[1]曾 超,徐国强,田青牛.TiC颗粒增强镍基合金激光熔覆工艺仿真[J].机械与电子,2021,(04):17-22.
 ZENG Chao,XU Guoqiang,TIAN Qingniu.Simulation of Laser Cladding Process of TiC Particle Reinforced Nickel Base Alloy[J].Machinery & Electronics,2021,(04):17-22.
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TiC颗粒增强镍基合金激光熔覆工艺仿真()
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机械与电子[ISSN:1001-2257/CN:52-1052/TH]

卷:
期数:
2021年04期
页码:
17-22
栏目:
设计与研究
出版日期:
2021-04-24

文章信息/Info

Title:
Simulation of Laser Cladding Process of  TiC Particle Reinforced Nickel Base Alloy
文章编号:
1001-2257(2021)04-0017-06
作者:
曾 超徐国强田青牛
贵州理工学院航空航天工程学院,贵州 贵阳 550003
Author(s):
ZENG Chao XU GuoqiangTIAN Qingniu
School of Aerospace Engineering, Guizhou Institute of Technology, Guiyang 550003, China
关键词:
有限元激光熔覆TiC/Inconel718金属基复合材料工艺参数
Keywords:
finite element laser cladding TiC/Inconel 718 MMCs process parameters
分类号:
TN249
文献标志码:
A
摘要:
通过有限元分析方法对不同激光功率、扫描速率以及光斑直径下TiC/Inconel 718复合材料制造过程中的热-力学特征进行了研究。通过线性组分公式确定复合材料的热物理性能参数,选用半球高斯热源模拟激光温度载荷,利用生死单元技术实现金属粉末增材过程。采用间接法进行激光熔覆热-力耦合分析,基于温度分析结果转换单元类型进行热应力计算。研究表明个工艺参数与温度、温度变化率及残余应力的变化存在一定的规律,且激光加工功率在225~250 W之间、扫描速度在1.0~1.5 mm/s之间、光斑半径在2.5~3.0 mm之间达存在最佳加工参数,可以达到较好的熔覆效果。
Abstract:
Thermal-mechanical characteristics of TiC/Inconel718 composites under different laser powers, scanning rates and spot diameters were studied by finite element method. The thermophysical properties of the composite were determined by a linear formula based on the mass rate of TiC to Inconel718. The hemispherical Gaussian heat source was used to simulate the laser temperature load, and the “birth and death element” technology was used to simulate the metal powder additive process. The laser cladding thermal-mechanical coupling effect was implemented by the indirect method, and the thermal stress was calculated based on the temperature analysis results by switching the element type. The result shows that the three process parameters have certain influence rules with the changed temperature, temperature rate and residual stress, and the optimal processing parameters which achieve good cladding effect lie in a laser power between 225 and 250 W, scanning velocity between 1.0 and 1.5 mm/s, and spot radius between 2.5 and 3 .0 mm.

参考文献/References:

[1]石齐民,顾冬冬,顾荣海,等.TiC/Inconel 718复合材料选区激光熔化成形的热物理机制[J].稀有金属材料与工程,2017,46(6):1543-1550.

[2]宋卫东,宁建国,毛小南.TiC颗粒增强钛基复合材料细观动态力学性能[J].稀有金属材料与工程,2011,40(9):1555-1560.

[3] EMAMIAN A , CORBIN S F , KHAJEPOUR A . The influence of combined laser parameters on in-situ formed TiC morphology during laser cladding[J]. Surface and coatings technology, 2011, 206(1):124-131.



[4]张可敏,邹建新,李军,等.TC4钛合金表面激光熔覆法制备Y2O3颗粒增强Ni/TiC复合涂层[J].中国有色金属学报(英文版),2012,22(8):1817-1823.

[5]杨光,王向明,王维,等.激光熔覆制备TiC颗粒增强涂层的组织和性能[J].红外与激光工程,2014(3):795-799.

[6]张现虎.原位合成复合颗粒增强镍基激光熔覆层研究[D].郑州:郑州大学,2009.

[7] CHEN T , WU W , LI W , et al. Laser cladding of nanoparticle TiC ceramic powder: Effects of process parameters on the quality characteristics of the coatings and its prediction model[J]. Optics and laser technology, 2019, 116:345-355.

[8]孔令海.TiC+TiB2颗粒增强Fe基激光熔覆层的组织与性能研究[J].现代制造技术与装备,2010(4):10-11,14.

[9] EMAMIANA , CORBIN S F , KHAJEPOUR A . Effect of laser cladding process parameters on clad quality and in-situ formed microstructure of Fe–TiC composite coatings[J]. Surface and coatings technology, 2010, 205(7):2007-2015.

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备注/Memo

备注/Memo:

收稿日期:2020-08-28

基金项目:贵州省基础科研重点项目(黔科合基础[2019]1415);贵州理工学院高层次人才科研启动经费项目XJGC20190947
作者简介:曾 超 (1986—),男,四川绵阳人,副教授,研究方向为激光表面改性。

更新日期/Last Update: 2021-04-15