Abstract
This article presents a new holistic multi-objective design approach for the optimization of Arctic Offshore Supply Vessels (OSVs) for cost- and eco-efficiency. The approach is intended to be used in the conceptual design phase of an Arctic OSV. It includes (a) a parametric design model of an Arctic OSV, (b) performance assessment models for independently operating and icebreaker-assisted Arctic OSVs, and (c) a novel adaptation of the Artificial Bee Colony (ABC) algorithm for multi-objective optimization of Arctic OSVs. To demonstrate the feasibility and viability of the proposed optimization approach, a series of case studies covering a wide range of operating scenarios are carried out. The results of the case studies indicate that the consideration of icebreaker assistance significantly extends the feasible design space of Arctic OSVs, enabling solutions with improved energy- and cost-efficiency. The results further indicate that the optimal amount of icebreaking assistance and optimal vessel speed differs for different vessels, highlighting the motivation for holistic design optimization. The applied adaptation of the ABC algorithm proved to be well suited and efficient for the multi-objective optimization problem considered.
Highlights
The framework is intended to be used in the conceptual design phase of a vessel and consists of three main components: (1) a parametric model of an Arctic Offshore Supply Vessels (OSVs), (2) a model representing the performance of an Arctic OSV in a given operational context, and (3) an algorithm for design optimization consisting of an original adaptation of the Artificial Bee Colony (ABC) algorithm for a multi-objective, well-constrained optimization problem
As demonstrated through case studies, the proposed approach is readily applicable for the conceptual design of an Arctic OSV
The adaptation of the ABC algorithm presented could be relevant for other types of multi-objective optimization problems utilizing black-box models, which are commonly used in the industry
Summary
There have been significant advances in science and technology since the 20th century, the ongoing transition from fossil fuel to renewable energy sources is expected to take decades to complete. To power this transition, a steady and as clean as possible supply of oil and gas is needed. A steady and as clean as possible supply of oil and gas is needed In this context, the Arctic shelf, which is estimated to contain some 90 billion barrels of oil and 47 trillion cubic meters of natural gas, is expected to play a significant role [2]
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