Abstract
The offshore industry operates increasingly large installations in exposed areas requiring high reliability and availability. Downtime of complex offshore systems leads to significant financial losses. Towards year-round offshore installation and maintenance service, this research focuses on the identification of weather-robust vessel designs. Even though it might seem that the motions of a larger vessel will be more favorable than those of a smaller vessel, this research shows that this hypothesis is not necessarily true. It will be shown that for certain vessel parameters the performance of a larger vessel is not better than that of a smaller vessel. This investigation aims to provide knowledge for a more holistic vessel design optimization approach to enable ship designers and operators to design and select an offshore vessel with main dimensions and hydrostatic parameters providing optimal seakeeping performance for a given operation and environment. The key aspect is a mission-dependent optimization of hull dimensions, including loading condition parameters, aiming for a hull design where natural periods of important responses such as pitch and roll are significantly distinct from the dominating wave periods. For this purpose, a novel parameter for seakeeping performance evaluation, the Operability Robustness Index (ORI), will be used.
Highlights
The optimization of seakeeping performance is the improvement of the vessel’s capability to efficiently execute its mission despite adverse weather conditions (Comstock and Keane, 1980)
The proposed methodology is applicable for a wide range of offshore vessels, such as offshore construction vessel (OCV), inspection maintenance and repair vessel (IMR), anchor handling vessel (AHV), platform supply vessel (PSV), as well as accommodation vessel, and crew transfer vessel
This is especially observed in the analysis of the percentage operability (percOP), while the Operability Robustness Index (ORI) is still capable of indicating the differences between the designs, the percOP value converges against 100% and is not capable of indicating performance variations
Summary
The optimization of seakeeping performance is the improvement of the vessel’s capability to efficiently execute its mission despite adverse weather conditions (Comstock and Keane, 1980). The focus of this work is on the systematic presentation of the influence of design parameters on roll at zero ship speed to identify and benchmark mission-oriented seakeeping performance. For this purpose, the percentage operability and the Operational Robustness Index (ORI), introduced by Gutsch et al (2016, 2017), will be utilized. The percentage operability and the Operational Robustness Index (ORI), introduced by Gutsch et al (2016, 2017), will be utilized Both performance parameters are suitable for the identification and benchmarking of mission-oriented vessel capabilities related to a selected motion parameter, sea area, and season. The complete RAO database can be used for further investigation and is accessible online by using the Vessel Response Tool, freely accessible on vrt.sintef.no
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