低温液氮冷却下高速切削淬硬钢的切屑形成及刀具磨损

doi:10.3969/j.issn.1004-132X.2022.05.003

摘要/Abstract

摘要： 针对低温液氮冷却下淬硬钢高速车削过程中切屑形成及刀具磨损机理尚缺乏相关研究的问题，开展了液氮冷却下的淬硬钢高速切削研究，并与干切进行了对比。分析了切削力、切削温度、切屑特征以及刀具磨损特征，讨论了冷却润滑、切屑形成及刀具磨损机理。结果表明: 与干切相比，各组实验中低温液氮冷却切削的切削温度降低了6.9%~9.9%，因材料硬化使得切削力增大了10.1%~12.8%；低温液氮冷却下，切屑锯齿化程度相比干切明显增大，这与第一变形区应力应变更大、切屑形成存在从热塑性剪切失稳到周期性脆性断裂的过渡有关；低温液氮对切削界面的润滑降低了切削热，液氮强射流吹离了高热切屑，强传热换热能力可迅速置换切削区热量；与干切相比，低温液氮明显减小了黏结磨损，通过冷却增强刀体减缓了刀具微剥落，刀具寿命延长了28.6%~47.1%;低温液氮冷却下，黏结不再是主要磨损机理之一，磨粒磨损、冲击磨损为主要磨损机理，后刀面片状剥落和微崩刃为主要刀具破损形式。

关键词: 低温液氮冷却, 高速切削, 淬硬钢, 切屑, 刀具磨损

Abstract: In view of the lack of relevant research on chip formation and tool wear mechanism in high-speed cutting of hardened steel under cryogenic liquid nitrogen cooling, a high-speed cutting of hardened steels under liquid nitrogen cooling was studied and compared with dry cutting. The cutting force, cutting temperature, characteristics of chip and tool wear were analyzed, and the mechanism of cooling and lubrication, chip formation and tool wear were discussed. The results show that compared with dry cutting, the cutting temperature of cryogenic liquid nitrogen cooling cutting is reduced by 6.9%-9.9%, and the cutting force is increased by 10.1%-12.8% due to material hardening. Compared with dry cutting, chip serration increases obviously under cryogenic liquid nitrogen cooling, which is related to the larger stress and strain in the first deformation zone and the transition from thermoplastic shear instability to periodic brittle fracture in chip formation. Cryogenic liquid nitrogen reduces cutting heat generation in cutting interfaces, the strong jet of liquid nitrogen blows away the chips, and the strong heat transfer capacity quickly take away the heat in the cut areas. Compared with the dry cutting, cryogenic liquid nitrogen may significantly reduce the adhesive wear, alleviate the tool micro-spalling by cooling and strengthen the tool, and improve the tool life by 28.6%-47.1%. Under cryogenic liquid nitrogen cooling conditions, adhesion is no longer one of the main wear mechanism, abrasive wear and impact wear are the main wear mechanism, and flank flaking and micro collapse blade are the main tool damage forms.

Key words: cryogenic liquid nitrogen cooling, high-speed cutting, hardened steel, chip, tool wear

中图分类号:

TG54

吴世雄, 张文锋, 刘广东, 王成勇. 低温液氮冷却下高速切削淬硬钢的切屑形成及刀具磨损[J]. 中国机械工程, 2022, 33(05): 551-559.

WU Shixiong, ZHANG Wenfeng, LIU Guangdong, WANG Chengyong. Chip Formation and Tool Wear in High-speed Cutting of Hardened Steels under Cryogenic Liquid Nitrogen Cooling[J]. China Mechanical Engineering, 2022, 33(05): 551-559.

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.2022.05.003

http://www.cmemo.org.cn/CN/Y2022/V33/I05/551

参考文献

［1］WANG Chengyong, XIE Yingxing, ZHENG Lijuan, et al. Research on the Chip Formation Mechanism during the High-speed Milling of Hardened Steel［J］. International Journal of Machine Tools and Manufacture, 2014, 79:31-48.
［2］SINGH A, PHILIP D, RAMKUMAR J. A Review on Work Environment Quality in Shop Floor:Impact of Aerosols［C］∥2016 IEEE Region 10 Humanitarian Technology Conference (R10-HTC). Agra, 2016:1-6.
［3］WANG X T, CHEN T, LI S Y, et al. The Simulation and Experimental Study of Residual Stress Based on Thermo-mechanical Model of GCr15［J］.Key Engineering Materials, 2014, 589:152-156.
［4］SHARMA J, SIDHU B S. Investigation of Effects of Dry and Near Dry Machining on AISI D2 Steel Using Vegetable Oil［J］. Journal of Cleaner Production, 2014, 66:619-623.
［5］MALKIN S, GUO C. Thermal Analysis of Grinding［J］. CIRP Annals, 2007, 56(2):760-782.
［6］MARUDA R W, KROLCZYK G M, NIESLONY P, et al. The Influence of the Cooling Conditions on the Cutting Tool Wear and the Chip Formation Mechanism［J］. Journal of Manufacturing Processes, 2016, 24:107-115.
［7］YIN Z, YAN S, YE J, et al. Cutting Performance of Microwave-sintered Sub-crystal Al2O3/SiC Ceramic Tool in Dry Cutting of Hardened Steel［J］. Ceramics International, 2019, 45(13):16113-16120.
［8］RAVI S, KUMAR M P. Experimental Investigations on Cryogenic Cooling by Liquid Nitrogen in the End Milling of Hardened Steel［J］. Cryogenics, 2011, 51(9):509-515.
［9］RAVI S, GURUSAMY P. Experimental Investigations on Performance of TiN and TiAlN Coated Tools in Cryogenic Milling of AISI D2 Hardened Steel［J］. Materials Today:Proceedings, 2020(33):3612-3615.
［10］SIAVAIAH P, CHAKRADHAR D. Effect of Cryogenic Coolant on Turning Performance Characteristics during Machining of 17-4PH Stainless Steel:a Comparison with MQL, Wet, Dry Machining［J］. CIRP Journal of Manufacturing Ence & Technology, 2018, 21:86-96.
［11］PEREIRA O, A RODRIGUEZ A, FERNANDEZ V, et al. Cryogenic Hard Turning of ASP23 Steel Using Carbon Dioxide［J］. Procedia Engineering, 2015, 132:486-491.
［12］KUMAR K K, CHOUDHURY S K. Investigation of Tool Wear and Cutting Force in Cryogenic Machining Using Design of Experiments［J］. Journal of Materials Processing Technology, 2008, 203(1/3):95-101.
［13］YUAN S M, YAN L T, LIU W D, et al. Effects of Cooling Air Temperature on Cryogenic Machining of Ti-6Al-4V Alloy［J］. Journal of Materials Processing Technology, 2011, 211(3):356-362.
［14］乔帆, 任斐, 刘晓, 等. 难加工材料超低温切削的切屑形貌研究［J］. 机械制造, 2018, 56(6):63-66.
QIAO Fan, REN Fei, LIU Xiao, et al. Research on Chip Morphology in Ultra-low Temperature Cutting of Difficult-to-machine Materials［J］. Machinery, 2018, 56(6):63-66.
［15］WELBER V L, MELO C A D, DE O A J, et al. Tool Wear and Chip Analysis after the Hard Turning of AISI D6 Steel Assisted by LN2［J］. Machining Science and Technology, 2019, 23(6):886-905.
［16］BERMINHAM M J, KIRSCH J, SUN S, et al. New Observations on Tool Life, Cutting Forces and Chip Morphology in Cryogenic Machining Ti-6Al-4V［J］. International Journal of Machine Tools and Manufacture, 2011, 51(6):500-511.
［17］黄标彩,宁博,陈玉叶,等.热处理工艺对P20模具钢组织和性能的影响［J］.金属热理,2021,46(1):88-91.
HUANG Biaocai, NING Bo, CHEN Yuye, et al. Effect of Heat Treatment Process on Microstructure and Properties of P20 Hardened Steel［J］.Metal Heat Reatment,2021,46(1):88-91.
［18］中国机械工业联合会. 单刃车削刀具寿命试验:GB/T 16461—2016［S］.北京:中国标准出版社，2016.
China Machinery Industry Federaion. Tool-life-testing with Single-point Turning Tools:GB/T 16461—2016［S］. Beijing:Standards Press of China, 2016.
［19］王帅康,李嫚,陈乾.锯齿形切屑几何表征分析［J］.工具技术, 2019, 53(10):23-28.
WANG Shuaikang, LI Man, CHEN Qian. Geometrical Characterization Analysis of Sawtooth Chips［J］.Tool Engineering, 2019, 53(10):23-28.
［20］GUO Y B, ANURAG S, JAWAHIR I S. A Novel Hybrid Predictive Model and Validation of Unique Hook-shaped Residual Stress Profiles in Hard Turning［J］. CIRP Annals—Manufacturing Techno-logy, 2009, 58(1):81-84.
［21］庞俊忠,辛志杰,沈兴全,等.高速铣削淬硬模具钢的切屑变形［J］.中国机械工程，2013，24（14）：1939-1942.
PANG Junzhong, XING Zhijie, SHEN Xingquan, et al. Chip Deformation in High Speed Milling of Hardened Die Steel［J］.China Mechanical Engineering, 2013，24（14）：1939-1942.
［22］李建明, 王相宇, 乔阳, 等. 液氮冷却低温切削镍基合金Inconel 718的试验与仿真［J］. 机械工程学报, 2020, 56(18):78-89.
LI Jianming, WANG Xiangyu, QIAO Yang, et al. Experiment and Simulation of Low Temperature Cutting of Nickel-based Alloy Inconel 718 by Liquid Nitrogen Cooling［J］. Journal of Mechanical Engineering, 2020, 56(18):78-89.
［23］曹永泉,张弘弢,董海，等.PCBN刀具切削淬硬钢GCr15的磨损实验研究［J］.中国机械工程, 2006, 17(21):2305-2308.
CAO Yongquan, ZHANG Hongtao, DONG Hai, et al. Experimental Study on Tool Wear during Maching Hardened Steel GCr15 with PCBN Tools［J］. China Mechanical Engineering, 2006, 17(21):2305-2308.
［24］宦海祥,徐九华,苏宏华，等. PCD和硬质合金刀具车削钛基复合材料时刀具磨损特征研究［J］.中国机械工程, 2016, 27(14):1877-1883.
HUAN Haiyang, XU Jiuhua, SU Honghua, et al. Study on Tool Wear Characteristics during Turning Titanium Matri Composite Using PCD and Carbide Tools［J］.China Mechanical Engineering,2016, 27(14):1877-1883.

[1]	勾睿杰, 张晓峰, 张鸿滨, 姚俊, 李勋. 刀具磨损对Allvac 718Plus高温合金铣削加工表面完整性及疲劳性能的影响[J]. 中国机械工程, 2023, 34(24): 2920-2926.
[2]	李小睿, 赵威, 李浩, 史卫奇, 何宁. 高压低温CO2射流冷却条件下高速车削淬硬轴承钢的试验研究[J]. 中国机械工程, 2023, 34(24): 2975-2985.
[3]	倪敬, 孙静波, 何利华, 崔智, 薛飞. PTFE材料正交切削切屑成形特性研究[J]. 中国机械工程, 2022, 33(22): 2733-2740.
[4]	刘会永, 张松, 李剑峰, 栾晓娜, . 采用改进CNN-BiLSTM模型的刀具磨损状态监测[J]. 中国机械工程, 2022, 33(16): 1940-1947，1956.
[5]	史珂铭, 邹益胜, 刘永志, 丁昆, 丁国富. 一种不同工艺条件下刀具磨损状态多类域适应迁移辨识方法[J]. 中国机械工程, 2022, 33(15): 1841-1849.
[6]	迟剑英, 于爱兵, 吴毛朝, 袁建东, 陈秋洁, 孙磊. 聚晶金刚石刀具的断屑槽尺寸参数设计[J]. 中国机械工程, 2022, 33(03): 299-309.
[7]	赵国龙, 信连甲, 李亮, 王珉, 郝秀清, 何宁. 高硅铝合金的金刚石涂层刀具铣削损伤机理研究[J]. 中国机械工程, 2022, 33(02): 153-159.
[8]	谢兴杰, 张小俭, . 激光加热辅助车削淬硬钢的白层形成临界切削速度预测与实验研究[J]. 中国机械工程, 2022, 33(01): 15-23.
[9]	李聪波, 孙鑫, 侯晓博, 赵希坤, 吴少卿. 数字孪生驱动的数控铣削刀具磨损在线监测方法[J]. 中国机械工程, 2022, 33(01): 78-87.
[10]	丁国龙, 叶梦传, 向华, 杨春兰. 面向切屑形成过程的瞬时滚削力模型研究[J]. 中国机械工程, 2021, 32(21): 2562-2570.
[11]	尹晨, 周世超, 何建樑, 孙宇昕, 王禹林. 基于多源同步信号与深度学习的刀具磨损在线识别方法[J]. 中国机械工程, 2021, 32(20): 2482-2491.
[12]	赵亭;肖继明;范思敏;杨振朝;杨福杰. TC4钛合金低频振动钻削切屑形态和钻削力研究[J]. 中国机械工程, 2020, 31(19): 2276-2282.
[13]	李强;郭辰光;赵丽娟;冷岳峰;岳海涛. DD5镍基单晶高温合金高速铣削判据及切屑毛边成形机理研究[J]. 中国机械工程, 2020, 31(19): 2388-2393.
[14]	戴稳1;张超勇1;孟磊磊1;薛燕社1;肖鹏飞1;尹勇2. 采用深度学习的铣刀磨损状态预测模型[J]. 中国机械工程, 2020, 31(17): 2071-2078.
[15]	何彦1;凌俊杰1;王禹林2;李育锋1;吴鹏程1;肖圳1. 基于长短时记忆卷积神经网络的刀具磨损在线监测模型[J]. 中国机械工程, 2020, 31(16): 1959-1967.