GIS 기반 철도 위험물 최적수송경로도출 표준화에 관한 연구

A Study on Standardization of Optimum Transportation Routing based on GIS for Railway HAZMAT Transportation

  • 팽정광 (서울산업대학교 철도경영정책학과) ;
  • 김시곤 (서울산업대학교 철도경영정책학과) ;
  • 박민규 (서울산업대학교 철도경영정책학과) ;
  • 강승필 (서울대학교 건설환경공학부)
  • Paeng, Jung-Goang (Department of Railroad Management & Policy, Seoul National University of Technology) ;
  • Kim, Si-Gon (Department of Railroad Management & Policy, Seoul National University of Technology) ;
  • Park, Min-Kyu (Department of Railroad Management & Policy, Seoul National University of Technology) ;
  • Kang, Seung-Pil (Department of Civil & Environmental Engineering Seoul National University)
  • 투고 : 2009.10.09
  • 심사 : 2009.10.20
  • 발행 : 2009.12.30

초록

The types and quantities of Hazmat and Hazmat transportation are gradually increasing, keeping pace with industrialization and urbanization. At present the safety management for Hazmat transportation only considers reducing accident probability, but even when an accident involving Hazmat-carrying vehicles occurs, that is not regarded as a Hazmat-related accident if the Hazmats do not leak out from the containers carrying them. Thus the methods to reduce risk (Risk=Probability$\times$Consequence) have to be developed by incorporating accident probability and consequence. By using Geographic Information System (GIS), a technical method is invented and is automatically able to evaluate the consequence by different types of Hazmat. Thus this study analyzed the degree of risk on the links classified by the Hazmat transport pathways. In order to mitigate the degree of risk, a method of 7-step risk management on Hazmat transportation in railway industries can be suggested. (1st step: building up GIS DB, 2nd step: calculating accident probability on each link, 3rd step: calculating consequence by Hazmat types, 4th step: determination of risk, 5th step: analysis of alternative plans for mitigating the risk, 6th: measure of effectiveness against each alternative, and 7th step: action plans to be weak probability and consequence by the range recommended from ALARP). In conclusion, those 7 steps are used as a standardization method of optimum transportation routing. And to increase the efficiency of optimum transportation routing, optional route can be revise by verification.

키워드

참고문헌

  1. Manish Verma, Vedat Verter, 'Railroad transportation of dangerous goods: Population exposure to airborne toxins', Computers & operations research(2007) https://doi.org/10.1016/j.cor.2005.06.013
  2. Hobeika, A. G. and Kim, Sigon 'Databases and Needs for Risk Assessment of Hazardous Materials Shipments by Truck, Transportation of Hazardous Materials', (1993) : 153
  3. Kim, Sigon, 'Development of Risk Assessment Decision Support System for Hazardous Materials Movement, Virginia Tech:', (1990)
  4. 국토해양부, 보도자료(2009)
  5. Kim, sigon and Ahn, S. 'GIS based Hazardous Materials Transportation Management System: A case Study for Ulsan City', Journal of transportation research society of Korea. (1999)
  6. US Dot, Highway Routing of Hazardous Materials, Guidelines for Applying Criteria
  7. Cadland, 'Workingwith the ArcviewSpatial Analyst', (2003)
  8. 조성훈, 서선덕, 권경숙, '건널목 개선사업 효과의 계량적 평가 방법의 적용', 한국철도학회, (2004)
  9. 김영호, '로스앤젤레스 알라미다코리도 사업의 편익.비용분석2', (2002), KINX10110317
  10. 신덕호, 이재호, 이강미, 황종규, 정의진, 왕종배, 박영수, '열차제어시스템의 안전입증에 관한 연구, 한국철도학회논문집(2006) 제9권 제4호, 한국철도학회
  11. 건설교통부, '철도안전종합계획', (2006)
  12. 건설교통부, '교통안전연차보고서', (2007)
  13. 건설교통부, '교통안전시행계획', (2006)