Experimental analysis of spatter generation and melt-pool behavior during the powder bed laser beam melting process

Gegenwärtig ist bei der additiven Fertigung eine prozessbegleitende Überwachung des Bauteils auf das Schmelzbad und oberflächennahe Bereiche limitiert. Mithilfe akustischer Signale lassen sich typische Defekte, die im Rahmen des LBM (laser beam melting – Laserstrahlschmelzen)-Verfahrens auftreten, detektieren. Dies umfasst neben Porosität und Rissen auch Eigenspannungen. In diesem Fachbeitrag werden die Möglichkeit eines in den LBM-Prozess integrierten akustischen Prüfsystems sowie alternative Sensorkonzepte diskutiert und evaluiert.   Current process monitoring techniques for additive manufacturing are limited to the melt pool and near-surface areas. Typical defects that occur within the LBM-process, such as porosity and cracks, as well as residual stress, can be detected by using acoustic waves. In this article, the possibility of an integrated ultrasonic inspection system, as well as various sensor concepts are discussed and evaluated.

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Laser beam melting process based on complete-melting energy density for commercially pure titanium

Journal of Manufacturing Processes ◽

10.1016/j.jmapro.2019.07.031 ◽

2019 ◽

Vol 45 ◽

pp. 455-459 ◽

Cited By ~ 4

Author(s):

Hyung Giun Kim ◽

Won Rae Kim ◽

Ohyung Kwon ◽

Gyung Bae Bang ◽

Min Ji Ham ◽

...

Keyword(s):

Energy Density ◽

Laser Beam ◽

Pure Titanium ◽

Melting Process ◽

Commercially Pure Titanium ◽

Commercially Pure ◽

Complete Melting ◽

Laser Beam Melting

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Selective laser sintering (melting) of stainless and tool steel powders: Experiments and modelling

Proceedings of the Institution of Mechanical Engineers Part B Journal of Engineering Manufacture ◽

10.1243/095440505x8109 ◽

2005 ◽

Vol 219 (4) ◽

pp. 339-357 ◽

Cited By ~ 117

Author(s):

T H C Childs ◽

C Hauser ◽

M Badrossamay

Keyword(s):

Laser Beam ◽

Tool Steel ◽

Selective Laser Sintering ◽

Element Model ◽

Powder Bed ◽

Melt Pool ◽

H13 Tool Steel ◽

Complete Melting ◽

Track Formation ◽

Elliptic Cross

When a laser beam scans once across the surface of a metallic powder bed, the resulting track may be continuous with a crescent or an elliptic cross-section, irregularly broken, balled or only partially melted. This paper reports what laser powers and scan speeds lead to what types of track, for a CO2 laser beam focused to 0.55 mm and 1.1 mm diameters, scanning over beds made from M2 and H13 tool steel and 314S-HC stainless steel powders. Beds have been made with particle size ranges from 300 μm to 150 μm, from 150 μm to 75 μm, from 75 μm to 38 μm, and less than 38 μm. Measurements are also reported of bed physical properties that are used in a finite element model to predict melt pool dimensions and temperatures. Boundaries between regions of different track formation are explained in terms of melt surface temperature gradients, melt pool length-diameter ratio instabilities, and transitions from partial to complete melting. Implications for building metal parts in powder beds without supports are considered. The modelling is briefly extended to multi-track and multi-layer processing, to conclude that bonding by remelting between layers, while still maintaining control of the melt flow, places severe constraints on the maximum allowable layer thickness.

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Quantifying Powder Losses and Analyzing Powder Conditions in order to Determine Material Efficiency in Laser Beam Melting

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.856.231 ◽

2016 ◽

Vol 856 ◽

pp. 231-237 ◽

Cited By ~ 2

Author(s):

Max Lutter-Günther ◽

Alexander Hofmann ◽

Christoph Hauck ◽

Christian Seidel ◽

Gunther Reinhart

Keyword(s):

Laser Beam ◽

Experimental Studies ◽

Manufacturing Processes ◽

Ecological Evaluation ◽

Powder Bed ◽

Material Efficiency ◽

Laser Beam Melting ◽

Measurement Results ◽

Subtractive Manufacturing ◽

End Use

Laser Beam Melting (LBM) is an additive manufacturing process, which is increasingly applied for the production of end use parts. One advantage of this powder bed fusion technology lies in the high material efficiency in comparison with subtractive manufacturing processes (i. e. milling, lathing). However, only few experimental studies have been conducted on the material efficiency of LBM. For the accurate evaluation of the LBM material efficiency, empirical values for powder losses are required. Furthermore, a lack of terminology for waste types and powder conditions in the context of LBM impedes communication and research on the topic. The presented paper aims to increase the understanding of material efficiency and powder conditions in Laser Beam Melting. A quantitative analysis of waste types is presented for different LBM application scenarios. This sets a basis for the ecological evaluation and comparison with conventional manufacturing processes. In order to achieve the aim, a terminology is introduced for waste types and powder conditions in the context of powder bed-based additive processes. Therefore, considerations regarding powder quality are taken into account. For the quantification of powder losses, the experimental setup and measurement results are described. Furthermore, loss types and their significance are analyzed and discussed.

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Reaction kinetics and curing behavior of epoxies for use in a combined selective laser beam melting process of polymers

Journal of Applied Polymer Science ◽

10.1002/app.46850 ◽

2018 ◽

Vol 136 (7) ◽

pp. 46850 ◽

Cited By ~ 1

Author(s):

K. Wudy ◽

T. Budde

Keyword(s):

Laser Beam ◽

Reaction Kinetics ◽

Melting Process ◽

Curing Behavior ◽

Laser Beam Melting

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Pyrometric-Based Melt Pool Monitoring Study of CuCr1Zr Processed Using L-PBF

Materials ◽

10.3390/ma13204626 ◽

2020 ◽

Vol 13 (20) ◽

pp. 4626

Author(s):

Katia Artzt ◽

Martin Siggel ◽

Jan Kleinert ◽

Joerg Riccius ◽

Guillermo Requena ◽

...

Keyword(s):

Stable Process ◽

Melting Process ◽

Quality Monitoring ◽

Powder Bed ◽

Part Geometry ◽

Melt Pool ◽

Process Understanding ◽

Reducing Costs ◽

Non Destructive

The potential of in situ melt pool monitoring (MPM) for parameter development and furthering the process understanding in Laser Powder Bed Fusion (LPBF) of CuCr1Zr was investigated. Commercial MPM systems are currently being developed as a quality monitoring tool with the aim of detecting faulty parts already in the build process and, thus, reducing costs in LPBF. A detailed analysis of coupon specimens allowed two processing windows to be established for a suitably dense material at layer thicknesses of 30 µm and 50 µm, which were subsequently evaluated with two complex thermomechanical-fatigue (TMF) panels. Variations due to the location on the build platform were taken into account for the parameter development. Importantly, integrally averaged MPM intensities showed no direct correlation with total porosities, while the robustness of the melting process, impacted strongly by balling, affected the scattering of the MPM response and can thus be assessed. However, the MPM results, similar to material properties such as porosity, cannot be directly transferred from coupon specimens to components due to the influence of the local part geometry and heat transport on the build platform. Different MPM intensity ranges are obtained on cuboids and TMF panels despite similar LPBF parameters. Nonetheless, besides identifying LPBF parameter windows with a stable process, MPM allowed the successful detection of individual defects on the surface and in the bulk of the large demonstrators and appears to be a suitable tool for quality monitoring during fabrication and non-destructive evaluation of the LPBF process.

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Experimental analysis of the influence of process parameters on the melt pool formation and stability in powder bed laser

International Congress on Applications of Lasers & Electro-Optics ◽

10.2351/1.5062886 ◽

2013 ◽

Cited By ~ 1

Author(s):

Runchen Cao ◽

Pascal Aubry ◽

Kevin Verdier

Keyword(s):

Process Parameters ◽

Experimental Analysis ◽

Influence Of Process Parameters ◽

Powder Bed ◽

Melt Pool ◽

Pool Formation

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Finite Element Thermal Analysis of Melt Pool in Selective Laser Melting Process

Volume 1A: 38th Computers and Information in Engineering Conference ◽

10.1115/detc2018-85701 ◽

2018 ◽

Author(s):

Zhibo Luo ◽

Yaoyao Fiona Zhao

Keyword(s):

Heat Source ◽

Selective Laser Melting ◽

Computational Cost ◽

Melting Process ◽

Point Heat Source ◽

Laser Melting ◽

Line Heat Source ◽

Powder Bed ◽

Melt Pool ◽

Gaussian Point

Selective laser melting is one of the powder bed fusion processes which fabricates a part through layer-wised method. Due to the ability to build a customized and complex part, selective laser melting process has been broadly studied in academic and applied in industry. However, rapidly changed thermal cycles and extremely high-temperature gradients among the melt pool induce a periodically changed thermal stress in solidified layers and finally result in a distorted part. Therefore, the temperature distribution in the melt pool and the size and shape of the melt pool directly determine the mechanical and geometrical property of final part. As experimental trial-and-error method takes a huge amount of cost, different numerical methods have been adopted to estimate the transient temperature and thermal stress distribution in the melt pool and powder bed. The most existing research utilizes the moving Gaussian point heat source to model the profile of the melt pool, which consumes a significant amount of computational cost and cannot be used to implement the part-level simulation. This research proposes a new line heat source to replace the moving point heat source. Some efforts are applied to reduce the computational cost. Specifically, a relatively large step size is used for the line heat source to reduce the number of time steps. In addition, a mesh refinement scheme is adopted to reduce the number of cells in each time step by refining the mesh close to the heat source and coarsening the mesh far away from it. On the other hand, efforts are implemented to increase the accuracy of the simulation result. Temperature-dependent material properties are considered in this FE framework. In addition, material transition among powder, liquid, and solid are incorporated in the developed FE framework. In this study, temperature simulation of one scanning track based on self-developed FE code is applied for Stainless Steel 316L. The simulation results show that the temperature distribution and history of melt pool within line heat source are comparable to that of the moving Gaussian point heat source. While the simulation time is reduced by more than two times depending on the length of line heat input. Therefore, this FE model can be used to numerically investigate the process parameters and help to control the quality of the final part.

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