A Hybrid Experimental Model of a Solid Oxide Fuel Cell Stack

Xiao-Juan Wu; Wan-Qi Hu; Xin-Jian Zhu; Guang-Yi Cao; Heng-Yong Tu

Source: Journal of Fuel Cell Science and Technology:;2009:;volume( 006 ):;issue: 001::page 11013

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DOI: 10.1115/1.2971125

Publisher: The American Society of Mechanical Engineers (ASME)

Abstract: A multivariable hybrid experimental model of a solid oxide fuel cell stack is developed in this paper. The model consists of an improved radial basis function (RBF) neural network model and a pressure-incremental model. The improved RBF model is built to predict the stack voltage with different temperatures and current density. Likewise, the pressure-incremental model is constructed to predict the stack voltage under various hydrogen, oxygen, and water partial pressures. We combine the two models together and make a powerful hybrid multivariable model that can predict the voltage under any current density, temperature, hydrogen, oxygen, and water partial pressure. The validity and accuracy of modeling are tested by simulations, and the simulation results show that it is feasible to build the hybrid multivariable experimental model.

keyword(s): Pressure , Temperature , Electric potential , Current density , Hydrogen , Oxygen , Water , Solid oxide fuel cells , Engineering simulation AND Artificial neural networks ,

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A Hybrid Experimental Model of a Solid Oxide Fuel Cell Stack

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contributor author	Xiao-Juan Wu
contributor author	Wan-Qi Hu
contributor author	Xin-Jian Zhu
contributor author	Guang-Yi Cao
contributor author	Heng-Yong Tu
date accessioned	2017-05-09T00:33:30Z
date available	2017-05-09T00:33:30Z
date copyright	February, 2009
date issued	2009
identifier issn	2381-6872
identifier other	JFCSAU-28936#011013_1.pdf
identifier uri	http://yetl.yabesh.ir/yetl/handle/yetl/140895
description abstract	A multivariable hybrid experimental model of a solid oxide fuel cell stack is developed in this paper. The model consists of an improved radial basis function (RBF) neural network model and a pressure-incremental model. The improved RBF model is built to predict the stack voltage with different temperatures and current density. Likewise, the pressure-incremental model is constructed to predict the stack voltage under various hydrogen, oxygen, and water partial pressures. We combine the two models together and make a powerful hybrid multivariable model that can predict the voltage under any current density, temperature, hydrogen, oxygen, and water partial pressure. The validity and accuracy of modeling are tested by simulations, and the simulation results show that it is feasible to build the hybrid multivariable experimental model.
publisher	The American Society of Mechanical Engineers (ASME)
title	A Hybrid Experimental Model of a Solid Oxide Fuel Cell Stack
type	Journal Paper
journal volume	6
journal issue	1
journal title	Journal of Fuel Cell Science and Technology
identifier doi	10.1115/1.2971125
journal fristpage	11013
identifier eissn	2381-6910
keywords	Pressure
keywords	Temperature
keywords	Electric potential
keywords	Current density
keywords	Hydrogen
keywords	Oxygen
keywords	Water
keywords	Solid oxide fuel cells
keywords	Engineering simulation AND Artificial neural networks
tree	Journal of Fuel Cell Science and Technology:;2009:;volume( 006 ):;issue: 001
contenttype	Fulltext

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