SHAO, Yanjie ;CHEN, Yangzhi ;XIAO, Xiaoping ;ZHENG, Maoxi ;HE, Weitao . Design and Stress Analysis of Bevel Line Gears with Vertical Flank Suitable for Micro Machining. Strojniški vestnik - Journal of Mechanical Engineering, [S.l.], v. 70, n.9-10, p. 483-493, may 2024. ISSN 0039-2480. Available at: <https://www.sv-jme.eu/article/design-and-stress-analysis-of-bevel-line-gears-with-vertical-flank-suitable-for-micro-machining/>. Date accessed: 09 dec. 2024. doi:http://dx.doi.org/10.5545/sv-jme.2024.917.
Shao, Y., Chen, Y., Xiao, X., Zheng, M., & He, W. (2024). Design and Stress Analysis of Bevel Line Gears with Vertical Flank Suitable for Micro Machining. Strojniški vestnik - Journal of Mechanical Engineering, 70(9-10), 483-493. doi:http://dx.doi.org/10.5545/sv-jme.2024.917
@article{sv-jmesv-jme.2024.917, author = {Yanjie Shao and Yangzhi Chen and Xiaoping Xiao and Maoxi Zheng and Weitao He}, title = {Design and Stress Analysis of Bevel Line Gears with Vertical Flank Suitable for Micro Machining}, journal = {Strojniški vestnik - Journal of Mechanical Engineering}, volume = {70}, number = {9-10}, year = {2024}, keywords = {line gear; bevel gear; meshing theory; stress analysis; micro machining; }, abstract = {The line gear (LG) exhibits promising applications in micromachinery owing to its simple structure and minimal teeth count. This paper aims to advance the meshing theory of LG and introduce a conical LG tooth configuration specifically tailored for micro-machining that is capable of driving with high performance. Based on the meshing principle of LG, a conical line gear pair with vertical flank (VFLG) of the driving gear was designed. Subsequently, adhering to the curvature non-interference principle that no local interference occurs in the meshing process and the specified range of fitting error in one direction, the design parameters for LG were determined. A comparison of the contact stress between two sets of different contact line types revealed the distinct advantage of VFLG with parameters identical to those of traditional LG. The experimental results conclusively demonstrate a transmission ratio error of 0.004, affirming the feasibility of the design. The curvature non-interference design formula proposed in this paper refines the LG design theory, and the novel LG design method presented holds significant implications for subsequent micromachining.}, issn = {0039-2480}, pages = {483-493}, doi = {10.5545/sv-jme.2024.917}, url = {https://www.sv-jme.eu/article/design-and-stress-analysis-of-bevel-line-gears-with-vertical-flank-suitable-for-micro-machining/} }
Shao, Y.,Chen, Y.,Xiao, X.,Zheng, M.,He, W. 2024 May 70. Design and Stress Analysis of Bevel Line Gears with Vertical Flank Suitable for Micro Machining. Strojniški vestnik - Journal of Mechanical Engineering. [Online] 70:9-10
%A Shao, Yanjie %A Chen, Yangzhi %A Xiao, Xiaoping %A Zheng, Maoxi %A He, Weitao %D 2024 %T Design and Stress Analysis of Bevel Line Gears with Vertical Flank Suitable for Micro Machining %B 2024 %9 line gear; bevel gear; meshing theory; stress analysis; micro machining; %! Design and Stress Analysis of Bevel Line Gears with Vertical Flank Suitable for Micro Machining %K line gear; bevel gear; meshing theory; stress analysis; micro machining; %X The line gear (LG) exhibits promising applications in micromachinery owing to its simple structure and minimal teeth count. This paper aims to advance the meshing theory of LG and introduce a conical LG tooth configuration specifically tailored for micro-machining that is capable of driving with high performance. Based on the meshing principle of LG, a conical line gear pair with vertical flank (VFLG) of the driving gear was designed. Subsequently, adhering to the curvature non-interference principle that no local interference occurs in the meshing process and the specified range of fitting error in one direction, the design parameters for LG were determined. A comparison of the contact stress between two sets of different contact line types revealed the distinct advantage of VFLG with parameters identical to those of traditional LG. The experimental results conclusively demonstrate a transmission ratio error of 0.004, affirming the feasibility of the design. The curvature non-interference design formula proposed in this paper refines the LG design theory, and the novel LG design method presented holds significant implications for subsequent micromachining. %U https://www.sv-jme.eu/article/design-and-stress-analysis-of-bevel-line-gears-with-vertical-flank-suitable-for-micro-machining/ %0 Journal Article %R 10.5545/sv-jme.2024.917 %& 483 %P 11 %J Strojniški vestnik - Journal of Mechanical Engineering %V 70 %N 9-10 %@ 0039-2480 %8 2024-05-19 %7 2024-05-19
Shao, Yanjie, Yangzhi Chen, Xiaoping Xiao, Maoxi Zheng, & Weitao He. "Design and Stress Analysis of Bevel Line Gears with Vertical Flank Suitable for Micro Machining." Strojniški vestnik - Journal of Mechanical Engineering [Online], 70.9-10 (2024): 483-493. Web. 09 Dec. 2024
TY - JOUR AU - Shao, Yanjie AU - Chen, Yangzhi AU - Xiao, Xiaoping AU - Zheng, Maoxi AU - He, Weitao PY - 2024 TI - Design and Stress Analysis of Bevel Line Gears with Vertical Flank Suitable for Micro Machining JF - Strojniški vestnik - Journal of Mechanical Engineering DO - 10.5545/sv-jme.2024.917 KW - line gear; bevel gear; meshing theory; stress analysis; micro machining; N2 - The line gear (LG) exhibits promising applications in micromachinery owing to its simple structure and minimal teeth count. This paper aims to advance the meshing theory of LG and introduce a conical LG tooth configuration specifically tailored for micro-machining that is capable of driving with high performance. Based on the meshing principle of LG, a conical line gear pair with vertical flank (VFLG) of the driving gear was designed. Subsequently, adhering to the curvature non-interference principle that no local interference occurs in the meshing process and the specified range of fitting error in one direction, the design parameters for LG were determined. A comparison of the contact stress between two sets of different contact line types revealed the distinct advantage of VFLG with parameters identical to those of traditional LG. The experimental results conclusively demonstrate a transmission ratio error of 0.004, affirming the feasibility of the design. The curvature non-interference design formula proposed in this paper refines the LG design theory, and the novel LG design method presented holds significant implications for subsequent micromachining. UR - https://www.sv-jme.eu/article/design-and-stress-analysis-of-bevel-line-gears-with-vertical-flank-suitable-for-micro-machining/
@article{{sv-jme}{sv-jme.2024.917}, author = {Shao, Y., Chen, Y., Xiao, X., Zheng, M., He, W.}, title = {Design and Stress Analysis of Bevel Line Gears with Vertical Flank Suitable for Micro Machining}, journal = {Strojniški vestnik - Journal of Mechanical Engineering}, volume = {70}, number = {9-10}, year = {2024}, doi = {10.5545/sv-jme.2024.917}, url = {https://www.sv-jme.eu/article/design-and-stress-analysis-of-bevel-line-gears-with-vertical-flank-suitable-for-micro-machining/} }
TY - JOUR AU - Shao, Yanjie AU - Chen, Yangzhi AU - Xiao, Xiaoping AU - Zheng, Maoxi AU - He, Weitao PY - 2024/05/19 TI - Design and Stress Analysis of Bevel Line Gears with Vertical Flank Suitable for Micro Machining JF - Strojniški vestnik - Journal of Mechanical Engineering; Vol 70, No 9-10 (2024): Strojniški vestnik - Journal of Mechanical Engineering DO - 10.5545/sv-jme.2024.917 KW - line gear, bevel gear, meshing theory, stress analysis, micro machining, N2 - The line gear (LG) exhibits promising applications in micromachinery owing to its simple structure and minimal teeth count. This paper aims to advance the meshing theory of LG and introduce a conical LG tooth configuration specifically tailored for micro-machining that is capable of driving with high performance. Based on the meshing principle of LG, a conical line gear pair with vertical flank (VFLG) of the driving gear was designed. Subsequently, adhering to the curvature non-interference principle that no local interference occurs in the meshing process and the specified range of fitting error in one direction, the design parameters for LG were determined. A comparison of the contact stress between two sets of different contact line types revealed the distinct advantage of VFLG with parameters identical to those of traditional LG. The experimental results conclusively demonstrate a transmission ratio error of 0.004, affirming the feasibility of the design. The curvature non-interference design formula proposed in this paper refines the LG design theory, and the novel LG design method presented holds significant implications for subsequent micromachining. UR - https://www.sv-jme.eu/article/design-and-stress-analysis-of-bevel-line-gears-with-vertical-flank-suitable-for-micro-machining/
Shao, Yanjie, Chen, Yangzhi, Xiao, Xiaoping, Zheng, Maoxi, AND He, Weitao. "Design and Stress Analysis of Bevel Line Gears with Vertical Flank Suitable for Micro Machining" Strojniški vestnik - Journal of Mechanical Engineering [Online], Volume 70 Number 9-10 (19 May 2024)
Strojniški vestnik - Journal of Mechanical Engineering 70(2024)9-10, 483-493
© The Authors 2024. CC BY 4.0 Int.
The line gear (LG) exhibits promising applications in micromachinery owing to its simple structure and minimal teeth count. This paper aims to advance the meshing theory of LG and introduce a conical LG tooth configuration specifically tailored for micro-machining that is capable of driving with high performance. Based on the meshing principle of LG, a conical line gear pair with vertical flank (VFLG) of the driving gear was designed. Subsequently, adhering to the curvature non-interference principle that no local interference occurs in the meshing process and the specified range of fitting error in one direction, the design parameters for LG were determined. A comparison of the contact stress between two sets of different contact line types revealed the distinct advantage of VFLG with parameters identical to those of traditional LG. The experimental results conclusively demonstrate a transmission ratio error of 0.004, affirming the feasibility of the design. The curvature non-interference design formula proposed in this paper refines the LG design theory, and the novel LG design method presented holds significant implications for subsequent micromachining.