Performance Assessment of Coal Fired Power Plant Integrated with Calcium Looping CO2 Capture Process

ABSTRACT

CaL technology is a promising means for post-combustion CO₂ capture in already existing power plants, and heat integration is an effective way to lower the efficiency penalty caused by CO₂ capture. Three cases with different heat integration degree were investigated in the manuscript to predict the efficiency penalty and the specific energy consumption for CO₂ capture, aiming to find the optimum scheme of integrating capture unit into coal-fired power plant. The sensitivity analysis was also conducted to compare the impacts of key parameters. The simulation results show that the Case 3, which employs a variety of measures to improve the internal heat integration within CaL and reclaims the surplus released heat via an additional steam cycle, has the lowest efficiency penalty, 5.75%. It also indicates that heat integration in Case 3 results in a 14.4% of decrease in coal consumption, a 5.8% of reduction in power consumed by CO₂ compression process, a 13.6% of drop in power consumption in ASU, and a 31.5% of decrease in specific energy consumption for CO₂ capture. The sensitivity analysis shows that the efficiency penalty may be reduced by 0.011 percentage points for each degree decrease in temperature difference of MH-1. As the compression efficiency increases from 70% to 85%, the efficiency penalty decreases from 6.51% to 5.47%, and the specific energy consumption reduces from 2.21 MJ/kg CO₂ to 1.80 MJ/kg CO₂.

Abbreviations: APH: Air Preheater; ASUL: Air Separation Unit; BFPT: Boiler Feedwater Pump Turbine; CaL: Calcium Looping; CCS: Carbon Capture and Sequestration; CFPP: Coal-Fired Power Plant; GSS: Gas-Solid Separator; HPC: High Pressure Column; HPEC: High Pressure Economizer; HPSH: High Pressure Super-Heater; HPST: High Pressure Steam Turbine; HRSG: Heat Recovery Steam Generator; IPEC: Intermediate Pressure Economizer; IPEV: Intermediate Pressure Evaporator; IPSH: Intermediate Pressure Super-Heater; LPST: Low Pressure Steam Turbine; LHV: Low Heat Value; LPC: Low Pressure Column; LPEC: Low Pressure Economizer; LPEV: Low Pressure Evaporator; ORC: Organic Rankine Cycle; RH: Reheater.

KEYWORDS:

• Calcium looping
• CO₂ capture
• air separation
• heat integration
• efficiency penalty

Nomenclature

ECCO2	=	Specific energy consumption coefficient (MJ/kg CO2)
ER	=	CO2 emission rate (kg CO2/kW∙h)
F0	=	Molar flow rate of fresh sorbent (kmol/s)
$F_{\mathrm{C}{\mathrm{O}}_2}$	=	Molar flow rate of CO2 stream (kmol/s)
$F_{\mathrm{S}{\mathrm{O}}_2}$	=	Molar flow rate of SO2 stream (kmol/s)
FR	=	Molar flow rate of recycled sorbent excluding fresh makeup (kmol/s)
p	=	Pressure (bar)
PASU	=	Power consumption in ASU (MW)
Paddit	=	Net electric power of additional steam cycle (MW)
Pbase	=	Net electric power of baseline plant (MW)
Pcomp	=	Power consumption in CO2 compression (MW)
Pnet	=	Net electric power of overall system (MW)
Qboiler	=	Heat consumption of boiler in baseline plant (MW)
Qcal	=	Heat consumption in calciner (MW)
Qhr	=	Heat recovered in additional steam cycle (MW)
RCa:C	=	Molar ratio of CaO to CO2
T	=	Temperature (C)
ηaddit	=	Net thermal efficiency of additional steam cycle
ηbase	=	Net thermal efficiency of baseline plant
ηcapt	=	CO2 capture efficiency
ηhr	=	Heat recovery efficiency
ηoverall	=	Overall thermal efficiency with CCS
ηGSS-1	=	Separation efficiency of GSS-1 (%)
ηGSS-2	=	Separation efficiency of GSS-2 (%)
Xave	=	Average carbonation conversion
x	=	Dryness

Acknowledgments

This work was supported by the National Key Research and Development Program of China (2018YFB0604302-02); the Fundamental Research Funds for the Central Universities (No. 2015MS116); and the National Natural Science Foundation (No.51606066).

Additional information

Funding

This work was supported by the National Key Research and Development Program of China [2018YFB0604302-02]; National Natural Science Foundation of China [51606066]; Fundamental Research Funds for the Central Universities [2015MS116].