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Mechanical characterization of polyamide cellular structures fabricated using selective laser sintering technologies
Highlights ► Nine types of lattice structures specimens were designed in a CAD environment. ► They were produced by SLS. ► Tensile tests were performed. ► A predictive model was proposed. ► The model was verified by FEM analyses, pointing out some aspects that justify experimentally measured trends.
Abstract The significantly growing use of Additive Manufacturing (AM) enables the fabrication of innovative parts, characterized by lightness and good mechanical properties. The biomedical field takes great advantage of these capabilities: in particular, the ability of producing porous or lattice structure-based parts allows to obtain prostheses with human bone like stiffness, with a positive influence in patient’s lifestyle. The knowledge of the mechanical behavior of materials used in AM and producible geometries is an essential requirement to profit and improve this characteristic: in particular, recent studies focus on the correlation between strength parameters and relative porosity of the part. In a previous work a set of tensile tests have been performed on different types of specimens, reproducing a set of corresponding emptying strategies, with different resulting porosity rates, and a linear predictive model has been proposed. Aim of this work is to integrate the already acquired data, providing an interpretation on previous results by numerical simulations: the influence of porosity rate on mechanical properties was investigated by performing both global and local Finite Element Analyses, finding out an explanation on inverse proportionality between material strength properties and porosity rate. The methodology proved to be a profitable way in the optimization of lattice structures for Additive Manufacturing.
Mechanical characterization of polyamide cellular structures fabricated using selective laser sintering technologies
Highlights ► Nine types of lattice structures specimens were designed in a CAD environment. ► They were produced by SLS. ► Tensile tests were performed. ► A predictive model was proposed. ► The model was verified by FEM analyses, pointing out some aspects that justify experimentally measured trends.
Abstract The significantly growing use of Additive Manufacturing (AM) enables the fabrication of innovative parts, characterized by lightness and good mechanical properties. The biomedical field takes great advantage of these capabilities: in particular, the ability of producing porous or lattice structure-based parts allows to obtain prostheses with human bone like stiffness, with a positive influence in patient’s lifestyle. The knowledge of the mechanical behavior of materials used in AM and producible geometries is an essential requirement to profit and improve this characteristic: in particular, recent studies focus on the correlation between strength parameters and relative porosity of the part. In a previous work a set of tensile tests have been performed on different types of specimens, reproducing a set of corresponding emptying strategies, with different resulting porosity rates, and a linear predictive model has been proposed. Aim of this work is to integrate the already acquired data, providing an interpretation on previous results by numerical simulations: the influence of porosity rate on mechanical properties was investigated by performing both global and local Finite Element Analyses, finding out an explanation on inverse proportionality between material strength properties and porosity rate. The methodology proved to be a profitable way in the optimization of lattice structures for Additive Manufacturing.
Mechanical characterization of polyamide cellular structures fabricated using selective laser sintering technologies
Cerardi, A. (author) / Caneri, M. (author) / Meneghello, R. (author) / Concheri, G. (author) / Ricotta, M. (author)
2012-11-23
6 pages
Article (Journal)
Electronic Resource
English
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