摘要
建立了滑动摩擦系统热弹性失稳的数学模型,并推导了不同热点模式对应的临界速度表达式。分析了摩擦副的厚度和滑动层材料的热物理特性参数对摩擦系统热弹性失稳的影响。结果表明:滑动摩擦系统更易出现反对称分布的热点模式;增加摩擦层厚度,减小滑动层厚度、热传导系数、弹性模量以及热膨胀系数均可以提高标志滑动摩擦系统进入热弹性失稳状态所需的最低临界速度,而滑动层比热容对系统的稳定性几乎没有影响。
First,a mathematical model related to the thermoelastic instability was established,and the critical speeds of two different types of distribution of hot spots were derived.Then the effects of the thickness of the brake pair and thermal-physical properties of the sliding layer on the stability of the sliding frictional systems were analyzed and compared.Results show that,the sliding frictional system is more vulnerable to have dissymmetrical mode of hot spots.The minimum critical speed,which denotes the threshold of thermoelastic instability of the sliding frictional system,can be enhanced by increasing the thickness of the frictional layer and decreasing thickness,thermal conductivity,thermal expansion coefficient and elastic modulus of the sliding layer.However,the specific heat of the sliding layer almost has no influence on the stability of the sliding frictional system.
出处
《吉林大学学报(工学版)》
EI
CAS
CSCD
北大核心
2016年第4期1163-1174,共12页
Journal of Jilin University:Engineering and Technology Edition
基金
国家留学基金项目(201406260074)
国家自然科学基金项目(61004077)
关键词
机械设计
扰动增长系数
热弹性失稳
最低临界速度
扰动频率
热点
mechanical design
growth rate of perturbation
thermoelastic instability
minimum critical speed
wave number
hot spot