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基于析因试验的固体氧化物燃料电池热电联供系统设计参数研究 被引量:2

Research on Design Parameters of Solid Oxide Fuel Cell Combined Heat and Power System Based on Factorial Experiment
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摘要 对固体氧化物燃料电池热电联供(solid oxide fuel cell combined heat and power,SOFC–CHP)系统的设计参数进行了研究,该系统由重整器、燃料电池电堆、燃烧室、2个热交换器及其它辅助设备组成。建立了系统的数学模型,以发电规模为70kWe的系统为研究对象,运用析因试验的设计方法进行了计算机模拟试验,对系统的部分设计参数进行了析因分析。分析结果表明:影响系统发电功率的主要设计参数是燃料利用率和过量空气比率;影响系统热回收和电热比的主要设计变量是燃料利用率和水蒸汽与碳的比率,且这2个参数的交互作用较过量空气比率对系统影响显著;阴极排气再循环比率对系统热、电功率的影响甚微,不是系统的主要设计参数。整个研究工作为SOFC–CHP系统的合理设计提供了指导。 The authors research the design parameters of solid oxide fuel cell combined heat and power (SOFC-CHP) system constituted by a pre-reformer, a SOFC stack, an afterburner, two heat exchangers and other assistant facilities, and build the mathematical model of this system. Taking a SOFC-CHP system with generation scale of 70 kWe as research subject and using the design method of factorial experiment, the computer simulation experiment is carried out and the factorial analysis on part of parameters of SOFC-CHP system is conducted. Analysis results show that the fuel utilization and excess air ratio are main design parameters impacting the power generation of this system; the main design variables impacting heat recovery of the system and electricity to heat ratio are fuel utilization and the steam to carbon ratio, and the influence of interaction between the two parameters on SOFC-CHP system is more evident than that of excess air ratio; the influence of cathode exhaust gas recirculation ratio on heat and electric power of the system is slight, so it is not regarded as the main design parameter of the system. The presented research is available for reference to rational design of SOFC-CHP system.
作者 赵玺灵 张兴梅 段常贵 邹平华
机构地区 哈尔滨工业大学市政环境工程学院
出处 《电网技术》 EI CSCD 北大核心 2007年第18期78-82,共5页 Power System Technology
关键词 析因试验 固体氧化物燃料电池 热电联供系统 交互作用 factorial experiment solid oxide fuel cell (SOFC) combined heat and power (CHP) system interaction
分类号 TM911 [电气工程—电力电子与电力传动]
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参考文献13

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共引文献72

同被引文献32

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二级引证文献7

电网技术
2007年 第18期

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