Deep learning for process monitoring of additive manufacturing

被引:0
|
作者
Yi L.
Ehmsen S.
Cassani M.
Glatt M.
Varshneya S.
Liznerski P.
Kloft M.
da Silva E.J.
Aurich J.C.
机构
来源
ZWF Zeitschrift fuer Wirtschaftlichen Fabrikbetrieb | 2020年 / 115卷 / 11期
关键词
Computer aided design - Additives - Deep learning - Porosity - Process monitoring;
D O I
10.3139/104.112447
中图分类号
学科分类号
摘要
A Concept for the Prediction of Material Porosity of Additive Manufactured Components by Deep Learning. Material porosity of components produced by additive manufacturing (AM) such as Laser Powder Bed Fusion (L-PBF) and Laser Directed Energy Deposition (L-DED) is related to process parameters, e.g., layer thickness and build-up rate. To enable the in-situ process monitoring of AM, deep learning is a promising solution, in which heterogeneous dara sets such as process parameters, CAD models and thermal images of layers can be used as training data. The trained model can predict the porosity of components manufactured with AM in-situ. © Carl Hanser Verlag GmbH & Co. KG
引用
收藏
页码:810 / 813
页数:3
相关论文
共 50 条
  • [21] Monitoring of the additive manufacturing process for the use of biomaterials in medical
    Blaya Haro, Fernando
    de Agustin del Burgo, Jose M.
    D'Amato, Roberto
    Islan Marcos, Manuel
    Soriano Heras, Enrique
    Garcia Alonso, Jesus Manuel
    SIXTH INTERNATIONAL CONFERENCE ON TECHNOLOGICAL ECOSYSTEMS FOR ENHANCING MULTICULTURALITY (TEEM'18), 2018, : 428 - 432
  • [22] Thermographic Process Monitoring in Powderbed Based Additive Manufacturing
    Krauss, Harald
    Zeugner, Thomas
    Zaeh, Michael F.
    41ST ANNUAL REVIEW OF PROGRESS IN QUANTITATIVE NONDESTRUCTIVE EVALUATION, VOL 34, 2015, 1650 : 177 - 183
  • [23] Process Monitoring of Additive Manufacturing by Using Optical Tomography
    Goegelein, A.
    Ladewig, A.
    Zenzinger, G.
    Bamberg, J.
    14TH QUANTITATIVE INFRARED THERMOGRAPHY CONFERENCE, 2018, : 266 - 272
  • [24] Review of dynamic monitoring of metal additive manufacturing process
    Wang F.
    Yang S.
    Lyu B.
    Peng S.
    Guo J.
    Zhao Y.
    Jisuanji Jicheng Zhizao Xitong/Computer Integrated Manufacturing Systems, CIMS, 2023, 29 (07): : 2245 - 2259
  • [25] Process Monitoring of Additive Manufacturing by Using Optical Tomography
    Zenzinger, Guenter
    Bamberg, Joachim
    Ladewig, Alexander
    Hess, Thomas
    Henkel, Benjamin
    Satzger, Wilhelm
    41ST ANNUAL REVIEW OF PROGRESS IN QUANTITATIVE NONDESTRUCTIVE EVALUATION, VOL 34, 2015, 1650 : 164 - 170
  • [26] Quality analysis in metal additive manufacturing with deep learning
    Xiang Li
    Xiaodong Jia
    Qibo Yang
    Jay Lee
    Journal of Intelligent Manufacturing, 2020, 31 : 2003 - 2017
  • [27] Quality analysis in metal additive manufacturing with deep learning
    Li, Xiang
    Jia, Xiaodong
    Yang, Qibo
    Lee, Jay
    JOURNAL OF INTELLIGENT MANUFACTURING, 2020, 31 (08) : 2003 - 2017
  • [28] In-Process monitoring of porosity during laser additive manufacturing process
    Zhang, Bin
    Liu, Shunyu
    Shin, Yung C.
    ADDITIVE MANUFACTURING, 2019, 28 : 497 - 505
  • [29] Deep Learning Applied to Defect Detection in Powder Spreading Process of Magnetic Material Additive Manufacturing
    Chen, Hsin-Yu
    Lin, Ching-Chih
    Horng, Ming-Huwi
    Chang, Lien-Kai
    Hsu, Jian-Han
    Chang, Tsung-Wei
    Hung, Jhih-Chen
    Lee, Rong-Mao
    Tsai, Mi-Ching
    MATERIALS, 2022, 15 (16)
  • [30] Process monitoring and machine learning for defect detection in laser-based metal additive manufacturing
    Herzog, T.
    Brandt, M.
    Trinchi, A.
    Sola, A.
    Molotnikov, A.
    JOURNAL OF INTELLIGENT MANUFACTURING, 2024, 35 (04) : 1407 - 1437
12345