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Abstract

The mitigation of material defects from additive manufacturing (AM) processes is critical to reliability in their fabricated parts and is enabled by modeling the complex relations between available build monitoring signals and final mechanical performance. To this end, the present study investigates a machine learning approach for predicting mechanical properties for Ti-6Al-4V fabricated through laser powder bed fusion (PBF-LB) AM using in situ photodiode processing signals. Samples were fabricated under different processing parameters, varying laser powers and scan speeds for the purpose of probing a wide range of microstructure and property variations. Photodiode data were collected during fabrication, later to be arranged in image format and extracted to information-dense vectors by the transferal of deep convolutional neural network (DCNN) structures and weights pretrained on a large computer vision benchmark image database. The extracted features were then used to train and test a newly designed regression model for mechanical properties. Average cross-validation accuracies were found to be 98.7% (r² value of 0.89) for the prediction of ultimate tensile strength, which ranged from 900 to 1150 MPa in the samples studied, and 93.1% (r² value of 0.96) for the prediction of elongation to fracture, which ranged from 0 to 17%. Thus, with high accuracy and hardware-accelerated inference speeds, we demonstrate that a transfer learning framework can be used to predict strength and ductility of metal AM components based on processing signals in PBF-LB, illustrating a potential route toward real-time closed-loop control and process optimization of PBF-LB in industrial applications.

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References

DebRoy

, Wei

, Zuback

, et al. Additive manufacturing of metallic components—Process, structure and properties. Prog Mater Sci, 2018; 92:112–224; doi: 10.1016/j.pmatsci.2017.10.001

Liu

, Shin

. Additive manufacturing of Ti6Al4V alloy: A review. Mater Des, 2019; 164:107552; doi: 10.1016/j.matdes.2018.107552

Gordon

, Narra

, Cunningham

, et al. Defect structure process maps for laser powder bed fusion additive manufacturing. Addit Manuf, 2020; 36:101552; doi: 10.1016/j.addma.2020.101552

Gong

, Rafi

, Gu

, et al. Analysis of defect generation in Ti–6Al–4V parts made using powder bed fusion additive manufacturing processes. Addit Manuf, 2014; 1–4(4):87–98; doi: 10.1016/j.addma.2014.08.002

Niu

, Chang

ITH

. Instability of scan tracks of selective laser sintering of high speed steel powder. Scr Mater, 1999; 41(11):1229–1234; doi: 10.1016/S1359-6462(99)00276-6

, Shen

. Balling phenomena during direct laser sintering of multi-component Cu-based metal powder. J Alloys Compd, 2007; 432(1–2):163–166; doi: 10.1016/j.jallcom.2006.06.011

Luo

, Yin

, Simpson

, et al. Effect of processing parameters on pore structures, grain features, and mechanical properties in Ti-6Al-4V by laser powder bed fusion. Addit Manuf, 2022; 56:102915; doi: 10.1016/j.addma.2022.102915

Furton

, Wilson-Heid

, Beese

. Effect of stress triaxiality and penny-shaped pores on tensile properties of laser powder bed fusion Ti-6Al-4V. Addit Manuf, 2021; 48:102414; doi: 10.1016/j.addma.2021.102414

du Plessis

, Yadroitsev

, Yadroitsava

, et al. X-ray microcomputed tomography in additive manufacturing: A review of the current technology and applications. 3D Print Addit Manuf, 2018; 5(3):227–247; doi: 10.1089/3dp.2018.0060

10.

, Zhang

, Li

, et al. Detection of internal holes in additive manufactured Ti-6Al-4V part using laser ultrasonic testing. Appl Sci, 2020; 10(1):10010365; doi: 10.3390/app10010365

11.

Honarvar

, Varvani-Farahani

. A review of ultrasonic testing applications in additive manufacturing: defect evaluation, material characterization, and process control. Ultrasonics, 2020; 108:106227; doi: 10.1016/j.ultras.2020.106227

12.

Everton

, Hirsch

, Stavroulakis

, et al. Review of in-situ process monitoring and in-situ metrology for metal additive manufacturing. Mater Des, 2016; 95:431–445; doi: 10.1016/J.MATDES.2016.01.099

13.

Petrich

, Snow

, Corbin

, et al. Multi-modal sensor fusion with machine learning for data-driven process monitoring for additive manufacturing. Addit Manuf, 2021; 48:102364; doi: 10.1016/j.addma.2021.102364

14.

Coeck

, Bisht

, Plas

, et al. Prediction of lack of fusion porosity in selective laser melting based on melt pool monitoring data. Addit Manuf, 2019; 25:347–356; doi: 10.1016/j.addma.2018.11.015

15.

Bisht

, Ray

, Verbist

, et al. Correlation of selective laser melting-melt pool events with the tensile properties of Ti-6Al-4V ELI processed by laser powder bed fusion. Addit Manuf, 2018; 22:302–306; doi: 10.1016/j.addma.2018.05.004

16.

Holm

. In defense of the black box. Science (80–), 2019; 364(6435):26–27; doi: 10.1126/science.aax0162

17.

Kouraytem

, Li

, Tan

, et al. Modeling process-Structure-property relationships in metal additive manufacturing: A review on physics-driven versus data-driven approaches. J Phys Mater, 2021; 4(3):032002; doi: 10.1088/2515-7639/abca7b

18.

Zhang

, Liu

, Shin

. In-process monitoring of porosity during laser additive manufacturing process. Addit Manuf, 2019; 28:497–505; doi: 10.1016/j.addma.2019.05.030

19.

Mao

, Lin

, Yu

, et al. A deep learning framework for layer-wise porosity prediction in metal powder bed fusion using thermal signatures. J Intell Manuf, 2023; 34(1):315–329; doi: 10.1007/s10845-022-02039-3

20.

Akhavan

, Lyu

, Manoochehri

. A deep learning solution for real-time quality assessment and control in additive manufacturing using point cloud data. J Intell Manuf, 2023; In Press; doi: 10.1007/s10845-023-02121-4

21.

Deng

, Dong

, Socher

, et al. ImageNet: A Large-Scale Hierarchical Image Database. In: 2009 IEEE Conference on Computer Vision and Pattern Recognition, Miami, FL, USA;, 2009; pp. 248–255; doi: 10.1109/cvpr.2009.5206848

22.

Lin

, Maire

, Belongie

, et al. Microsoft COCO: Common Objects in Context. Computer Vision–ECCV 2014: 13th European Conference, Zurich, Switzerland, September 6-12, 2014, Proceedings, Part V, 13; pp. 740–755; doi: 10.1007/978-3-319-10602-1_48

23.

Luo

, Holm

, Wang

. A transfer learning approach for improved classification of carbon nanomaterials from TEM images. Nanoscale Adv, 2021; 3(1):206–213; doi: 10.1039/D0NA00634C

24.

Tang

, Rahmani Dehaghani

, Wang

. Review of transfer learning in modeling additive manufacturing processes. Addit Manuf, 2023; 61:103357; doi: 10.1016/j.addma.2022.103357

25.

Fischer

, Zimmermann

, Praetzsch

, et al. Monitoring of the powder bed quality in metal additive manufacturing using deep transfer learning. Mater Des, 2022; 222:111029; doi: 10.1016/j.matdes.2022.111029

26.

Pandiyan

, Drissi-Daoudi

, Shevchik

, et al. Deep transfer learning of additive manufacturing mechanisms across materials in metal-based laser powder bed fusion process. J Mater Process Technol, 2022; 303:117531; doi: 10.1016/j.jmatprotec.2022.117531

27.

, Zhang

, Zhao

, et al. A transfer learning approach for microstructure reconstruction and structure-property predictions. Sci Rep, 2018; 8(1):1–13; doi: 10.1038/s41598-018-31571-7

28.

, Zhou

, Huang

, et al. In situ quality inspection with layer-wise visual images based on deep transfer learning during selective laser melting. J Intell Manuf, 2023; 34(2):853–867; doi: 10.1007/s10845-021-01829-5

29.

Luo

, Yin

, Simpson

, et al. Dataset of process-structure-property feature relationship for laser powder bed fusion additive manufactured Ti-6Al-4V material. Data Br, 2023; 46:108911; doi: 10.1016/j.dib.2023.108911

30.

Ray

, Bisht

, Thijs

, et al. DMP Monitoring as a Process Optimization Tool for Direct Metal Printing (DMP) of Ti-6Al-4V. In: Solid Freeform Fabrication 2018: Proceedings of the 29th Annual International Solid Freeform Fabrication Symposium—An Additive Manufacturing Conference, SFF 2018, Austin, TX, USA; 2018; pp. 2244–2253.

31.

Abadi

, Barham

, Chen

, et al. TensorFlow: A System for Large-Scale Machine Learning. In: Proceedings of the 12th USENIX Symposium on Operating Systems Design and Implementation, OSDI 2016, Savannah, GA, USA; 2016; pp. 265–283.

32.

Chollet

Keras: The Python Deep Learning Library. Astrophysics Source Code Library. KerasIo; 2018. Available from: https://keras.io [Last accessed: January 16, 2024].

33.

Luebke

CUDA: Scalable Parallel Programming for High-Performance Scientific Computing. In: 2008 5th IEEE International Symposium on Biomedical Imaging: From Nano to Macro, IEEE: Paris, France;, 2008; pp. 836–838; doi: 10.1109/ISBI.2008.4541126

34.

Simonyan

, Zisserman

. Very deep convolutional networks for large-scale image recognition. arXiv preprint;, 2014; arXiv:1409.1556.

35.

, Zhang

, Ren

, et al. Deep Residual Learning for Image Recognition. In: 2016 IEEE Conference on Computer Vision and Pattern Recognition, CVPR 2016, Las Vegas, NV, USA;, 2016; pp.770–778; doi: 10.1109/CVPR.2016.90

36.

Kingma

, Ba

. Adam: A method for stochastic optimization. arXiv preprint;, 2014; arXiv:1412.6980.

37.

Everitt

, Skrondal

The Cambridge Dictionary of Statistics. Cambridge University Press: Cambridge; 2010.

38.

Cortes

, Vapnik

. Support-vector networks. Mach Learn, 1995; 20(3):273–297; doi: 10.1023/A:1022627411411

39.

Breiman

Random forests. Mach Learn, 2001; 45(1):5–32; doi: 10.1023/A:1010933404324

40.

Diehl

, Nassar

. Reducing near-surface voids in metal (Ti-6Al-4V) powder bed fusion additive manufacturing: the effect of inter-hatch travel time. Addit Manuf, 2020; 36:101592; doi: 10.1016/j.addma.2020.101592

41.

Schwalbach

, Donegan

, Chapman

, et al. A discrete source model of powder bed fusion additive manufacturing thermal history. Addit Manuf, 2019; 25:485–498; doi: 10.1016/j.addma.2018.12.004

42.

ASTM E8, ASTM E8/E8M standard test methods for tension testing of metallic materials 1, Annu. B ASTM Stand, 4 2010; 1–27; doi.org/10.1520/E0008

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An Image-Based Transfer Learning Approach for Using In Situ Processing Data to Predict Laser Powder Bed Fusion Additively Manufactured Ti-6Al-4V Mechanical Properties

Abstract

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References

Supplementary Material