Energy-exergy analysis of an integrated small-scale LT-PEMFC based on steam methane reforming process

•A novel integrated system for power generation with on-site produced hydrogen and heat recovery.•ASPEN Plus and MATLAB/Simulink jointed simulation model is used to establish an accurate model for the whole integrated system.•With S/C of 3.0, SMR reaction temperature of 700 °C, and the PEMFC hydroge...

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Bibliographic Details
Published inEnergy conversion and management Vol. 246; p. 114685
Main Authors Wang, Zaixing, Mao, Junkui, He, Zhenzong, Liang, Fengli
Format Journal Article
LanguageEnglish
Published Oxford Elsevier Ltd 15.10.2021
Elsevier Science Ltd
Subjects
Destruction
Energy
Exergy
Fuel technology
Heat
Heat exchange
Heat recovery
Heat recovery systems
Hydrogen
Hydrogen production
Low temperature
LT-PEMFC
Methane
Modules
Nuclear fuels
On-site hydrogen production
Operating temperature
Palladium
Parametric analysis
Proton exchange membrane fuel cells
Reactors
Reforming
Simulation
Steam
Steam methane reforming
Thermodynamic performance analysis
Thermodynamics
On-site hydrogen production
Thermodynamic performance analysis
LT-PEMFC
Steam methane reforming
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Summary:•A novel integrated system for power generation with on-site produced hydrogen and heat recovery.•ASPEN Plus and MATLAB/Simulink jointed simulation model is used to establish an accurate model for the whole integrated system.•With S/C of 3.0, SMR reaction temperature of 700 °C, and the PEMFC hydrogen utilization of 0.8, the electrical power is achieved at 520 W.•The PEMFC stack is the primary source of system exergy destruction. This study reports a novel integrated system for power generation with on-site produced hydrogen and heat recovery. The main equipment of the integrated system includes a steam methane reforming (SMR) reactor for hydrogen production, a palladium membrane (Pd-M) unit for hydrogen purification, a waste heat collector (HC) unit for heat recovery, and a low-temperature proton exchange membrane fuel cell (LT-PEMFC) for power generation. ASPEN Plus and MATLAB/Simulink jointed simulation model is used to establish an accurate model for the whole integrated system. Moreover, for the SMR reactor, it is found that the RPlug reactor simulation module is more appropriate compared with the RGibb module. Then a detailed parametric analysis is carried out to estimate the effects of hydrogen utilization, the SMR reactor operating temperature, and the current density of the PEMFC stack on the overall energy and exergy efficiency of the integrated system. Finally, thermodynamic analysis is performed on the integrated system with S/C of 3.0, SMR reaction temperature of 700 °C, PEMFC hydrogen utilization rate of 0.8, and power generation of 520 W, delivering energy and exergy efficiencies as high as 47.4% and 45.7% under these operating parameters. The thermodynamic analysis shows that the PEMFC stack is the primary source of the system exergy destruction (326.27 W) with 34.33% of the relative exergy destruction ratio.
ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2021.114685