A method for risk analysis of ship collisions with stationary infrastructure using AIS data and a ship manoeuvring simulator
2021 (English)In: Ocean Engineering, ISSN 0029-8018, E-ISSN 1873-5258, Vol. 235, article id 109396Article in journal (Refereed) Published
Abstract [en]
The study presents a methodology that uses AIS data and a ship manoeuvring simulator to simulate and analyse marine traffic schemes with regard to risks for accidents. An event identification method is presented, which is needed for the accident scenario part of the methodology. This is based on AIS data, where the Great Belt VTS area was used to verify the methodology. Three events that could result in ship-bridge allisions were modelled and simulated in the simulator: drifting ship, sharp turning ship and miss of turning point. The Monte Carlo method was used to perform large number of simulator runs, including a parameter sensitivity analysis. The probability of a ship allision against the Great Belt Bridge was calculated to be 0.007. Analysis of the ship-bridge allision cases was shown to be dominated by the event drifting ship. This event has a relatively low kinetic energy at the impact, and the expected allision energy for a 1,000-year allision corresponds to a 178 m tanker with 57,870 DWT and ship speed 14.6 knots. Finally, this study presents a mitigation analysis, which shows how the probability of allisions can be reduced by reducing the ship speed or altering the traffic separation scheme. © 2021 The Authors
Place, publisher, year, edition, pages
Elsevier Ltd , 2021. Vol. 235, article id 109396
Keywords [en]
AIS analysis, Allision energy, Event identification, Ship grounding, Ship manoeuvring simulator, Ship-bridge allision, Accidents, Kinetic energy, Kinetics, Monte Carlo methods, Risk analysis, Risk assessment, Sensitivity analysis, Simulators, AIS analyse, Energy, Ship collision, Ship maneuvering, Ship maneuvering simulator, Ship speed, Ships, bridge, collision avoidance, Monte Carlo analysis, navigation aid, ship handling, ship motion, tracking, transportation infrastructure
National Category
Vehicle and Aerospace Engineering
Identifiers
URN: urn:nbn:se:ri:diva-57267DOI: 10.1016/j.oceaneng.2021.109396Scopus ID: 2-s2.0-85109021547OAI: oai:DiVA.org:ri-57267DiVA, id: diva2:1619244
Note
Funding details: HHI-133; Funding details: 2016-04767; Funding details: Interreg; Funding details: Statens vegvesen; Funding text 1: The authors acknowledge the financial support from the Norwegian Public Roads Administration , The Hugo Hammar Foundation (Grant no. HHI-133 ), the Swedish Innovation Agency (Vinnova Grant no. 2016-04767 ) and the EU Interreg Öresund-Kattegat-Skagerrak project MARIA. The authors acknowledge the maintainers of the open source language Python and the packages available at www.pypi.org .; Funding text 2: The authors acknowledge the financial support from the Norwegian Public Roads Administration, The Hugo Hammar Foundation (Grant no. HHI-133), the Swedish Innovation Agency (Vinnova Grant no. 2016-04767) and the EU Interreg ?resund-Kattegat-Skagerrak project MARIA. The authors acknowledge the maintainers of the open source language Python and the packages available at www.pypi.org.
2021-12-132021-12-132025-09-23Bibliographically approved