A novel distributed energy system using high-temperature proton exchange membrane fuel cell integrated with hybrid-energy heat pump

•A novel PEMFC distributed energy system with hybrid-energy heat pump is proposed.•It enables dynamic supply–demand match flexibly and lifts cooling/heating capacity.•Power density/efficiency higher by 18.5/7.9% for cooling and 54.8/20.3% for heating.•Optimization raises power density to 4.341 and 5...

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Bibliographic Details
Published in:Energy conversion and management 2021-05, Vol.235, p.113990, Article 113990
Main Authors: Wu, Wei, Zhai, Chong, Sui, Yunren, Zhang, Houcheng
Format: Article
Language:English
Subjects:
Absorption
Absorption-compression cycle
Compression
Configurations
Cooling
Distributed energy
Distributed generation
Energy
Equivalence
Fuel cells
Fuel technology
Heat
Heat exchangers
Heat pumps
Heat recovery
Heating load
High temperature
Hybrid systems
Hybrid-energy heat pump
Optimization
Proton exchange membrane fuel cell
Proton exchange membrane fuel cells
Protons
Waste heat
Working conditions
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Summary:•A novel PEMFC distributed energy system with hybrid-energy heat pump is proposed.•It enables dynamic supply–demand match flexibly and lifts cooling/heating capacity.•Power density/efficiency higher by 18.5/7.9% for cooling and 54.8/20.3% for heating.•Optimization raises power density to 4.341 and 5.357 kW/m2 for cooling and heating.•A high absorption fraction enhances electrical power but reduces thermal capacity. Distributed energy systems based on proton exchange membrane fuel cell (PEMFC) pave a promising technological pathway to achieve carbon neutrality. The waste heat from PEMFC can be well recovered for cooling/heating, but additional systems are required if the available waste heat is not enough to meet the building cooling/heating demands. To achieve a dynamic supply–demand match efficiently and flexibly, this study proposes a novel PEMFC distributed energy system integrated with a hybrid-energy heat pump (HEHP). It can flexibly switch between a single absorption heat pump under sufficient waste heat and a hybrid absorption-compression heat pump under deficient waste heat. The integrated PEMFC-HEHP system is characterized and optimized using a validated model under different working conditions and hybrid configurations. The equivalent power density and fuel cell efficiency can be improved by 18.5% and 7.9% with supply temperatures of −10–10 °C for cooling, and be improved by 54.8% and 20.3% with supply temperatures of 40–60 °C for heating. Optimization yields a maximum equivalent power density of 4.341 kW/m2 in cooling mode and 5.357 kW/m2 in heating mode, compared to 3.290 kW/m2 of the individual PEMFC system. A higher absorption fraction enhances the PEMFC equivalent power while a higher compression fraction improves the HEHP cooling/heating capacity, the hybrid configuration needs to be determined by comprehensively considering the required cooling/heating loads and the available waste heat. The results can facilitate the better development of PEMFC distributed energy systems.
ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2021.113990