期刊文献+

基于ANSYS的温差发电器耦合设计分析 被引量:1

Coupling design analysis of thermoelectric generator based on ANSYS
原文传递
导出
摘要 作为新能源技术,温差发电具有体积小、环保清洁、无运动部件等方面的优点。更重要的是,它可以实现热能与电能的直接转化,从而增强能源的利用率。以塞贝克效应为基本原理的温差发电器遵循了热电耦合能量守恒定律。通过运用软件ANSYS的热电耦合计算分析功能,建立温差发电仿真模型,对其进行了计算分析,得出相应的温差发电器的温度场分布与电场分布。由于ANSYS仿真计算出的数据与实验测得的结果在合理误差范围里,因而两者数据基本吻合,这说明了温差发电器设计合理,能够优化资源利用率,从而在军事、航空、器械制造等领域具有良好前景。 As a new energy technology,thermoelectric power generation has the advantages of small size,environmentally friendly cleaning,and no moving parts.More importantly,it can achieve direct conversion of heat and electricity to enhance energy efficiency.The thermoelectric generator based on the Seebeck effect follows the law of conservation of thermoelectric coupling energy.Through the thermoelectric coupling analysis function of ANSYS finite element software,the simulation model of temperature difference power generation is established,and the temperature field distribution map and electric field distribution map of the corresponding thermoelectric generator are obtained.Since the data calculated by ANSYS and the experimental results are in a reasonable error range,the data are basically consistent.This shows that the temperature difference generator is reasonable in design and can optimize resource utilization,thus in military,aviation,equipment manufacturing,etc.The field has good prospects.
作者 陈威 李筠 杨海马 张亚平 杨萍 袁宝龙 Chen Wei;Li Jun;Yang Haima;Zhang Yaping;Yang Ping;Yuan Baolong(School of Optoelectronic Information and Computer Engineering,University of Shanghai for Science and Technology,Shanghai 200093,China;Shanghai Aerospace Equipment Manufacturing Plant,Shanghai 200245,China;Shanghai Huaike Intelligent Technology Co.,Ltd.,Shanghai 200000,China)
出处 《电子测量技术》 2018年第24期12-16,共5页 Electronic Measurement Technology
基金 上海航天创新基金(SAST2017-062) 宝山区科技创新专项基金(17-C-21) 上海市自然科学基金(17ZR1443500)项目资助
关键词 温差发电器 热电耦合 ANSYS 温度场 thermoelectric generator thermoelectric coupling ANSYS temperature field
  • 相关文献

参考文献6

二级参考文献31

  • 1贾磊,陈则韶,胡芃,孙炜.半导体温差发电器件的热力学分析[J].中国科学技术大学学报,2004,34(6):684-687. 被引量:25
  • 2SUNJi-quan,SUNJing-hong,WUBin,LIANJia-chuang.Mathematical Model for Temperature Field of Strip Coil in Cooling and Heating Process[J].Journal of Iron and Steel Research International,2005,12(2):33-36. 被引量:5
  • 3Bejan A. Advanced engineering thermodynamics[M]. New York: Wiley & Sons, 1997.
  • 4深圳市广通源实业有限公司.制冷片介绍[EB/OL].(2007-02-10).http://www.gty168.com/glory2.html.
  • 5王富耻,张朝晖.ANSYSIO.0有限元:分析理论与工程应用[M].北京:电子工业出版社,2006.
  • 6尚仁操,乔渭阳,许开富.气冷涡轮叶片气热耦合数值模拟研究[J].机械设计与制造,2007(12):11-13. 被引量:14
  • 7Kim S, Park S, Kim S, Rhi S H. A Thermoelectric GeneratorUsing Engine Coolant for Light-Duty Internal Combustion Engine-Powered Vehicles [J]. Journal of Electronic Materials, 2011, 40(5): 812-816.
  • 8Tatarinov D, Wallig D, Bastian G. Optimized characterization of thermoelectric generators for automotive application[J]. Journal of Electronic Materials, 2012, 41(6): 1706-1712.
  • 9Crane D T, Ira Grandeur J W, Harris F, Bell L E. Performance Results of a High-Power-Density Thermoelectric Generator: Beyond the Couple[J]. Journal of electronic materials, 2009, 38 (7) : 1375-1381.
  • 10Ziolkowski P, Poinas P, Leszczynski, et al. Estimation of Thermoelectric Generator Performance by Finite Element Modeling[J]. Journal of Electronic Materials, 2010, 39 (9) : 1934-1943.

共引文献16

同被引文献8

引证文献1

二级引证文献1

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部