Transactions of The China Welding Institution >

2022 , Vol. 43 >Issue 2: 11 - 19

DOI: https://doi.org/10.12073/j.hjxb.20210710001

Thermo-mechanical modelling of direct energy deposition using inversely identified heat source parameter

  • HOU Liang ,
  • XU Yang ,
  • CHEN Yun ,
  • YE Chao ,
  • GUO Jing ,
  • HU Xueman
Expand
  • Xiamen University, Xiamen, 361102, China

Received date: 2021-07-10

  Online published: 2022-04-18

Fold

Abstract

Thermal-mechanical simulation of direct energy deposition (DED) is an effective method to predict the residual stress and deformation and optimize deposition process parameters. The simulation accuracy depends on input parameters which are difficult to be directly and accurately measured in most cases. This paper, taking heat source parameters as examples, proposes an inverse identification method based on support vector machine and genetic algorithm, and the inversely-identified heat parameters are further used to improve the thermal-mechanical model accuracy of real DED applications. Firstly, simulation errors of simple single-track deposition models under different heat source parameters are obtained. Secondly, the relationship between the heat source parameters and simulation errors is established using support vector regression, and the optimized initial heat sources are identified using genetic algorithm. Thirdly, a forward-inverse closed loop is applied to narrow the ranges of heat source parameters for more precise parameter identification. Finally, a thermal-mechanical model for a turbine blade using the optimal parameters is constructed to further verify the proposed method. The results show that the optimal heat source parameters extracted from single-track deposition models can be extended to accurately predict the thermal and mechanical results of a turbine blade DED case, which provide a practical method for DED process optimization (e.g. distortion compensation) in industry applications.

Key words: direct energy deposition; inverse identification; heat source parameter; thermo-mechanical modelling

Cite this article

HOU Liang , XU Yang , CHEN Yun , YE Chao , GUO Jing , HU Xueman . Thermo-mechanical modelling of direct energy deposition using inversely identified heat source parameter[J]. Transactions of The China Welding Institution, 2022 , 43(2) : 11 -19 . DOI: 10.12073/j.hjxb.20210710001

References

[1] Wang Q, Shi J M, Zhang L X, et al. Impacts of laser cladding residual stress and material properties of functionally graded layers on titanium alloy sheet[J]. Additive Manufacturing, 2020, 35: 101303 - 101312.
[2] Zhang Z, Kovacevic R. A thermo-mechanical model for simulating the temperature and stress distribution during laser cladding process[J]. The International Journal of Advanced Manufacturing Technology, 2019, 102(1-4): 457 - 472.
[3] 舒林森, 王家胜, 白海清, 等. 磨损轴面激光熔覆过程的数值模拟及试验[J]. 机械工程学报, 2019, 55(9): 217 - 223
Shu Linsen, Wang Jiasheng, Bai Haiqing, et al. Numerical and experimental investigation on laser cladding treatment of wear shaft surface[J]. Journal of Mechanical Engineering, 2019, 55(9): 217 - 223
[4] Liu H M, Qin X P, Wu M W, et al. Numerical simulation of thermal and stress field of single track cladding in wide-beam laser cladding[J]. The International Journal of Advanced Manufacturing Technology, 2019, 104(9-12): 3959 - 3976.
[5] Walker T R, Bennett C J, Lee T L, et al. A novel numerical method to predict the transient track geometry and thermomechanical effects through in-situ modification of the process parameters in direct energy deposition[J]. Finite Elements in Analysis & Design, 2020, 169: 103347 - 103366.
[6] 李亚敏, 咬登治, 范福杰. 激光熔覆718合金工艺参数优化的数值模拟研究[J]. 应用激光, 2018, 38(6): 920 - 938
Li Yamin, Yao Dengzhi, Fan Fujie. Numerical Simulation of Inconel 718 Alloy during laser cladding[J]. Applied Laser, 2018, 38(6): 920 - 938
[7] Zeng Z, Wang L J, Li X B. Numerical optimization design on the parameters of double ellipsoid welding heat source[C]//2nd International Conference on Manufacturing Science and Engineering, 2011: 189-193.
[8] Moniz L, Chen Q, Guillemot G, et al. Additive manufacturing of an oxide ceramic by laser beam melting—Comparison between finite element simulation and experimental results[J]. Journal of Materials Processing Technology, 2019, 270: 106 - 117.
[9] Yadav A, Ghosh A, Kumar A. Experimental and numerical study of thermal field and weld bead characteristics in submerged arc welded plate[J]. Journal of Materials Processing Technology, 2017, 248: 262 - 274.
[10] Karkhin V A, Pittner A, Schwenk C, et al. Simulation of inverse heat conduction problems in fusion welding with extended analytical heat source models[J]. Frontiers of Materials Science, 2011, 5(2): 119 - 125.
[11] Hao M Z, Sun Y. 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: 325 - 360.
[12] Slavash G, Gholam H F, Movahhedy M R. Considering cyclic plasticity to predict residual stresses in laser cladding of Inconel 718 multi bead samples[J]. Journal of Manufacturing Processes, 2019, 42: 149 - 158.
[13] 宋燕利, 余成, 戴定国, 等. 基于BP和GA的激光焊接热源模型参数优化[J]. 塑性工程学报, 2017, 24(1): 218 - 222
Song Yanli, Yu Cheng, Dai Dingguo, et al. Parameter optimization of heat source model for laser welding based on BP neural network and genetic algorithm[J]. Journal of Plasticity Engineering, 2017, 24(1): 218 - 222
[14] 刘青星, 黄海松, 姚立国, 等. 改进孪生神经网络的控制图模式识别方法[J]. 小型微型计算机系统, 2021, 42(5): 935 - 939
Liu Qingxing, Huang Haisong, Yao Liguo, et al. Pattern recognition of control chart method improving siamese neural networks[J]. Journal of Chinese Ccomputer Systems, 2021, 42(5): 935 - 939
[15] Ren K, Chew Y, Fuh J Y H, et al. Thermo-mechanical analyses for optimized path planning in laser aided additive manufacturing processes[J]. Materials & Design, 2019, 162: 80 - 93.
[16] Walker T R, Bennett C J, Lee T L, et al. A validated analytical-numerical modelling strategy to predict residual stresses in single-track laser deposited IN718[J]. International Journal of Mechanical Sciences, 2018, 151: 609 - 621.
[17] Javid Y, Ghoreishi M. Thermo-mechanical analysis in pulsed laser cladding of WC powder on Inconel 718[J]. The International Journal of Advanced Manufacturing Technology, 2017, 92(1-4): 69 - 79.
[18] Goldak J, Charkavarti A, Bibby M. A new finite element model for welding heat sources[J]. Metallurgical Transactions B, 1984, 15(2): 299 - 305.
[19] 路华伟. 激光熔覆成形薄壁件及其温度场的有限元模拟研究[D]. 沈阳: 东北大学, 2017.
Lu Huawei. The study of laser cladding forming thin-wall part and the temperature field of the forming process[D]. Shenyang: Northeastern University, 2017.
[20] 朱大业, 丁晓红, 王神龙, 等. 基于支持向量机模型的复杂非线性系统试验不确定度评定方法[J]. 机械工程学报, 2018, 54(8): 177 - 184
Zhu Daye, Ding Xiaohong, Wang Shenlong, et al. Uncertainty evaluation method of complex nonlinear system test[J]. Journal of Mechanical Engineering, 2018, 54(8): 177 - 184
[21] Li B, Chen Y B. Review on intelligence fault diagnosis in power networks[J]. Power System Protection and Control, 2014, 42(3): 146 - 153.
[22] 李彬, 张云, 王立平, 等. 基于遗传算法优化小波神经网络数控机床热误差建模[J]. 机械工程学报, 2019, 55(21): 215 - 220
Li Bin, Zhang Yun, Wang Liping, et al. Modeling for CNC machine tool thermal error based on genetic algorithm optimization wavelet neural networks[J]. Journal of Mechanical Engineering, 2019, 55(21): 215 - 220
[23] 田芳, 周孝信, 于之虹. 基于支持向量机综合分类模型和关键样本集的电力系统暂态稳定评估[J]. 电力系统保护与控制, 2017, 45(22): 1 - 8
Tian Fang, Zhou Xiaoxin, Yu Zhihong. Power system transient stability assessment based on comprehensive SVM classification model and key sample set[J]. Power System Protection and Control, 2017, 45(22): 1 - 8
[24] Li P, Lu H. Hybrid heat source model designing and parameter prediction on tandem submerged arc welding[J]. The International Journal of Advanced Manufacturing Technology, 2012, 62(5-8): 577 - 585.
[25] Gu Y, Li Y D, Yong Y, et al. Determination of parameters of double-ellipsoidal heat source model based on optimization method[J]. Springer Berlin Heidelberg, 2019, 63(2): 365 - 376.
[26] 孔刘伟, 王振忠, 叶超, 等. 五轴增减材混合加工中心集成开发技术研究[J]. 航空制造技术, 2019, 62(6): 53 - 59
Kong Liuwei Wang Zhenzhong, Ye Chao, et al. Research on developing technology of five-axis additive-subtractive hybrid machining center[J]. Aeronautical Manufacturing Technology, 2019, 62(6): 53 - 59
[27] Lu X, Lin X, Chiument M, et al. Residual stress and distortion of rectangular and S-shaped Ti-6Al-4V parts by directed energy deposition: Modelling and experimental calibration[J]. Additive Manufacturing, 2019, 26: 169 - 179.
[28] Withers P J, Preuss M, Steuwer A, et al. Methods for obtaining the strain-free lattice parameter when using diffraction to determine residual stress[J]. Journal of Applied Crystallography, 2007, 40(5): 891 - 904.
[29] Chun B C, Mei Y L, Bin H. Numerical simulation iron-based cladding coating with wide-band laser at different preheating temperatures[J]. Applied Laser, 2017, 37(1): 66 - 71.
Options
Outlines

/

  Copyright © Transactions of The China Welding Institution, All Rights Reserved.
Powered by Beijing Magtech Co. Ltd,.