基于改进型遗传算法的数控铣削参数优化

严胜利; 付辉; 李浩

doi:10.16579/j.issn.1001.9669.2022.03.016

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基于改进型遗传算法的数控铣削参数优化

优化·可靠性 | 更新时间：2022-09-22

- 基于改进型遗传算法的数控铣削参数优化
- NUMERICAL CONTROL MILLING PARAMETER OPTIMIZATION ON THE BASIS OF IMPROVED GENETIC ALGORITHM
- 机械强度 2022年44卷第3期页码：620-626
- 作者机构：
  
  1. 广安职业技术学院
  2. 兰州理工大学电气工程与信息工程学院
- 作者简介：
- 基金信息：
  
  国家自然科学基金项目(62001198)
- DOI：10.16579/j.issn.1001.9669.2022.03.016
  中图分类号：
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严胜利, 付辉, 李浩. 基于改进型遗传算法的数控铣削参数优化[J]. 机械强度, 2022,44(3):620-626.

YAN ShengLi, FU Hui, LI Hao. NUMERICAL CONTROL MILLING PARAMETER OPTIMIZATION ON THE BASIS OF IMPROVED GENETIC ALGORITHM[J]. 2022,44(3):620-626.
严胜利, 付辉, 李浩. 基于改进型遗传算法的数控铣削参数优化[J]. 机械强度, 2022,44(3):620-626. DOI： 10.16579/j.issn.1001.9669.2022.03.016.

YAN ShengLi, FU Hui, LI Hao. NUMERICAL CONTROL MILLING PARAMETER OPTIMIZATION ON THE BASIS OF IMPROVED GENETIC ALGORITHM[J]. 2022,44(3):620-626. DOI： 10.16579/j.issn.1001.9669.2022.03.016.

摘要

数控加工在传统制造业与国防战略产业中的运用日益广泛，而优化铣削参数与加工的效率、质量与成本息息相关。首先构建了带约束性的多目标优化函数作为参数优化模型，进而采用ENDE-NSGA-II的方法完成参数优化，该方法采用NDX交叉算法、CA排序方法和DE策略能增大搜索区间，可通过累积单体Pareto序列结果与密度参量保证群体多元化分布，并提升收敛速率。采用DMU125P型五轴数控机床结合Matlab 2020完成加工参数、质量和系统稳态的对比实验。结果表明，与传统经验加工方法对比，通过ENDE-NSGA-II的方法所优化的加工参数能够保证加工效率的前提下，改善表面粗糙程度，提升工件的加工品质；并增大刀具耐磨度，提高经济效益。此外，能够让系统较快达到稳态。

Abstract

Numerical control machining is widely used in traditional manufacturing industry and national defense strategic industry, and optimization of milling parameters is closely related to processing efficiency, quality and cost. Firstly, a constrained multi-objective optimization function is constructed as a parameter optimization model. Then, the ENDE-NSGA-II method is adopted to complete the parameter optimization. By adoption of the NDX crossover algorithm, CA sorting method and DE strategy can increase the search interval, ensure the population diversification distribution, and improve the convergence rate. The DMU125 P five-axis CNC machine tool combined with Matlab 2020 was used to complete the comparison experiment of processing parameters, quality and system steady-state. Experimental results show that in comparison with the traditional empirical processing method, the processing parameters optimized by the ENDE-NSGA-II method can improve the surface roughness and the processing quality of the workpiece, under the premise of ensuring the processing efficiency. And increase the wear resistance of cutting tools, improve economic benefits. In addition, it allows the system to reach steady state more quickly.

关键词

多目标NDX交叉CA排序ENDE-NSGA-II数控加工

Keywords

Multi-objectiveNDX crossoverCA sortingENDE-NSGA-IINumerical control machining

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