特高压输电线路磁场对电力金具材料摩擦磨损的影响OA北大核心CSTPCD
Influence of Magnetic Field on Friction and Wear of Metal Tools in UHV Transmission Lines
目的 通过分析特高压直流线路工频磁场环境对电力金具材料磨损行为的影响,探究其磨损机理,为联接金具的磨损失效预测提供理论依据.方法 分析线路实际运行参数,计算工频磁场强度,采用自制电磁线圈与M-2000 型磨损试验机相结合,通过分组控制变量法研究额定工况下金具材料的磨损过程,以及不同磁场强度下材料的磨损行为.结果 在磁场环境中材料的磨损程度远小于无磁场情况下.在0~800 A/m范围内,随着磁场强度的增加,摩擦因数稍降低,质量损失量和磨损率呈下降趋势.在不同磁场强度下磨损试样均呈现越贴近摩擦接触表面区域其显微硬度越高,且随着纵深向后呈递减趋势.在无磁场情况下,磨损接触表面的犁沟较深,遍布锯齿型边缘的凹坑和山脊型微凸峰.在磁场环境中试样的接触表面和磨屑表面更加光滑平整,且氧含量明显升高.结论 在无磁场情况下,接触表面为严重的磨粒磨损和黏着磨损.在磁场环境中,磨损试样在短时间内经历了初期磨合阶段和磨损加剧阶段,从而加速过渡到稳定磨损阶段,由严重的磨粒磨损和黏着磨损加速向轻微磨损转变.稳定阶段的主要磨损机制为氧化磨损,并伴随着轻微的磨粒磨损、黏着磨损,以及两摩擦副与磨屑"阻隔层"之间的三体磨损.工频磁场环境对试样磨损起到了一定的减摩作用,磨损程度减轻.
By analyzing the influence of the power-frequency magnetic field environment of UHVDC transmission lines on the wear behavior of the electric power fittings materials,the wear mechanism of the electric power fittings materials in the power-frequency magnetic field environment was explored to provide a theoretical basis for the wear failure prediction of the connected hardware in service.According to the actual operating parameters of UHVDC transmission lines,the power frequency magnetic induction intensity was analyzed and calculated.The self-made electromagnetic coil connected with external voltage and current stabilized power supply was combined with an M-2000 friction and wear testing machine.The magnetic field intensity generated by the coil was measured with a Gaussian meter,and the sample wear test was designed by using the group control variable method.Before the test,a hand-held degaussing device was used to degauss the pin-ring sample and the rotating shaft of the wear machine.Group A:In the range of 0-800 A/m magnetic field intensity,five gradients of 0,240,400,640 and 800 A/m were selected for wear tests to study the wear behavior of goldware materials in different magnetic induction environments.Group B:The power frequency magnetic field intensity of the transmission line under rated working conditions was selected to study the wear process variation of the goldware material in a specific magnetic induction environment.An electronic balance was used to weigh the sample mass before and after the test and calculate the wear rate.A micro-Vickers hardness tester was used to measure the hardness value of the specimen before and after the test.An industrial microscope was used to observe the macro morphology of the wear contact surface of the sample.A FEG scanning electron microscope(SEM)and an energy dispersive spectrometer(EDS)were used to observe the microstructure of the specimen wear contact surface and wear debris,and to analyze the distribution and content of elements.The results showed that the intensity of wear was much less than that without a magnetic field.With the increase of magnetic induction,the weight loss and wear rate of the worn sample decreased,and the friction coefficient decreased slightly with little fluctuation.The higher the microhardness of the worn samples in different magnetic induction intensities,the closer they were to the wear contact surface,and decreased with the depth.In the absence of the magnetic field,there were deep furrows on the worn contact surface,and there were pits on the irregular jagged edges and micro-convex peaks on the ridge.In the condition of the magnetic field,the worn contact surface and the chip surface were smoother,and the oxygen content was significantly higher than that in the absence of the magnetic field.The analysis shows that:The wear samples in the magnetic field environment accelerate from the initial run-in stage and the wear intensification stage to the stable wear stage in a short time,which accelerate the serious wear and adhesive wear to the slight wear.The main wear mechanism in the stable stage is oxidative wear,accompanied by slight wear and adhesive wear as well as three-body wear between the two friction pairs and the wear debris"barrier layer".The power frequency magnetic field environment plays a certain role in reducing friction and reducing wear.
商利;李新梅;路国闯;陈霸;杨现臣
新疆大学 机械工程学院,乌鲁木齐 830017
机械工程
特高压输电线路磁场U型环摩擦磨损
UHV transmission linesmagnetic fieldU-ringfriction and wear
《表面技术》 2024 (003)
激光熔覆制备CoCuFeNiTi-x系高熵合金涂层及其极端环境下磨损行为研究
132-141,209 / 11
国家自然科学基金(52161017,51865505);新疆维吾尔自治区自然科学基金(2022D01C386)National Natural Science Foundation of China(52161017,51865055);Natural Science Foundation of Xinjiang Uygur Autonomous Region(2022D01C386)
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