – 70

1e-4 – 300

77 – 260

DISoA

0 – 40

1e-4 – 300

77 – 260

Data not correlated for H2S and CO2 loadings > 1.0 mole acid gas/mole amine

Amine package details: Methods of calculation: • Liquid: VLE (vapor liquid equilibrium) : Kent Eisenberg & Li Mather • Vapor: VLE (vapor liquid equilibrium) = Peng Robinson • Enthalpy/Entropy = Curve Fit

Underlying chemistry: Electrochemical reactions occur in the aq solution.

Power plant process simulation diagram: HP Steam turbine

LP Steam turbine

Steam condenser

Steam boiler Gas Turbine Block Flue gas to CO2 absorption unit

CO2 capture plant process simulation diagram: Amine regen tower

Amine absorption tower

Simulation figures: Power plant capacity

Available data:

Natural gas flow

400

MW

12480

m3/hr

Fuel air ratio

2.22

Compressor duty

154.6

MW

120

bar

110.6

MW

4

bar

LP steam turbine capacity

29.96

MW

Condensate pump capacity

2.832

MW

Heat input in boiler

445.2

MW

Rankine cycle efficiency

0.309

High Pr steam HP steam turbine capacity Low Pr steam

Compressor in

Compressor out

cp/cv

1.401

1.352

kavg

1.3765

pr increase ratio (rp)

30

Brayton cycle efficiency

0.606

efficiency (combined power cycle)

0.728

1-(1/rp )^(k-1)/k

Simulation figures (Contd): Total flue gas flow rate

48810

kmol/hr

Flue gas cooler duty

89.57

MW

Flue gas blower duty

29.37

MW

Blower after cooler duty

45.87

MW

Feed rate to amine absorption column

44010

kmol/hr

CO2 molar flow into absorption column

2358.6

kmol/hr

CO2 molar flow from absorption column

67.12

kmol/hr

% removal of CO2

97.15

Absorption column operating pr

200

kpa

Total lean MEA flow into absorption column

79220

kmol/hr

Fresh make up lean MEA

292.8

kmol/hr

0.04233

MW

Regenerator pre-heater duty

80.00

MW

Regenerator column reboiler duty

110.5

MW

lean amine cooler duty

81.42

MW

lean amine pump duty

0.06197

MW

Total energy invested in the absorption unit

139.97

MW

Energy required per mole of CO2 scrubbed

5.00

MJ/kg

Rich amine pump duty

Absorption parameters:

% reduction of C O2

Pressure effect on % reduction of CO2

• CO2 absorption is enhanced as higher pressure however the advantage saturates at 300 kpa (not shown)

97.400 97.200 97.000 96.800 96.600 96.400 96.200 96.000 100.000

120.000

140.000

160.000

180.000

200.000

220.000

kmol/hr

Pressure (kpa)

Pressure effect on % reduction of CO2 % re duc tion of C O2

- Circulation rate fixed at 79220

• CO2 absorption is enhanced with amine circulation rate however the advantage diminishes at higher flow rate

99.000 98.500 98.000 97.500

-pressure kept constant at 200 kpa

97.000 100

20100

40100

60100

80100

Amine circulation rate (kmol/hr)

100100

120100

Tower tray sizing details: Absorption tower tray internals

Valve

Regenerator tower tray internals

Valve

Section Diameter [m]

9.60

Section Diameter [m]

5.33

Max Flooding [%]

81.21

Max Flooding [%]

67.63

X-Sectional Area [m2]

72.40

X-Sectional Area [m2]

22.35

Section Height [m]

6.10

Section Height [m]

4.57

Section DeltaP [kPa]

11.53

Section DeltaP [kPa]

5.92

Number of Flow Paths

5.00

Number of Flow Paths

5.00

Flow Length [mm]

1739.90

Flow Length [mm]

901.70

Flow Width [mm]

7881.10

Flow Width [mm]

4465.13

Max DC Backup [%]

38.31

Max DC Backup [%]

43.06

Max Weir Load [m3/h-m]

47.17

Max Weir Load [m3/h-m]

89.52

Max DP/Tray [kPa]

1.32

Max DP/Tray [kPa]

1.30

Tray Spacing [mm]

609.60

Tray Spacing [mm]

762.00

Total Weir Length [mm]

39150.16

Total Weir Length [mm]

22219.25

Weir Height [mm]

50.80

Weir Height [mm]

100.00

Active Area [m2]

68.56

Active Area [m2]

20.13

DC Clearance [mm]

38.10

DC Clearance [mm]

90.00

DC Area [m2]

1.92

DC Area [m2]

1.11

Side Weir Length [m]

3.43

Side Weir Length [m]

2.38

Hole Area [m2]

10.49

Hole Area [m2]

3.08

Estimated # of Holes/Valves

8858.66

Estimated # of Holes/Valves

2601.43

Simulation - Probable problems & solutions: Probable problems

Possible solutions

Convergence with recycle loop

Increase recycle gradually with the help of a TEE

Total feed rate to absorption column changes as recycle increases

Keep a ratio set point of total amine feed into tower with feed flue gas

CO2 loading in amine crosses package limit (all streams’ color turn yellow)

Decrease amine conc. in fresh make up

Regenerator pressure profile

Change column bottom pressure to match column bottom temperature

Presence of vapor at rich amine pump inlet Stripper column convergence Very large %equilibrium approach for acid gas

Increase amine circulation rate Use spec for top temperature and recycle ratio Still Searching!

Wind up:


Combined power plant cycle gives more efficiency than the individual constituent cycle.




Setting up a CO2 capture plant sounds beneficial from both environment as well as economic point of view (pending techno-economic analysis)




Qualitatively the benefit is more tangible if energy consumed/mole of CO2 absorbed is further reduced (5MJ/kg as per present simulation) – thrust on selecting various amines to reduce circulation rate.




Regenerator tower energy requirement can be met by the HP ST exhaust obtained from power plant (discarding option of producing power from LP ST) which needs to be substantiated by the techno-economic analysis.

Thanks for your attention!