Performance evaluation of solid oxide fuel cell for exergy recuperation of exhaust heat by electrochemical partial oxidation

Transactions of the Japan Society of Mechanical Engineers. B Pub Date : 2013-10-14 DOI:10.1299/KIKAIB.79.1583

Takayuki Ozeki, T. Nakagaki

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Abstract

©2013 The Japan Society of Mechanical Engineers Electrochemical partial oxidation (EPOx) of methane can convert exhaust heat into electricity as much as difference between change of Gibbs free energy and change of enthalpy. To quantify recuperated heat and converted electric power of EPOx, we simulated the performance of EPOx in the microtubular Solid Oxide Fuel Cell (SOFC) using Gadolinium Doped Ceria as electrolyte. The quasi-two dimensional and non-isothermal model applied to this SOFC simulation, which consisted of three solid layers and two gas layers, considering with mass, energy and chemical species conservation equations as well as detailed electrochemical reaction. The simulation computed temperature and current density distributions, and evaluated energy flow in SOFC. The simulation code was validated by consistency between the simulation result of power generation using H2 as fuel and the result of previous experimental report. The results showed that EPOx could convert 40% of theoretically recuperated heat into the electric power at the operation condition maximizing total regenerated heat.

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电化学部分氧化法废热火用回收固体氧化物燃料电池性能评价

©2013日本机械工程师学会(Japan Society of Mechanical Engineers)甲烷的电化学部分氧化(EPOx)可以将废热转化为电能，其量相当于吉布斯自由能变化量与焓变量之差。为了量化环氧树脂的回热和转换电能，我们以掺钆铈为电解质，模拟了环氧树脂在微管固体氧化物燃料电池(SOFC)中的性能。该SOFC模拟采用准二维非等温模型，考虑了质量、能量和化学物质守恒方程以及详细的电化学反应，包括三层固体和两层气体。模拟计算了SOFC的温度和电流密度分布，并评估了SOFC的能量流。以氢气为燃料发电的模拟结果与前人实验报告的结果一致，验证了仿真代码的有效性。结果表明，在总回热最大化的工况下，环氧树脂能将40%的理论回热转化为电能。

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Transactions of the Japan Society of Mechanical Engineers. B

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