摘要
为了给超磁致伸缩执行器(GMA)提供恒温的工作环境以保证输出精度,针对传统间接冷却温控系统热效率较低的问题,基于直接液体冷却原理,提出了一种可应用于弯曲型微位移执行器的新型高热效率GMA温控方法,及提出了新型的卡盘式温控腔体结构。仿真结果表明,多层油道的直接冷却温控方法将磁致伸缩材料(GMM)的温升范围由传统间接冷却温控方式的±0.4℃~±0.5℃提升到±0.02℃之内,新的温控方法和热结构为GMM材料进一步的开发和应用研究提供了设计方向和依据。
In order to provide a stable working temperature for giant magnetostrictive actuator( GMA), thereby ensuring its high-precise-out- put, aiming at improving the thermal efficiency of traditional temperature controlling method, a novel high thermal efficiency temperature con- trolling method as well as a new chuck-style thermal structure, were proposed for flexure type GMA on the basis of direct liquid cooling prin- ciple. Simulation results show that the novel direct liquid cooling method with multi-layer oil tunnels could provide a temperature disturbance range of ±0.02 ℃ for giant magnetostrictive material (GMM) compared with previous results of ±0.4 %-±0.5 % by the traditional method, and the novel temperature controlling method and thermal structure will shed light on further application research and development utilizing GMM.
出处
《机电工程》
CAS
2011年第7期779-783,826,共6页
Journal of Mechanical & Electrical Engineering
基金
国家自然科学基金资助项目(50975256)
国家教育部博士点基金资助项目(20070335204)
浙江省自然科学基金重点资助项目(Z1080537)
关键词
超磁致伸缩材料
超磁致伸缩执行器
温度控制
卡盘式
giant magnetostrictive material(GMM)
giant magnetostrictive actuator(GMA)
temperature control
chuck style
