Design principle and meshing performance analysis of asymmetric internal meshing gears with meshing line modification

Abstract

The asymmetric internal meshing gear with meshing line modification is designed in this article. Compared with symmetrical gears, asymmetric gears have better meshing performance. The core of the design principle of asymmetric gears tooth profiles: different meshing lines are designed for the left and right tooth profiles respectively. This further affected the left and right tooth profiles of the gears. Fix the left meshing line (non-working side), and modify the right meshing line (working side). By adjusting the center position of the right meshing line to change the shape variation of the meshing line, different asymmetric gear tooth profiles can be designed. The mathematical model of the tooth profile was derived by using the gear meshing theory, and the data points of the tooth profile were obtained through discrete numerical methods. The tooth profiles of asymmetric gears under different parameters are analyzed, and the variation laws of their tooth profiles are discovered. The changing trend of its sliding ratio is obtained by numerical calculation. The contact stress, tooth root bending stress, meshing stiffness, and transmission error of asymmetric gears under different parameters were analyzed by the finite element method. The changing trends of various meshing characteristics are obtained by comparison. The results show that keeping the center of the meshing line away from the Y_f-axis can reduce the contact stress and the tooth root bending stress. Moving the center of the meshing line to the right can improve the meshing stiffness and reduce the transmission error. This study provides a reference for the design of asymmetric internal meshing gears.

Keywords

asymmetric internal meshing gears meshing line modification tooth profile design meshing performance analysis

Get full access to this article

View all access options for this article.

References

Litvin

Fuentes

Gear geometry and applied theory. Cambridge University Press, 2004.

Litvin

Coy

JJ.

Spiral-bevel geometry and gear train precision. Adv Power Transm Technol 1983, NASA CP-2210: 335–344. https://ntrs.nasa.gov/citations/19830011868

Wang

Hou

Luo

SM.

Research on tooth profile design of spur gears based on line of action. Adv Mater Res 2013; 631-632: 817–823.

Wang

Liang

Luo

, et al. Active design of tooth profiles using parabolic curve as the line of action. Mech Mach Theory 2013; 67: 47–63.

Wang

Luo

, et al. Geometric design and simulation of tooth profile using elliptical segments as its line of action. J Central South Univ 2015; 22(6): 2119–2126.

Peng

Chen

Liang

, et al. Mathematical model and tooth contact analysis of an internal helical gear pair with selectable contact path. Int J Precis Eng Manuf 2018; 19(6): 837–848.

Geng

Deng

, et al. Calculation and experiment of spiral bevel gear by duplex helical method predesigned contact path. J Adv Mech Des Syst Manuf 2021; 15(1): JAMDSM0006.

Tkach

Nosko

Bashta

, et al. High load capacity spur gears with conchoidal path of contact. Mech Ind 2021; 22: 47.

Zorko

Duhovnik

Tavčar

Tooth bending strength of gears with a progressive curved path of contact. J Comput Des Eng 2021; 8(4): 1037–1058.

10.

Zorko

Investigation on the high-cycle tooth bending fatigue and thermo-mechanical behavior of polymer gears with a progressive curved path of contact. Int J Fatigue 2021; 151: 106394.

11.

Wang

Ren

Design and manufacturing of a novel high contact ratio internal gear with a circular arc contact path. Int J Mech Sci 2019; 153–154: 143–153.

12.

Wang

Liu

Dou

Investigation of load capacity of high-contact-ratio internal spur gear drive with arc path of contact. Appl Sci 2022; 12(7): 3345.

13.

Tan

Chen

Liang

, et al. Theoretical and experimental analyses of spiral bevel gears with two contact paths. Proc Inst Mech Eng C J Mech Eng Sci 2018; 232(4): 665–676.

14.

Tan

Zhang

Guo

, et al. An analytical framework of the kinematic geometry for general point-contact gears from contact path. Proc Inst Mech Eng C J Mech Eng Sci 2022; 236(11): 6363–6382.

15.

Chen

Xiao

, et al. Computerized design, simulation of meshing, and stress analysis of curvilinear cylindrical gears based on the active design of the meshing line function. Mech Mach Theory 2023; 188: 105389.

16.

Chen

Zeng

Nonrelative sliding of spiral bevel gear mechanism based on active design of meshing line. Proc Inst Mech Eng C J Mech Eng Sci 2019; 233(3): 1055–1067.

17.

Chen

Ding

Zeng

Nonrelative sliding gear mechanism based on function-oriented design of meshing line functions for parallel axes transmission. Adv Mech Eng 2018; 10(9): 1687814018796327.

18.

Jia

Computerized design and analysis of a novel high load bearing internal gear drive with curved meshing line. Proc Inst Mech Eng C J Mech Eng Sci 2025; 239(2): 613–624.

19.

Jia

Zhang

Numerical analysis of tooth contact and wear characteristics of internal cylindrical gears with curved meshing line. Appl Sci 2024; 14(13): 5399.

20.

Jia

Xiao

, et al. Design and analysis of novel non-involute cylindrical gears with a curved path of contact. Mathematics 2022; 10(22): 4290.

21.

Marimuthu

Muthuveerappan

Design of asymmetric normal contact ratio spur gear drive through direct design to enhance the load carrying capacity. Mech Mach Theory 2016; 95: 22–34.

22.

Marimuthu

Muthuveerappan

Investigation of load carrying capacity of asymmetric high contact ratio spur gear based on load sharing using direct gear design approach. Mech Mach Theory 2016; 96: 52–74.

23.

Chen

Yang

Pai

PF.

Design and kinematics evaluation of a gear pair with asymmetric parabolic teeth. Mech Mach Theory 2016; 101: 140–157.

24.

Shuai

Guoguang

, et al. Design principle and modeling method of asymmetric involute internal helical gears. Proc Inst Mech Eng C J Mech Eng Sci 2019; 233(1): 244–255.

25.

Luo

Song

, et al. Geometry design and tooth contact analysis of non-orthogonal asymmetric helical face gear drives. Mech Mach Theory 2022; 173: 104831.

26.

Zhang

Tang

, et al. Design methods and stress analysis of asymmetric offset face-gear transmission. Proc Inst Mech Eng C J Mech Eng Sci 2022; 236(14): 7814–7828.

27.

Wang

, et al. An analytical method for the meshing characteristics of asymmetric helical gears with tooth modifications. Mech Mach Theory 2023; 185: 105321.

28.

Sekar

RP.

Influence of profile correction factor on asymmetric spur gear efficiency. J Inst Eng (India) Ser C 2022; 103(6): 1373–1387.

29.

Sekar

RP.

Reduction of tooth wear on asymmetric spur gear through profile correction factors. Aust J Mech Eng 2024; 22(3): 506–522.

30.

Zheng

Liu

Chen

, et al. A novel forward performance-driven design method for gear parameters. Proc Inst Mech Eng C J Mech Eng Sci 2024; 238(22): 10632–10653.

31.

Chen

Zhang

Xiao

, et al. Computerized design of asymmetric pure rolling gears with a method for predesigning the desired function of unloaded transmission errors. Mech Mach Theory 2025; 213: 106072.