Journal of the Korea Society for Simulation (한국시뮬레이션학회논문지)

The Korea Society for Simulation (한국시뮬레이션학회)
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Dynamic Simulation of Rail Strain and Vibration Changes According to Track Irregularity

선로 궤도틀림에 따른 레일 변형률과 진동 변화 동역학 시뮬레이션

  • Received : 2021.02.17
  • Accepted : 2021.03.13
  • Published : 2021.03.31
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Abstract

The method of utilizing the strain and vibration values of rails is primarily used to diagnose the condition of wheels and railroad facilities. The dynamic load is measured under the assumption that the strain of the rail and the load of the railroad vehicle are proportional. Wheel condition is measured under the assumption that the magnitude of the defect and the magnitude of the rail vibration are proportional. However, environmental factors affecting the strain and vibration of the rail such as vehicle speed, wheel load, climate, and track conditions are not reflected, many errors occur depending on the measurement conditions. In this study, the effect of track distortion, which is a major indicator of the track condition among the environmental factors that affect the strain and vibration of the rail, on the strain and vibration of the rail, was examined through dynamic simulation. As a measure to reduce the measurement deviation, the effect of securing additional measurement points was analyzed.

철도시설물 안전 확보를 위한 동하중 관리 및 철도차량 유지보수 효율화를 위한 차륜 상태진단을 위해 레일의 변형률과 진동 값을 이용하는 방법이 주로 사용된다. 동하중은 레일의 변형률과 철도차량 하중이 비례한다는 가정을 바탕으로 측정이 이루어지며 차륜 상태는 결함의 크기와 레일 접촉진동의 크기가 비례한다는 가정을 통해 진단이 이루어진다. 하지만 차량 속도, 차륜 하중, 기후, 선로 상태와 같이 레일의 변형률과 진동에 영향을 주는 환경요소를 반영하지 않으면 측정 조건에 따라 많은 편차가 발생한다. 본 연구에서는 레일의 변형률과 진동에 영향을 주는 환경요소 중 선로 상태를 나타내는 주요 지표인 궤도틀림이 레일의 변형률과 진동에 미치는 영향을 동역학 시뮬레이션을 통해 살펴보고 측정 편차를 줄이기 위한 방안으로 측정지점 추가 확보에 따른 효과를 분석하였다.

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References

  1. Park, S.M., Yeo, I.H, Paik, I.Y. (2015), Analysis of design live load of railway bridge through statistical analysis of WIM data for high-speed Rail, Journal of computational structural engineering instute of Korea, 28(6), pp. 589-597. https://doi.org/10.7734/COSEIK.2015.28.6.589
  2. Kim, H.M., Kim, S.I., Kim, T.H. (2009), Development & application of RWIM(Railroad Weigh In Motion) system for measuring train load, 2009 Autumn conference of the Korean society for railway, pp. 1878-1885.
  3. Kang, B.B. (2017), Dynamic analysis of the influence of the track irregularity on the running performance of the railway vehicle, Korean society for precision engineering, 34(12), pp. 881-887. https://doi.org/10.7736/KSPE.2017.34.12.881
  4. Kim, S.Y. (2010), An identification of track irregularity by analyzing dynamic characteristics of a train, 2010 Spring conference of the Korean society for railway, pp. 2095-2106.
  5. Korea national railway, Track maintenance guidelines (2020), pp. 74.
  6. Lee, B.W., Yeom, H.J., Park, Y.G. (2018), Inspection and maintenance of track irregularity in concrete track, Journal of the Korean society for railway, 21(8), pp. 774-785. https://doi.org/10.7782/jksr.2018.21.8.774
  7. Oh, K.C., Yang, H.S., Choi, I.Y., Lee, S.J., Bae, B.W. (2014), Study on integrated operation system for high speed track inspection, 2014 Spring conference of the Korean society for railway, pp. 1000-1005.
  8. Jang, S.H., Lee, S.I. (2006), Numerical simulation of dynamic behaviour of a gauge-changeable freight wagon, Journal of the Korean society for railway, 9(4), pp. 461-466.
  9. Lee, S.I., Choi, Y.S. (2003), Analysis on the snake motion of one freight car for high speed running, Journal of the Korean society for railway, 6(3), pp. 149-155.
  10. Hur, H.M., Kwon, S.T. (2005), Analysis on the influence of wheel/rail geometric parameters on the equivalent conicity, Journal of the Korean society for railway, 8(5), pp. 490-494.
  11. Park, S.E., Park, M.H., Kwon, M.H. (2006), Nonlinear finite element analysis of reinforced concrete column using timoshenko beam Theory and fiber section model, Korean society of civil enginners, 26(4A), pp. 577-585.