Melt pool imaging using a configurable architecture additive testbed system

AbstractIn this study, the effect of powder spreading direction was investigated on selectively laser-melted specimens. The results showed that the metallurgical properties of the specimens varied during fabrication with respect to their position on the build tray. The density, porosity, and tensile properties of the Co–Cr–W–Mo alloy were investigated on cuboid and tensile specimens fabricated at different locations. Two different significant positions on the tray were selected along the powder spreading direction. One set of specimens was located near the start line of powder spreading, and the other set was located near the end of the building tray. The main role in the consequences of powder layering was played by the distribution of powder particle sizes and the packing density of the layers. As a result, laser penetration, melt pool formation, and fusion characteristics varied. To confirm the occurrence of variations in sample density, an additional experiment was performed with a Ti–6Al–4V alloy. Furthermore, the powders were collected at two different fabricating locations and their size distribution for both materials was investigated.

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Process characterization and analysis of ceramic powder bed fusion

The International Journal of Advanced Manufacturing Technology ◽

10.1007/s00170-021-07625-y ◽

2021 ◽

Author(s):

Kevin Florio ◽

Dario Puccio ◽

Giorgio Viganò ◽

Stefan Pfeiffer ◽

Fabrizio Verga ◽

...

Keyword(s):

High Speed ◽

Ceramic Powder ◽

Integrating Sphere ◽

Alumina Powder ◽

Powder Bed Fusion ◽

Single Track ◽

Ceramic Powders ◽

Pure Alumina ◽

Powder Bed ◽

Melt Pool

AbstractPowder bed fusion (PBF) of ceramics is often limited because of the low absorptance of ceramic powders and lack of process understanding. These challenges have been addressed through a co-development of customized ceramic powders and laser process capabilities. The starting powder is made of a mix of pure alumina powder and alumina granules, to which a metal oxide dopant is added to increase absorptance. The performance of different granules and process parameters depends on a large number of influencing factors. In this study, two methods for characterizing and analyzing the PBF process are presented and used to assess which dopant is the most suitable for the process. The first method allows one to analyze the absorptance of the laser during the melting of a single track using an integrating sphere. The second one relies on in-situ video imaging using a high-speed camera and an external laser illumination. The absorption behavior of the laser power during the melting of both single tracks and full layers is proven to be a non-linear and extremely dynamic process. While for a single track, the manganese oxide doped powder delivers higher and more stable absorptance. When a full layer is analyzed, iron oxide-doped powder is leading to higher absorptance and a larger melt pool. Both dopants allow the generation of a stable melt-pool, which would be impossible with granules made of pure alumina. In addition, the present study sheds light on several phenomena related to powder and melt-pool dynamics, such as the change of melt-pool shape and dimension over time and powder denudation effects.

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Modeling and Experiments of Laser Cladding With Droplet Injection

Journal of Heat Transfer ◽

10.1115/1.2005273 ◽

2005 ◽

Vol 127 (9) ◽

pp. 978-986 ◽

Cited By ~ 48

Author(s):

J. Choi ◽

L. Han ◽

Y. Hua

Keyword(s):

Fluid Flow ◽

Laser Cladding ◽

Dynamic Motion ◽

Cladding Layer ◽

Melt Pool ◽

Material Deposition ◽

Modeling And Experiments ◽

Solid Liquid Interface ◽

Solid Liquid ◽

The Impact

Laser aided Directed Material Deposition (DMD) is an additive manufacturing process based on laser cladding. A full understanding of laser cladding is essential in order to achieve a steady state and robust DMD process. A two dimensional mathematical model of laser cladding with droplet injection was developed to understand the influence of fluid flow on the mixing, dilution depth, and deposition dimension, while incorporating melting, solidification, and evaporation phenomena. The fluid flow in the melt pool that is driven by thermal capillary convection and an energy balance at the liquid–vapor and the solid–liquid interface was investigated and the impact of the droplets on the melt pool shape and ripple was also studied. Dynamic motion, development of melt pool and the formation of cladding layer were simulated. The simulated results for average surface roughness were compared with the experimental data and showed a comparable trend.

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Integrated Computational Materials Engineering to Predict Dimensions for Steady-State and Transient Melt-Pool Formation in the Selective Laser Melting of Inconel 625

Integrating Materials and Manufacturing Innovation ◽

10.1007/s40192-021-00223-6 ◽

2021 ◽

Author(s):

Stephen Wormald ◽

Jordan Clingenpeel ◽

Tim Vincent ◽

Anil Chaudhary

Keyword(s):

Steady State ◽

Selective Laser Melting ◽

Inconel 625 ◽

Laser Melting ◽

Materials Engineering ◽

Melt Pool ◽

Integrated Computational Materials Engineering ◽

Computational Materials ◽

Pool Formation

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A Comparative Analysis of Laser Additive Manufacturing of High Layer Thickness Pure Ti and Inconel 718 Alloy Materials Using Finite Element Method

Materials ◽

10.3390/ma14040876 ◽

2021 ◽

Vol 14 (4) ◽

pp. 876 ◽

Cited By ~ 1

Author(s):

Sapam Ningthemba Singh ◽

Sohini Chowdhury ◽

Yadaiah Nirsanametla ◽

Anil Kumar Deepati ◽

Chander Prakash ◽

...

Keyword(s):

Finite Element Method ◽

Finite Element ◽

Layer Thickness ◽

Inconel 718 ◽

Laser Power ◽

Scanning Speed ◽

Laser Additive Manufacturing ◽

Inconel 718 Alloy ◽

Melt Pool ◽

High Layer

Investigation of the selective laser melting (SLM) process, using finite element method, to understand the influences of laser power and scanning speed on the heat flow and melt-pool dimensions is a challenging task. Most of the existing studies are focused on the study of thin layer thickness and comparative study of same materials under different manufacturing conditions. The present work is focused on comparative analysis of thermal cycles and complex melt-pool behavior of a high layer thickness multi-layer laser additive manufacturing (LAM) of pure Titanium (Ti) and Inconel 718. A transient 3D finite-element model is developed to perform a quantitative comparative study on two materials to examine the temperature distribution and disparities in melt-pool behaviours under similar processing conditions. It is observed that the layers are properly melted and sintered for the considered process parameters. The temperature and melt-pool increases as laser power move in the same layer and when new layers are added. The same is observed when the laser power increases, and opposite is observed for increasing scanning speed while keeping other parameters constant. It is also found that Inconel 718 alloy has a higher maximum temperature than Ti material for the same process parameter and hence higher melt-pool dimensions.

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Numerical investigation on heat transfer of melt pool and clad generation in directed energy deposition of stainless steel

International Journal of Thermal Sciences ◽

10.1016/j.ijthermalsci.2021.106954 ◽

2021 ◽

Vol 165 ◽

pp. 106954

Author(s):

Y.M. Zhang ◽

C.W.J. Lim ◽

C. Tang ◽

B. Li

Keyword(s):

Heat Transfer ◽

Stainless Steel ◽

Numerical Investigation ◽

Energy Deposition ◽

Melt Pool ◽

Directed Energy Deposition ◽

Directed Energy

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Transient Simulation of Particle Transport and Deposition in the Laser Powder Bed Fusion Process: A new Approach to Model Particle and Heat Ejection from the Melt Pool

Additive Manufacturing ◽

10.1016/j.addma.2021.102135 ◽

2021 ◽

pp. 102135

Author(s):

J. Altmeppen ◽

R. Nekic ◽

P. Wagenblast ◽

S. Staudacher

Keyword(s):

Particle Transport ◽

Transient Simulation ◽

Fusion Process ◽

Powder Bed Fusion ◽

Laser Powder Bed Fusion ◽

New Approach ◽

Powder Bed ◽

Model Particle ◽

Melt Pool

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Hot-Wire Laser-Directed Energy Deposition: Process Characteristics and Benefits of Resistive Pre-Heating of the Feedstock Wire

Metals ◽

10.3390/met11040634 ◽

2021 ◽

Vol 11 (4) ◽

pp. 634

Author(s):

Agnieszka Kisielewicz ◽

Karthikeyan Thalavai Pandian ◽

Daniel Sthen ◽

Petter Hagqvist ◽

Maria Asuncion Valiente Bermejo ◽

...

Keyword(s):

Heat Input ◽

Energy Deposition ◽

Fine Tuning ◽

Hot Wire ◽

Process Stability ◽

Electrical Signals ◽

Melt Pool ◽

Directed Energy Deposition ◽

Directed Energy ◽

The Stability

This study investigates the influence of resistive pre-heating of the feedstock wire (here called hot-wire) on the stability of laser-directed energy deposition of Duplex stainless steel. Data acquired online during depositions as well as metallographic investigations revealed the process characteristic and its stability window. The online data, such as electrical signals in the pre-heating circuit and images captured from side-view of the process interaction zone gave insight on the metal transfer between the molten wire and the melt pool. The results show that the characteristics of the process, like laser-wire and wire-melt pool interaction, vary depending on the level of the wire pre-heating. In addition, application of two independent energy sources, laser beam and electrical power, allows fine-tuning of the heat input and increases penetration depth, with little influence on the height and width of the beads. This allows for better process stability as well as elimination of lack of fusion defects. Electrical signals measured in the hot-wire circuit indicate the process stability such that the resistive pre-heating can be used for in-process monitoring. The conclusion is that the resistive pre-heating gives additional means for controlling the stability and the heat input of the laser-directed energy deposition.

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