湿式离合器摩擦片接合过程温度场分析
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摘要
建立某型矿用机车摩擦离合器的动力学模型,采用欧拉方法求解主从动摩擦片接合过程的角速度及热流密度。建立湿式离合器接合过程摩擦片径向热传导方程,采用微分求积法离散热传导方程及边界条件,并利用龙格-库塔法计算矿用机车名义和满载载荷情况下摩擦片的温升值随时间和半径的变化。计算结果表明,离合器接合过程摩擦片的径向温升值随着时间和半径的增大而增大,且载荷越大,接合时间越长,温升值越高。该结论为摩擦离合器的设计与性能分析提供了一定的理论基础。
The dynamics model of friction clutch of a mine locomotive is established, and the angularspeed and heat flux of the master-slave friction disc in engagement process are solved by Euler method. The ra-dial heat conduction equation of engagement process of friction disc in wet clutch is established, and the differ-ential quadrature method is used to discretize the heat conduction equation and boundary conditions. The Run-ge-Kutta method is used to calculate the temperature rise of friction disc changing with time and radius undernominal and full-load conditions of mining locomotive. The results show that the radial varying temperature ofthe friction disc increases with the increase of time and radius during the engagement process. The greater theload, the longer engagement time and higher corresponding temperature. This conclusion provides a theoreticalbasis for the design and performance analysis of friction clutch.
The dynamics model of friction clutch of a mine locomotive is established, and the angularspeed and heat flux of the master-slave friction disc in engagement process are solved by Euler method. The ra-dial heat conduction equation of engagement process of friction disc in wet clutch is established, and the differ-ential quadrature method is used to discretize the heat conduction equation and boundary conditions. The Run-ge-Kutta method is used to calculate the temperature rise of friction disc changing with time and radius undernominal and full-load conditions of mining locomotive. The results show that the radial varying temperature ofthe friction disc increases with the increase of time and radius during the engagement process. The greater theload, the longer engagement time and higher corresponding temperature. This conclusion provides a theoreticalbasis for the design and performance analysis of friction clutch.
引文
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[5]李东兵.混合动力车辆湿式多片离合器径向矩形油槽宽度对温度场影响[J].机械传动,2015,39(12):49-52.
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[7]于亮,马彪,李和言,等.卡簧约束对多片离合器温度场的影响分析[J].兵工学报,2018,39(4):636-644.
[8]WU J M,Shao M Y,WANG Yan,et al.Stability analysis of moving printing web with wine half-wave variable density based on differential quadrature method[J].Journal of Vibration and Acoustics,2017,139(6):061018.
[9]张世军,林腾蛟,吕和生.湿式摩擦离合器摩擦片油槽对瞬态传热的影响[J].机械设计,2009,26(11):34-37.
[10]董宇,杨翊仁,鲁丽.基于微分求积法的轴向流作用下叠层板的稳定性和模态分析[J].振动工程学报,2015,28(2):197-202.
[2]邹婷婷,张志刚,陈瑶,等.湿式离合器典型工况参数对摩擦钢片温度场的影响[J].重庆理工大学学报(自然科学),2018,32(1):50-57.
[3]杨亚联,张喀,秦大同,等.湿式多片离合器热机耦合温度场及应力场分析[J].中国机械工程,2014,25(20):2740-2744.
[4]朱茂桃,浦宇斌,刘涛,等.车用干式双离合器温升对比研究[J].机械传动,2017,41(12):77-82.
[5]李东兵.混合动力车辆湿式多片离合器径向矩形油槽宽度对温度场影响[J].机械传动,2015,39(12):49-52.
[6]曲艳阳,黄继雄,莫易敏,等.基于有限元法的微车离合器温度场的研究[J].机械研究与应用,2008,21(5):75-77.
[7]于亮,马彪,李和言,等.卡簧约束对多片离合器温度场的影响分析[J].兵工学报,2018,39(4):636-644.
[8]WU J M,Shao M Y,WANG Yan,et al.Stability analysis of moving printing web with wine half-wave variable density based on differential quadrature method[J].Journal of Vibration and Acoustics,2017,139(6):061018.
[9]张世军,林腾蛟,吕和生.湿式摩擦离合器摩擦片油槽对瞬态传热的影响[J].机械设计,2009,26(11):34-37.
[10]董宇,杨翊仁,鲁丽.基于微分求积法的轴向流作用下叠层板的稳定性和模态分析[J].振动工程学报,2015,28(2):197-202.
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