Tag Archives: Selective Laser Melting

Progress in 3D: Future of Medical Implants

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By Christian Nölke, Matthias Gieseke, Ronny Hagemann and Stefan Kaierle

Using two step laser additive manufacturing (LAM), commonly known as Selective Laser Melting, offers the opportunity to manufacture three dimensional (3D) parts. This manufacturing technique has gained a lot of attention and interest during the recent years and is of particular interest because prior computer tomography investigations allow an easy providing of the required patient individual dataset. This way offers a completely digital process chain until the required implant is produced. Manufacturing of steel and titanium implants with adapted surface structures and adapted mechanical properties is already within the scope of industrial research. Continue reading

Post-Processing of LAM Parts with Ultrafast Lasers

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By Ilya Mingareev, Tobias Bonhoff, Ashraf F. El-Sherif, Wilhelm Meiners, Ingomar Kelbassa, Tim Biermann and Martin Richardson

Laser Additive Manufacturing (LAM) is a rapidly developing field of advanced fabrication technologies that will benefit many industries by enabling near-net shape manufacturing of high-value components from metals, ceramics and compound materials. However, the geometry and the surface quality of parts produced by LAM can be significantly affected by heat-induced distortions, solidified melt droplets, partially fused powders, and surface modifications induced by the laser tool motion. The dimensional accuracy is insufficient for many application areas, thus requiring a certain amount of post-processing such as CNC milling and polishing. While efficient for solid and bulk components, conventional post-processing techniques cannot be applied to parts made of brittle, heat-sensitive materials, many multi-layer material systems and components with engineered porosity. Continue reading

Digital Photonic Production and Its Emerging Opportunities

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By Christian Hinke

Digital photonic production enables us to fabricate almost any component or product directly from digital data. Experts characterize the photon or the laser as the only tool that “works” as quickly as a computer “thinks.” An office laser printer functions according to this principle and reveals what will be possible in future manufacturing with high energy lasers – when the fundamental interactions between material, light and photonic process chains have been understood and, based on this knowledge, digital photonic production systems have been put into practice. Continue reading

LAM 2013 Presents Groundbreaking Applications in AM

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By Geoff Giordano

If additive manufacturing is becoming the next big thing as some experts and companies believe, the Laser Institute of America’s fifth-annual Laser Additive Manufacturing (LAM®) Workshop helped pave the way by providing more information on the road map leading to an AM revolution.

Situated in its largest venue yet, LAM 2013 featured more than 20 presentations covering everything from nuts-and-bolts  cladding and repair to sky’s-the-limit projections of the growing impact of additive processes. While US government initiatives trumpet innovation in photonics and manufacturing, LIA continues to lead the charge in advocating greater profitability through advanced laser-based AM applications.

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Laser Surface Treatment and Additive Manufacturing – Basics and Application Examples

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By: Dr. Ingomar Kelbassa

Laser Surface Treatment and Additive Manufacturing have a strong impact on classical manufacturing and repair tasks addressing markets such as turbo machinery, aeronautics, automotive, off-shore and mining as well as tool, die, and mold making and life science.

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