Journal of Korean Society for Quality Management (품질경영학회지)

Korean Society for Quality Management (한국품질경영학회)
권호 표지
DOI QR코드

DOI QR Code

A Case Study on Configuration Change for Preventing Propulsion Wire Fracture and Structural Deformation of Launch System of UAV

무인기용 발사장비의 추진와이어 파단 및 구조변형 방지를 위한 형상변경 사례

  • Received : 2022.08.03
  • Accepted : 2022.09.02
  • Published : 2022.09.30
Download PDF
⟨ Previous Next ⟩

Abstract

Purpose: The purpose of this study is to identify and resolve the causes of defects in the unmanned aerial vehicle launch system(propulsion wire fracture, rear rail deformation) and to prevent recurrence. Methods: The causes of the two defects were derived through fault tree analysis for each of the two defects and fault reproduction tests. In the case of propulsion wire, the installation of a high speed camera to check the behavior of wire was the driving force behind the defect resolution. Results: The results of this study are as follows; It was determined that the thickness of the washer was less than the maximum tolerance of the pulley was the cause of the propulsion wire fracture defect. Failure to comply with the launch procedure and insufficient safety margin were judged as the cause of the rear rail deformation defect. Accordingly, the configuration was changed to remove each defect. Conclusion: The case of this study was conducted to eliminate defects in the launch system for UAV. The causes of defects were estimated through fault tree analysis. After the configuration change, Structural analysis and launch tests were performed to demonstrate the safety and effectiveness of the modified configuration. As a result, the effect of the modified configuration was verified.

Keywords

References

  1. Arjomandi, Maziar, et al. 2006. Classification of unmanned aerial vehicles. Report for Mechanical Engineering class, University of Adelaide, Adelaide, Australia:1-48.
  2. Choi, Jae won. 2014. The research and development trends of UAV(Korean). Defense and Technology 424:104-113.
  3. Elsevier Masson SAS. 1999. UAVs: Launch and recovery. Air & Space Europe 1(5-6):59-62. https://doi.org/10.1016/S1290-0958(00)88872-3
  4. Jang, Jin-Seok. 1999. Characteristics of the development trend of UAV(korean). The Journal of Aerospace Industry 62-71.
  5. Kim, Gyou-Beom, Cho, In-Je, and Seo, Il-Soo. 2021. Analysis of Domestic and Foreign Military UAV Development Trends and Suggestions for Countermeasures Against North Korea UAVs. Journal of Convergence for Information Technology 11(12): 97-105. https://doi.org/10.22156/CS4SMB.2021.11.12.097
  6. Novakovic, Zoran and Nikola Medar. 2013. Analysis of a UAV bungee cord launching device. Scientific Technical Review 63(3):41-47.
  7. Novakovic, Zoran, et al. 2016. Integration of tactical-medium range UAV and catapult launch system. Scientific Technical Review 66(4):22-28. https://doi.org/10.5937/STR1604022N
  8. Novakovic, Zoran, Nikola Medar, and Lidija Mitrovic. 2014. Increasing launch capability of a UAV bungee catapult. Scientific Technical Review 64(4):17-26.
  9. SSibilska-Mroziewicz, Anna, and Edyta Ladyzynska-Kozdras. 2018. Mathematical model of levitating cart of magnetic UAV catapult. Journal of Theoretical and Applied Mechanics 56(3):793-802. https://doi.org/10.15632/jtam-pl.56.3.793
  10. STANAG-4671.
  11. Winnefeld, James A. and Frank Kendall. 2011. Unmanned systems integrated roadmap FY 2011-2036. US Department of Defense.