数控铣床低碳高质建模及工艺参数优化

doi:10.3969/j.issn.1004-132X.2024.10.014

摘要/Abstract

摘要： 针对数控铣床生产过程中工艺参数不合理导致碳排放量高、表面质量差等问题，提出了一种面向低碳高质的数控铣床工艺参数优化方法。分析了铣削过程碳排放因素，给出碳排放效率、表面粗糙度和加工时间的目标函数，构建基于灰狼算法改进支持向量回归的数控铣床碳排放效率和表面粗糙度预测模型。以主轴转速、进给速度和切削宽度为优化变量，采用改进白鹭算法进行切削参数优化，获得了低碳高质高效工艺参数Pareto前沿解，通过熵权逼近理想解排序法选择合适的工艺参数。搭建了数控铣床碳排放监测实验平台，实验结果验证了所提方法的可行性和有效性。

关键词: 低碳高质, 改进支持向量回归, 改进白鹭算法, 熵权逼近理想解排序法

Abstract: Aiming at the problems of high carbon emission efficiency and poor surface quality caused by using unreasonable processing parameters during the working processes of CNC milling machines, an optimization method of CNC milling machine processing parameters oriented to low carbon and high quality was proposed. Initially, carbon emission factors in the milling processes were analyzed, and target functions of carbon emission efficiency, surface roughness, and processing time were defined. Prediction models for carbon emission efficiency and surface roughness for CNC milling machines were subsequently established, utilizing the support vector regression improved by grey wolf optimizer. Then, with spindle speed, feed rate, and cutting width designated as optimization variables, an improved egret swarm optimization algorithm was applied to optimize the cutting parameters. This resulted in obtaining Pareto front solutions for processing parameters that were low in carbon emissions, high in quality and efficient. Suitable processing parameters were selected using the EW-TOPSIS method. Finally, an experimental platform for monitoring carbon emissions in CNC milling machines was established, and the feasibility and validity of the proposed method were verified by the experimental results.

Key words: , low-carbon and high-quality, improved support vector regression, improved egret swarm optimization algorithm, entropy weight-technique for order preference by similarity to ideal solution（EW-TOPSIS）

中图分类号:

TH16

李泽亚1, 罗敏1, 张超勇2, 徐金瑜1. 数控铣床低碳高质建模及工艺参数优化[J]. 中国机械工程, 2024, 35(10): 1845-1851.

LI Zeya1, LUO Min1, ZHANG Chaoyong2, XU Jinyu1. Low Carbon and High Quality Modeling and Processing Parameter Optimization of CNC Milling Machines[J]. China Mechanical Engineering, 2024, 35(10): 1845-1851.

导出引用管理器 EndNote|Ris|BibTeX

链接本文: http://www.cmemo.org.cn/CN/10.3969/j.issn.1004-132X.2024.10.014

http://www.cmemo.org.cn/CN/Y2024/V35/I10/1845

参考文献

［1］赵希坤,李聪波,杨勇,等.数据机理混合驱动下考虑刀具柔性的柔性加工工艺参数能效优化方法［J］.机械工程学报， 2024, 60(7):236-248.
ZHAO Xikun, LI Congbo, YANG Yong, et al. A Data and Model Hybrid Driven Cutting Parameter Energy-efficiency Optimization Method for Flexible Machining Process Considering Cutting Tool Flexibility［J］.Journal of Mechanical Engineering, 2024, 60(7):236-248.
［2］高亮,杨扬,李新宇.数控加工参数优化的研究现状与进展［J］. 航空制造技术, 2010(22):48-51.
GAO Liang, YANG Yang, LI Xinyu. Research and Development of Optimization of NC Machining Parameters［J］. Aeronautical Manufacturing Technology, 2010(22):48-51.
［3］XIAO Yongmao, JIANG Zhigang, GU Quan, et al. A Novel Approach to CNC Machining Center Processing Parameters Optimization Considering Energy-saving and Low-cost［J］. Journal of Manufacturing Systems, 2021, 59:535-548.
［4］李聪波,崔龙国,刘飞，等.面向高效低碳的数控加工参数多目标优化模型［J］. 机械工程学报, 2013, 49(9):87-96.
LI Congbo, CUI Longguo, LIU Fei, et al. Multi-objective NC Machining Parameters Optimization Model for High Efficiency and Low Carbon［J］. Journal of Mechanical Engineering, 2013, 49(9):87-96.
［5］詹欣隆,张超勇,孟磊磊，等.基于改进引力搜索算法的铣削加工参数低碳建模及优化［J］.中国机械工程, 2020, 31(12):1481-1491.
ZHAN Xinlong, ZHANG Chaoyong, MENG Leilei, et al. Low Carbon Modeling and Optimization of Milling Parameters Based on Improved Gravity Search Algorithm［J］. China Mechanical Engineering, 2020,31(12):1481-1491.
［6］迟玉伦,范志辉,葛爱丽,等.面向绿色高表面质量制造的硬态车削工艺多目标参数优化［J］.表面技术, 2023, 52(9):278-293.
CHI Yulun, FAN Zhihui, GE Aili, et al.Multi-objective Parameter Optimization of Hard Turning Process for Green High Surface Quality Manufacturing［J］.Surface Technology,2023,52(9):278-293.
［7］易茜,柳淳,李聪波，等.基于小样本数据驱动的滚齿工艺参数低碳优化决策方法［J］. 中国机械工程, 2022, 33(13):1604-1612.
YI Qian, LIU Chun, LI Congbo, et al. A Low Carbon Optimization Decision Method for Gear Hobbing Process Parameters Driven by Small Sample Data［J］. China Mechanical Engineering, 2022, 33(13):1604-1612.
［8］FANG Yilin, ZHAO Lili, LOU Ping, et al. Cutting Parameter Optimization Method in Multi-pass Milling Based on Improved Adaptive PSO and SA［C］∥Journal of Physics:Conference Series. Sanya, 2021:012116.
［9］LIU Zhijie, SUN Deping, LIN Chengxin, et al. Multi-objective Optimization of the Operating Conditions in a Cutting Process Based on Low Carbon Emission Costs［J］. Journal of Cleaner Production, 2016, 124:266-275.
［10］ZHANG Hua, DENG ZhaoHui, FU Yahui, et al. A Process Parameters Optimization Method of Multi-pass Dry Milling for High Efficiency, Low Energy and Low Carbon Emissions［J］. Journal of Cleaner Production, 2017, 148:174-184.
［11］ZHOU Guanghui, LU Qi, XIAO Zhongdong, et al. Cutting Parameter Optimization for Machining Operations Considering Carbon Emissions［J］. Journal of Cleaner Production, 2019, 208:937-950.
［12］李聪波，崔龙国，刘飞，等.基于广义边界的机械加工系统碳排放量化方法［J］.计算机集成制造系统, 2013, 19(9):2229-2236.
LI Congbo, CUI Longguo, LIU Fei，et al. Carbon Emissions Quantitative Method of Machining System Based on Generalized Boundary［J］. Computer Integrated Manufacturing Systems, 2013, 19(9):2229-2236.
［13］DENG ZhaoHui, LYU Lishu, LI Shichun, et al. Study on the Model of High Efficiency and Low Carbon for Grinding Parameters Optimization and Its Application［J］. Journal of Cleaner Production, 2016, 137:1672-1681.
［14］吕景祥,唐任仲,郑军.数据驱动的车削和钻削加工能耗预测［J］.计算机集成制造系统, 2020, 26(8):2073-2082.
LYU Jingxiang, TANG Renzhong, ZHENG Jun. Data-driven Methodology for Energy Consumption Prediction of Turning and Drilling Processes［J］. Computer Integrated Manufacturing Systems,2020,26(8):2073-2082.
［15］殷孝雎,都治良,卲国策，等.基于GWO-SVR的风电机组柔性塔架振动建模与仿真分析［J］. 太阳能学报,2023, 44(8):404-411.
YIN Xiaoju, DU Zhiliang, SHAO Guoce, et al. Vibration Modeling and Simulation Analysis of Flexible Tower of Wind Turbines Based on GWO-SVR［J］. Acta Energiae Solaris Sinica, 2023, 44(8):404-411.
［16］孙东,汪若尘,丁仁凯,等.基于灰狼算法的矿用自卸车油气悬架半主动控制［J］.中国机械工程, 2023, 34(4):490-497.
SUN Dong, WANG Ruochen, DING Renkai, et al. Semi-active Control of Hydro-pneumatic Suspensions for Mining Dump Trucks Based on Grey Wolf Algorithm［J］. China Mechanical Engineering, 2023, 34(4):490-497.
［17］CHEN Zuyan, FRANCIS A, LI Shuai, et al. Egret Swarm Optimization Algorithm:an Evolutionary Computation Approach for Model Free Optimization［J］. Biomimetics, 2022, 7(4):144.
［18］童水光,何顺,童哲铭，等.基于组合近似模型的轻量化设计方法［J］.中国机械工程, 2020, 31(11):1337-1343.
TONG Shuiguang, HE Shun, TONG Zheming，et al. Lightweight Design Method Based on Combined Approximation Model［J］. China Mechanical Engineering，2020, 31(11):1337-1343.
［19］马军,尹春洋,李医中，等.基于聚合代理模型的土压平衡盾构刀盘轻量化设计方法［J］.计算机集成制造系统,2023,29(1):310-319.
MA Jun, YIN Chunyang, LI Yizhong, et al. Lightweight Design Method of Earth Pressure Balance Shield Cutter Head Based on Ensemble Surrogate Model［J］. Computer Integrated Manufacturing Systems, 2023,29(1):310-319.
［20］生态环境部应对气候变化司.2019年度减排项目中国区域电网基准线排放因子［EB/OL］.［2020-12-29］. https:∥www.mee.gov.cn/ywgz/ydqhbh/wsqtkz/202012/t20201229_815386.shtml.
Department of Climate Change， Ministry of Ecology and Environment. Emission Factors of China’s Regional Power Grid Base Line in 2019［EB/OL］.［2020-12-29］. http:∥www. mee. gov. cn/ywgz/ydqhbh/wsqtkz/202012/t20201229815386. shtml.

[1]	聂鹏1, 杨程越1, 彭新月1, 于家鹤2, 潘五九1. 采用空间和通道激励注意力机制优化ResNet-50的CFRP/TC4叠层材料钻削刀具磨损状态监测[J]. 中国机械工程, 2024, 35(10): 1793-1801.
[2]	金明磊1, 2, 金明生1, 2, 宋正江3, 曾晰1, 2, 李燕1, 2, 唐璇1, 2. 中心供液弹性研抛工具的材料去除模型研究[J]. 中国机械工程, 2024, 35(09): 1659-1666.
[3]	滕佳篷, 武国启. 基于SOA-VMD-ICA的海水泵激励源特征提取方法[J]. 中国机械工程, 2024, 35(08): 1373-1380.
[4]	李国龙1, 肖扬1, 李喆裕1, 徐凯2, 张薇1. 数控机床旋转轴多自由度静/热误差同步测量与建模[J]. 中国机械工程, 2024, 35(08): 1426-1434.
[5]	吴石, 张勇, 王宇鹏, 王春风. 基于双信号融合的主轴/刀柄结合面刚度退化程度预测[J]. 中国机械工程, 2024, 35(08): 1449-1461.
[6]	刘哲1, 杨德存1, 2, 阳智麾1, 江磊1. 基于接触区域自适应调整的圆弧头立铣刀后刀面磨削轨迹精确计算方法[J]. 中国机械工程, 2024, 35(07): 1222-1231，1240.
[7]	张文斌, 刘焕牢, 王宇林, 周恒宇. 双转台五轴数控机床旋转轴位置无关几何误差辨识[J]. 中国机械工程, 2024, 35(06): 1023-1033.
[8]	王栋, 陈磊, 张志鹏. 外圆磨削18CrNiMo7-6力模型及表面完整性研究[J]. 中国机械工程, 2024, 35(03): 381-393.
[9]	倪敬, 崔智, 何利华, 付新, 朱泽飞. 聚四氟乙烯材料切削工艺和应用研究进展[J]. 中国机械工程, 2024, 35(03): 498-514.
[10]	包锐, 刘阔, 张杰, 韩灵生, 李建明, 左月帅, 刘海波, 王永青. 聚碳酸酯超低温冷却车削表面形貌试验研究[J]. 中国机械工程, 2024, 35(02): 201-207.
[11]	杜煦, 常泽鑫, 郑军强, 任鹏飞. 一种考虑关节跃度约束的实时刀具路径光顺算法[J]. 中国机械工程, 2024, 35(02): 280-286.
[12]	琚春, 刘佳, 杨胜强, 张晶晶, 赵旭辉, . 叶片前后缘识别及百叶轮抛磨工艺研究[J]. 中国机械工程, 2023, 34(22): 2674-2683，2692.
[13]	梁小冰, 卢耀安, 王成勇, . 双转台五轴机床旋转轴位置无关几何误差的辨识[J]. 中国机械工程, 2023, 34(21): 2585-2591.
[14]	白小帆, 刘志强, 刘彦士. 轴向低频振动对皮质骨钻削进给力的影响试验与分析[J]. 中国机械工程, 2023, 34(20): 2411-2427.
[15]	王明, 董海, 王柏何, 王峥, 王加威. 2.5D Cf/SiC刹车材料浮动磨削工艺试验研究[J]. 中国机械工程, 2023, 34(20): 2434-2441.