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Development of a compact sewerage robot with multi-DOF cutting tool

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Abstract

This research is about development of the in-pipe robot for heavy duties, such as repairing and maintenance tasks, by focusing on the sewers between households or businesses to the main sewers. The robot is expected to work instead of workers to help them work easier and safer, such as in small pipe that the workers cannot access or dirty and dangerous environment that can affect to the health and life of the workers. The most conventional robots in the past were mainly designed for survey and inspection. While some robots focus on maintenance task, but their robots are not available for small pipe and their manipulator have a few DOF. Then, we propose a compact in-pipe robot with multi-DOF cutting tool (CIPbot-1) for the target pipes between 150 and 300 mm in diameter to enhance the ability of these kind of robot. The difficulties of development this robot is the space limitation caused by the smallest target pipe which affects to the mechanism design, and the rigidity of robot’s structure. The expandable mechanisms must be able to adjust the diameter of the robot about 2 times to fit with the smallest and the biggest target pipes. The proposed robot mainly consists of a locomotion section (adjustable folding mechanism and six-crawlers, each of them is driven by only one motor) and a manipulator Sect. (3-DOF manipulator with a cutting tool and a camera system for inspection). The prototype of CIPbot-1 was made and confirmed the mobility, the ability, and the usefulness by the experimentations.

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References

  1. Li Z, Zhu J, He C, et al. (2009) A new pipe cleaning and inspection robot with active pipe-diameter adaptability based on ATmega64. The 9 Int. Conf. on Electronic Measurement and Instruments, pp.616–619.

  2. Waleed D, Mustafa SH, Mukhopadhyay S et al (2019) An in-pipe leak detection robot with a neural-network-based leak verification system. IEEE Sens J 19(3):1153–1165

    Article  Google Scholar 

  3. Carrigan TD, Forrest BE, Andem HN et al (2019) Nondestructive testing of nonmetallic pipelines using microwave reflectometry on an in-line inspection robot. IEEE Trans Instrument Measure 68(2):586–594

    Article  Google Scholar 

  4. Song Z, Ren H, Zhang J et al (2016) Kinematic analysis and motion control of wheeled mobile robots in cylindrical workspaces. IEEE Trans Sci Eng 13(2):1207–1214

    Article  Google Scholar 

  5. Nagaya K, Yoshino T, Katayama M et al (2012) Wireless piping inspection vehicle using magnetic adsorption force. IEEE ASME Trans Mech 17(03):472–479

    Article  Google Scholar 

  6. Kim S, Kim CH, Bae YG, et al (2013) NDT inspection mobile robot with spiral driven mechanism in pipes. IEEE ISR Conf.

  7. Nakagawa K, Dohta S, Akagi T, et al (2017), Improvement of pipe holding mechanism for pipe inspection robot using flexible pneumatic cylinder. Int. Conf. on Robotics and Automation Sciences, pp.6–10.

  8. Takayama T, Takeshima H, Hori T et al (2015) A twisted bundled tube locomotive device proposed for in-pipe mobile robot. IEEE ASME Trans Mech 20(6):2915–2923

    Article  Google Scholar 

  9. Savin S, Vorochaeva L (2017), Footstep Planning for a Six-Legged in-Pipe Robot Moving in Spatially Curved Pipes. Int. Siberian Conf. on Control and Communications.

  10. Lim HO, Ohki T (2009) Development of Pipe Inspection Robot. Int. Joint Conf. ICROS-SICE. pp. 5717-5721.

  11. Kakogawa A, Oka Y, Ma S (2018) Multi-link articulated wheeled in-pipe robot with underactuated twisting joints. Proc. of IEEE Int. Conf. on Mechatronics and Automation, pp.942–947.

  12. Kakogawa A, Nishimura T, Ma S (2013) Development of a screw drive in-pipe robot for passing through bent and branch pipes. IEEE ISR Conf.

  13. Kim HM, Choi YS, Lee YG et al (2017) Novel mechanism for in-pipe robot based on a multiaxial differential gear mechanism. IEEE ASME Trans Mech 22(1):227–236

    Article  Google Scholar 

  14. Roh SG, Choi HR (2005) Differential-drive in-pipe robot for moving inside urban gas pipelines. IEEE Trans Robotics 21:1

    Article  Google Scholar 

  15. Kim SH, Lee SJ, Kim SW (2018) Weaving laser vision system for navigation of mobile robots in pipeline structures. IEEE Sens J 18(6):2585–2591

    Article  Google Scholar 

  16. Park J, Hyun D, Cho WH et al (2011) Normal-force control for an in-pipe robot according to the inclination of pipelines. IEEE Trans Ind Electron 58(12):5304–5310

    Article  Google Scholar 

  17. Sato K, Ohki T, Lim HO (2011) Development of in-pipe robot capable of coping with various diameters. 11th Int. Conf. on control, automation and systems, pp. 1076–1081.

  18. Kim YG, Shin DH, Moon JI, et al (2011) Design and implementation of an optimal in-pipe navigation mechanism for a steel pipe cleaning robot. 8th Int. Conf. on Ubiquitous Robots and Ambient Intelligence, pp.772–773.

  19. Kwon YS, Yi BJ (2012) Design and motion planning of a two-module collaborative indoor pipeline inspection robot. IEEE Trans Robotics 28(3):681–696

    Article  Google Scholar 

  20. Kakogawa A, Ma S, Hirose S (2014) An in-pipe robot with underactuated parallelogram crawler modules. IEEE Int. Conf. on robotics and automation, pp. 1687–1692.

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Correspondence to Thaelasutt Tugeumwolachot.

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This work was presented in part at the 26th International Symposium on Artificial Life and Robotics (Online, January 21-23, 2021).

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Tugeumwolachot, T., Seki, H., Tsuji, T. et al. Development of a compact sewerage robot with multi-DOF cutting tool. Artif Life Robotics 26, 404–411 (2021). https://doi.org/10.1007/s10015-021-00694-y

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  • DOI: https://doi.org/10.1007/s10015-021-00694-y

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