METALS AND METAL MATRIX COMPOSITES |
|
|
|
|
|
Research Progress on Temperature Measurement Technology of Friction Contact Surfaces |
YANG Xianchen, LI Xinmei
|
School of Mechanical Engineering, Xinjiang University, Urumqi 830000, China |
|
|
Abstract The temperature rise of friction surface affects the physical, chemical and mechanical properties of material surface, which leads to accelerated failure of key components. Therefore, temperature information of friction contact surface is of great significance for research of friction characteristics, wear mechanism and practical engineering application. At present, researchers have established a variety of contact models based on the mixed elastoplastic theory and fractal theory on rough surface, which can be used to calculate the thermodynamic distribution and flash temperature under different working conditions. However, the friction temperature depends on load, speed, environment and friction pair materials and other factors. Furthermore, the irregular distribution of asperities and dynamic changes of contact characteristics hinder the development of theoretical analysis. With the development of measurement technology, researchers have a better understanding of the friction surface temperature. In this paper, a variety of temperature measurement technologies of friction contact surface are summarized, including traditional methods like thermocouple and infrared radiation, new methods such as ultrasonic technology, grindable thermocouple and thin film thermocouple, and methods for post detection like metallographic structure and kryptonization. The research status and application scope of each technology are illuminated. The problems, advantages and disadvantages of the current technologies in the temperature measurement of the friction surface are discussed. Meanwhile, the challenges of temperature measurement technology of friction contact surface are put forward and the future development direction is prospected.
|
Published: 25 June 2022
Online: 2022-06-24
|
|
Fund:National Natural Science Foundation of China (51865055) and Xinjiang Tianshan Talents Program Funded Project (201720025). |
|
|
1 Wang J G, Dai Y J, Hong Y F, et al. Journal of Harbin Institute of Technology, 2020, 52(1), 8 (in Chinese). 汪久根, 戴雨静, 洪玉芳, 等.哈尔滨工业大学学报, 2020, 52(1), 8. 2 Kennedy F E. Journal of Tribology, 1982, 104(4), 582. 3 Iiyuk. Thin-layer tribology, China Machine Press, China, 1980 (in Chinese ). 伊留克. 薄层摩擦学, 机械工业出版社, 1980. 4 Kennedy F E. Wear, 1984, 100(1-3), 453. 5 Yagi K, Kyogoku K, Nakahara T. Tribology Transactions, 2006, 49(4), 482. 6 Tian X, Kennedy F E. Journal of Tribology,1994,116( 1), 167. 7 Carslaw H S, Jaeger J C. The Mathematical Gazette, 1959, 36(316), 142. 8 Ashby M F,Abulawi J, Kong H S. Tribology Transactions,1991,34(4), 577. 9 Smith E H, Aranell R D. Tribology Letters, 2013, 52(3),407. 10 Liu Y W, Ye F H, Li H Y, et al. Journal of Vibration and Shock, 2019,38(22),178(in Chinese ). 刘雨薇, 叶福浩, 李和言,等.振动与冲击,2019,38(22),178. 11 Jaeger J C. Proceedings of the Royal Society, 1942, 76, 202 12 Archard J F. Wear, 1959, 2(6), 438. 13 Komanduri R, Hou Z B. Tribology International,2001, 34(3), 145. 14 Liu Z Q, Huang C Z, Wan Y, et al. Tool Engineering, 2002(3), 3(in Chinese ). 刘战强,黄传真,万熠,等.工具技术, 2002(3),3. 15 Bhushan B. Modern Tribology Handbook, CRC Press, American, 2001, pp.60. 16 Shankar V K, Kunar B M, Murthy C S, et al. Friction, 2020,8(6), 1073. 17 Yuan C H. Multi-scale simulation and experimental study of thermal effect of metal friction. Master's Thesis, Harbin Institute of Technology,China,2017(in Chinese). 袁晨昊. 金属摩擦热效应的多尺度模拟及实验研究.硕士学位论文, 哈尔滨工业大学,2017. 18 Newcomb T P. Proceedings of the Institution of Mechanical Engineers Automobile Division, 1958,12(7), 227. 19 Stephenson D A. Journal of Engineering for Industry, 1993, 115 (4), 432. 20 Pang J, Wu C, Wang Q, et al. International Journal of Advanced Manufacturing Technology, 2018, 97, 25. 21 Chen R Y. Metal cutting principles, China Machine Press, China, 2002(in Chinese ). 陈日曜.金属切削原理,机械工业出版社,2002. 22 Lu J Z, Sun J N. Metal cutting principles and tools, China Machine Press, China, 2011(in Chinese ). 陆剑中,孙家宁.金属切削原理与刀具,机械工业出版社,2011. 23 Cai G Q, Zheng H W. Journal of Northeastern University, 1985(4), 74(in Chinese). 蔡光起,郑焕文.东北工学院学报,1985(4),74. 24 Wu Y P, Shi Z H, Li X Z, et al. Journal of Anhui University of Technology,1988(2),182(in Chinese ). 吴一平,施占华,李熙章,等.安徽工学院学报,1988(2),182. 25 Nosko O, Nagamine T, Nosko A L, et al. Tribology International, 2015, 88,100. 26 Bendersky D. Mechanical Engineering Machine, 1953, 75(2),117. 27 Lei J F, Martin L C, Will H A. In:ASME 1997 International gas turbine and aeroengine congress and exhibition. Florida, 1997, pp.1. 28 Wrbanek J D, Fralick G C. In: International Instrumentation Symposium. Cleveland, 2006, pp. 214395. 29 Chen Y Z. Research on fabrication of thin film thermocouples on nickel base superalloy and related technology. Master's Thesis, University of electronic Science and Technology, China, 2014(in Chinese ). 陈寅之. 在镍基高温合金上制备薄膜热电偶及其相关技术研究. 硕士学位论文,电子科技大学,2014. 30 方钢, 陈曦.中国专利, CN2013105290222. 2013. 31 Tian X, Kennedy F E, Deacutis J J, et al. Journal of Tribology-Transactions of the ASME, 1992, 35(3), 167. 32 Kennedy F E, Frusescu D, Jiaying L. Wear,1997,207(1), 46. 33 Chang X, Chen W Y. China Mechanical Engineering, 1995(S1),120(in Chinese ). 常兴, 陈五一.中国机械工程,1995(S1),120. 34 Yao Y L, Dai J, Huang C F. Aeronautical Manufacturing Technology,2015(12), 103(in Chinese ). 姚艳玲,代军,黄春峰.航空制造技术,2015(12),103. 35 Xu X,Yang X X. Applied Technology,2012,62, 1674. 36 Modest M F. International Journal of Heat & Mass Transfer,2003,12 (10), 1331. 37 Wang C, Gou X K, Duan Y, et al. Journal of Infrared and Millimeter Waves, 2018, 37(4), 501 (in Chinese). 王超, 苟学科, 段英, 等. 红外与毫米波学报, 2018, 37(4), 501. 38 Wang K H. Practical technology of temperature measurement, China Machine Press, China, 2007(in Chinese ). 王魁汉.温度测量实用技术, 机械工业出版社,2007. 39 Wieleba W. Wear, 2005,258(5),870 40 Wang Y, Yan M F, Xu J J, et al. In: Proceedings of the First National Youth Tribology Conference.Beijing, 1991,pp.13(in Chinese ). 王铀,闫牧夫, 徐景俊, 等. 第一届全国青年摩擦学学术会议论文集. 北京, 1991, pp.13. 41 Wei W. The model of sliding friction temperature field and it's application. Master's Thesis, Hefei University of Technology, China, 2016 (in Chinese). 魏巍. 滑动摩擦副温度场模型研究及应用. 硕士学位论文, 合肥工业大学, 2016. 42 Yu J W, Cheng Q, Wei W, et al. Lubrication Engineering, 2013, 38(4), 1. 俞建卫, 程清, 魏巍, 等. 润滑与密封, 2013, 38(4),1. 43 Li Q L. Research on the frictional temperature field of face-to -face contact based on the measurement of the interface. Master's Thesis, Hefei University of Technology, China, 2009 (in Chinese). 李奇亮. 基于界面测温的面接触摩擦温度场研究. 硕士学位论文, 合肥工业大学, 2009. 44 Wang L F. The research of spherical plain bearing friction temperature fieldbased on infrared measurement.Master's Thesis, Hefei University of Technology, China, 2015 (in Chinese). 王礼飞. 基于红外测温方法的关节轴承摩擦温度场研究. 硕士学位论文, 合肥工业大学, 2015. 45 Xing D M. Research on the frictional temperature field of copper-based bearing materials based on backstepping heat flow method. Master's Thesis, Hefei University of Technology, China, 2012 (in Chinese). 邢大淼. 基于反推热流法的铜基轴承材料端面摩擦温度场研究.硕士学位论文, 合肥工业大学, 2012. 46 Rowe K G, Bennett A I, Krick B A, et al. Tribology International, 2013, 62, 208. 47 Quinn T F, Winer W O. Elsevier, 1985, 102(1-2), 67. 48 Shi Y A, Wei D, H B, et al. Journal of Nondestructive Evaluation, 2020, 139(2), 48. 49 Xu L, Wang G, Lyu G Y, et al. Journal of Test and Measurement Technology, 2019, 33(2), 178 (in Chinese). 许琳, 王高, 吕国义, 等. 测试技术学报, 2019, 33(2), 178. 50 Lynnworth L C, Carnevale E H. Temperature Measurement and Control, 1972, 1(4), 715. 51 Balasubramaniam K, Shan V V, Costley R D, et al. Review of Scientific Instruments, 1999, 70(12), 46. 52 Ihara I, Tomomatsu T. Iop Conference, 2011, 18(2), 022008. 53 Aoki S, Ihara I. Mechanical Engineering Journal, 2015, 2(1), 431. 54 Ihara I, Aoki S. International Journal on Smart sensing and Intelligent Systems, 2020, 7(5), 1. 55 Silva M B D, Wallbank J. Journal of Materials Processing Technology, 1999, 88(1-3), 195. 56 Wu Y P, Shi Z H. Journal of Anhui Institute of Technology,1988(2), 175 (in Chinese). 吴一平, 施占华.安徽工学院学报, 1988(2), 175. 57 Wright P K, Trent E M. Journal of the Iron and Steel Institute, 1973, 211, 364. 58 Wright P K. Engineering for Industry, 1978, 100(2), 131. 59 Huang X T, Huang L G. Lubricatio Engineering, 1985(1), 12 (in Chinese). 黄湘泰, 黄林根. 润滑与密封, 1985(1), 12. 60 Fang H, Zhang G D. Materials for Mechanical Engineering, 1998(5), 3 (in Chinese). 方浩, 张国定. 机械工程材料, 1998(5), 3. 61 Li Y, Yin G M. Aeroengine, 2017, 43(3), 83 (in Chinese). 李杨, 殷光明. 航空发动机, 2017, 43(3), 83. 62 Zhang J Y, Qin Y, Qiu J H, et al. China Coatings, 2020, 35(4), 45 (in Chinese). 张建英, 秦颖, 邱家浩, 等. 中国涂料, 2020, 35(4), 45. 63 Chi Y, Jhih R, Tong M. Journal of Mechanics, 2020, 36(4), 15. 64 Yu M, Osamu K. International Journal of Heat and Mass Transfer, 2020, 153,119567. 65 Zhu A C, Gao C H, Huang J M. Machinery, 2005(11), 62 (in Chinese). 主安成, 高诚辉, 黄健萌. 机械制造, 2005(11), 62. 66 Ding H D, Han W Z, Xie F K, et al. China Surface Engineering, 1999(1), 3 (in Chinese). 丁华东, 韩文政, 谢凤宽, 等. 中国表面工程, 1999(1), 3. |
|
|
|