Selective Laser Melting of Biomaterial (Pure Titanium) with High-Power Laser

The Selective Laser Melting (SLM) technology uses metal powders as building material which is melted and welded together using a high-power laser in order to obtain quick configuration of complex parts, most often for testing them. Another advantage of this method is the fact that allows obtaining any 3D geometry of the parts, even parts that cannot be processed through conventional manufacturing procedures. In this work were performed a number of tests for accelerated corrosion of AlSi10Mg alloy specimens in order to determine their mean life in the conditions of their use in a high salinity environment. For specimens, optical analysis was used the SEM microscope which has the advantage of obtaining an enlarged image of the investigated objects without processing. Following these analyses, it has been determined the mass loss of specimens due to corrosion.

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Beam Diameter Dependence of Performance in Thick-Layer and High-Power Selective Laser Melting of Ti-6Al-4V

Materials ◽

10.3390/ma11071237 ◽

2018 ◽

Vol 11 (7) ◽

pp. 1237 ◽

Cited By ~ 6

Author(s):

Wentian Shi ◽

Yude Liu ◽

Xuezhi Shi ◽

Yanjun Hou ◽

Peng Wang ◽

...

Keyword(s):

Selective Laser Melting ◽

High Power ◽

Large Diameter ◽

Thick Layer ◽

Beam Diameter ◽

Laser Melting ◽

Power Laser ◽

Beam Laser ◽

Melt Pool ◽

Thick Layers

A 400 W high-power laser was used to fabricate 200-µm-thick Ti-6Al-4V samples to evaluate the effects of small (50 μm) and large (200 μm) beam diameter on density, microstructure and mechanical properties. A series of single-track experiments demonstrated that it was challenging for the small-beam laser to fabricate smooth and defect-free scan tracks. A larger beam diameter efficiently avoided process instability and provided a more stable and uniform melt pool. By increasing the beam diameter, the density of multilayer samples reached 99.95% of the theoretical value, which is much higher than that achieved with the small beam diameter. However, it was difficult to completely eliminate defects due to serious spatter and evaporation. Moreover, all of the generated samples had relatively coarse surfaces. For the large beam diameter of 200 µm, the optimal yield strength, ultimate tensile strength and elongation were 1150 MPa, 1200 MPa and 8.02%, respectively. In comparison, the small beam diameter of 50 µm resulted in values of 1035 MPa, 1100 MPa and 5.91%, respectively. Overall, the large-diameter laser is more suitable for high-power selective laser melting (SLM) technology, especially for thick layers.

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Elucidation of melt flows and spatter formation mechanisms during high power laser welding of pure titanium

Journal of Laser Applications ◽

10.2351/1.4922383 ◽

2015 ◽

Vol 27 (3) ◽

pp. 032012 ◽

Cited By ~ 47

Author(s):

Hiroshi Nakamura ◽

Yousuke Kawahito ◽

Koji Nishimoto ◽

Seiji Katayama

Keyword(s):

Laser Welding ◽

High Power ◽

Pure Titanium ◽

Formation Mechanisms ◽

High Power Laser ◽

Power Laser

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Continuous fiberizing by laser melting (Cofiblas): Production of highly flexible glass nanofibers with effectively unlimited length

Science Advances ◽

10.1126/sciadv.aax7210 ◽

2020 ◽

Vol 6 (6) ◽

pp. eaax7210

Author(s):

F. Quintero ◽

J. Penide ◽

A. Riveiro ◽

J. del Val ◽

R. Comesaña ◽

...

Keyword(s):

High Power ◽

Gas Jet ◽

Experimental Setup ◽

High Power Laser ◽

Physical Processes ◽

Laser Melting ◽

Power Laser ◽

Distinctive Features ◽

Innovative Method ◽

Supersonic Gas Jet

The development of nanofibers is expected to foster the creation of outstanding lightweight nanocomposites and flexible and transparent composites for applications such as optoelectronics. However, the reduced length of existing nanofibers and nanotubes limits mechanical strengthening and effective manufacturing. Here, we present an innovative method that produces glass nanofibers with lengths that are, effectively, unlimited by the process. The method uses a combination of a high-power laser with a supersonic gas jet. We describe the experimental setup and the physical processes involved, and, with the aid of a mathematical simulation, identify and discuss the key parameters which determine its distinctive features and feasibility. This method enabled the production of virtually unlimited long, solid, and nonporous glass nanofibers that display outstanding flexibility and could be separately arranged and weaved.

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