Detecting voids in 3D printing using melt pool time series data

被引：45

作者：

Mahato, Vivek ^{[1
]}

Obeidi, Muhannad Ahmed ^{[2
]}

Brabazon, Dermot ^{[2
]}

Cunningham, Padraig ^{[1
]}

机构：

[1] Univ Coll Dublin, Dublin, Ireland

[2] Dublin City Univ, Dublin, Ireland

来源：

JOURNAL OF INTELLIGENT MANUFACTURING | 2022年 / 33卷 / 03期

基金：

爱尔兰科学基金会;

关键词：

Process monitoring; Classification; Time-series; POWDER;

D O I：

10.1007/s10845-020-01694-8

中图分类号：

TP18 [人工智能理论];

学科分类号：

081104 ; 0812 ; 0835 ; 1405 ;

摘要：

Powder Bed Fusion (PBF) has emerged as an important process in the additive manufacture of metals. However, PBF is sensitive to process parameters and careful management is required to ensure the high quality of parts produced. In PBF, a laser or electron beam is used to fuse powder to the part. It is recognised that the temperature of the melt pool is an important signal representing the health of the process. In this paper, Machine Learning (ML) methods on time-series data are used to monitor melt pool temperature to detect anomalies. In line with other ML research on time-series classification, Dynamic Time Warping andk-Nearest Neighbour classifiers are used. The presented process is effective in detecting voids in PBF. A strategy is then proposed to speed up classification time, an important consideration given the volume of data involved.

引用

页码：845 / 852

页数：8

共 50 条

[21] Building 3D Printing: The Anisotropy Mechanical Properties and Printing Time
Xin, Penghao
Wang, Ziming
Xi, Wenbo
Peng, Jingying
He, Huan
Tang, Ruifeng
ADVANCES IN ENERGY AND ENVIRONMENTAL MATERIALS, 2018, : 535 - 543
[22] 3D printing crystallographic data for post-printing construction
Brown, Matthew L.
Van Wieren, Ken
Tailor, Hamel N.
Hartling, David
Merbouh, Nabyl
ACTA CRYSTALLOGRAPHICA A-FOUNDATION AND ADVANCES, 2019, 75 : A23 - A23
[23] DETECTING MALICIOUS DEFECTS IN 3D PRINTING PROCESS USING MACHINE LEARNING AND IMAGE CLASSIFICATION
Wu, Mingtao
Phoha, Vir V.
Moon, Young B.
Belman, Amith K.
PROCEEDINGS OF THE ASME INTERNATIONAL MECHANICAL ENGINEERING CONGRESS AND EXPOSITION, 2016, VOL. 14, 2017,
[24] The Modeling of 3D Color Topography Based on DEM Data for 3D Printing
Zhang, Kaili
He, Liuxi
Wang, Xiaochun
Chen, Guangxue
APPLIED SCIENCES IN GRAPHIC COMMUNICATION AND PACKAGING, 2018, 477 : 175 - 184
[25] Development of a mirascope using 3D printing
Huang, Chien-Yao
Ho, Cheng-Fang
Kuo, Hui-Jean
Chen, Jun-Cheng
Lin, Ping-Hung
Chen, Hung-Pin
Wang, A-Cheng
INTERNATIONAL JOURNAL OF ADVANCED MANUFACTURING TECHNOLOGY, 2019, 102 (5-8): : 2275 - 2283
[26] Development of a mirascope using 3D printing
Chien-Yao Huang
Cheng-Fang Ho
Hui-Jean Kuo
Jun-Cheng Chen
Ping-Hung Lin
Hung-Pin Chen
A-Cheng Wang
The International Journal of Advanced Manufacturing Technology, 2019, 102 : 2275 - 2283
[27] Manipulating molten pool dynamics during metal 3D printing by ultrasound
Yang, Zhichao
Wang, Shuhao
Zhu, Lida
Ning, Jinsheng
Xin, Bo
Dun, Yichao
Yan, Wentao
APPLIED PHYSICS REVIEWS, 2022, 9 (02):
[28] 3DACN: 3D Augmented convolutional network for time series data
Pei, Songwen
Shen, Tianma
Wang, Xianrong
Gu, Chunhua
Ning, Zhong
Ye, Xiaochun
Xiong, Naixue
INFORMATION SCIENCES, 2020, 513 : 17 - 29
[29] ESTIMATING FOREST AGE AND SITE PRODUCTIVITY USING TIME SERIES OF 3D REMOTE SENSING DATA
Wallerman, Jorgen
Nystrom, Kenneth
Bohlin, Jonas
Persson, Henrik J.
Soja, Maciej J.
Fransson, Johan E. S.
2015 IEEE INTERNATIONAL GEOSCIENCE AND REMOTE SENSING SYMPOSIUM (IGARSS), 2015, : 3321 - 3324
[30] Fabrication of Polylactide/Carbon Nanopowder Filament using Melt Extrusion and Filament Characterization for 3D Printing
Jain, Shrenik Kumar
Tadesse, Yonas
INTERNATIONAL JOURNAL OF NANOSCIENCE, 2019, 18 (05)

← 1 2 3 4 5 →