考虑模糊交货期的风电拉挤板生产智能排程

doi:10.12005/orms.2026.0020

摘要/Abstract

摘要： 针对风电拉挤板生产过程中存在序列依赖换型时间、区域化生产组织与顺序齐套等多重约束的排程难题,在交货期模糊的前提下,构建了最小化设备负荷偏差、最大化客户满意度和最小化换型时间的多目标优化模型。考虑到各个目标之间的复杂关系,设计了一种基于混合学习策略的改进小龙虾算法进行求解。构建了基于组件与加工区域的两层编码方案,并提出“倒排生成、约束修复与优化增强”的解码策略,引入反向折射学习机制进行种群初始化,使得初始解更加靠近最优解位置;此外在探索阶段对收敛因子非线性改进,觅食阶段融合次摆线算法和动态步长因子策略,从而增强算法的全局搜索能力。最后通过对某风电拉挤板的生产数据进行分析,验证了智能排程模型和算法的有效性。

关键词: 风电拉挤板, 生产排程, 多目标优化, 模糊交货期, 小龙虾算法

Abstract: Wind power is a cost-effective, clean and mature energy source, offering a sustainable alternative to fossil fuels. Wind turbine extrusion plates, critical structural components of turbine blades, are manufactured through a continuous, order-driven and flexible production process to meet diverse market needs. However, the Wind Turbine Extrusion Plate Production Scheduling Problem (PSP-WTEP) is highly complex and falls into the NP-hard category, as it must consider constraints such as mold replacements, sequential flush sets and operational limitations. PSP-WTEP can be divided into three sub-problems: assigning production areas for orders, allocating processing equipment within those areas and sequencing components on machines. These challenges require a multi-objective optimization model to balance equipment load, maximize customer satisfaction, and minimize mold changeover times, all while adhering to fuzzy delivery deadlines. Effectively solving PSP-WTEP is essential for improving production efficiency, reducing costs and promoting innovation in the wind power industry.
To tackle this issue, the study develops the Enhanced Multi-Objective CrayfishOptimization Algorithm (EMOCOA), an improvement over the Crayfish Optimization Algorithm (COA). EMOCOA incorporates advanced strategies such as non-dominated sorting, refractive inverse learning for population initialization, nonlinear convergence factors, sub-swing perturbations and dynamic step adjustments. The algorithm employs a two-layer coding system for components and regions, converting continuous variables into discrete codes using Ranked Order Value (ROV) encoding. It adopts a “backward-repair-optimize” decoding strategy to resolve fuzzy delivery constraints and improve solution feasibility. These enhancements allow EMOCOA to effectively balance global exploration and local exploitation, handle the coupling of PSP-WTEP sub-problems, and deliver diverse and high-quality solutions that meet production goals. The algorithm’s hybrid learning strategies ensure fast convergence and robust performance, even in complex scenarios.
Extensive experiments highlight the superiority of EMOCOA over the Multi-Objective Crayfish Optimization Algorithm (MOCOA) and Multi-Objective Whale Optimization Algorithm (MOWOA). EMOCOA consistently outperforms its counterparts, generating 10 Pareto solutions compared to 7 by MOCOA and 8 by MOWOA, with better results on key evaluation metrics such as IGD and HV. These metrics indicate that EMOCOA provides improved solution diversity and convergence, making it more practical for real-world application. Production managers can use methods such as hierarchical analysis and entropy weight to rank and select Pareto solutions for implementation. By solving various scenarios and demonstrating its adaptability, EMOCOA proves to be a powerful tool for optimizing production scheduling, reducing costs, and increasing efficiency. The algorithm supports intelligent upgrades in wind turbine extrusion plates manufacturing, facilitating the sustainable growth and technological advancement of the wind power industry.

Key words: wind turbine extrusion plate, production scheduling, multi-objective optimization, fuzzy lead times, crayfish optimization algorithm

中图分类号:

TP497
F406.2

杨欣, 杨晓英. 考虑模糊交货期的风电拉挤板生产智能排程[J]. 运筹与管理, 2026, 35(1): 139-144.

YANG Xin, YANG Xiaoying. Intelligent Scheduling of Wind Turbine Extrusion Plate Production Considering Fuzzy Lead Times[J]. Operations Research and Management Science, 2026, 35(1): 139-144.

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