Direct fabrication of compositionally graded Ti-Al2O3 multi-material structures using Laser Engineered Net Shaping

[Display omitted] •Direct additive manufacturing of ceramics using melt cast route.•Fabrication of compositionally gradient ceramic-metal structure in one additive manufacturing operation.•Characterization and defect analysis of AM processed parts. Laser Engineered Net Shaping (LENS™), which is a la...

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Published inAdditive manufacturing Vol. 21; pp. 104 - 111
Main Authors Zhang, Yanning, Bandyopadhyay, Amit
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.05.2018
Subjects
Additive manufacturing
Alumina
Laser processing
LENS
Multi-materials structures
Laser processing
Additive manufacturing
Multi-materials structures
Alumina
LENS
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Abstract [Display omitted] •Direct additive manufacturing of ceramics using melt cast route.•Fabrication of compositionally gradient ceramic-metal structure in one additive manufacturing operation.•Characterization and defect analysis of AM processed parts. Laser Engineered Net Shaping (LENS™), which is a laser based additive manufacturing method, was utilized to fabricate Ti-Al2O3 compositionally graded structures. The Ti-Al2O3 graded composites consisted of different sections −Ti6Al4V alloy, Ti6Al4V + Al2O3 composites, and pure Al2O3 ceramic. After LENS™ processing, microstructural characterization, phase analysis, elemental distribution, and microhardness measurements were performed on the cross sections of Ti-Al2O3 graded composites. Each section had their unique microstructures and phases. Moreover, hardness measurements demonstrated that the pure Al2O3 section had the highest hardness of 2365.5 ± 64.7 HV0.3. Conventional ceramic processing requires extensive post-processing including high temperature sintering, which makes it difficult for direct fabrication of metal-ceramic multi-layer structures. The results demonstrate that LENS™ can be utilized to process multi-material metal ceramic composites in a single step while maintaining the size, shape and compositional variations based on computer aided design files. Since this is a first-generation work, and limited research results are available in published literature related to LENS™ processing of both metals and ceramics in one operation, the demonstration of this work is expected to inspire future studies on manufacturing of multi-material composites using AM.
AbstractList [Display omitted] •Direct additive manufacturing of ceramics using melt cast route.•Fabrication of compositionally gradient ceramic-metal structure in one additive manufacturing operation.•Characterization and defect analysis of AM processed parts. Laser Engineered Net Shaping (LENS™), which is a laser based additive manufacturing method, was utilized to fabricate Ti-Al2O3 compositionally graded structures. The Ti-Al2O3 graded composites consisted of different sections −Ti6Al4V alloy, Ti6Al4V + Al2O3 composites, and pure Al2O3 ceramic. After LENS™ processing, microstructural characterization, phase analysis, elemental distribution, and microhardness measurements were performed on the cross sections of Ti-Al2O3 graded composites. Each section had their unique microstructures and phases. Moreover, hardness measurements demonstrated that the pure Al2O3 section had the highest hardness of 2365.5 ± 64.7 HV0.3. Conventional ceramic processing requires extensive post-processing including high temperature sintering, which makes it difficult for direct fabrication of metal-ceramic multi-layer structures. The results demonstrate that LENS™ can be utilized to process multi-material metal ceramic composites in a single step while maintaining the size, shape and compositional variations based on computer aided design files. Since this is a first-generation work, and limited research results are available in published literature related to LENS™ processing of both metals and ceramics in one operation, the demonstration of this work is expected to inspire future studies on manufacturing of multi-material composites using AM.
Author Bandyopadhyay, Amit
Zhang, Yanning
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Keywords Laser processing
Additive manufacturing
Multi-materials structures
Alumina
LENS
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Snippet [Display omitted] •Direct additive manufacturing of ceramics using melt cast route.•Fabrication of compositionally gradient ceramic-metal structure in one...
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SubjectTerms Additive manufacturing
Alumina
Laser processing
LENS
Multi-materials structures
Title Direct fabrication of compositionally graded Ti-Al2O3 multi-material structures using Laser Engineered Net Shaping
URI https://dx.doi.org/10.1016/j.addma.2018.03.001
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