Top

The International Journal of Advanced Manufacturing Technology

Published in:

14-12-2023 | ORIGINAL ARTICLE

Convolutional LSTM based melt-pool prediction from images of laser tool path strategy in laser powder bed fusion for additive manufacturing

Authors: Joung Min Park, Minho Choi, Jumyung Um

Published in: The International Journal of Advanced Manufacturing Technology | Issue 3-4/2024

Activate our intelligent search to find suitable subject content or patents.

search-config

AI-assisted search

Off

Abstract

As the importance of mass customization production is increasing, additive manufacturing have been an emerging method of end-product process not only prototype production. Despite continuous improvements, metal processes, such as Laser Powder Bed Fusion, face challenges such as inconsistent output quality and the need for extensive post-processing. Recent approaches are the real-time adjustments of laser power along the meltpool size captured by an online camera. This method, however, still consume the cost and time to find optimized process plan. This paper introduces a novel approach that predicts melt-pool size and thermal peaks based on tool path strategies, without the trial-and-error of actual processes, by using pre-trained deep learning models. Convolutional Long Short-Term Memory algorithm-based model converts enhanced images of toolpath data-including laser coordinates and laser paramenters-into the size graph of meltpools. Using an open dataset of 12 different cubes made by additive process, The deep learning model is trained with tool path strategies and meltpool images in advance. The proposed model detects intensive meltpool peaks to choose optimal laser powers during bi-directional and spiral tool paths.

previous article Numerical and analytical estimation of rolling force and torque in hot strip rolling

next article Graded cellular structures for enhanced performance of additively manufactured orthopaedic implants

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

inform now

Baumgartl H, Tomas J, Buettner R et al (2020) A deep learning-based model for defect detection in laser-powder bed fusion using in-situ thermographic monitoring. Prog Addit Manufac 5(3):277–285CrossRef

Boutaous M, Liu X, Siginer DA et al (2021) Balling phenomenon in metallic laser based 3d printing process. Int J Therm Sci 167(107):011

Cook PS, Murphy AB (2020) Simulation of melt pool behaviour during additive manufacturing: underlying physics and progress. Addit Manufac 31(100):909

Fathizadan S, Ju F, Lu Y (2021) Deep representation learning for process variation management in laser powder bed fusion. Addit Manufac 42(101):961

Gan Z, Lian Y, Lin SE et al (2019) Benchmark study of thermal behavior, surface topography, and dendritic microstructure in selective laser melting of inconel 625. Integr Mater Manufac Innov 8(2):178–193CrossRef

Hassan MR, Jeon HW, Kim G et al (2021) The effects of infill patterns and infill percentages on energy consumption in fused filament fabrication using cfr-peek. Rapid Prototyp J

Jiang J, Ma Y (2020) Path planning strategies to optimize accuracy, quality, build time and material use in additive manufacturing: a review. Micromach 11(7):633CrossRef

Koren Y (2010) The global manufacturing revolution: product-process-business integration and reconfigurable systems. John Wiley & Sons, Ney Jersey, Unitied States of AmeciaCrossRef

Kwon O, Kim HG, Ham MJ et al (2020) A deep neural network for classification of melt-pool images in metal additive manufacturing. J Intell Manufac 31(2):375–386CrossRef

10.

Kwon O, Kim HG, Kim W et al (2020b) A convolutional neural network for prediction of laser power using melt-pool images in laser powder bed fusion. IEEE Access 8:23,255–23,263

11.

Lane B, Yeung H (2019) Process monitoring dataset from the additive manufacturing metrology testbed (ammt):“three-dimensional scan strategies’’. J Res Nat Inst Stand Technol 124:1CrossRef

12.

Lee Y, Zhang W (2016) Modeling of heat transfer, fluid flow and solidification microstructure of nickel-base superalloy fabricated by laser powder bed fusion. Addit Manufac 12:178–188CrossRef

13.

Letenneur M, Brailovski V, Kreitcberg A et al (2017) Laser powder bed fusion of water-atomized iron-based powders: process optimization. J Manufac Mater Process 1(2):23

14.

Lo YL, Liu BY, Tran HC (2019) Optimized hatch space selection in double-scanning track selective laser melting process. Int J Adv Manufac Technol 105(7):2989–3006CrossRef

15.

Masoomi M, Thompson SM, Shamsaei N (2017) Quality part production via multi-laser additive manufacturing. Manufac Lett 13:15–20CrossRef

16.

Moges T, Yang Z, Jones K et al (2021) Hybrid modeling approach for melt-pool prediction in laser powder bed fusion additive manufacturing. J Comput Inf Sci Eng 21(5)

17.

Oh JW, Na H, Choi H (2017) Technology trend of the additive manufacturing (am). J Korean Powder Metall Inst 24(6):494–507CrossRef

18.

Quinlan HE, Hasan T, Jaddou J et al (2017) Industrial and consumer uses of additive manufacturing: a discussion of capabilities, trajectories, and challenges

19.

Redwood B, Schöffer F, Garret B (2017) The 3D printing handbook: technologies, design and applications. 3D Hubs, Amsterdam, The Netherlands

20.

Sobhi A, Hamoud M, Barakat A (2019) Optimal building orientation based on minimum volumetric error using a new direct slicing algorithm. Int J Sci Eng Investig, ISSN pp 2251–8843

21.

Sola A, Nouri A (2019) Microstructural porosity in additive manufacturing: the formation and detection of pores in metal parts fabricated by powder bed fusion. J Adv Manufac Process 1(3):e10,021

22.

Um J, Park J, Stroud IA (2021) Squashed-slice algorithm based on step-nc for multi-material and multi-directional additive processes. Appl Sci 11(18):8292CrossRef

23.

Wang W, Mao W, Tong X et al (2021) A novel recursive model based on a convolutional long short-term memory neural network for air pollution prediction. Remote Sensing 13(7):1284CrossRef

24.

Waqar S, Sun Q, Liu J et al (2021) Numerical investigation of thermal behavior and melt pool morphology in multi-track multi-layer selective laser melting of the 316l steel. Int J Adv Manufac Technol 112(3):879–895CrossRef

25.

Yan W, Ge W, Smith J et al (2015a) Towards high-quality selective beam melting technologies: modeling and experiments of single track formations. In: 2015 International solid freeform fabrication symposium, University of Texas at Austin

26.

Yan W, Smith J, Ge W et al (2015) Multiscale modeling of electron beam and substrate interaction: a new heat source model. Comput Mech 56(2):265–276CrossRef

27.

Yang Z, Lu Y, Yeung H et al (2020) From scan strategy to melt pool prediction: a neighboring-effect modeling method. J Comput Inf Sci Eng 20(5):051,001

28.

Yeung H, Yang Z, Yan L (2020) A meltpool prediction based scan strategy for powder bed fusion additive manufacturing. Addit Manufac 35(101):383

29.

Zhang B, Liu S, Shin YC (2019) In-process monitoring of porosity during laser additive manufacturing process. Addit Manufac 28:497–505CrossRef

30.

Zhang Z, Liu Z, Wu D (2021) Prediction of melt pool temperature in directed energy deposition using machine learning. Addit Manufac 37(101):692

31.

Zheng L, Zhang Q, Cao H et al (2019) Melt pool boundary extraction and its width prediction from infrared images in selective laser melting. Mater & Des 183(108):110

32.

Zhu Q, Liu Z, Yan J (2021) Machine learning for metal additive manufacturing: predicting temperature and melt pool fluid dynamics using physics-informed neural networks. Comput Mech 67(2):619–635MathSciNetCrossRef

33.

Zhuang JR, Lee YT, Hsieh WH et al (2018) Determination of melt pool dimensions using doe-fem and rsm with process window during slm of ti6al4v powder. Opt Laser Technol 103:59–76CrossRef

Title: Convolutional LSTM based melt-pool prediction from images of laser tool path strategy in laser powder bed fusion for additive manufacturing
Authors: Joung Min Park
Minho Choi
Jumyung Um
Publication date: 14-12-2023
Publisher: Springer London
Published in: The International Journal of Advanced Manufacturing Technology / Issue 3-4/2024
Print ISSN: 0268-3768
Electronic ISSN: 1433-3015
DOI: https://doi.org/10.1007/s00170-023-12697-z

Springer Professional

Abstract

Please log in to get access to your license.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Other articles of this Issue 3-4/2024

Diametral error correction in turning slender workpieces: an integrated approach

Machining of titanium metal matrix composites: a short review

Optimization of contact surfaces in assembly in the presence of form defects and interference

Simulation and experimentation of renewable dielectric gap flow fields in EDM

Design and processing behavior of large tubes with a rotating magnetic pole core-based magnetic abrasive finishing

Influence of cutting parameters on PCD tool wear during milling tungsten carbide

Premium Partners