DESIGN AND SIMULATION OF A COMPACT LINE INSPECTION ROBOT

Authors

  • Mark James Ferrer Department of Mechanical Engineering, Gokongwei College of Engineering, De La Salle University, Manila, Philippines
  • Jeongrok Lee Department of Mechanical Engineering, Gokongwei College of Engineering, De La Salle University, Manila, Philippines
  • Marc Heinz Linsangan Department of Mechanical Engineering, Gokongwei College of Engineering, De La Salle University, Manila, Philippines
  • Nygel Gian Santillan Department of Mechanical Engineering, Gokongwei College of Engineering, De La Salle University, Manila, Philippines
  • Matthew Sybingco Department of Mechanical Engineering, Gokongwei College of Engineering, De La Salle University, Manila, Philippines
  • Alvin Chua Department of Mechanical Engineering, Gokongwei College of Engineering, De La Salle University, Manila, Philippines

DOI:

https://doi.org/10.11113/aej.v14.20803

Keywords:

Clamshell design, Wire-riding robot, Motion analysis, Stress analysis, 3D printing

Abstract

Power line inspection is a rather risky and complex task. As a result, robots have been introduced that perform power line inspections with minimal human interaction with the power line itself. Most current designs, however, are unsuited for use in residential powerlines due to their architecture. The study aims to present a compact and lightweight design capable of inspecting residential power lines using a clamshell design. Several elements of the design were designed with the premise that these would be 3D printed to reduce weight and save costs. The study focused on designing several chassis models and different wheel designs. These were run through software such as ANSYS and SOLIDWORKS to determine their structural integrity and ability to traverse the power line respectively. After running tests, it was found that a thin rectangular chassis design with U-type grooved wheels yielded the best results in terms of overall performance, with the highest equivalent stress of 6.484e5 Pa for the individual top chassis and a highest equivalent stress of 3.363e6 Pa found in the wheel axel when an assembly simulation was performed. This resulted in a safety factor of 15 in the stress simulations. Stable behavior was observed in the motion analysis, indicating that the design was feasible for performing an inspection. The design was then modified to reduce print time along with incorporating a specific print setting that yielded a total print time of just over 1 day and an equivalent mass of under 1.5 kg with no relative effect on the structural integrity and stability of the robot.

References

Huawei. 2023. Intelligent Transmission Line Inspection Solution. [Online] Available: https://e.huawei.com/en/industries/grid/power-grid/transmission-line-intelligent-inspection. Accessed May 2023.

D. J. Friedman, 2014. “Electrical Safety Hazards and Safe Electrical Inspection Procedures for Electrical Inspectors & Home Inspectors. ”https://inspectapedia.com/electric/Electrical_Inspector_Safety.php (accessed Oct. 16, 2022).

Power Magazine, 2020 “The past, present, and future of Powerline Inspection Automation,” Sep. 18, 2020. https://www.powermag.com/the-past-present-and-future-of-powerline-inspection-automation/ (accessed Oct. 16, 2022).

S. Hrabar, T. Merz, and D. Frousheger, 2010. “Development of an autonomous helicopter for aerial powerline inspections,” in 2010 1st International Conference on Applied Robotics for the Power Industry, CARPI 2010, doi: 10.1109/CARPI.2010.5624432.

W. Chang, G. Yang, J. Yu, Z. Liang, L. Cheng, and C. Zhou. 2017. Development of a Power Line Inspection Robot with Hybrid Operation Modes. International Conference on Intelligent Robots and Systems. Vancouver: IEEE. doi: 10.1109/IROS.2017.8202263.

A. Fonseca, R. Abdo, and J. Alberto. 2012. Robot for inspection of transmission lines. 2nd International Conference on Applied Robotics for the Power Industry. Zurich: EEE Computer Society. 83–87. doi: 10.1109/CARPI.2012.6473356.

M. A. Gulzar, M. Sharif, K. Kumar, and M. A. Javed. 2018. High-Voltage Transmission Line Inspection Robot. 2018 International Conference on Engineering and Emerging Technologies (ICEET). Lahore: IEEE. doi: 10.1109/ICEET1.2018.8338632.

D. Yang, Z. Feng, X. Ren, and N. Lu. 2014. A novel power line inspection robot with dual-parallelogram architecture and its vibration suppression control. Advanced Robotics. 28(12): 807–819. doi: 10.1080/01691864.2014.884936.

P. Debenest and M. Guarnieri. 2010. Expliner - From prototype towards a practical robot for inspection of high-voltage lines. 1st International Conference on Applied Robotics for the Power Industry. Montreal: IEEE. Doi: 10.1109/CARPI.2010.5624434.Conference on Applied Robotics for the Power Industry, CARPI 2010, 2010. doi: 10.1109/CARPI.2010.5624434.

Y. G. Wang, H. D. Yu, and J. K. Xu. 2014. Design and simulation on inspection robot for high-voltage transmission lines. Applied Mechanics and Materials. 615: 173–180. doi: 10.4028/www.scientific.net/AMM.615.173.

droneblog. 2020. How Long Does a Drone Battery Last? What You Need to Know! [Online] Available: https://www.droneblog.com/how-long-does a-dronebattery-last-what-you-need-to- know/#:~:text=The%20typical%20flight%20time%20for,between%2020%20to%2030%20minutes. Accessed April 2023.

A. H. Ali, S. M. H. Kazmi, H. A. Poonja, H. Khan, M. A. Shirazi, and R. Uddin. 2022. Motor Parametric Calculations for Robot Locomotion. Engineering Proceedings. 20(1): 1–5, doi: 10.3390/engproc2022020008.

R. Kurtus. 2016. Coefficient of Rolling Friction. [Online] Available: https://www.school for champions.com/science/friction_rolling_coefficient.htm#.ZDd_yHZBy3A. Accessed April 2023.

M. K. Gönüllü. 2013. Development of a Mobile Robot Platform to Be Used in Mobile Robot Research. Middle East Technical University. 1: 16–18.

Handson Technology. 2019. 3420 Dual Ball Bearing Long Life DC Motor. [Online] Available: https://handsontec.com/dataspecs/motor_fan/XD3420-Motor.pdf. Accessed June 2023.

Newport Vessels. 2021. Trolling Motor Run Time: How to Calculate Run Time. [Online] Available: https://newportvessels.com/blogs/resource/calculate-motor-run-time#:~:text=Motor%20amperage%20draw%20describes%20how,it%20by%20the%20amperage%20draw. Accessed April 2023.

S. Thornton. 2020. Microcontroller power source considerations for Arduino. [Online] Available: https://www.eeworldonline.com/microcontroller-power-source-considerations-arduino/. Accessed April 2023.

LiitoKala. 2019. Lii-35A. [Online] Available: http://www.liito-kala.com/page92?product_id=13. Accessed June 2023.

Philflex. 2020. Service Drop Cable (Triplex). [Online] Available: https://www.philflex.com/_files/ugd/8be76e_909372397733428ea8349900634c3b74.pdf. Accessed November 2022.

McMaster-Carr. 2020. Round-Belt Pulleys. [Online] Available: https://www.mcmaster.com/pulleys/for belt type~round/. Accessed April 2023.

D. Nedelkovski. 2019. DIY Arduino RC Transmitter. [Online] Available: https://howtomechatronics.com/projects/diy-arduino-rc -transmitter/. Accessed June 2023.

D. Nedelkovski. 2020. DIY Arduino RC Receiver for RC Models and Arduino Projects. [Online] Available: https://howtomechatronics.com/projects/diy arduino rc receiver/. Accessed June 2023.

GoPro. 2022. HERO11 Black. [Online] Available: https://gopro.com/en/us/shop/cameras/hero11-black/CHDHX-111-master.html. Accessed September 2022.

Downloads

Published

2024-11-30

Issue

Vol. 14 No. 4: December 2024

Section

Articles

How to Cite

DESIGN AND SIMULATION OF A COMPACT LINE INSPECTION ROBOT. (2024). ASEAN Engineering Journal, 14(4), 27-35. https://doi.org/10.11113/aej.v14.20803