Control-Oriented Modeling of the Cooling Process of a PEMFC-Based [Formula Omitted]-CHP System

Micro-combined heat and power systems (μ-CHP) based on proton exchange membrane fuel cell stacks (PEMFC) are capable of supplying electricity and heat for the residential housing sector with a high energy efficiency and a low level of CO2 emissions. For this reason, they are regarded as a promising...

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Bibliographic Details
Published inIEEE access Vol. 7; p. 95620
Main Authors Santiago Navarro Gimenez, Herrero Dura, Juan Manuel, Francesc Xavier Blasco Ferragud, Raul Simarro Fernandez
Format Journal Article
LanguageEnglish
Published Piscataway The Institute of Electrical and Electronics Engineers, Inc. (IEEE) 01.01.2019
Subjects
Cogeneration
Cooling
Cooling systems
Dynamic models
Electric power systems
First principles
Heat exchange
Low level
Model testing
Optimization
Optimization techniques
Predictive control
Proton exchange membrane fuel cells
Temperature control
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Summary:Micro-combined heat and power systems (μ-CHP) based on proton exchange membrane fuel cell stacks (PEMFC) are capable of supplying electricity and heat for the residential housing sector with a high energy efficiency and a low level of CO2 emissions. For this reason, they are regarded as a promising technology for coping with the current environmental challenges. In these systems, the temperature control of the stack is crucial, since it has a direct impact on its durability and electrical efficiency. In order to design a good temperature control, however, a dynamic model of the μ-CHP cooling system is required. In this paper, we present a model of the cooling system of a PEMFC-based μ-CHP system, which is oriented to the design of the temperature control of the stack. The model has been developed from a μ-CHP system located in the laboratory of our research team, the predictive control and heuristic optimization group (CPOH). It is based on first principles, dynamic, non-linear, and has been validated against the experimental data. The model is implemented in Matlab/Simulink and the adjustment of its parameters was carried out using evolutionary optimization techniques. The methodology followed to obtain it is also described in detail. Both the model and the test data used for its adjustment and validation are accessible to anyone who wants to consult them. The results show that the model is able to faithfully represent the dynamics of the μ-CHP cooling system, so it is appropriate for the design of the stack temperature control.
ISSN:2169-3536
DOI:10.1109/ACCESS.2019.2928632