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Additive manufacturing - metal

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Opening hours

By arrangement

Profile

The "Additive Manufacturing - Metal" laboratory houses equipment and systems for the additive manufacturing of metallic components using the LBF process (Laser Powder Bed Fusion).
The centerpiece is the MLab Cusing SLM system from ConceptLaser.
This can be used to manufacture components up to a size of around 85 mm x 85 mm x 80 mm.
The peripheral equipment for the system includes a powder mixer, a sieve system for recycling metal powder and a nitrogen generator for the continuous supply of shielding gas. A sandblasting system is also available for post-processing the SLM-produced components.
The main starting materials used are Fe and Cu matrixes.

Publications

02/2023 Chapter: F. Foadian, R. Kremer, "In-Situ Alloy Formation during Selective Laser Melting with CuSn10 and Aluminum Powders ", TMS 2023 Conference Proceedings
12/2022 Chapter: F. Foadian, R. Kremer, S. Khani, "Chapter: Rapid alloying in additive manufacturing using integrated computational materials engineering ", Elsevier
11/2022 R. Kremer, J. Etzkorn, H. Palkowski, F. Foadian, "Corrosion Resistance of 316L/CuSn10 Multi-Material Manufactured by Powder Bed Fusion", Materials 2022
05/2022

R. Kremer, S. Khani, T. Appel, H. Palkowski, F. Foadian, "Selective Laser Melting of CuSn10: Simulation of Mechanical Properties, Microstructure, and Residual Stresses", Materials 2022

Final theses

2023 Numerical mapping of dislocation movement in CuSn alloys using a molecular dynamics approach, Master thesis
2022 Multiscale simulation of Cu and CuSn10 using density functional theory, molecular dynamics and dislocation dynamics, Master thesis
PBF-processed high-entropy alloys, multi-material materials, corrosion of PBF-processed components, and multiscale simulations, Bachelor's thesis
Feasibility study on the processing of highly reflective powder materials with low laser power in the field of in-situ alloying in the SLM process, Bachelorthesis
In-situ alloy formation during selective laser melting with CuSn10 and Al powder, Bachelorthesis
Experimental investigation of the influence of humidity on the process of selective laser melting with 1.4404, Bachelorthesis
2021 Influence study of an alloying of copper to 1.4404 in the field of selective laser melting, bachelor thesis
Experimental and simulative investigation of the crystal structure and residual stresses on selective laser-melted components made of CuSn10, Master's thesis
Parameterization of Brz10 in the field of selective laser melting, Bachelorthesis
Influence of heat treatments on CuSn10 after selective laser melting, Bachelorthesis

Equipment

  • Concept Laser Mlab Cusing R
  • Nitrogen generator Parker HPN2-12.500
  • Sieving station for metal powder
  • iepco Peenmatic PM 550 sandblasting system
  • Moisture meter Mettler Toledo HE73
  • Vacuum drying oven Goldbrunn 1450
  • Analytical balance Sartorius analytic

Service & Offer

Selected research activities

  • Integrated material simulation (ICME) with coupling for process simulation of additively manufactured CuSn10 components with a focus on anisotropy and residual stresses caused by the manufacturing process
  • Development of wear-optimized materials for additive manufacturing using nitrogen-modified manganese hard steels
  • In-situ alloys
  • Multi-material and hybrid materials

Contact

Contact person

Portrait von Robert Kremer __ Portrait of Robert Kremer
Robert Kremer, M.Eng.
Office hours

by arrangement by mail

Management

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