Faculty Publications
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Item A Closed-Form Solution for the Effect of Free Edges on Melt Pool Geometry and Solidification Microstructure in Additive Manufacturing of Thin-Wall Geometries(Springer Boston, 2016) Gockel, J.; Klingbeil, N.; Bontha, S.Laser and electron beam-based additive manufacturing of Ti-6Al-4V are under consideration for application to aerospace components. A critical concern for these processes is the ability to obtain a consistent and desirable microstructure and corresponding mechanical properties of the deposit. Based on the Rosenthal solution for a moving point-heat source, recent work has developed simulation-based process maps for the thermal conditions controlling microstructure (grain size and morphology) in beam-based deposition of semi-infinite geometries, where a steady-state melt pool exists away from free edges. In the current study, the Rosenthal solution is modified to include the effects of free edges. This is accomplished by the superposition of two point-heat sources approaching one another, with the line of symmetry representing the free edge. The result is an exact solution for the case of temperature-independent properties. Dimensionless results for melt pool geometry are determined, and plotted as a function of distance from the free edge. Results are plotted on solidification maps to predict trends in microstructure for Ti-6Al-4V. Finite element analysis is used to verify results. Results suggest that melt pool geometry is more sensitive to free edges than solidification microstructure. © 2015, The Minerals, Metals & Materials Society and ASM International.Item Eco-friendly lightweight filament synthesis and mechanical characterization of additively manufactured closed cell foams(Elsevier Ltd, 2019) Patil, B.; Bharath Kumar, B.R.; Bontha, S.; Balla, V.K.; Powar, S.; Hemanth Kumar, V.H.; Suresha, S.N.; Doddamani, M.Environmentally pollutant fly ash cenospheres (hollow microballoons) are utilized with most widely consumed, relatively expensive high density polyethylene (HDPE) for developing lightweight eco-friendly filament for 3D printing of closed cell foams. Cenospheres (20, 40 and 60 by volume %) are blended with HDPE and subsequently extruded in filament to be used for 3D printing. Cenosphere/HDPE blends are studied for melt flow index (MFI) and rheological properties. MFI decreases with cenospheres addition. Complex viscosity, storage and loss modulus increase with filler loading. DSC results on the filament and printed samples reveal increasing crystallization temperature and decreasing crystallinity % with no appreciable change in peak melting temperature. Cooling rate variations exhibit crystallinity differences between the filament and the prints. CTE decreases with increasing cenosphere content resulting in lower thermal stresses and under diffusion of raster leading to non-warped prints. Micrography on freeze fractured filament and prints show cenospheres uniform distribution in HDPE. Intact cenospheres lower the foam density making it lightweight. Tensile tests are carried out on filaments and printed samples while flexural properties are investigated for 3D prints. Cenospheres addition resulted in improved tensile modulus and decreased filament strength. Tensile and flexural modulus of printed foams increases with filler content. Results are also compared with injection molded samples. Printed foams registered comparable tensile strength. Specific tensile modulus is noted to be increased with cenospheres loading implying weight saving potential of 3D printed foams. Property map reveals printed foams advantage over other fillers and HDPE composites synthesized through injection and compression molding. © 2019 Elsevier LtdItem Material extrusion additive manufacturing of bioactive glass/high density polyethylene composites(Elsevier Ltd, 2021) Jeyachandran, P.; Bontha, S.; Bodhak, S.; Balla, V.K.; Doddamani, M.Bioactive glasses (BAG) are renowned for their unique ability to bond with tissues and therefore are used extensively for bone repair and functional recovery. In this work, high density polyethylene (HDPE) reinforced with BAG is processed using material extrusion additive manufacturing (MEAM) for potential orthopaedic applications. The constituents are melt compounded by varying BAG proportions (5, 10, and 20 wt %) and subsequently extruded into filaments. DSC curves show an insignificant change in the peak melting temperature, increase in crystallization temperature, and a decrease in the crystallinity of HDPE with BAG addition. Warpage analysis confirms that the enhanced temperature parameters and BAG addition result in reduced warpage and improved dimensional stability. Rheological results show that the addition of BAG increases complex viscosity, storage and loss modulus. Melt behavior and print parameters are tailored to improve first layer adhesion and interfacial bonding rendering dimensionally stable prints without any print induced defects. Dynamic mechanical analysis (DMA) of printed samples show an increase in storage (E?), loss (E?) modulus, and a decrease in damping factor (Tan ?) with BAG addition. MEAM of the developed H/BAG composites shows a strong potential for developing customizable scaffolds and implants as bone replacements. © 2021 Elsevier LtdItem Quasi-static compressive behavior of bioactive glass reinforced high density polyethylene composites(Elsevier B.V., 2022) Jeyachandran, P.; Bontha, S.; Bodhak, S.; Krishna Balla, V.; Doddamani, M.Compressive behavior of additively manufactured bioactive glass (BAG) reinforced high density polyethylene (HDPE) composites under quasi static conditions (0.001, 0.01 and 0.1 s−1 strain rates) is investigated in this work. HDPE feedstock filaments with 5, 10 and 20 wt% of bioactive glass are extruded for fused filament fabrication (FFF) based 3D printing (3DP). Compressive properties are extracted from the stress–strain plots. Elastic modulus and yield strength of the samples increase with filler addition and strain rate. Energy absorption increases with increase in strain rate and BAG content. All the samples exhibit homogeneous ductile deformation with distinct barrelling effect without any visible cracks. Deformation and energy absorption behavior of the tested samples are investigated using micrography. © 2021 Elsevier B.V.