摘要
针对高强韧性难加工材料因磨削高温导致加工效率低、工件表面易出现热损伤的问题,提出了利用热管技术提高砂轮自身传热能力以增强对磨削弧区的换热效果,进而实现降低磨削温度的新方法.在此基础上,基于热管砂轮的结构与传热原理,设计并建立了一套用于测试热管砂轮传热性能的试验装置和方法,分析了砂轮速度、工质属性、热端热流输入强度、冷端散热条件和液膜厚度各因素对热管砂轮传热能力以及传热启动特性的影响规律.试验结果表明,热管砂轮能够显著增强对磨削弧区的换热效果,此外,该装置和方法可准确评估各因素对热管砂轮传热性能的影响,且适于预测热管砂轮的传热能力.
According to the problems of low machining efficiency and thermal damage caused by high grind- ing temperature for difficult-to-cut materials with high strength and toughness, a new method of improving heat transfer capacity of grinding wheel by virtue of heat pipe technology was proposed to enhance heat ex- change at the contact zone and avoid high grinding temperature. On the basis of the structure of heat pipe grinding wheel and its heat transfer principle, experimental device and test method were designed and set up to investigate the heat transfer performance of heat pipe grinding wheel. Moreover, the effects of wheel speed, working fluid property, heat flux input at the evaporator, cooling condition at the condenser and liquid film thickness on heat transfer capacity and starting characteristic of heat pipe grinding wheel were analyzed. The results show that heat pipe grinding wheel can significantly increase heat exchange at the contact zone. Besides, the test method for heat pipe grinding wheel can accurately evaluate the effects of various factors on its heat transfer performance and is suitable for prediction of its heat transfer capacity.
出处
《上海交通大学学报》
EI
CAS
CSCD
北大核心
2017年第11期1355-1360,共6页
Journal of Shanghai Jiaotong University
基金
国家自然科学基金(51775170)
国家青年科学基金(51605144)
NSFC-河南联合基金重点支持项目(U1604254)资助
关键词
热管砂轮
高效磨削
磨削温度
heat pipe grinding wheel
high efficiency grinding
grinding temperature