Use of HFACS and fault tree model for collision risk factors analysis of icebreaker assistance in ice-covered waters

[Display omitted] •Collision accidents between icebreaker and assisted ship in ice-covered waters are investigated.•The collision risk factors are identified and classified according to HFACS-SIBCI model.•The fault tree model is proposed to analyze collision risk factors under icebreaker assistance....

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Veröffentlicht in:	Safety science 2019-01, Vol.111, p.128-143
Hauptverfasser:	Zhang, Mingyang, Zhang, Di, Goerlandt, Floris, Yan, Xinping, Kujala, Pentti
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Sprache:	eng
Schlagworte:	Accidents Arctic shipping Climate change Collision accidents Collisions Fault tree analysis FTA Global warming Hazards HFACS Human factors Ice Ice cover Ice environments Icebreakers Judgments Organizational aspects Qualitative analysis Qualitative research Risk analysis Risk factors Risk management Sailing Sea ice Ship to icebreaker Shipping Statistical analysis Water
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container_title	Safety science
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creator	Zhang, Mingyang Zhang, Di Goerlandt, Floris Yan, Xinping Kujala, Pentti
description	[Display omitted] •Collision accidents between icebreaker and assisted ship in ice-covered waters are investigated.•The collision risk factors are identified and classified according to HFACS-SIBCI model.•The fault tree model is proposed to analyze collision risk factors under icebreaker assistance.•Risk Control Options (RCOs) are formulated to prevent collision accident occurrence in ice-covered waters. With the global warming and a large amount of sea ice melting, the available Arctic Sea Route has greatly enhanced the value of Arctic shipping. Ship operations under icebreaker assistance have become an essential way to facilitate the safe navigation of merchant vessels sailing through the Arctic Sea Route in ice-covered waters, but they can also put the crew and the ship in danger caused by a possible collision between the assisted ship and the icebreaker. In this paper, a dedicated Human and Organizational Factors (HoFs) model of ship collision accidents between an assisted ship and an icebreaker is developed and analyzed with the aim to identify and classify collision risk factors. First, a modified model of the Human Factors Analysis and Classification System (HFACS) for collision accidents between a ship and an icebreaker in ice-covered waters is proposed, which helps to analyze ship collision reports. Then, a Fault Tree Analysis (FTA) model is utilized to analyze the fundamental collision risk factors according to the statistical analysis of accident reports and expert judgments based on the HFACS-SIBCI model. Finally, qualitative analysis is carried out to analyze collision risk factors under icebreaker assistance, where Risk Control Options (RCOs) are formulated. An important guidance for the risk control of ship collisions during icebreaker assistance in ice-covered waters is provided for lawmakers and shipping companies.
doi_str_mv	10.1016/j.ssci.2018.07.002
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With the global warming and a large amount of sea ice melting, the available Arctic Sea Route has greatly enhanced the value of Arctic shipping. Ship operations under icebreaker assistance have become an essential way to facilitate the safe navigation of merchant vessels sailing through the Arctic Sea Route in ice-covered waters, but they can also put the crew and the ship in danger caused by a possible collision between the assisted ship and the icebreaker. In this paper, a dedicated Human and Organizational Factors (HoFs) model of ship collision accidents between an assisted ship and an icebreaker is developed and analyzed with the aim to identify and classify collision risk factors. First, a modified model of the Human Factors Analysis and Classification System (HFACS) for collision accidents between a ship and an icebreaker in ice-covered waters is proposed, which helps to analyze ship collision reports. Then, a Fault Tree Analysis (FTA) model is utilized to analyze the fundamental collision risk factors according to the statistical analysis of accident reports and expert judgments based on the HFACS-SIBCI model. Finally, qualitative analysis is carried out to analyze collision risk factors under icebreaker assistance, where Risk Control Options (RCOs) are formulated. 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With the global warming and a large amount of sea ice melting, the available Arctic Sea Route has greatly enhanced the value of Arctic shipping. Ship operations under icebreaker assistance have become an essential way to facilitate the safe navigation of merchant vessels sailing through the Arctic Sea Route in ice-covered waters, but they can also put the crew and the ship in danger caused by a possible collision between the assisted ship and the icebreaker. In this paper, a dedicated Human and Organizational Factors (HoFs) model of ship collision accidents between an assisted ship and an icebreaker is developed and analyzed with the aim to identify and classify collision risk factors. First, a modified model of the Human Factors Analysis and Classification System (HFACS) for collision accidents between a ship and an icebreaker in ice-covered waters is proposed, which helps to analyze ship collision reports. 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subjects	Accidents Arctic shipping Climate change Collision accidents Collisions Fault tree analysis FTA Global warming Hazards HFACS Human factors Ice Ice cover Ice environments Icebreakers Judgments Organizational aspects Qualitative analysis Qualitative research Risk analysis Risk factors Risk management Sailing Sea ice Ship to icebreaker Shipping Statistical analysis Water
title	Use of HFACS and fault tree model for collision risk factors analysis of icebreaker assistance in ice-covered waters
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