激光熔覆过程中的粉、气、光耦合温度场

doi:10.3969/j.issn.1004-132X.2022.01.008

中国机械工程 ›› 2022, Vol. 33 ›› Issue (01): 70-77.DOI: 10.3969/j.issn.1004-132X.2022.01.008

激光熔覆过程中的粉、气、光耦合温度场

许明三1,2;周春辉1,2;张正1,2;曾寿金1,2

1.福建工程学院机械与汽车工程学院，福州，350118
2.福建工程学院先进制造生产力促进中心，福州，350118

出版日期:2022-01-10 发布日期:2022-01-19
作者简介:许明三，男，1974年生，教授。研究方向为激光增材制造技术、硬脆材料加工技术。发表论文40余篇。E-mail:xums368@163.com。
基金资助:
国家自然科学基金（51575110）;
福建省自然科学基金(2020J01872，2021J011052)

Temperature Distribution of Powder-gas-optical Coupling temperature field in Laser Cladding Processes

XU Mingsan1，2;ZHOU Chunhui1，2;ZHANG Zheng1，2;ZENG Shoujin1，2

1.School of Mechanical & Automotive Engineering, Fujian University of Technology,Fuzhou,350118
2.Advanced Manufacturing Productivity Promotion Center,Fujian University of Technology,Fuzhou,350118

Online:2022-01-10 Published:2022-01-19

摘要/Abstract

摘要： 激光熔覆过程中，粉末到达基体表面前存在粉、气、光的耦合温度场。建立了送粉过程中粉、气、光耦合温度场的三维数值模型。耦合温度场的研究结果表明：激光功率是影响耦合温度的主要因素，载粉气是影响耦合温度场的主要因素；温度场的红外测温仪实测结果与仿真结果基本相符。

关键词: 激光熔覆, 温度场, 数值模拟, 耦合, 金属粉末

Abstract: There was a powder-gas-light coupling temperature field before powders reachesd substrate surfaces in laser cladding processes. A 3D numerical model of the powder-gas-light coupling temperature field during the feeding processes was established. Research results of the coupling temperature field show that laser power is the main factor of coupling temperature, and the powder carrier gas is the main factor of coupling temperature field; the coupling temperature field of infrared thermometer is basically consistent with simulated temperature field.

Key words: laser cladding, temperature field, numerical simulation, coupling, metal powder

中图分类号:

TN249

许明三, 周春辉, 张正, 曾寿金, . 激光熔覆过程中的粉、气、光耦合温度场[J]. 中国机械工程, 2022, 33(01): 70-77.

XU Mingsan, ZHOU Chunhui, ZHANG Zheng, ZENG Shoujin, . Temperature Distribution of Powder-gas-optical Coupling temperature field in Laser Cladding Processes[J]. China Mechanical Engineering, 2022, 33(01): 70-77.

参考文献

［1］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 on ICE Remanufacture with Additive Repair Technology［J］. China Mechanical Engineering, 2019, 30(9)：1119-1127.
［2］朱红梅,胡际鹏,李柏春,等. 铁基材料表面激光熔覆不锈钢涂层的研究进展［J］. 表面技术, 2020, 49(3)：74-84.
ZHU Hongmei, HU Jipeng, LI Baichun ,et al. Research Progress of Laser Cladding Stainless Steel Coating on Fe-based Substrate［J］. Surface Technology, 2020, 49(3):74-84.
［3］黄怡晨. 激光熔覆喷嘴粉末汇聚特性及其与熔池相互作用研究［D］.哈尔滨：哈尔滨工业大学, 2017.
HANG Yichen. Research on Convenience Properties of Powder in Coaxial Laser Cladding Nozzle and the Interaction with Melt Pool［D］. Harbin：Harbin Institute of Technology, 2017.
［4］TAMANNA N, CROUCH R, NAHER S. Progress in Numerical Simulation of the Laser Cladding Process［J］. Optics and Laser in Engineering, 2019, 122：151-163.
［5］BEDENKO D V, GULAIEV I P, GURIN A M, et al. Modelling of Gas-powder Transportation during Coaxial Laser Cladding［C］∥International Conference on the Methods of Aerophysical Research. Novosibirsk, 2018:23-24.
［6］FERREIRA E, DAL M, COLIN C, et al. Experimental and Numerical Analysis of Gas/Powder Flow for Different LMD Nozzles［J］. Metals, 2020, 10(5)：667.
［7］POLYANSKIY T A, ZAITSEV A V, GULYAEV I P, et al. Numerical and Experimental Investigation of Two Phase Flow for Direct Metal Deposition［J］. Journal of Physics Conference Series, 2018,1109(1)：012010.
［8］KOVALEV O. Comparative Analysis of Performance Characteristics of Nozzle Heads for Powder Transportation in a Laser Cladding and Direct Material Deposition［J］. Matec Web of Conferences, 2018, 224:01041.
［9］ZAITSEV A V, GULYAEV I P, POLYANSKIY T A, et al. Numerical and Experimental Study of Dispersed Flow in Laser Cladding［C］∥International Conference on the Methods of Aerophysical Research［J］.AIP Conference Proceedings, 2018, 2027：030147.
［10］WIRTH F, WEGENER K. Simulation of the Multi-component Process Gas Flow for the Explanation of Oxidation during Laser Cladding［J］. Additive Manufacturing, 2018, 24：249-256.
［11］ZHANG J, YANG L, ZHANG W, et al. Numerical Simulation and Experimental Study for Aerodynamic Characteristics and Powder Transport Behavior of Novel Nozzle［J］. Optics and Lasers in Engineering, 2020,126(1)：105873.
［12］李刚,张津超,石世宏,等. 开放环境下钛合金激光熔覆局部保护气体的质量分布［J］. 中国激光, 2019, 46(7)：118-124.
LI Gang, ZHANG Jinchao, SHI SHihong, et al. Mass Distribution of Local Shielding Gas for Laser Cladding of Titanium Alloy in Open Environment［J］. Chinese Journal of Lasers, 2019, 46(7)：118-124.
［13］GAO J L, WU C Z, LIANG X D, et al. Numerical Simulation and Experimental Investigation of the Influence of Process Parameters on Gas-powder Flow in Laser Metal Deposition［J］. Optics and Laser in Engineering, 2020, 125：106009.
［14］LIU H, HAO J B, YU G, et al. A Numerical Study on Metallic Powder Flow in Coaxial Laser Cladding［J］. Journal of Applied Fluid Mechanics, 2016, 9(5)：2247-2256.
［15］MONTERO J, ROODRGUEZ , AMADO J M, et al. Inspection of Powder Flow during LMD Deposition by High Speed Imaging［J］. Physics Procedia, 2016, 83(1)：1319-1328.
［16］席明哲，虞钢，张永忠，等. 同轴送粉激光成形中粉末与激光的相互作用［J］. 中国激光, 2005， 32(4)：562-566.
XI Mingzhe, YU Gang, ZHANG Yongzhong, et al. Interaction of the Laser Beam and the Metal Powder Conveyed by Coaxial Powder Feeder［J］. Chinese Journal of Lasers, 2005, 32(4)：562-566.
［17］彭如意,罗岚,刘勇,等. 同轴送粉器喷嘴研究进展［J］. 激光与光电子学进展, 2017,54(8)：37-45.
PENG Ruyi, LUO Lan, LIU Yong, et al. Research Progress in Coaxial Powder Feeding Nozzles［J］.Laser & Optoelectronics Progress, 2017,54(8)：37-54.
［18］AL HAMAHMY M I, DEIAB Z. Review and Analysis of Heat Source Models for Additive Manufacturing［J］. The International Journal of Advanced Manufacturing Technology, 2020, 106(1)：1223–1238.
［19］张冬云,吴瑞,张晖峰,等. 激光金属熔覆成形过程中温度场演化的三维数值模拟［J］. 中国激光, 2015, 42(5)：104-115.
ZHANG Dongyun, WU Rui, ZHANG Huifeng, et al. Numerical Simulation of Temperature Field Evolution in the Process of Laser Metal Deposition［J］. Chinese Journal of Lasers, 2015,42(5)：104-155.

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激光熔覆过程中的粉、气、光耦合温度场

Temperature Distribution of Powder-gas-optical Coupling temperature field in Laser Cladding Processes

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