Prediction of the risk of capsize of small ships

The lack of a necessary rational framework for assessing ship stability was the main concern of this research. The aim was to develop a rational philosophy and a logical procedure of assessing intact stability in order to ensure a consistent and unified approach to design for operation and for survi...

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Main Author: Deakins, Eric
Published: University of Plymouth 1988
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Online Access:http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.233943
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spelling ndltd-bl.uk-oai-ethos.bl.uk-2339432015-05-02T03:20:54ZPrediction of the risk of capsize of small shipsDeakins, Eric1988The lack of a necessary rational framework for assessing ship stability was the main concern of this research. The aim was to develop a rational philosophy and a logical procedure of assessing intact stability in order to ensure a consistent and unified approach to design for operation and for survival. The method uniquely brings together a linearised analysis for assessing a potentially dangerous roll motion with a probabilistic assessment of ship performance in rough seas on a standard test-track. This represents a significant advance on previous research. A novel feature of the analysis was that prediction of the extreme capsize roll motion was not attempted per se. Instead a reduced level of roll response termed "potentially dangerous" roll motion was selected (based on discussions with seagoing personnel) beyond which there was evidence that loss of the vessel is likely. Validation of the linear spectral analysis used in the simulations was performed using full scale trial results of a fisheries protection vessel. Provided that measured values of roll damping coefficient were used, the predicted values of extreme roll closely matched the maximum values experienced on sea trials up to the chosen value of critical roll angle of 30 degrees. Particular attention was paid to the realistic modelling of total system behaviour in rough seas. Families of wave spectra were used to represent the complete range of wave conditions encountered in nature. Avoidance and pacifying seamanship were incorporated based on the results of available trials data and discussions with serving masters. Independent (Bernoulli) trials procedures were used to calculate the cumulative probability of a critical roll motion being exceeded at least once during the vessel's passage through the test-track. The value of critical motion exceedance obtained was 5x10ˉ² for the fisheries protection vessel which has a large metacentic height and is reported to have good seakeeping characteristics.623.8Ship stability][Fishing boat safetyUniversity of Plymouthhttp://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.233943http://hdl.handle.net/10026.1/2343Electronic Thesis or Dissertation
collection NDLTD
sources NDLTD
topic 623.8
Ship stability][Fishing boat safety
spellingShingle 623.8
Ship stability][Fishing boat safety
Deakins, Eric
Prediction of the risk of capsize of small ships
description The lack of a necessary rational framework for assessing ship stability was the main concern of this research. The aim was to develop a rational philosophy and a logical procedure of assessing intact stability in order to ensure a consistent and unified approach to design for operation and for survival. The method uniquely brings together a linearised analysis for assessing a potentially dangerous roll motion with a probabilistic assessment of ship performance in rough seas on a standard test-track. This represents a significant advance on previous research. A novel feature of the analysis was that prediction of the extreme capsize roll motion was not attempted per se. Instead a reduced level of roll response termed "potentially dangerous" roll motion was selected (based on discussions with seagoing personnel) beyond which there was evidence that loss of the vessel is likely. Validation of the linear spectral analysis used in the simulations was performed using full scale trial results of a fisheries protection vessel. Provided that measured values of roll damping coefficient were used, the predicted values of extreme roll closely matched the maximum values experienced on sea trials up to the chosen value of critical roll angle of 30 degrees. Particular attention was paid to the realistic modelling of total system behaviour in rough seas. Families of wave spectra were used to represent the complete range of wave conditions encountered in nature. Avoidance and pacifying seamanship were incorporated based on the results of available trials data and discussions with serving masters. Independent (Bernoulli) trials procedures were used to calculate the cumulative probability of a critical roll motion being exceeded at least once during the vessel's passage through the test-track. The value of critical motion exceedance obtained was 5x10ˉ² for the fisheries protection vessel which has a large metacentic height and is reported to have good seakeeping characteristics.
author Deakins, Eric
author_facet Deakins, Eric
author_sort Deakins, Eric
title Prediction of the risk of capsize of small ships
title_short Prediction of the risk of capsize of small ships
title_full Prediction of the risk of capsize of small ships
title_fullStr Prediction of the risk of capsize of small ships
title_full_unstemmed Prediction of the risk of capsize of small ships
title_sort prediction of the risk of capsize of small ships
publisher University of Plymouth
publishDate 1988
url http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.233943
work_keys_str_mv AT deakinseric predictionoftheriskofcapsizeofsmallships
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