Selective laser melting (SLM) has been attracting a growing interest in different industrial sectors as it is one of the key technologies for metal additive manufacturing (AM). Despite the relevant improvements made by the SLM technology in the recent years, process capability is still a major issue for its industrial breakthrough. As a matter of fact, different kinds of defect may originate during the layerwise process. In some cases, they propagate from one layer to the following ones leading to a job failure. In other cases, they are hardly visible and detectable by inspecting the final part, as they can affect the internal structure or structural features that are difficult to measure. This implies the need for in-process monitoring methods able to rapidly detect and locate defect onsets during the process itself. Different authors have been investigating machine sensorization architectures, but the development of statistical monitoring techniques is still in a very preliminary phase. This paper proposes a method for the detection and spatial identification of defects during the layerwise process by using a machine vision system in the visible range. A statistical descriptor based on principal component analysis (PCA) applied to image data is presented, which is suitable to identify defective areas of a layer. The use of image k-means clustering analysis is then proposed for automated defect detection. A real case study in SLM including both simple and complicated geometries is discussed to demonstrate the performances of the method.
Issue Section:
Research Papers
References
1.
Gibson
, I.
, Rosen
, D. W.
, and Stucker
, B.
, 2010
, Additive Manufacturing Technologies
, Springer
, New York
.2.
Horn
, T. J.
, and Harrysson
, O. L.
, 2012
, “Overview of Current Additive Manufacturing Technologies and Selected Applications
,” Sci. Prog.
, 95
(3
), pp. 255
–282
.3.
Mellor
, S.
, Hao
, L.
, and Zhang
, D.
, 2014
, “Additive Manufacturing: A Framework for Implementation
,” Int. J. Prod. Econ.
, 149
, pp. 194
–201
.4.
Olakanmi
, E. O.
, Cochrane
, R. F.
, and Dalgarno
, K. W.
, 2015
, “A Review on Selective Laser Sintering/Melting (SLS/SLM) of Aluminium Alloy Powders: Processing, Microstructure, and Properties
,” Prog. Mater. Sci.
, 74
, pp. 401
–477
.5.
Zhang
, B.
, and Coddet
, C.
, 2015
, “Selective Laser Melting of Iron Powder: Observation of Melting Mechanism and Densification Behavior Via Point-Track-Surface-Part Research
,” ASME J. Manuf. Sci. Eng.
, 138
(5
), p. 051001
.6.
Mertens
, R.
, Clijsters
, S.
, Kempen
, K.
, and Kruth
, J. P.
, 2014
, “Optimization of Scan Strategies in Selective Laser Melting of Aluminum Parts With Downfacing Areas
,” ASME J. Manuf. Sci. Eng.
, 136
(6
), p. 061012
.7.
Gu
, D.
, Chang
, F.
, and Dai
, D.
, 2015
, “Selective Laser Melting Additive Manufacturing of Novel Aluminum Based Composites With Multiple Reinforcing Phases
,” ASME J. Manuf. Sci. Eng.
, 137
(2
), p. 021010
.8.
Frazier
, W. E.
, 2014
, “Metal Additive Manufacturing: A Review
,” J. Mater. Eng. Perform.
, 23
(6
), pp. 1917
–1928
.9.
Zhang
, L. C.
, and Attar
, H.
, 2015
, “Selective Laser Melting of Titanium Alloys and Titanium Matrix Composites for Biomedical Applications: A Review
,” Adv. Eng. Mater.
, 18
(4
), pp. 463
–475
.10.
Chua
, C. K.
, Leong
, K. F.
, and Liu
, Z. H.
, 2015
, “Rapid Tooling in Manufacturing
,” Handbook of Manufacturing Engineering and Technology
, Springer
, London
, pp. 2525
–2549
.11.
Tapia
, G.
, and Elwany
, A.
, 2014
, “A Review on Process Monitoring and Control in Metal-Based Additive Manufacturing
,” ASME J. Manuf. Sci. Eng.
, 136
(6
), p. 060801
.12.
Mani
, M.
, Lane
, B.
, Donmez
, A.
, Feng
, S.
, Moylan
, S.
, and Fesperman
, R.
, 2015
, “Measurement Science Needs for Real-Time Control of Additive Manufacturing Powder Bed Fusion Processes
,” NISTIR, Report No. 8036.13.
Craeghs
, T.
, Bechmann
, F.
, Berumen
, S.
, and Kruth
, J.-P.
, 2010
, “Feedback Control of Layerwise Laser Melting Using Optical Sensors
,” Phys. Procedia
, 5
(Part B), pp. 505
–514
.14.
Craeghs
, T.
, Clijsters
, S.
, Yasa
, E.
, Bechmann
, F.
, Berumen
, S.
, and Kruth
, J.-P.
, 2011
, “Determination of Geometrical Factors in Layerwise Laser Melting Using Optical Process Monitoring
,” Opt. Lasers Eng.
, 49
(12
), pp. 1440
–1446
.15.
Clijsters
, S.
, Craeghs
, T.
, Buls
, S.
, Kempen
, K.
, and Kruth
, J.-P.
, 2014
, “In Situ Quality Control of the Selective Laser Melting Process Using a High-Speed, Real-Time Melt Pool Monitoring System
,” Int. J. Adv. Manuf. Technol.
, 75
(5
), pp. 1089
–1101
.16.
Doubenskaia
, M.
, Pavlov
, M.
, Grigoriev
, S.
, Tikhonova
, E.
, and Smurov
, I.
, 2012
, “Comprehensive Optical Monitoring of Selective Laser Melting
,” J. Laser Micro/Nanoeng.
, 7
(3
), pp. 236
–243
.17.
Lott
, P.
, Schleifenbaum
, H.
, Meiners
, W.
, Wissenbach
, K.
, Hinke
, C.
, and Bültmann
, J.
, 2011
, “Design of an Optical System for the In Situ Process Monitoring of Selective Laser Melting (SLM)
,” Phys. Procedia
, 12
(Part A), pp. 683
–690
.18.
Abdelrahman
, M.
, and Starr
, T. L.
, 2014
, “Layerwise Monitoring of Polymer Laser Sintering Using Thermal Imaging
,” 25th Solid Freeform Fabrication Symposium (SFF 2014)
, Laboratory for Freeform Fabrication, University of Texas at Austin, Austin, TX, pp. 244–255.19.
Krauss
, H.
, Eschey
, C.
, and Zaeh
, M.
, 2012
, “Thermography for Monitoring the Selective Laser Melting Process
,” Solid Freeform Fabrication Symposium
, pp. 999
–1014
.20.
Jacobsmuhlen
, J. Z.
, Kleszczynski
, S.
, Schneider
, D.
, and Witt
, G.
, 2013
, “High Resolution Imaging for Inspection of Laser Beam Melting Systems
,” Instrumentation and Measurement Technology Conference (I2MTC)
, IEEE, Minneapolis, MN, pp. 707
–712
.21.
Schilp
, J.
, Seidel
, C.
, Krauss
, H.
, and Weirather
, J.
, 2014
, “Investigations on Temperature Fields During Laser Beam Melting by Means of Process Monitoring and Multiscale Process Modelling
,” Adv. Mech. Eng.
, 6
, p. 217584
.22.
Jolliffe
, I. T.
, 2002
, Principal Component Analysis
(Springer Series in Statistics), 2nd ed., Springer
, New York
.23.
Johnson
, R. A.
, and Wichern
, D. W.
, 1992
, Applied Multivariate Statistical Analysis
, Vol. 4
, Prentice Hall
, Englewood Cliffs, NJ
.24.
Montgomery
, D. C.
, 2008
, Introduction to Statistical Quality Control
, 6th ed., Wiley
, New York.25.
Hastie
, T.
, Tibshirani
, R.
, and Friedman
, J.
, 2009
, The Elements of Statistical Learning
, Vol. 2
, Springer
, New York
.26.
Galimberti
, G.
, Guagliano
, M.
, Previtali
, B.
, and Rampino
, L.
, 2015
, “Digital Aesthetic of New Products Obtained by Selective Laser Melting Processes
,” 20th International Conference on Engineering Design
(ICED15
), Milan, Italy, July 27–30, Vol. 4
, 193–204.http://m.designsociety.org/index.php?menu=31&action=3779527.
Kiers
, H. A. L.
, 2000
, “Towards a Standardized Notation and Terminology in Multiway Analysis
,” J. Chemom.
, 14
(3
), pp. 105
–122
.28.
Yang
, J.
, Zhang
, D.
, Frangi
, A. F.
, and Yang
, J.
, 2004
, “Two-Dimensional PCA: A New Approach to Appearance-Based Face Representation and Recognition
,” IEEE Trans. Pattern Anal. Mach. Intell.
, 26
(1
), pp. 131
–137
.29.
Gottumukkal
, R.
, and Asari
, V. K.
, 2004
, “An Improved Face Recognition Technique Based on Modular PCA Approach
,” Pattern Recognit. Lett.
, 25
(4
), pp. 429
–436
.30.
Rodarmel
, C.
, and Shan
, J.
, 2002
, “Principal Component Analysis for Hyperspectral Image Classification
,” Surv. Land Inf. Sci.
, 62
(2
), pp. 115
–122
.https://www.researchgate.net/publication/265198128_Principal_Component_Analysis_for_Hyperspectral_Image_Classification31.
Ye
, J.
, Janardan
, R.
, and Li
, Q.
, 2004
, “GPCA: An Effcient Dimension Reduction Scheme for Image Compression and Retrieval
,” 10th ACM SIGKDD International Conference on Knowledge Discovery and Data Mining
, pp. 354
–363
.32.
Nomikos
, P.
, and MacGregor
, J. F.
, 1995
, “Multivariate SPC Charts for Monitoring Batch Processes
,” Technometrics
, 37
(1
), pp. 41
–59
.33.
Megahed
, F. M.
, Woodall
, W. H.
, and Camelio
, J. A.
, 2011
, “A Review and Perspective on Control Charting With Image Data
,” J. Qual. Technol.
, 43
(2
), pp. 83
–98
.https://www.researchgate.net/publication/258566049_A_Review_and_Perspective_on_Control_Charting_with_Image_Data34.
Jäger
, M.
, and Hamprecht
, F.
, 2009
, “Principal Component Imagery for the Quality Monitoring of Dynamic Laser Welding Processes
,” IEEE Trans. Ind. Electron.
, 56
(4
), pp. 1307
–1313
.35.
Senin
, N.
, Ziliotti
, M.
, and Groppetti
, R.
, 2007
, “Three-Dimensional Surface Topography Segmentation Through Clustering
,” Wear
, 262
(3
), pp. 395
–410
.36.
Hartigan
, J. A.
, 1975
, Clustering Algorithms
, Wiley
, New York
.37.
Ball
, G. H.
, and Hall
, D. J.
, 1965
, “ISODATA: A Novel Method of Data Analysis and Pattern Classification
,” Stanford Research Institute, Menlo Park, CA, Technical Report, NTIS No. AD 699616.38.
Calinski
, T.
, and Harabasz
, J.
, 1974
, “A Dendrite Method for Cluster Analysis
,” Commun. Stat.
, 3
(1), pp. 1
–27
.39.
Zhao
, Q.
, Xu
, M.
, and Fränti
, P.
, 2009
, “Sum-of-Squares Based Cluster Validity Index and Significance Analysis. Adaptive and Natural Computing Algorithms
,” Lect. Notes Comput. Sci.
, 5495
, pp. 313
–322
.40.
Xu
, L.
, 1997
, “Bayesian Ying-Yang Machine, Clustering and Number of Clusters
,” Pattern Recognit. Lett.
, 18
(11–13), pp. 1167
–1178
.41.
Grasso
, M.
, Colosimo
, B. M.
, and Pacella
, M.
, 2014
, “Profile Monitoring Via Sensor Fusion: The Use of PCA Methods for Multi-Channel Data
,” Int. J. Prod. Res.
, 52
(20
), pp. 6110
–6135
.42.
Williams
, J. D.
, Woodall
, W. H.
, Birch
, J. B.
, and Sullivan
, J. H.
, 2006
, “On the Distribution of Hotelling's T2 Statistic Based on the Successive Differences Covariance Matrix Estimator
,” J. Qual. Technol.
, 38
(3), pp. 217
–229
.43.
Valle
, S.
, Li
, W.
, and Qin
, S. J.
, 1999
, “Selection of the Number of Principal Components: The Variance of Reconstruction Error Criterion With a Comparison to Other Methods
,” Ind. Eng. Chem. Res.
, 38
(11
), pp. 4389
–4401
.44.
Colosimo
, B. M.
, and Pacella
, M.
, 2007
, “On the Use of Principal Component Analysis to Identify Systematic Patterns in Roundness Profiles
,” Qual. Reliab. Eng. Int.
, 23
(6), pp. 925
–941
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