Journal of the Society of Naval Architects of Korea (대한조선학회논문집)

The Society of Naval Architects of Korea (대한조선학회)
권호 표지
DOI QR코드

DOI QR Code

Automation of Simplified Evacuation Analysis for Calculating Required Evacuation Time

승객 탈출 시간 계산을 위한 Simplified Evacuation Analysis 자동화

  • Ki-Su Kim (School of Naval Architecture and Ocean Engineering, University of Ulsan)
  • 김기수 (울산대학교 조선해양공학부)
  • Received : 2024.07.29
  • Accepted : 2024.08.30
  • Published : 2024.10.20
Download PDF
⟨ Previous Next ⟩

Abstract

The International Maritime Organization (IMO) mandates that evacuation analysis must be performed at the design stage to ensure the safety of passengers aboard ships. Therefore, ship designers are required to conduct this evacuation analysis during the ship design process. Evacuation analysis begins with creating an escape diagram that outlines the routes from each cabin to the designated assembly stations based on the designed plans. Subsequently, necessary parameters for escape analysis are measured and recorded, and the analysis is conducted using an Excel-based program. This process is manual and time-consuming. Additionally, due to the frequent design changes characteristic of passenger ships, this process must be repeated multiple times. Hence, this study proposes a method to automate this analysis process. The proposed method in this study starts with a preprocessing step to extract key components from 2D drawings. Following this, it distinguishes spaces such as cabins, corridors, and doors within the processed drawings. Using the identified spaces, it then searches for the shortest evacuation routes from each cabin to the assembly station. Based on the identified routes, the method automatically performs the simplified evacuation analysis as prescribed by IMO regulations. Applying the algorithm for automated escape analysis to Ro-Pax vessels demonstrated that the analysis time per ship, which previously took about 15 days, can be reduced to less than 10 minutes.

Keywords

Acknowledgement

본 연구는 울산대학교와 2024년도 교육부의 재원으로 한국연구재단의 지원을 받아 수행된 지자체-대학 협력기반 지역혁신 사업의 결과임을 밝히며, 이에 감사드립니다(2021RIS-003).

References

  1. Delling, D., Sanders, P., Schultes, D. and Wagner, D., 2009. Engineering Route Planning Algorithms. Springer.
  2. Ha, S., Ku, N.K., Roh, M.I. and Lee, K.Y., 2012. Cell-based evacuation simulation considering human behavior in a passenger ship. Ocean Engineering, 53, pp.138-152.
  3. Harris, C. and Stephens, M., 1988. A combind corner and edge detector. Proceedings of the Alvey Vision Conference 1988, Manchester, United Kingdom, September 1988.
  4. IMO, 1999. Interim guidelines for a simplified evacuation analysis on RO-RO passenger ships. MSC/Circ.909.
  5. IMO, 2002. Interim guidelines for evacuation analysis for new and existing passenger ships. MSC/Circ.1033.
  6. IMO, 2007. Guidelines for evacuation analysis for new and existing passenger ships. MSC/Circ.1238.
  7. IMO, 2016. Revised guidelines for evacuation analysis for new and existing passenger ships. MSC/Circ.1533.
  8. Kim, H., Roh, M.I. and Han, S,, 2019. Passenger evacuation simulation considering the heeling angle change during sinking. International Journal of Naval Architecture and Ocean Engineering, 11(1), pp.329-343.
  9. Prim, R., 1957. Shortest connection networks and some generalizations. Bell System Technical Journal, 36(6), pp.1389-1401.
  10. Serra, J., 1982. Image analysis and mathematical morphology. Academic Press, Inc.