Design and simulation of reconfigurable modular snake robots with bevel gear transmission
Abstract
With the advancement of technologies, robotics is playing an increasingly important role in various fields. The snake robot has attracted widespread academic attention due to its efficient and flexible movement characteristics. Nevertheless, its popularity and application range are constrained by complex control, low durability, and high cost. Given this, this study proposed a modular design framework based on the concept of modular design and a reconfigurable modular snake robot using bevel gear transmission. The snake robot consists of several basic module units with the same structure, which are restructured and reconfigured to achieve different shapes and functions. A standardized interface and communication protocol were optimized and designed, with each module containing an autonomous control unit and several execution units. The robot realized motion and tasks through the collaborative work of multiple modules to adapt to various work and environmental requirements. In addition, the research analyzes distributed control, improved motion control (using PID algorithm), energy management, safety design and other aspects, based on the cost data, improvement measures were proposed. At the same time, the work risks of the robot are analyzed, such as mechanical damage to the human body, adverse environment and electromagnetic interference, and corresponding solutions are proposed, and problems are found through durability testing and material improvement measures are proposed. Finally, based on SolidWorks software, a three-dimensional modeling and simulation analysis was conducted on the robot to verify its correctness. This study can provide inspiration for the design and research of snake robots.
References
1. Yan S. Research on a Inchworm-like Crawling Robot. Chongqing University, 2024.
2. Chun C. Design and motion simulation of biomimetic snakes. Harbin Institute of Technology, 2009.
3. Rigelsford J. Neurotechnology for biomimetic robots. Industrial Robot, 2004, 31(6): 534.
4. Wright C, Buchan A, Brown B, et al. Design and architecture of the unified modular snake robot. The 2012 IEEE International Conference on Robotics and Automation, St Paul, USA, May 14-18, 2012.
5. Wright C, Johnson A, Peck A, et al. Design of a modu lar snake robot. IEEE/RSJ International Conference on Intelligent Robots and Systems, San Diego, USA, October 29-November 2, 2007.
6. Behl M, DuBro J, Flynt T, et al. Autonomous electric vehicle charging system. The 2019 Systems and In formation Engineering Design Symposium (SIEDS), Charlottesville, USA, April 26, 2019.
7. Liljeback P, Stavdahl O, Beitnes A, et al. Develop ment of a water hydraulic fire fighting snake robot. The 9th International Conference on Control, Automa tion, Robotics and Vision, Singapore, December 5-8, 2006.
8. Transeth A A, Liljebäck P, Pettersen K Y. Snake robot obstacle aided locomotion: an experimental validation of a non-smooth modeling approach. The 2007 IEEE/ RSJ International Conference on Intelligent Robots and Systems, California, USA, October 29-November 2, 2007.
9. Liljeback P, Pettersen K Y, Stavdahl O. A snake robot with a contact force measurement system for obstacle aided locomotion. The 2010 IEEE International Conference on Robotics and Automation(ICRA2010), Anchorage, USA, May 3-7, 2010.
10. Cui X S, Yan G Z, Chen Y, et al. Research on a miniature snake-like robot prototype. Robots, 1999 (02): 3-5.
11. Xu M, Zou Y. Design of a closed-loop control system for a snake-like robot. Journal of Xiamen University of Technology, 2008 (03): 30-34.
12. Li D F, Yang H S, Deng H B, et al. Adaptive trajectory-tracking controller for tracking-error prediction of snake robots. Chinese Journal of Scientific Instrument, 2021 (011): 042.
13. Wen J, Ji P P. Implementation of sliding mode control for 6-PTRT parallel mechanism based on synchronization error. Journal of Changchun Normal University, 2021, 40 (2): 6.
14. Lei Y X. A rigid-flexible composite soft-finger module and a mechanical gripper integrated with this module: CN201921239626.2 [P]. CN210704868U [2024-04-12].
15. Tian J Z. Virtual assembly and dynamic simulation motion of planetary gear drive with small tooth difference. Shanxi Science and Technology, 2016 (5): 3.
16. Zhou H Y. Research on measurement and error evaluation technologies of straight bevel gears. Harbin Institute of Technology, 2008.
17. Zhang X F. Prediction of fatigue life and research on load balance of wheel-side reducer gears. Jilin University, 2012.
18. Liu M F. Design and analysis of planetary gear drive with small tooth difference for electric valve actuators based on Romax Designer. Wuhan University of Science and Technology, 2024.
19. Jiang Y G. Finite element analysis of spiral bevel gears based on precise tooth-surface modeling. Zhejiang University, 2011.
20. Mao X. Drop simulation and experimental verification of IP-telephony light pipes. Shanghai Jiao Tong University, 2024.
21. Li D F, Deng H B, Xiu Y. Global research progress and key technologies of multi-joint snake robots. Unmanned System Technology, 2023,6 (05): 50-60.
Copyright (c) 2024 Zhimin Yan, Jinbo Li, Jianyang Liu, Chaoyi Li, Xiaoxin Zhang
This work is licensed under a Creative Commons Attribution 4.0 International License.
Copyright on all articles published in this journal is retained by the author(s), while the author(s) grant the publisher as the original publisher to publish the article.
Articles published in this journal are licensed under a Creative Commons Attribution 4.0 International, which means they can be shared, adapted and distributed provided that the original published version is cited.
Submit a Paper
