Düsenberg B, Gomez Bonilla JS, Christ M, Schmidt J, Wirth KE, Peukert W, Bück A (2025)
Publication Language: English
Publication Type: Book chapter / Article in edited volumes
Publication year: 2025
Publisher: Springer Nature
Edited Volumes: Progress in Powder Based Additive Manufacturing
Series: Springer Tracts in Additive Manufacturing
Book Volume: Part F386
Pages Range: 37-55
DOI: 10.1007/978-3-031-78350-0_3
The majority of commercially available particulate materials in additive manufacturing are single-material systems. Multi-material systems are typically generated by bulk mixing as heterogeneous systems that are difficult to reproduce due to segregation effects during mixing and later deposition in the manufacturing process. This limits the properties of the additively manufactured components. For further application areas of additively manufactured components, it is therefore imperative to produce process-optimized single-material particles in addition to multi-material systems, whereby the production of the material systems and their handling require new process routes. The base materials for powder-based additive manufacturing must meet various requirements for processing, and the particles should be between 70 and 120 μm in size and have good flowability. These targeted properties also apply to multi-material systems.
APA:
Düsenberg, B., Gomez Bonilla, J.S., Christ, M., Schmidt, J., Wirth, K.-E., Peukert, W., & Bück, A. (2025). Gas Phase Functionalization of Polymer and Metallic Materials for Powder-Based Additive Manufacturing. In Progress in Powder Based Additive Manufacturing. (pp. 37-55). Springer Nature.
MLA:
Düsenberg, Björn, et al. "Gas Phase Functionalization of Polymer and Metallic Materials for Powder-Based Additive Manufacturing." Progress in Powder Based Additive Manufacturing. Springer Nature, 2025. 37-55.
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