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Design of Variable-Density Structures for Additive Manufacturing Using Gyroid LatticesZhang, Botao January 2018 (has links)
No description available.
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Conformal Lattice Structures in Additive Manufacturing (AM)Melpal, Gopalakrishna Ranjan January 2018 (has links)
No description available.
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SIMULATION OF METAL GRAIN GROWTH IN LASER POWDER BED FUSION PROCESS USING PHASE FIELD THERMAL COUPLED MODELHuang, Zhida 23 May 2019 (has links)
No description available.
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Rasters vs Contours For Thin Wall ULTEM 9085 FDM ApplicationsKota, Vasuman 04 September 2019 (has links)
No description available.
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3D Printed Wearable Electronic Sensors with MicrofluidicsZellers, Brian Andrew 09 December 2019 (has links)
No description available.
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Characterizing the effects of build interruptions on the microstructure and mechanical properties of powder bed fusion processed Al-Si-10MgStokes, Ryan Mitchell 09 August 2019 (has links) (PDF)
This work seeks to characterize the impact of build interruptions to additively manufactured Al-Si-10-Mg produced by the powder bed fusion (PBF) process. Additive manufacturing represents a significant investment in overhead, machine, and material making an interruption to the process a potential waste of money and time. Interruptions in the form of power outages, lack of powdered feedstock, and/or shielding gas will cause the machine to operate in an unintended manner, potentially even stopping the build process. The process of manufacturing will influence the microstructure, which determine the material’s properties and performance. An interrupted PBF process could exhibit unique microstructural features and reduced mechanical properties that distinguish the resulting material from a continuous PBF process. Experiments were performed to simulate a production interruption with varying time periods of interruption and air exposure. The zone of interruption was characterized using optical micrographs, EDS, and hardness measurements to determine any effects of the interruption.
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UTILIZATION OF ADDITIVE MANUFACTURING IN THE DEVELOPMENT OF STATIONARY DIFFUSION SYSTEMS FOR AEROENGINE CENTRIFUGAL COMPRESSORSAdam Thomas Coon (16379487) 15 June 2023 (has links)
<p> Rising costs and volatility in aviation fuel and increased regulations resulting from climate change concerns have driven gas turbine engine manufacturers to focus on reducing fuel consumption. Implementing centrifugal compressors as the last stage in an axial engine architecture allows for reduced core diameters and higher fuel efficiencies. However, a centrifugal compressor's performance relies heavily on its stationary diffusion system. Furthermore, the highly unsteady and turbulent flow field exhibited in the diffusion system often causes CFD models to fall short of reality. Therefore, rapid validation is required to match the speed at which engineers can simulate different diffuser designs utilizing CFD. One avenue for this is through the use of additive manufacturing in centrifugal compressor experimental research. This study focused on implementing a new generation of the Centrifugal Stage for Aerodynamic Research (CSTAR) at the Purdue Compressor Research Lab that utilizes an entirely additively manufactured diffusion system. In addition, the new configuration was used to showcase the benefits of additive manufacturing (AM) in evaluating diffusion components. Two diffusion systems were manufactured and assessed. The Build 2 diffusion system introduced significant modifications to the diffusion system compared to the Build 1 design. The modifications included changes to the diffuser vane geometry, endwall divergence, and increased deswirl pinch and vane geometries. The Build 2 diffusion system showed performance reductions in total and static pressure rise, flow range, and efficiencies. These results were primarily attributed to the changes made to the Build 2 diffuser. The end wall divergence resulted in end wall separation that caused increased losses. The changes to the diffuser vane resulted in increased throat blockage and lower pressure rise and mass flow rate. In addition to the experimental portion of this study, a computational study was conducted to study the design changes made to the Build 2 diffusion system. A speedline at 100% corrected rotational speed was solved, and the results were compared to experimental data. The simulated data matched the overall stage and diffusion system performance relatively well, but the internal flow fields of the diffusion components, namely the diffuser, were not well predicted. This was attributed to 16 using the SST turbulence model over BSL EARSM. The BSL EARSM model more accurately predicted the diffuser flow field to the SST model. </p>
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Microstructural Effects on the Effective Piezoelectric Responses of Additively Manufactured Triply Periodic Co-Continuous PiezocompositesYang, Wenhua 10 August 2018 (has links)
Triply Periodic Co-continuous piezocomposites, which consist of a ferroelectric-ceramic phase and an elastic-polymer phase continuously interconnected in three dimensions (3D), are emerging flexible piezoelectric materials with high efficiency in absorbing and converting multi-directional mechanical stimuli into electrical signals. Current co-continuous piezocomposites cannot be achieved with controlled piezoelectric properties due to the limited capability of traditional fabrication methods in carefully controlling the morphology of each phase, additive manufacturing such as Suspension-Enclosing Projection-Stereolithography process thus was selected. Porous ceramic skeleton with randomly distributed grain size is commonly observed in sintered ceramic skeleton fabricated by additive manufacturing. The effective piezoelectric properties of the piezocomposites were thus studied utilizing a two-scale method. Through analyzing the simulated results of different process parameters, optimal parameters of 3D printing processes including post-processes was subsequently suggested.
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Additively manufactured lenses for modulating guided waves in laminated compositesRighi, Hajar 09 December 2022 (has links) (PDF)
Composite materials have increasingly been used as an alternative to metals and other isotropic materials for primary structural components in aerospace industries. Unlike traditional isotropic materials, composite materials are known to have complex internal microstructures. Therefore, it is essential to develop methods for the inspection, evaluation, and monitoring of composite materials. Ultrasonic-guided waves and, more precisely, Lamb waves have proven to be an efficient and accurate technique for the non-destructive testing. Since guided waves are dispersive and multimodal, it is important to develop a practical method to manipulate Lamb waves to achieve better structural health monitoring and non-destructive inspection results. There are minimal studies involving manipulating guided waves for the inspection of composite materials. Moreover, the currently proposed methods to manipulate Lamb waves are complex and costly.
The objective of this dissertation research is to offer practical and straightforward methods with a simple design to control Lamb waves using additively manufactured lenses used as superstrates on composite plates. This dissertation is organized in three major parts. Part I focuses on the Lamb wave propagation in composite plates with different lay-up and plate orientations. Finite element simulations were performed to investigate the behavior of Lamb wave propagation in different plates. A semi-finite element approach was used to derive the dispersive curves in each plate.
In Part II, a lap-joint study was conducted to investigate the interaction of Lamb waves in the lap joint regions. Two different lap joints were considered, composite-aluminum and composite-plastic. In each lap joint the thickness of the top surface (aluminum or plastic) is continuously increased.
In Part III, additively manufactured lenses are designed to modulate the wavefront of Lamb waves in thick composite plates. The first design is a prism-shaped lens proposed to steer Lamb waves to a targeted direction. Multiple prism designs are considered to offer a flexible steering direction by either changing the prism thickness or the wedge angle. The second design is a plano-concave shaped lens designed to focus the Lamb wave at a targeted focal point.
This dissertation research will provide a clear understanding of Lamb wave propagation in anisotropic material, anisotropic-isotropic lap joints, and wavefront modulation on anisotropic material using additively manufactured lenses. This approach contributes to the development of better quality SHM for online monitoring systems.
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A data-driven approach for the investigation of microstructural effects on the effective piezoelectric responses of additively manufactured triply periodic bi-continuous piezocompositeYang, Wenhua 10 December 2021 (has links) (PDF)
A two-scale model consisting of ceramic grain scale and composite scale are developed to systematically evaluate the effects of microstructures (e.g., residual pores, grain size, texture) and geometry on the piezoelectric responses of the polarized triply periodic bi-continuous (TPC) piezocomposites. These TPC piezocomposites were fabricated by a recently developed additive manufacturing (AM) process named suspension-enclosing projection-stereolithography (SEPS) under different process conditions. In the model, the Fourier spectral iterative perturbation method (FSIPM) and the finite element method will be adopted for the calculation at the grain and composite scale, respectively. On the grain scale, a DL approach based on stacked generative adversarial network (StackGAN-v2) is proposed to reconstruct microstructures. The presented modeling approach can reconstruct high-fidelity microstructures of additively manufactured piezoceramics with different resolutions, which are statistically equivalent to original microstructures either experimentally observed or numerically predicted. Design maps for hydrostatic piezoelectric charging coefficients dh show they can achieve optimal performance at wide ranges of micro-porosity and geometry parameter u for the proposed TPC piezocomposites. In addition, geometry parameter u plays a dominant role in determining the intensity of hydrostatic voltage coefficient gh and hydrostatic figure of merit (HFOM) of all the presented TPC piezocomposites in the vicinity of the starting point of three-dimension (3D) interconnectivity. Within this range, these properties would increase first with the increasing of micro-porosity volume fraction (VF) and start to decrease once they reach peak values. The presented TPC piezocomposites exhibit a superb hydrostatic properties, with the same 20% VF of ceramics and 2% VF of micro-porosity with respect to composites and ceramics, respectively, TPC of face center cubic (FCC) demonstrates 327-fold enhancement of HFOM than that of the piezocomposite with three intersecting ceramic cuboids. The piezoelectric properties of FCC are superior to those of body center cubic (BCC) and simple cubic (SC). The calculated piezoelectric charging constants d33 and relative permittivity κ33 were then compared with the data measured from the products fabricated by the SEPS under different process conditions. The calculation results at both grain scale and composite scale were found to agree well with experimental results.
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