热处理工艺对激光熔覆316L温度场与应力场的影响规律

doi:10.3969/j.issn.1004-132X.2024.04.010

摘要/Abstract

摘要： 为研究不同热处理工艺对激光熔覆残余应力的调控作用，利用ANSYS有限元分析软件建立了热力耦合模型，对不同温度(22~900 ℃)的熔覆前预热处理、不同温度(200~1000 ℃)的熔覆后退火处理以及熔覆前后协同热处理条件下的激光熔覆316L不锈钢温度场和应力场进行了数值模拟。研究结果表明：预热对熔池温度影响最大，熔池温度随预热温度的增高而增高;退火处理对激光熔覆残余应力的改善效果最好，800 ℃退火处理可使残余应力减小约50%,其次是熔覆前后协同热处理，可使残余应力减小约35%,预热处理对激光熔覆残余应力有一定改善，其中预热500 ℃可使残余应力减小约20%。

关键词: 316L不锈钢, 激光熔覆, 热处理, 数值模拟, 残余应力

Abstract: In order to study the control effectiveness of different heat treatment processes on the residual stress of laser cladding, a thermo-mechanics coupling model was established by using ANSYS finite element analysis software. The temperature and stress fields during the laser cladding of 316L stainless steel were simulated under the conditions of preheating(22~900 ℃) before cladding, annealing treatment(200~1000 ℃) after cladding and combined heat treatment before and after cladding. The results show that preheating has the greatest influence on the temperature of molten pool. The temperature of the molten pool increases with the increase of the preheating temperature. Annealing treatment has the best effect on improving the residual stress of laser cladding, and the residual stress is reduced by about 50% at 800 ℃. Comparatively, followed by preheating and annealing treatment, the residual stress is reduced by about 35%. In addition, preheating treatment may also effectively adjust the residual stress, with a reduction of 20% at 500 ℃.

Key words: 316L stainless steel, laser cladding, heat treatment, numerical simulation, residual stress

中图分类号:

U270

李燕乐, 潘忠涛, 戚小霞, 崔维强, 陈健, 李方义. 热处理工艺对激光熔覆316L温度场与应力场的影响规律[J]. 中国机械工程, 2024, 35(04): 666-677.

LI Yanle, PAN Zhongtao, QI Xiaoxia, CUI Weiqiang, CHEN Jian, LI Fangyi. Effect of Heat Treatment on Temperature and Stress Distribution during Laser Cladding of 316L Steels[J]. China Mechanical Engineering, 2024, 35(04): 666-677.

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链接本文: http://www.cmemo.org.cn/CN/10.3969/j.issn.1004-132X.2024.04.010

http://www.cmemo.org.cn/CN/Y2024/V35/I04/666

参考文献

［1］李方义，戚小霞，李燕乐，等. 盾构机关键零部件再制造修复技术综述［J］. 中国机械工程, 2021, 32(7):820-831.
LI Fangyi, QI Xiaoxia, LI Yanle, et al. Review of Remanufacturing Repair Technology for Key Components of Shield Machine［J］. China Mechanical Engineering, 2021, 32(7):820-831.
［2］李方义，李振，王黎明，等. 内燃机增材再制造修复技术综述［J］. 中国机械工程, 2019, 30(9):1119-1127.
LI Fangyi, LI Zhen, WANG Liming， et al. Review of Additive Remanufacturing Repair Technology for Internal Combustion Engine［J］. China Mechanical Engineering, 2019, 30(9):1119-1127.
［3］WENG Fei, CHEN Chuanzhong, YU Huijun. Research Status of Laser Cladding on Titanium and Its Alloys: a Review［J］. Materials & Design, 2014, 58:412-425.
［4］李广琪，朱刚贤，王丽芳，等. 离焦量对中空环形激光熔覆层温度场及应力场的影响［J］. 中国机械工程, 2021, 32(5):587-593.
LI Guangqi, ZHU Gangxian, WANG Lifang, et al. Effect of Defocusing Distance on Temperature Field and Stress Field of Hollow Ring Laser Cladding Layer［J］. China Mechanical Engineering, 2021, 32(5):587-593.
［5］WANG Dengzhi, HU Qianwu, ZENG Xiaoyan. Residual Stress and Cracking Behaviors of Cr13Ni5Si2 Based Composite Coatings Prepared by Laser-induction Hybrid Cladding［J］. Surface and Coatings Technology， 2015, 274:51-59.
［6］张天刚，孙荣禄. TC4表面激光熔覆Ni60涂层裂纹有限元分析［J］. 金属热处理, 2018, 43(3):190-194.
ZHANG Tiangang, SUN Ronglu. Finite Element Analysis of Crack in Laser Clad Ni60 Coating on TC4 Surface［J］. Heat Treatment of Metals, 2018, 43(3):190-194．
［7］ZHU Ping, LI Peng, GE Fangfang, et al. Effect of Residual Stress on the Wear Behavior of Magnetron Sputtered V-Al-N Coatings Deposited at the Substrate Temperature <200 ℃［J］. Materials Chemistry and Physics. 2023, 296:127218.
［8］郭华锋，李菊丽，孙涛，等. WC颗粒增强Ni基涂层的残余应力及耐磨性能［J］. 金属热处理, 2014, 39(2):72-76.
GUO Huafeng, LI Juli, SUN Tao, et al. Residual Stress and Wear Resistance of WC Particle Reinforced Ni-based Coating［J］. Metal Heat Treatment, 2014, 39(2):72-76.
［9］CRUZ V, CHAO Q, BIRBILIS N, et al. Electrochemical Studies on the Effect of Residual Stress on the Corrosion of 316L Manufactured by Selective Laser Melting［J］. Corrosion Science. 2020, 164:108314.
［10］FARAHMAND P, KOVACEVIC R, An Experimental Numerical Investigation of Heat Distribution and Stress Field in Single- and Multi-track Laser Cladding by a High-power Direct Diode Laser［J］. Optics and Laser Technology, 2014, 63:154-168.
［11］ZHAO Yu, YU Tianbiao, SUN Jiayu, et al. Effect of Laser Cladding on Forming Microhardness and Tensile Strength of YCF101 Alloy Powder in the Different Full Lap Joint Modes［J］. Journal of Alloys and Compounds. 2020, 820:150230.
［12］KRZYZANOWSKI M, BAJDA S, LIU Yijun, et al. 3D Analysis of Thermal and Stress Evolution during Laser Cladding of Bioactive Glass Coatings［J］. Journal of the Mechanical Behavior of Biomedical Materials， 2016, 59:404-417.
［13］VUNDRU C, PAUL S, SINGH R, et al. Numerical Analysis of Multi-layered Laser Cladding for Die Repair Applications to Determine Residual Stresses and Hardness［J］. Procedia Manufacturing, 2018, 26:952-961.
［14］王丽芳，孙亚新，朱刚贤，等. 激光熔覆316L不锈钢残余应力工艺参数的优化模拟［J］. 应用激光, 2019, 39(3):376-380.
WANG Lifang, SUN Yaxin, ZHU Gangxian, et al. Optimization Simulation of Process Parameters for Laser Cladding Residual Stress of 316L Stainless Steel［J］. Applied Lasers, 2019, 39(3):376-380.
［15］MENG Guiru, ZHANG Jingdong, ZHU Lida, et al. Effect of Process Optimization on Laser Additive Manufacturing of Inconel 718 Alloy Based on Finite Element Analysis: Thermal and Structural Evaluation［J］. Optics and Laser Technology， 2023, 162:109261.
［16］古昭昭. 同轴送粉激光熔覆热力耦合数值模拟及工艺参数优化研究［D］．沈阳：东北大学，2018.
GU Zhaozhao. Thermal-mechanical Coupling Numerical Simulation and Process Parameters Optimization of Coaxial Powder Feeding Laser Cladding［D］. Shenyang：Northeastern University, 2018.
［17］赵元. 航空发动机变曲率叶片的激光熔覆修复技术数值仿真模拟研究［D］．秦皇岛：燕山大学，2021.
ZHAO Yuan. Numerical Simulation of Laser Cladding Repair Technology for Variable Curvature Blade of Aeroengine［D］. Qinhuangdao: Yanshan University, 2021.
［18］蔡春波，李美艳，韩彬，等.不同预热温度下宽带激光熔覆铁基涂层数值模拟［J］.应用激光，2017,37(1):66-71.
CAI Chunbo, LI Meiyan, HAN Bin, et al. Numerical Simulation of Fe-based Coating by Wide-band Laser Cladding at Different Preheating Temperatures［J］. Applied Lasers, 2017, 37(1):66-71.
［19］LI Zhonghua, XU Renjun, ZHANG Zhengwen, et al. The Influence of Scan Length on Fabricating Thin-walled Components in Selective Laser Melting［J］. International Journal of Machine Tools and Manufacture, 2017, 126:1-12.
［20］陈昌棚. 基于有限元模拟的激光选区熔化成形TC4应力及变形研究［D］.武汉：华中科技大学，2020.
CHEN Changpeng. Study on Stress and Deformation of TC4 Formed by Selective Laser Melting Based on Finite Element Simulation［D］. Wuhan: Huazhong University of Science and Technology, 2020.
［21］顾建强. 激光熔覆残余应力场的数值模拟［D］.杭州：浙江工业大学,2010.
GU Jianqiang. Numerical Simulation of Residual Stress Field in Laser Cladding［D］. Hangzhou: Zhejiang University of Technology, 2010.
［22］WAQAR S, GUO Kai, SUN Jie. Evolution of Residual Stress Behavior in Selective Laser Melting (SLM) of 316L Stainless Steel through Preheating and In-situ Re-scanning Techniques［J］. Optics & Laser Technology， 2022, 149:107806.
［23］YU Tianyu, LI Ming, BREAUX A, et al. Experimental and Numerical Study on Residual Stress and Geometric Distortion in Powder Bed Fusion Process［J］. Journal of Manufacturing Processes， 2019, 46:214-224.
［24］HAO Mingzhong, SUN Yuwen. A FEM Model for Simulating Temperature Field in Coaxial Laser Cladding of TI6AL4V Alloy Using an Inverse Modeling Approach［J］. International Journal of Heat and Mass Transfer， 2013, 64:352-360.
［25］LIU Shiwen, ZHU Haihong, PENG Gangyong, et al. Microstructure Prediction of Selective Laser Melting AlSi10Mg Using Finite Element Analysis［J］. Materials and Design,2018,142:319-328.
［26］YIN Jie, ZHU Haihong, KE Linda, et al. A Finite Element Model of Thermal Evolution in Laser Micro Sintering［J］. The International Journal of Advanced Manufacturing Technology, 2015, 83:1847-1859.
［27］XIA Mujian, GU Dongdong, YU Guanqun, et al. Selective Laser Melting 3D Printing of Ni-based Superalloy: Understanding Thermodynamic Mechanisms［J］. Science Bulletin, 2016, 61:1013-1022.
［28］TAMANNA N, KABIR I R, NAHER S. Thermo-mechanical Modelling to Evaluate Residual Stress and Material Compatibility of Laser Cladding Process Depositing Similar and Dissimilar Material on Ti6Al4V Alloy［J］. Thermal Science & Engineering Progress， 2022, 31:101283.
［29］HUANG Shuyu, QIAO Shangfei, SHAO Chendong, et al. Study on Residual Stress Evolution of Laser Cladding Low Chromium Carbon Alloy on Low-pressure Rotor［J］. Journal of Manufacturing Processes, 2023, 85:31-42.
［30］任仲贺，武美萍，唐又红，等.基于热力耦合的激光熔覆数值模拟与实验研究［J］.激光与光电子学进展, 2019, 56(5):176-185.
REN Zhonghe, WU Meiping, TANG Youhong, et al. Numerical Simulation and Experimental Research of Laser Cladding Based on Thermo-mechanical Coupling［J］Laser & Optoelectronics Progress, 2019, 56(5):176-185.
［31］潘浒，赵剑峰，刘云雷，等. 激光熔覆修复镍基高温合金稀释率的可控性研究［J］.中国激光, 2013, 40(4):109-115.
PAN Hu , ZHAO Jianfeng, LIU Yunlei, et al. Controllability Research on Dilution Ratio of Nickel-based Superalloy by Laser Cladding Reparation［J］. Chinese Journal of Lasers, 2013, 40(4):109-115.
［32］KAMARA A M, WANG W, MARIMUTHU S, et al. Modelling of the Melt Pool Geometry in the Laser Deposition of Nickel Alloys Using the Anisotropic Enhanced Thermal Conductivity Approach［J］.Proceedings of the Institution of Mechanical Engineers Part B Journal of Engineering Manufacture. 2011, 225:87-99.
［33］CHEN Changpeng, YIN Jie, ZHU Haihong, et al. Effect of Overlap Rate and Pattern on Residual Stress in Selective Laser Melting［J］. International Journal of Machine Tools and Manufacture, 2019, 145:103433.
［34］HUSSEIN A, HAO Liang, YAN Chunze, et al. Finite Element Simulation of the Temperature and Stress Fields in Single Layers Built Without-support in Selective Laser Melting［J］. Materials and Design, 2013, 52:638-647.
［35］LI Yingli, ZHOU Kun, TAN Pengfei, et al. Modeling Temperature and Residual Stress Fields in Selective Laser Melting［J］. International Journal of Mechanical Sciences, 2018, 136:24-35.
［36］CHENG Bo, SHRESTHA S, CHOU K. Stress and Deformation Evaluations of Scanning Strategy Effect in Selective Laser Melting［J］. Additive Manufacturing, 2016, 12:240-251.
［37］MUGWAGWA L, DIMITROV D, MATOPE S, et al. Evaluation of the Impact of Scanning Strategies on Residual Stresses in Selective Laser Melting［J］. The International Journal of Advanced Manufacturing Technology, 2019, 102:2441-2450.

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