Uprint catalystex 4.5 download cnet
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Restrepo S, Ocampo S, Ramírez JA et al (2017) Mechanical properties of ceramic structures based on triply periodic minimal surface (TPMS) processed by 3D printing. Zhang L, Feih S, Daynes S et al (2018) Energy absorption characteristics of metallic triply periodic minimal surface sheet structures under compressive loading. Sychov MM, Lebedev LA, Dyachenko S V., Nefedova LA (2018) Mechanical properties of energy-absorbing structures with triply periodic minimal surface topology Acta Astronaut 1–4. Ībueidda DW, Bakir M, Abu Al-Rub RK et al (2017) Mechanical properties of 3D printed polymeric cellular materials with triply periodic minimal surface architectures. ĭomínguez-Rodríguez G, Ku-Herrera JJ, Hernández-Pérez A (2017) An assessment of the effect of printing orientation, density, and filler pattern on the compressive performance of 3D printed ABS structures by fuse deposition Int J Adv Manuf Technol 1–11. Lee DW, Khan KA, Abu Al-Rub RK (2017) Stiffness and yield strength of architectured foams based on the Schwarz primitive triply periodic minimal surface. Zhao M, Zhang DZ, Liu F et al (2020) Mechanical and energy absorption characteristics of additively manufactured functionally graded sheet lattice structures with minimal surfaces.
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Maskery I, Sturm L, Aremu AO et al (2018) Insights into the mechanical properties of several triply periodic minimal surface lattice structures made by polymer additive manufacturing. Sreedhar N, Thomas N, Al-ketan O et al (2018) Mass transfer analysis of ultrafiltration using spacers based on triply periodic minimal surfaces: effects of spacer design, directionality and voidage. The TPMS scaffold type combined with the loading direction significantly affected the compressive strength and elastic modulus of the scaffolds, showing the importance of considering both these properties in the design of AM scaffold structures.Īlmeida HA, Bártolo PJ (2014) Design of tissue engineering scaffolds based on hyperbolic surfaces: structural numerical evaluation. It also had the shortest manufacturing time and smallest quantity of support material needed for FDM manufacture. The primitive scaffold achieved the best performance in compression tests. The combination of compressive load direction (0° and 90° with respect to the manufacturing orientation) and TPMS type resulted in large changes in compressive strength. The main contribution of this research is the examination of the effect of manufacturing orientation and TPMS type on the mechanical properties of scaffolds manufactured by fused deposition modeling (FDM), a widely used form of AM. Additive manufacturing (AM) has the potential to build such TPMS structures due to its inherent manufacturing freedom and layer-by-layer construction however, the manufacturing orientation in AM is known to have a significant effect on the resulting mechanical properties. Triply periodic minimal surfaces (TPMS) enable the construction of lightweight scaffolds, complex geometry heat exchangers, and energy absorbing materials.