Abstract
Additively manufactured (AM) metallic sheet-based Triply Periodic Minimal Surface Structures (TPMSS) meet several requirements in both bio-medical and engineering fields: Tunable mechanical properties, low sensitivity to manufacturing defects, mechanical stability, and high energy absorption. However, they also present some challenges related to quality control, which can prevent their successful application. In fact, the optimization of the AM process is impossible without considering structural characteristics as manufacturing accuracy, internal defects, as well as surface topography and roughness. In this study, the quantitative non-destructive analysis of TPMSS manufactured from Ti-6Al-4V alloy by electron beam melting was performed by means of X-ray computed tomography (XCT). Several advanced image analysis workflows are presented to evaluate the effect of build orientation on wall thicknesses distribution, wall degradation, and surface roughness reduction due to the chemical etching of TPMSS. It is shown that the manufacturing accuracy differs for the structural elements printed parallel and orthogonal to the manufactured layers. Different strategies for chemical etching show different powder removal capabilities and both lead to the loss of material and hence the gradient of the wall thickness. This affects the mechanical performance under compression by reduction of the yield stress. The positive effect of the chemical etching is the reduction of the surface roughness, which can potentially improve the fatigue properties of the components. Finally, XCT was used to correlate the amount of retained powder with the pore size of the functionally graded TPMSS, which can further improve the manufacturing process.
Highlights
These methods have been widely investigated by some researchers in order to improve some morphological characteristics of Additively manufactured (AM)-samples [16,17]
We focus on X-ray computed tomography (XCT) characterization of sheet-based Triply Periodic Minimal Surface Structures (TPMSS) manufactured using electron beam melting (EBM)
We present novel strategies workflows for quantitative present novel strategies andand workflows for quantitative image analysis of metallic and functionally graded porous structures (FGPS)
Summary
In contrast to the strut-based lattice structures, this can be achieved without loss of structural integrity Another challenge is the production of defect-free, accurate TMPSS with low deviation from the intended geometrical models. Other ways to treat the whole volume of the porous specimen are chemical and electrochemical etching (CE, ECE) These methods have been widely investigated by some researchers in order to improve some morphological characteristics (in particular surface roughness) of AM-samples [16,17]. Materials 2021, 14, 3002 application of the global thresholding [26]; (2) the morphological filters or Watershed segmentation tools modify profile as well thickness of additional the walls, could modify thecould surface profilethe as surface well as the thickness of as thethe walls, bringing bringing additional error to the analysis Another challenge challenge is is the the quantitative quantitative assessment assessment of of material material loss loss caused caused by by CE. Scope of this will be discussed in the follow-up publications
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