Additive Manufacturing Viewed from Material Science: State of the Art & Fundamentals

J.Y. Hascoet; K.P. Karunakaran; Surendar Marya

doi:10.4028/www.scientific.net/MSF.783-786.2347

Paper Titles

Plastic Rotational Factor Calculation for Shallow-Notched SE(B) Specimens
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Contribution of the Nanoindentation to the Study of HCP Metals
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Particle Dispersion Simulator for Gel Printer
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Microstructural Barriers against Fatigue Crack Growth
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Additive Manufacturing Viewed from Material Science: State of the Art & Fundamentals
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Effects of Heat Treatments on Tungsten for Armours in NFR
p.2353

Evaluation of Fatigue Damage by Diffraction Contrast Tomography Using Synchrotron Radiation
p.2359

High Performance Materials by Laser Deposition
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RETRACTED: Microstructural Characterization and Mechanical Properties of Laser Deposited High Entropy Alloys
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HomeMaterials Science ForumMaterials Science Forum Vols. 783-786Additive Manufacturing Viewed from Material...

Additive Manufacturing Viewed from Material Science: State of the Art & Fundamentals

Abstract:

Additive Manufacturing (AM), also designated as 3D Printing (3DP), is one of the mostvisionary and friendly approaches for flexible manufacturing with conservation of energy andmaterial resources. It is a factory in a box that can generate multiple objects. It requires littlemanpower to bring virtual innovations into the real world. AM for metals can be mechanisticallyassociated with welding. The technique employs a variety of energy sources (laser, electron beam,electric Arc, …), feed stocks (powder, wire and ribbon) and motion kinematics & control(articulated robot and 3-5 axes CNC machine ). From the materials perspectives, akin to fusionwelding in many respects, AM involves a multitude of complex and interacting physical phenomenasuch as heat transfer, fluid flow, discrete and continuum mechanics, sintering, melting,solidification, solid state transformations, grain growth, diffusion, textures etc. The desired processperformance can be achieved by controlling the parameters of energy, feed stock and motion. Theeffect of successive thermal cycles along with the epitaxial relations between substratum anddeposits constitute some of the challenging tasks for developing optimized parts. This paper reviewsthe state of the art and presents some challenges facing metal product development for serviceapplications.

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Materials Science Forum (Volumes 783-786)

Pages:

2347-2352

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.783-786.2347

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Online since:

May 2014

Authors:

J.Y. Hascoet, K.P. Karunakaran, Surendar Marya

Keywords:

3D Printing, Additive Manufacturing (AM), Laser Melting, Lens, Rapid Prototyping

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References

[1] G.N. Levy, R. Schindel, J.P. Kruth, Rapid manufacturing and rapid tooling with layer manufacturing (LM) technologies, State of the art and future perspectives, CIRP Annals - Manufacturing Technology, Volume 52, Issue 2, 2003, 589-609.

DOI: 10.1016/s0007-8506(07)60206-6

Google Scholar

[2] G. Levy, Additive Manufacturing and Electro Physical & Chemical Processes, CIRP ICME '12 - 8th CIRP Conference on Intelligent Computation in Manufacturing engineering, Innovative and Cognitive Production Technology Systems , 18 - 20 July 2012, Ischia (Naples), Italy.

Google Scholar

[3] Further information from http: /www. wohlerassociates. com.

Google Scholar

[4] Further information from Irccyn, Ecole Centrale Nantes (France), http: /www. ec-nantes. fr.

Google Scholar

[5] H. El Cheikh, B. Courant, S. Branchu, X. Huang, J.Y. Hascoet, Direct laser fabrication process with coaxial projection of 316L steel. Geometrical Characteristics and microstructure characterization of wall structures, Optics & laser Engineering 50 (2012).

DOI: 10.1016/j.optlaseng.2012.07.002

Google Scholar

[6] S. Akula, K . P . Karunakaran, Hybrid adaptive layer manufacturing: an intelligent art of direct metal rapid tooling process. Robotics and Computer-Integrated Manufacturing 2 2, (2006) 113–123.

DOI: 10.1016/j.rcim.2005.02.006

Google Scholar

[7] F. Martina, J. Mehnen, S.W. Williams, P. Colegrove, and F. Wang, Investigation of the benefits of plasma deposition for the additive layer manufacture of Ti–6Al–4V, Journal of Materials Processing Technology 212 (2012) 1377– 1386.

DOI: 10.1016/j.jmatprotec.2012.02.002

Google Scholar

[8] J.P. Kruth, G. Levy, F. Klocke, T.H.C. Childs, Consolidation phenomena in laser and powder-bed based layered manufacturing. CIRP Annals: Manufacturing Technology 56, (2007)730–759.

DOI: 10.1016/j.cirp.2007.10.004

Google Scholar