Published ArticleTopology optimization approach was used for the design of Ti6Al4V ELI lattice structures with stiffness and density close to the human bone for implant applications. Three lattice designs with volume densities of 35 %, 40 % and 45 % and corresponding elastic modulus of 18.6 GPa, 23.1 GPa 27.4 GPa close to the human bone were generated. Laser powder bed fusion (LPBF) technique was used for the manufacturing of the specimens. Physical measurements and mechanical characterization of specimens were assessed by microCT analyses and compression test, perpendicular and parallel to the building direction of the specimens. LPBF Ti6Al4V ELI manufactured lattice structures showed deviations in wall thickness in comparison with t...
Published Conference ProceedingsThe type of material used in biomedical applications depends on spec...
Cellular structures are similarly identified as lattice structures or foam structures which are comm...
CITATION: Du Plessis, A., et al. 2018. Mechanical properties and in situ deformation imaging of micr...
© 2023 The Author. Published by MDPI. This is an open access article available under a Creative Comm...
Additive manufacturing (AM) of titanium (Ti) and Ti-6Al-4V lattices has been proposed for bone impla...
A key advantage of additive manufacturing (AM) is that it allows the fabrication of lattice structur...
The data included in this article provides additional supporting information on our publication (McG...
Laser powder bed fusion (L-PBF) techniques have been increasingly adopted for the production of high...
The call for orthopedic implants is a growing concern with an ever-rising aging population. Current ...
Ti6Al4V sub-millimetric cellular structures arise as promising solutions concerning the progress of ...
Lattice structure topology is a rapidly growing area of research facilitated by developments in addi...
Ti alloys with lattice structures are garnering more and more attention in the field of bone repair ...
The progress in additive manufacturing has remarkably increased the application of lattice materials...
Mechanical and architectural features play an important role in designing biomedical devices. The us...
The development of medical implants is an ongoing process pursued by many studies in the biomedical ...
Published Conference ProceedingsThe type of material used in biomedical applications depends on spec...
Cellular structures are similarly identified as lattice structures or foam structures which are comm...
CITATION: Du Plessis, A., et al. 2018. Mechanical properties and in situ deformation imaging of micr...
© 2023 The Author. Published by MDPI. This is an open access article available under a Creative Comm...
Additive manufacturing (AM) of titanium (Ti) and Ti-6Al-4V lattices has been proposed for bone impla...
A key advantage of additive manufacturing (AM) is that it allows the fabrication of lattice structur...
The data included in this article provides additional supporting information on our publication (McG...
Laser powder bed fusion (L-PBF) techniques have been increasingly adopted for the production of high...
The call for orthopedic implants is a growing concern with an ever-rising aging population. Current ...
Ti6Al4V sub-millimetric cellular structures arise as promising solutions concerning the progress of ...
Lattice structure topology is a rapidly growing area of research facilitated by developments in addi...
Ti alloys with lattice structures are garnering more and more attention in the field of bone repair ...
The progress in additive manufacturing has remarkably increased the application of lattice materials...
Mechanical and architectural features play an important role in designing biomedical devices. The us...
The development of medical implants is an ongoing process pursued by many studies in the biomedical ...
Published Conference ProceedingsThe type of material used in biomedical applications depends on spec...
Cellular structures are similarly identified as lattice structures or foam structures which are comm...
CITATION: Du Plessis, A., et al. 2018. Mechanical properties and in situ deformation imaging of micr...