石墨密封材料高温摩擦磨损行为及预测  被引量：32

作　　者：闫玉涛[1] 李雪娟[2] 胡广阳[3] 胡添琪 孙志礼[1] 

机构地区：[1]东北大学机械工程与自动化学院,沈阳110819 [2]中国航空工业集团公司沈阳黎明航空发动机集团有限责任公司,沈阳110043 [3]中国航空工业集团公司沈阳发动机设计研究所,沈阳110015

出　　处：《航空动力学报》2014年第2期314-320,共7页Journal of Aerospace Power

基　　金：航空科学基金(20100450001)

摘　　要：利用HT-1000型高温摩擦磨损试验机研究了石墨M210密封材料高温下摩擦磨损性能,采用扫描电子显微镜(SEM)观察分析了磨损表面形貌.基于试验数据,通过灰色理论GM(1,1)建立了摩擦因数和磨损率预测模型.结果表明:石墨M210密封材料摩擦因数呈先增大再减小,而后趋于一稳定值,试验温度为450℃时,摩擦因数最小;磨损率随着试验温度升高而增大.试验温度在低于300℃,磨损表面具有明显的黏着、撕裂和无序的塑流动痕迹,高于400℃时,塑流动痕迹具有明显的方向性,出现了剥落和断裂痕迹.温度较低时,石墨材料表面主要是水汽物理吸附膜起润滑作用,随着试验温度升高,由物理吸附膜润滑逐渐转向反应膜润滑.基于试验数据建立了精度等级均为1级的摩擦因数和磨损率的预测模型.The tribological properties of graphite M210 seal material under high temper- ature were investigated on a HT 1000 high temperature friction/wear tester. The worn sur- face of graphite pin was observed by scanning electronic microscope （SEM）. The predication model on friction coefficient and wear rate was established by grey theory GM （1,1） based on the test data. The results show that the friction coefficient of graphite M210 seal material gradually augmented, then gradually diminished, and reached a steady value with the test time. The value of friction coefficient was minimal when the temperature was 450 ℃. The wear rate increased with the temperature rise. The worn surface was characterized by obvi- ous adhesion, laceration and unordered plastic flow under temperature 300℃. The plastic flow trace had obvious directivity, and the desquamation and the rift were found on the worn surface when the temperature was above 400 ℃. The lubrication action was mostly depend-ent of the physically absorbed film by water vapor at lower temperature. With the tempera ture rise, the lubrication action turned to reaction film, and the lubrication of physical ad- sorbed film disappeared. The predication model for friction coefficient and wear rate was es- tablished based on test data by the gray theory, and the precision grade of the model was the first grade by the grade verification.

关 键 词：石墨M210 高温 摩擦因数 磨损率 预测模型 

分 类 号：V233.5[航空宇航科学与技术—航空宇航推进理论与工程] TH117.1[机械工程—机械设计及理论]