Application and dynamical performance simulation of tooth surface measured data of hypoid gear

XU Zhong-si1, FENG Lei2, LEI Hong-xia1

(1. School of Mechatronic Engineering, North University of China, Taiyuan 030051, China;2. School of Mechatronic Engineering, Lanzhou Institute of Technology, Lanzhou 730050, China)

Abstract： The tooth surface shape of hypoid gear is very complicated, and tooth surface accuracy of hypoid gear can be measured by using the latticed measurement and scanning measurement. Advantages and disadvantages of the two measurement patterns are compared and application of their measurement data on hypoid gear's quality management is analyzed. How to use these measurement data to simulate the dynamical performance of hypoid gear is researched, and the intelligent predicton of the dynamical performance indexes of contact spot, root stress, vibration exciting forces and load distribution and hertz contact stress on the tooth surface are carried out. This research work has an important guiding sense to design and machine hypoid gear with low vibration and noise.

Key words： hypoid gear; latticed measurement; scanning measurement; tooth surface; dynamical performance simulation

CLD number： TH132.429 Document code： A

Article ID： 1674-8042(2014)02-0001-08   doi： 10.3969/j.issn.1674-8042.2014.02.001

References

[1] XU Zhong-si. The research on evaluation method of tooth surface topographic deviation for hypoid gear. Beijing: Beijing University of Technology, 2006.
[2] XIE Hua-kun, WANG Zhi, SHI Zhao-yao, et al. Development on technology of bevel gear measurement.Tool Engineering, 2003, 37(10): 48-51.
[3] XU Zhong-si, FU Sheng. Different surface and application on topography deviation characterization of the hypoid gear. Modular Machine Tool& Automatic Manufacturing Technique, 2006, (5): 39-42.
[4] DONG Xue-zhu. Basic theory of gear meshing.Beijing: China Machine Press, 1989.
[5] LIN Chung-yun, Tsay C B, FENG Zhang-hua. Mathematical model of spiral bevel and hypoid gears manufactured by the modified roll method. Mechanism and Machine Theory, 1997, 32(2): 121-136.
[6] ZENG Tao. Design and manufacture of hypoid gear. Harbin: Harbin Institute of technology press, 1989.
[7] LI Jing-cai, WANG Tai-yong, FAN sheng-bo, et al. Error corrections of hypoid gear tooth surface based on digitized manufacturing. Transactions of the Chinese Society for Agricultural Machinery, 2008, 39(5): 174-177.
[8] SU Jin-ming, HUANG Guo-ming, LIU Bo. Matlab and external program interface. Beijing: China Electronic Press, 2004.
[9] WANG Jun, WANG Xiao-chun, JIANG Hong. Measurement of tooth surface of hypoid gear. Chinese Journal of Mechanical Engineering, 2003, 39(6): 151-154.
[10] Gosselin, Guertin, Remond. Simulation and experimental measurement of the transmission error of real hypoid gears under load. Journal of Mechanical Design, 2000, 122(3): 109-122.
[11] Litvin F L, Kuan C, Wang J C, et al. Minimization of deviation of gear real tooth surface determined by coordinate measurements. Journal of Mechanical Design, 1993, 115(4): 995-1001.
[12] Pfeifer T, Kurokawa S, Meyer S. Derivation of parameters of global form deviations for 3-dimensional surfaces in actual manufacturing processes. Measurement, 2001, 29(3): 179-200.
[13] XU Zhong-si, SU Tie-xiong, JIN Lei. Research on global form deviations for hypoid gear based on latticed measurement. Journal of Measurement Science and Instrumentation, 2003, 3(1): 1-9.
[14] Wang X C, Ghosh SK. Advanced theories of hypoid gears. Amsterdam: Elsevier Science BV, 1994.
[15] Takeda R, WANG Zhong-hou, Kubo A, et al. Performance analysis of hypoid gears by tooth flank form measurement. Gear Technology, 2002: 26-30.
[16] Suh S H, Lee E S, Kim H C, et al. Geometric error measurement of spiral bevel gears using a virtual gear model for STEP-N. International. Journal of Machine Tools and Manufacture, 2002, 42(3): 335-342.
[17] Suh S H, Jih W S, Hong H D. Sculptured surface machining of hypoid gears with CNC milling. International Journal of Machine Tools and Manufacture, 2001, 41(6): 833-850.
[18] LI Xiao-qing, ZHOU Yun-fei, WANG Yan-zhong. Reserch on an algorithm for an NC machining hypoid pinion. International Journal of Advances Manufacture Technology, 2003, 22: 491-497.
[19] Simon V. Head-cutter for optimal tooth modifications in hypoid gears. Mechanism and Machine Theory, 2009, 44(7): 1420-1435.
[20] WANG Pei-yu, FONG Zhang-hua. Adjustability improvement of face-milling hypoid gears by modified radial motion (MRM) method. Mechanism and Machine Theory, 2005, 40(1): 69-89.
[21] CAO Xue-mei, FANG Zong-de, XU Hao.Design of pinion machine tool-settings for hypoid gears by controlling contact path and transmission errors. Chinese Journal of Aeronautics, 2008, 21(2): 179-186.

准双曲面齿轮齿面测量数据的应用与动态性能仿真

徐忠四1，冯蕾2，雷红霞1

（1. 中北大学 机电工程学院，山西 太原 030051；2. 兰州工业学院 机电工程学院， 甘肃 兰州 730050）

摘要:准双曲面齿轮齿面形状非常复杂， 可以用点阵式测量和扫描式测量法对齿轮的齿面精度进行测量。 比较了两种测量模式的优缺点， 分析了测量数据在齿轮齿面品质管理中的应用， 研究了如何利用这些测量数据进行准双曲面齿轮的动态性能仿真， 并且对接触斑点、 齿根应力、 振动激振力以及齿面上的载荷分布、 赫芝接触应力等动态性能指标进行智能预测。 该项研究对设计与制造低振动噪音的准双曲面齿轮有重要指导意义。

关键词:准双曲面齿轮； 点阵式测量； 扫描式测量； 齿面； 动态性能仿真

引用格式：XU Zhong-si, FENG Lei, LEI Hong-xia. Application and dynamical performance simulation of tooth surface measured data of  hypoid gear. Journal of Measurement Science and Instrumentation, 2014, 5(2): 1-8. [doi: 10.3969/j.issn.1674-8042.2014.02.001]

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