Multi-physics model for regenerative PEM fuel cell energy storage

Alotto, Piergiorgio

doi:10.1109/icit.2013.6505765

Cited by 3 publications

(1 citation statement)

References 24 publications

(32 reference statements)

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“…On the other hand, very few articles have been published on physical models of UR-PEMFC dedicated to hydrogenechlorine (H 2 eCl 2 ) chemistry [24] and hydrogen-bromine (H 2 eB 2 ) chemistry [25,26]. The literature on modeling of H 2 eO 2 UR-PEMFC is extremely limited and very few papers presenting unified multiphysics models have been published to date [27,28]. This paper presents a zerodimensional model aimed at analyzing the performance of a UR-PEMFC in terms of power and round-trip efficiency under different physical conditions (temperature, pressure, flow, hydration).…”

Section: Pem Unitized Regenerative Fuel Cellsmentioning

confidence: 99%

Modeling the performance of hydrogen–oxygen unitized regenerative proton exchange membrane fuel cells for energy storage

Guarnieri

Alotto

Moro

2015

Journal of Power Sources

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Section: Pem Unitized Regenerative Fuel Cellsmentioning

confidence: 99%

Modeling the performance of hydrogen–oxygen unitized regenerative proton exchange membrane fuel cells for energy storage

Guarnieri

Alotto

Moro

2015

Journal of Power Sources

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Stochastic Methods for Parameter Estimation of Multiphysics Models of Fuel Cells

Alotto

2014

IEEE Trans. Magn.

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Numerical Study of the Dynamic Response of Heat and Mass Transfer to Operation Mode Switching of a Unitized Regenerative Fuel Cell

Hong

Guo

et al. 2016

Energies

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Abstract:Knowledge concerning the complicated changes of mass and heat transfer is desired to improve the performance and durability of unitized regenerative fuel cells (URFCs). In this study, a transient, non-isothermal, single-phase, and multi-physics mathematical model for a URFC based on the proton exchange membrane is generated to investigate transient responses in the process of operation mode switching from fuel cell (FC) to electrolysis cell (EC). Various heat generation mechanisms, including Joule heat, reaction heat, and the heat attributed to activation polarizations, have been considered in the transient model coupled with electrochemical reaction and mass transfer in porous electrodes. The polarization curves of the steady-state models are validated by experimental data in the literatures. Numerical results reveal that current density, gas mass fractions, and temperature suddenly change with the sudden change of operating voltage in the mode switching process. The response time of temperature is longer than that of current density and gas mass fractions. In both FC and EC modes, the cell temperature and gradient of gas mass fraction in the oxygen side are larger than that in the hydrogen side. The temperature difference of the entire cell is less than 1.5 K. The highest temperature appears at oxygen-side catalyst layer under the FC mode and at membrane under a more stable EC mode. The cell is exothermic all the time. These dynamic responses and phenomena have important implications for heat analysis and provide proven guidelines for the improvement of URFCs mode switching.

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Multi-physics model for regenerative PEM fuel cell energy storage

Cited by 3 publications

References 24 publications

Modeling the performance of hydrogen–oxygen unitized regenerative proton exchange membrane fuel cells for energy storage

Modeling the performance of hydrogen–oxygen unitized regenerative proton exchange membrane fuel cells for energy storage

Stochastic Methods for Parameter Estimation of Multiphysics Models of Fuel Cells

Numerical Study of the Dynamic Response of Heat and Mass Transfer to Operation Mode Switching of a Unitized Regenerative Fuel Cell

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