Load optimization of cogeneration units based on intuitive multi-objective fish swarm algorithm

Load optimization of cogeneration units based on intuitive multi-objective fish swarm algorithm

This study addresses the multi-objective optimization challenges in seasonal heat-power load distribution for cogeneration units by proposing a multi-objective artificial fish swarm algorithm based on intuitionistic fuzzy entropy (IFEMOAFSA). The algorithm enhances the original intuitionistic fuzzy...

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Bibliographic Details
Main Authors: Xueqiang Shen, Jiaxin Wang
Format: Article
Language:English
Published: Elsevier 2025-06-01
Series:International Journal of Electrical Power & Energy Systems
Subjects:
Artificial fish schools
Multi-objective optimization
Economic allocation
Cogeneration
Intuitionistic fuzzy entropy
Online Access:http://www.sciencedirect.com/science/article/pii/S0142061525001462
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Summary:This study addresses the multi-objective optimization challenges in seasonal heat-power load distribution for cogeneration units by proposing a multi-objective artificial fish swarm algorithm based on intuitionistic fuzzy entropy (IFEMOAFSA). The algorithm enhances the original intuitionistic fuzzy entropy framework, integrating membership, non-membership, and hesitation degrees to guide fish swarm behavior. It dynamically categorizes swarm particles into three states, improving solution space coverage and priority-based solution identification. Convergence direction is adaptively adjusted using intuitionistic fuzzy entropy, with Pareto frontier solutions determining optimal load allocation. Evaluated via the Zitzler-Deb-Thiele (ZDT) benchmark functions, IFEMOAFSA achieves a 42.63% comprehensive performance improvement over four benchmark algorithms, verified by Mean Inverted Generational Distance (MIGD) and Mean Hypervolume Metric (MHV). A cogeneration unit model incorporating operational characteristics and historical data demonstrates the method’s efficacy: multi-objective balance is maintained across iterations, achieving a 1.41% thermoelectric load increase and 1.54% optimal coal consumption reduction. The algorithm reduces heat/electricity losses and operational costs under diverse conditions while enhancing load utilization rates. These results validate IFEMOAFSA’s effectiveness in solving annual load optimization challenges for cogeneration systems, showing promising applications for similar multi-objective optimization problems requiring dynamic adaptability and robust convergence properties.
ISSN:0142-0615

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