XU, Tiantian ;GUAN, Qingyu ;MA, Chunlu . The Impact of Micro-texture Distribution on the Frictional Performance of Straight Bevel Cylindrical Gears. Articles in Press, [S.l.], v. 0, n.0, p. 582-594, september 2024. ISSN 0039-2480. Available at: <https://www.sv-jme.eu/article/the-impact-of-micro-texture-distribution-on-the-frictional-performance-of-straight-bevel-cylindrical-gears/>. Date accessed: 25 nov. 2024. doi:http://dx.doi.org/10.5545/sv-jme.2024.1033.
Xu, T., Guan, Q., & Ma, C. (0). The Impact of Micro-texture Distribution on the Frictional Performance of Straight Bevel Cylindrical Gears. Articles in Press, 0(0), 582-594. doi:http://dx.doi.org/10.5545/sv-jme.2024.1033
@article{sv-jmesv-jme.2024.1033, author = {Tiantian Xu and Qingyu Guan and Chunlu Ma}, title = {The Impact of Micro-texture Distribution on the Frictional Performance of Straight Bevel Cylindrical Gears}, journal = {Articles in Press}, volume = {0}, number = {0}, year = {0}, keywords = {gear transmission; micro-texture; friction; wear; stress-strain; temperature; }, abstract = {In order to alleviate wear on the tooth surfaces during gear transmission and to enhance the anti-seizing capabilities of the tooth faces, this paper proposes micro-textured gears as a solution to this challenge. Firstly, three types of micro-textured gears were designed based on the mechanism of action of micro-textures and the meshing positions during gear transmission. Secondly, finite element simulation tests were conducted with and without micro-textured gears, and the stresses, strains, and wear levels experienced by the micro-textured gears during transmission were analyzed. The study found that torque and rotational speed have a direct impact on the gear surface. Compared to traditional gears, gears with micro-textures distributed above the pitch circle promoted a 51.57% reduction in stress and a 61.81% reduction in strain, also altering the concentration locations of stress and strain on the tooth surfaces, which led to a 50.51% reduction in wear. This research has significant implications for improving the frictional performance of gears, with micro-textures on the tooth surfaces acting as containers for lubricants and metal filings, preventing abrasive wear of the friction pairs on the tooth faces and enhancing the durability of the gears.}, issn = {0039-2480}, pages = {582-594}, doi = {10.5545/sv-jme.2024.1033}, url = {https://www.sv-jme.eu/article/the-impact-of-micro-texture-distribution-on-the-frictional-performance-of-straight-bevel-cylindrical-gears/} }
Xu, T.,Guan, Q.,Ma, C. 0 September 0. The Impact of Micro-texture Distribution on the Frictional Performance of Straight Bevel Cylindrical Gears. Articles in Press. [Online] 0:0
%A Xu, Tiantian %A Guan, Qingyu %A Ma, Chunlu %D 0 %T The Impact of Micro-texture Distribution on the Frictional Performance of Straight Bevel Cylindrical Gears %B 0 %9 gear transmission; micro-texture; friction; wear; stress-strain; temperature; %! The Impact of Micro-texture Distribution on the Frictional Performance of Straight Bevel Cylindrical Gears %K gear transmission; micro-texture; friction; wear; stress-strain; temperature; %X In order to alleviate wear on the tooth surfaces during gear transmission and to enhance the anti-seizing capabilities of the tooth faces, this paper proposes micro-textured gears as a solution to this challenge. Firstly, three types of micro-textured gears were designed based on the mechanism of action of micro-textures and the meshing positions during gear transmission. Secondly, finite element simulation tests were conducted with and without micro-textured gears, and the stresses, strains, and wear levels experienced by the micro-textured gears during transmission were analyzed. The study found that torque and rotational speed have a direct impact on the gear surface. Compared to traditional gears, gears with micro-textures distributed above the pitch circle promoted a 51.57% reduction in stress and a 61.81% reduction in strain, also altering the concentration locations of stress and strain on the tooth surfaces, which led to a 50.51% reduction in wear. This research has significant implications for improving the frictional performance of gears, with micro-textures on the tooth surfaces acting as containers for lubricants and metal filings, preventing abrasive wear of the friction pairs on the tooth faces and enhancing the durability of the gears. %U https://www.sv-jme.eu/article/the-impact-of-micro-texture-distribution-on-the-frictional-performance-of-straight-bevel-cylindrical-gears/ %0 Journal Article %R 10.5545/sv-jme.2024.1033 %& 582 %P 13 %J Articles in Press %V 0 %N 0 %@ 0039-2480 %8 2024-09-09 %7 2024-09-09
Xu, Tiantian, Qingyu Guan, & Chunlu Ma. "The Impact of Micro-texture Distribution on the Frictional Performance of Straight Bevel Cylindrical Gears." Articles in Press [Online], 0.0 (0): 582-594. Web. 25 Nov. 2024
TY - JOUR AU - Xu, Tiantian AU - Guan, Qingyu AU - Ma, Chunlu PY - 0 TI - The Impact of Micro-texture Distribution on the Frictional Performance of Straight Bevel Cylindrical Gears JF - Articles in Press DO - 10.5545/sv-jme.2024.1033 KW - gear transmission; micro-texture; friction; wear; stress-strain; temperature; N2 - In order to alleviate wear on the tooth surfaces during gear transmission and to enhance the anti-seizing capabilities of the tooth faces, this paper proposes micro-textured gears as a solution to this challenge. Firstly, three types of micro-textured gears were designed based on the mechanism of action of micro-textures and the meshing positions during gear transmission. Secondly, finite element simulation tests were conducted with and without micro-textured gears, and the stresses, strains, and wear levels experienced by the micro-textured gears during transmission were analyzed. The study found that torque and rotational speed have a direct impact on the gear surface. Compared to traditional gears, gears with micro-textures distributed above the pitch circle promoted a 51.57% reduction in stress and a 61.81% reduction in strain, also altering the concentration locations of stress and strain on the tooth surfaces, which led to a 50.51% reduction in wear. This research has significant implications for improving the frictional performance of gears, with micro-textures on the tooth surfaces acting as containers for lubricants and metal filings, preventing abrasive wear of the friction pairs on the tooth faces and enhancing the durability of the gears. UR - https://www.sv-jme.eu/article/the-impact-of-micro-texture-distribution-on-the-frictional-performance-of-straight-bevel-cylindrical-gears/
@article{{sv-jme}{sv-jme.2024.1033}, author = {Xu, T., Guan, Q., Ma, C.}, title = {The Impact of Micro-texture Distribution on the Frictional Performance of Straight Bevel Cylindrical Gears}, journal = {Articles in Press}, volume = {0}, number = {0}, year = {0}, doi = {10.5545/sv-jme.2024.1033}, url = {https://www.sv-jme.eu/article/the-impact-of-micro-texture-distribution-on-the-frictional-performance-of-straight-bevel-cylindrical-gears/} }
TY - JOUR AU - Xu, Tiantian AU - Guan, Qingyu AU - Ma, Chunlu PY - 2024/09/09 TI - The Impact of Micro-texture Distribution on the Frictional Performance of Straight Bevel Cylindrical Gears JF - Articles in Press; Vol 0, No 0 (0): Articles in Press DO - 10.5545/sv-jme.2024.1033 KW - gear transmission, micro-texture, friction, wear, stress-strain, temperature, N2 - In order to alleviate wear on the tooth surfaces during gear transmission and to enhance the anti-seizing capabilities of the tooth faces, this paper proposes micro-textured gears as a solution to this challenge. Firstly, three types of micro-textured gears were designed based on the mechanism of action of micro-textures and the meshing positions during gear transmission. Secondly, finite element simulation tests were conducted with and without micro-textured gears, and the stresses, strains, and wear levels experienced by the micro-textured gears during transmission were analyzed. The study found that torque and rotational speed have a direct impact on the gear surface. Compared to traditional gears, gears with micro-textures distributed above the pitch circle promoted a 51.57% reduction in stress and a 61.81% reduction in strain, also altering the concentration locations of stress and strain on the tooth surfaces, which led to a 50.51% reduction in wear. This research has significant implications for improving the frictional performance of gears, with micro-textures on the tooth surfaces acting as containers for lubricants and metal filings, preventing abrasive wear of the friction pairs on the tooth faces and enhancing the durability of the gears. UR - https://www.sv-jme.eu/article/the-impact-of-micro-texture-distribution-on-the-frictional-performance-of-straight-bevel-cylindrical-gears/
Xu, Tiantian, Guan, Qingyu, AND Ma, Chunlu. "The Impact of Micro-texture Distribution on the Frictional Performance of Straight Bevel Cylindrical Gears" Articles in Press [Online], Volume 0 Number 0 (09 September 2024)
Articles in Press
© The Authors 2024. CC BY 4.0 Int.
In order to alleviate wear on the tooth surfaces during gear transmission and to enhance the anti-seizing capabilities of the tooth faces, this paper proposes micro-textured gears as a solution to this challenge. Firstly, three types of micro-textured gears were designed based on the mechanism of action of micro-textures and the meshing positions during gear transmission. Secondly, finite element simulation tests were conducted with and without micro-textured gears, and the stresses, strains, and wear levels experienced by the micro-textured gears during transmission were analyzed. The study found that torque and rotational speed have a direct impact on the gear surface. Compared to traditional gears, gears with micro-textures distributed above the pitch circle promoted a 51.57% reduction in stress and a 61.81% reduction in strain, also altering the concentration locations of stress and strain on the tooth surfaces, which led to a 50.51% reduction in wear. This research has significant implications for improving the frictional performance of gears, with micro-textures on the tooth surfaces acting as containers for lubricants and metal filings, preventing abrasive wear of the friction pairs on the tooth faces and enhancing the durability of the gears.