Abstract
Additive Manufacturing (AM) technologies offer the ability to construct complex geometrical structures in short manufacturing lead time coupled with a relatively low production cost when compared to traditional manufacturing processes. The next trend in mechanical engineering design is the adaption of design strategies that build products with lightweight lattice geometries like sandwich structures. These structures possess low mass, large surface area to volume ratio, high porosity, and adequate mechanical behavior, which are properties of great importance in scientific fields such as bioengineering, automotive, and aerospace engineering. The present work is focused on producing sandwich structures with complex lattice patterns like the Triply Periodic Minimal Surface (TPMS) Schwarz diamond structure. The specimens were manufactured with two different Additive Manufacturing procedures employing various relative densities. More specifically, Material Jetting Printing (MJP) and Fused Filament Fabrication (FFF) processes were employed to investigate the performance of Acrylonitrile Butadiene Styrene (ABS) lightweight lattice structures. These structures were examined using digital microscopy in order to measure the dimensional accuracy and the surface characteristics of the utilized AM technologies. Furthermore, three-point bending tests and finite elements analyses have been applied to investigate the mechanical performance of the proposed technologies and designs as well as the influence of the relative density on the Schwarz diamond TPMS structure. The experimental results demonstrate that the investigated structure possesses a remarkable performance in respect to its weight due to the specific distribution of its material in space.
Highlights
The demand for novel lightweight structures emerged in several application domains e.g., aerospace, automotive, etc., and resulted in the development of various manufacturing and design methodologies [1]
The advances of manufacturing processes and the development in Additive Manufacturing (AM) technologies extend the capabilities of constructing parts with complex geometrical characteristics [2]
The main objective of the work is to investigate the effect of the relative density on the mechanical performance of these complex lattice structures using two different AM operations
Summary
The demand for novel lightweight structures emerged in several application domains e.g., aerospace, automotive, etc., and resulted in the development of various manufacturing and design methodologies [1]. Components constructed via an AM procedure could possess a complex and lightweight structure, properties that are difficult short manufacturing and lead time [4]. Components constructed via an AM procedure could possess a complex and lightweight structure, properties that are difficult to be addressed in other manufacturing techniques such as subtractive manufacturing [5,6]. This design freedom that AM technology can provide is highly valuable in numertoorder be addressed in other manufacturing subtractive manufacturing [5,6]
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