基于ANSYS的温差发电器性能

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摘要温差发电器用作高压电气设备的电源,能够有效解决检测装置的信号和电源隔离问题,并使设备余热得到利用。为了提高温差发电器的性能,本论文研究了影响温差发电器性能的各种因素,并在ANSYS上建立了由单PN结组成的热电单偶的三维模型。分别在稳态和瞬态条件下,研究了几种不同的绝缘填充物和散热片翅片高度对热电单偶的冷热两端温差和输出电压的影响。结果表明,随着冷端散热片翅片高度的增高,稳态时冷热两端温差和输出电压增大到逐渐趋于稳定;随着PN结的缝隙之间所添加的绝缘填充物的热导率的增大,稳态时冷热两端的温差和输出电压减小到逐渐趋于稳定。通过实验结果对比分析,仿真结果得到了进一步验证。

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	喻红涛
	张志丰
	邱清泉
	张国民

关键词 ：热电耦合, 稳态特性, 瞬态特性, 散热片, 绝缘填充物

Abstract：The high voltage isolation of signal and power supply between electrical equipment and detector is solved effectively by using thermoelectric generator as power supply, which also use the waste heat of devices. In order to improve the performance of thermoelectric generator, the factors that would affect the performance of thermoelectric generator are researched, and the 3D model of a thermoelectric generator composed of signal PN junctions is built with ANSYS. Both on steady and transient state, the temperature difference between hot and cold side, and output voltage are simulated under different thermal conductivity of the insulation padding between p-n junctions and different fin heights of the cooling fin on the cold side. As a result of simulation, with the increase of the fin height of cooling fin, the temperature difference and output voltage will rise until reaching a limit, and with the amplify of thermal conductivity of insulation padding, they will minish to a steady state. Through contrastive analysis with the experimental result, the simulation result is proved.

Key words： Thermoelectric coupling steady-state feature transient-state feature cooling fin insulation padding

收稿日期: 2013-05-08 出版日期: 2014-08-05

PACS:

TM913

基金资助:国家自然科学基金（51177161,51277172）和中国电机工程学会电力青年科技创新资助项目

作者简介: 喻红涛男,1987年生,硕士,研究方向为能源材料与电力电子控制技术研究。张志丰男,1967年生,副研究员,硕士生导师,研究方向为超导电力技术、控制理论与工程、电力系统分析等。

引用本文:

喻红涛, 张志丰, 邱清泉, 张国民. 基于ANSYS的温差发电器性能[J]. 电工技术学报, 2014, 29(7): 253-260. Yu Hongtao, Zhang Zhifeng, Qiu Qingquan, Zhang Guomin. Performance of Thermoelectric Generator with ANSYS. Transactions of China Electrotechnical Society, 2014, 29(7): 253-260.

链接本文:

http://dgjsxb.ces-transaction.com/CN/Y2014/V29/I7/253

[1] 赵建云, 朱冬生, 周泽广, 等. 温差发电技术的研究进展及现状[J]. 电源技术, 2010, 34(3): 310-313. Zhao Jianyun, Zhu Dongsheng, Zhou Zeguang, et al. Research progress of thermoelectric power generation [J]. Power Technology, 2010, 34(3): 310-313.
[2] 李应林, 黄虎. 温差热发电技术及其应用[J]. 南京师范大学学报(工程技术版), 2011, 11(3): 23-30. Li Yinglin, Huang Hu. Thermal power generation technology and its application[J]. Journal of Nanjing Normal University(Engineering and Technology Edition), 2011, 11(3): 23-30.
[3] Chen Lingen, Meng Fankai, Sun Fengrui. Effect of heat transfer on the performance of thermoelectric generator-driven thermoelectric refrigerator system[J]. Cryogenics, 2012, 52(1): 58-65.
[4] 张晓丹, 杜群贵, 蒋新强, 等. Bi2Te3基温差发电组件的热应力和结构参数选择[J]. 电源技术, 2011, 35(4): 422-425. Zhang Xiaodan, Du Qungui, Jiang Xinqiang, et al. Thermal stress and structural parameter selection of Bi2Te3- based thermoelectic modules[J]. Power Technology, 2011, 35(4): 422-425.
[5] 张韬, 周孑民, 黄学章, 等. 半导体温差发电器匹配负载的热电耦合分析[J]. 电源技术, 2010, 34(10): 1084-1100. Zhang Tao, Zhou Jiemin, Huang Xuezhang, et al. Thermal electric coupling analysis of matched load of semiconductor thermoelectric generator[J]. Power Technology, 2010, 34(10): 1084-1100.
[6] 梁高卫, 周孑民, 黄学章, 等. 串联连接半导体温差发电器的解析模型[J]. 江苏大学学报（自然科学版）, 2011, 32(3): 314-319. Liang Gaowei, Zhou Jiemin, Huang Xuezhang, et al. Analytical model of series semiconductor thermoelectric generators[J]. Journal of Jiangsu University(Natural Science Edition), 2011, 32(3): 314-319.
[7] Dirk Ebling, Martin Jaegle, Markus Bartel, et al. Multiphysics simulation of thermoelectric systems for comparison with experimental device performance[J]. Journal of Electronic Materials, 2009, 38(7): 1456-1461.
[8] Li Peng, Cai Lanlan, Zhai Pengcheng, et al. Design of a concentration solar thermoelectric generator[J]. Journal of Electronic Materials, 2010, 39(9): 1522-1530.
[9] Amatye R, Ram R. Solar thermoelectric generator for micropower applications[J]. Journal of Electronic Materials, 2010, 39(9): 1735-1740.
[10] Crane T. An Introduction to system-level, steady-state and transient modeling and optimization of high- power-density thermoelectric generator devices made of segmented thermoelectric elements[J]. Journal of Electronic Materials, 2011, 40(5): 561-569.
[11] Wang Ziyang, Leonov Vladimir, Fiorini Paolo, et al. Realization of a wearable miniaturized thermoelectric generator for human body applications[J]. Sensors and Actuators A: Physical, 2009, 156(1): 95-102.
[12] Niu Xing, Yu Jianlin, Wang Shuzhong. Experimental study on low-temperature waste heat thermoelectric generator[J]. Journal of Power Sources, 2009, 188(2): 621-626.
[13] Molina M, Juanico L, Rinalde G. Design of improved controller for thermoelectric generator used in distributed generation[J]. Intermational Journal of Hydrogen Energy, 2010, 35(11): 5968-5973.
[14] 杨素文, 肖恒, 欧强, 等. 废热式温差发电器性能仿真[J]. 计算机仿真, 2012, 29(11): 341-344. Yang Suwen, Xiao Heng, Ou Qiang, et al. Simulation on performance of thermoelectric generator applied in waste heat recovery[J]. Computer Simulation, 2012, 29(11): 341-344.
[15] Xiao Heng, Gou Xiaolong, Yang Chen. Simulation analysis on thermoelectric generator system performance [C]. Asia Simulation Conference-7th International Conference on System Simulation and Scientific Computing, 2008: 1183-1187.