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Date
2021-06-16
Author
Wegener, ThomasKoopmann, JulianRichter, JuliaKrooß, PhilippNiendorf, Thomas
Subject
620  Engineering  660  Chemical engineering  Selektives LaserschmelzenRapid Prototyping <Fertigung>KupferChromZirkoniumElektrische LeitfähigkeitErmüdung bei niedrigen LastspielzahlenMechanische EigenschaftMikrostruktur
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doi:10.17170/kobra-202108104523

doi:10.1111/ffe.13527
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Aufsatz

CuCrZr processed by laser powder bed fusion — Processability and influence of heat treatment on electrical conductivity, microstructure and mechanical properties

Abstract
CuCrZr parts were fabricated by laser beam powder bed fusion (LB-PBF) technique and subjected to different heat treatments. As a result, four different conditions were considered for further investigations, that is, the as-built condition, conditions of maximum hardness (MH) and maximum electrical conductivity (MC), and a condition representing a compromise between hardness and conductivity (H&C). Microstructural evolution and performance under monotonic and cyclic loading were studied. Fracture surfaces revealed significant volume fractions of process-induced defects such as lack-of-fusion (LoF) and pores, irrespective of the condition considered. The effect of these defects on the tensile behavior was found to be marginal, whereas the fatigue performance was noticeably affected due to multiple crack nucleation promoted by large LoF defects. Assessment by computed tomography (CT) revealed a strong influence of the geometry and therefore, of the scan path length, on resulting microstructure and defect population eventually rationalizing obvious discrepancies to the initial process parameter and material density optimization study.
Citation
In: Fatigue & Fracture of Engineering Materials & Structures (FFEMS)  Volume 44 / Issue 9 (2021-06-16) , S. 2570-2590 ; eissn:1460-2695
Sponsorship
Gefördert im Rahmen des Projekts DEAL
Collections
Artikel  (Publikationen im Open Access gefördert durch die UB)
Citation
@article{doi:10.17170/kobra-202108104523,
   author={Wegener, Thomas and Koopmann, Julian and Richter, Julia and Krooß, Philipp and Niendorf, Thomas},
   title={CuCrZr processed by laser powder bed fusion — Processability and influence of heat treatment on electrical conductivity, microstructure and mechanical properties},
   journal={Fatigue & Fracture of Engineering Materials & Structures (FFEMS)},
   year={2021}
}
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2021-08-23T12:35:15Z
2021-08-23T12:35:15Z
2021-06-16
doi:10.17170/kobra-202108104523
http://hdl.handle.net/123456789/13152
Gef&ouml;rdert im Rahmen des Projekts DEAL
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electrical conductivity
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low-cycle fatigue
mechanical properties
microstructure
620
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CuCrZr processed by laser powder bed fusion &mdash; Processability and influence of heat treatment on electrical conductivity, microstructure and mechanical properties
Aufsatz
CuCrZr parts were fabricated by laser beam powder bed fusion (LB-PBF) technique and subjected to different heat treatments. As a result, four different conditions were considered for further investigations, that is, the as-built condition, conditions of maximum hardness (MH) and maximum electrical conductivity (MC), and a condition representing a compromise between hardness and conductivity (H&amp;C). Microstructural evolution and performance under monotonic and cyclic loading were studied. Fracture surfaces revealed significant volume fractions of process-induced defects such as lack-of-fusion (LoF) and pores, irrespective of the condition considered. The effect of these defects on the tensile behavior was found to be marginal, whereas the fatigue performance was noticeably affected due to multiple crack nucleation promoted by large LoF defects. Assessment by computed tomography (CT) revealed a strong influence of the geometry and therefore, of the scan path length, on resulting microstructure and defect population eventually rationalizing obvious discrepancies to the initial process parameter and material density optimization study.
open access
Wegener, Thomas
Koopmann, Julian
Richter, Julia
Kroo&szlig;, Philipp
Niendorf, Thomas
doi:10.1111/ffe.13527
Selektives Laserschmelzen
Rapid Prototyping &lt;Fertigung&gt;
Kupfer
Chrom
Zirkonium
Elektrische Leitf&auml;higkeit
Erm&uuml;dung bei niedrigen Lastspielzahlen
Mechanische Eigenschaft
Mikrostruktur
publishedVersion
eissn:1460-2695
Issue 9
Fatigue &amp; Fracture of Engineering Materials &amp; Structures (FFEMS)
2570-2590
Volume 44
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Attribution-NonCommercial-NoDerivatives 4.0 International
Except where otherwise noted, this item's license is described as Attribution-NonCommercial-NoDerivatives 4.0 International