Optimization on temperature efficiency and switch time of thin-walled regenerator with perturbation analysis

Optimization on temperature efficiency and switch time of thin-walled regenerator with perturbation analysis

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摘要 The heat transfer characteristic of honeycomb ceramic regenerator was optimized by the perturbation analytical-numerical method. The results show that there is a temperature efficiency peak and the corresponding optimal switch time. The decrease of air oxygen concentration leads to the decrease of maximum temperature efficiency. Optimal switch time is directly proportional to the matrix thickness. The solid heat conduction along the flow direction and the regenerator heat storage capacity of the unit volume have no impact on maximum temperature efficiency and optimal switch time. The temperature efficiency tendency based on the semi-analysis is the same as dispersion combustion tests with low oxygen concentration, and optimal switch time of 2-4 s agrees well with that of 4 s in high-temperature gasification tests. The possibility of design, operate and control a thin-walled regenerator with high efficiency by means of the perturbation method is proved. The heat transfer characteristic of honeycomb ceramic regenerator was optimized by the perturbation analytical-numerical method. The results show that there is a temperature efficiency peak and the corresponding optimal switch time. The decrease of air oxygen concentration leads to the decrease of maximum temperature efficiency. Optimal switch time is directly proportional to the matrix thickness. The solid heat conduction along the flow direction and the regenerator heat storage capacity of the unit volume have no impact on maximum temperature efficiency and optimal switch time. The temperature efficiency tendency based on the semi-analysis is the same as dispersion combustion tests with low oxygen concentration, and optimal switch time of 2 - 4 s agrees well with that of 4 s in high-temperature gasification tests. The possibility of design, operate and control a thin-walled regenerator with high efficiency by means of the perturbation method is proved.

作者艾元方梅炽蒋绍坚黄国栋陈红荣

机构地区 School of Energy Science and Engineering

出处《Journal of Central South University of Technology》 EI 2006年第5期506-510,共5页 中南工业大学学报（英文版）

基金 Project(2001AA514013) supported by the National High Technology Research and Development Programof China

关键词 thin-walled regenerator PERTURBATION temperature efficiency switch time 薄壁蓄热器扰动温度效率开关时间优化

分类号 TK172 [动力工程及工程热物理—热能工程]

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参考文献11

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Journal of Central South University of Technology

2006年第5期

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Optimization on temperature efficiency and switch time of thin-walled regenerator with perturbation analysis

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