Comprehensive numerical simulation of an indirect internal reforming tubular SOFC

A comprehensive numerical simulation of a cell-based indirect internal reforming tubular Solid Oxide Fuel Cell has been conducted. Two-dimensional axisymmetric thermo-fluid fields and non-axisymmetric electric potential/current fields in the tubular cell were simultaneously solved. As a result, comp...

पूर्ण विवरण

ग्रंथसूची विवरण
मुख्य लेखकों: Nishino, T, Iwai, H, Suzuki, K
स्वरूप: Journal article
भाषा:Japanese
प्रकाशित: 2005
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author Nishino, T
Iwai, H
Suzuki, K
author_facet Nishino, T
Iwai, H
Suzuki, K
author_sort Nishino, T
collection OXFORD
description A comprehensive numerical simulation of a cell-based indirect internal reforming tubular Solid Oxide Fuel Cell has been conducted. Two-dimensional axisymmetric thermo-fluid fields and non-axisymmetric electric potential/current fields in the tubular cell were simultaneously solved. As a result, complex interactions between the thermo-fluid and electrical fields were clearly demonstrated. It was also revelated how the thermal field and power generation characteristics of the cell are affected by catalyst density distribution for the reforming in the cell. A linear distribution of the catalyst greatly reduced the maximum temperature and temperature gradients of the cell with little negative impact on the power generation performance of the cell.
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spelling oxford-uuid:dcabb89d-a29e-4811-a998-6e93ebc5bbbc2022-03-27T09:19:17ZComprehensive numerical simulation of an indirect internal reforming tubular SOFCJournal articlehttp://purl.org/coar/resource_type/c_dcae04bcuuid:dcabb89d-a29e-4811-a998-6e93ebc5bbbcJapaneseSymplectic Elements at Oxford2005Nishino, TIwai, HSuzuki, KA comprehensive numerical simulation of a cell-based indirect internal reforming tubular Solid Oxide Fuel Cell has been conducted. Two-dimensional axisymmetric thermo-fluid fields and non-axisymmetric electric potential/current fields in the tubular cell were simultaneously solved. As a result, complex interactions between the thermo-fluid and electrical fields were clearly demonstrated. It was also revelated how the thermal field and power generation characteristics of the cell are affected by catalyst density distribution for the reforming in the cell. A linear distribution of the catalyst greatly reduced the maximum temperature and temperature gradients of the cell with little negative impact on the power generation performance of the cell.
spellingShingle Nishino, T
Iwai, H
Suzuki, K
Comprehensive numerical simulation of an indirect internal reforming tubular SOFC
title Comprehensive numerical simulation of an indirect internal reforming tubular SOFC
title_full Comprehensive numerical simulation of an indirect internal reforming tubular SOFC
title_fullStr Comprehensive numerical simulation of an indirect internal reforming tubular SOFC
title_full_unstemmed Comprehensive numerical simulation of an indirect internal reforming tubular SOFC
title_short Comprehensive numerical simulation of an indirect internal reforming tubular SOFC
title_sort comprehensive numerical simulation of an indirect internal reforming tubular sofc
work_keys_str_mv AT nishinot comprehensivenumericalsimulationofanindirectinternalreformingtubularsofc
AT iwaih comprehensivenumericalsimulationofanindirectinternalreformingtubularsofc
AT suzukik comprehensivenumericalsimulationofanindirectinternalreformingtubularsofc