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['Dickens, Phill', 'Reeves, Phill', 'Hague, Richard']

2021-10-05T15:29:56Z

2021-10-05T15:29:56Z

2012

Mechanical Engineering

['https://hdl.handle.net/2152/88391', 'http://dx.doi.org/10.26153/tsw/15330']

eng

2012 International Solid Freeform Fabrication Symposium

Open

['Additive Manufacturing', 'Additive Manufacturing education', 'UK', 'Institution of Mechanical Engineers']

Additive Manufacturing Education in the UK

Conference paper

https://repositories.lib.utexas.edu//bitstreams/8e6899cc-83af-46f7-8dfb-127718e382fb/download

University of Texas at Austin

There has been and continues to be a considerable effort regarding education for Additive Manufacturing (AM) in the UK. This generally started in 1992 with a seminar organised by the Institution of Mechanical Engineers and an industrial exhibition stand at Mach 92. However, before the education activities are discussed it is useful to show the AM research landscape in the UK as this will give an indication of the level of activity It should be noted that there will also be a considerable number of organisations involved in using AM but not involved in research.

['Dey, N.K.', 'Liou, F.W.', 'Nedic, C.']

2021-10-12T17:55:55Z

2021-10-12T17:55:55Z

2013

Mechanical Engineering

['https://hdl.handle.net/2152/88707', 'http://dx.doi.org/10.26153/tsw/15641']

eng

2013 International Solid Freeform Fabrication Symposium

Open

['additive manufacturing', 'laser deposition', 'titanium', 'Ti-6Al-4V', 'aerospace repair']

Additive Manufacturing Laser Deposition of Ti-6Al-4V for Aerospace Repair Applications

Conference paper

https://repositories.lib.utexas.edu//bitstreams/895a2fc0-e880-4da6-aa51-6a01b0fbbcc8/download

University of Texas at Austin

Parts or products from high performance metal are very expensive, partly due to the processing complexities during manufacturing. The purpose of this project is to use additive laser deposition and machining processes to repair titanium parts, thus extending the service life of these parts. The study broadly included preparing the defects, laser deposition, machining, sample preparation and mechanical tests. Comparative study of mechanical properties (UTS, YS, percentage elongation) of the repaired samples to the ideal conditions was undertaken. The research throws up interesting facts where the data from the test sample shows enhancement of properties of the repaired part.

['Knapp, C.M.', 'Lienert, T.J.', 'Chen, C.', 'Kovar, D.']

2021-10-12T22:25:13Z

2021-10-12T22:25:13Z

2014

Mechanical Engineering

['https://hdl.handle.net/2152/88755', 'http://dx.doi.org/10.26153/tsw/15689']

eng

2014 International Solid Freeform Fabrication Symposium

Open

['direct metal deposition', 'Laser Engineered Net Shaping', 'AISI 1018 steel', 'heat-affected zone', 'steel substrates', 'microstructure', 'additive manufacturing']

Additive Manufacturing of 1018 Steel: Process Observations and Calculations

Conference paper

https://repositories.lib.utexas.edu//bitstreams/f8df7da2-641d-451e-a0e5-f5c758037e0a/download

University of Texas at Austin

The temperature distribution in the vicinity of the laser used in direct metal deposition (DMD) plays a critical role in determining the final microstructure and mechanical properties of the deposit and the heat-affected zone (HAZ) within the substrate. Samples were prepared using Laser Engineered Net Shaping (LENSTM) by depositing AISI 1018 steel powder onto AISI 1018 steel substrates in multiple, overwritten passes. The laser power and speed were varied to control the heat input and the rate of cooling. The process characteristics were then quantified and compared across the samples to determine the effect of input parameters on the resulting deposit microstructures.

['Tsui, Lok-kun', 'Maines, Erin', 'Evans, Lindsey', 'Keicher, David', 'Lavin, Judith']

2021-11-10T21:14:14Z

2021-11-10T21:14:14Z

2018

Mechanical Engineering

['https://hdl.handle.net/2152/90177', 'http://dx.doi.org/10.26153/tsw/17098']

eng

2018 International Solid Freeform Fabrication Symposium

Open

['UV curable resin', 'alumina pastes', 'in-situ', 'material extrusion', 'printing', 'additive manufacturing']

Additive Manufacturing of Alumina Components by Extrusion of In-Situ UV-Cured Pastes

Conference paper

https://repositories.lib.utexas.edu//bitstreams/eeb89f9c-c6b5-47e3-b23f-f3d91a6f49ba/download

University of Texas at Austin

Additive manufacturing of ceramic materials is an attractive technique for rapid prototyping of components at small scales and low cost. We have investigated the printing of alumina pastes loaded at 70-81.5 wt% solids in a UV curable resin. These can be deposited by extrusion from a syringe head on a Hyrel System 30M printer. The print head is equipped with an array of UV LEDs, which solidify the paste without the need for any applied heating. Parameters optimized include print speed, layer height, applied force, and deposition rate. Using A15 alumina and submicron A16 powder precursors, we can achieve bulk densities of 91% and 96% of theoretical density respectively. The influence of dispersants and surfactants added to the powder on the rheology of the pastes, the print process parameters, and the quality of the final components are also investigated.

['Girdis, Jordan', 'McCaffrey, Matthew', 'Proust, Gwénaëlle']

2021-10-27T22:48:47Z

2021-10-27T22:48:47Z

2016

Mechanical Engineering

https://hdl.handle.net/2152/89638

eng

2016 International Solid Freeform Fabrication Symposium

Open

['fused deposition modeling', 'short carbon fibers', 'graphene', 'polymer composites']

Additive Manufacturing of Carbon Fiber and Graphene – Polymer Composites using the technique of Fused Deposition Modelling

Conference paper

https://repositories.lib.utexas.edu//bitstreams/be914ffc-d48c-4bd0-ab34-064a97b61cbd/download

University of Texas at Austin

Adding micro or nano-carbon reinforcements to polymers enhances their mechanical and electrical properties. In this paper, the effects of the addition of short carbon fibres (SCF) and graphene into acrylonitrile butadiene styrene (ABS) and polylactic acid (PLA) polymer to create composite filaments for fused deposition modelling (FDM) are investigated. After creating carbon polymer composite filaments, using a commercial 3D printer, samples were printed and tested for mechanical and electrical properties. The measured values for these composites were compared to those obtained for pure ABS and pure PLA. It was found that by using only 2% SCF it was possible to achieve a 22% increase in tensile strength with no significant impact on printability. With addition of graphene, PLA was made to be conductive. These results show the feasibility of developing new materials for 3D printing that will create structurally sound and conductive designs.

['Zhang, Xinchang', 'Pan, Tan', 'Chen, Yitao', 'Liou, Frank']

2021-12-06T22:48:08Z

2021-12-06T22:48:08Z

2021

Mechanical Engineering

['https://hdl.handle.net/2152/90704', 'http://dx.doi.org/10.26153/tsw/17623']

eng

2021 International Solid Freeform Fabrication Symposium

Open

['additive manufacturing', 'functionally graded materials', 'Cu', 'stainless steel', 'dissimilar materials']

Additive Manufacturing of Cu on 316L Stainless Steel via Inconel 718 Intermediate Layers

Conference paper

https://repositories.lib.utexas.edu//bitstreams/ed6892db-8d24-45b3-92bd-083a4bef3302/download

University of Texas at Austin

Joining of dissimilar materials is becoming increasingly prevalent to combine differing material properties to enhance product design flexibility and performance. In this study, pure copper was built on 316L stainless steel (SS316L) by laser-based additive manufacturing technology in which copper was deposited layer-by-layer on SS316L with Inconel 718 intermediate layers. The goal is to fabricate multi-metallic structures with improved thermal conductivity. The direct joining of Cu on SS316L would result in porosities at the interface and the consequent poor mechanical properties, which could be addressed by Inconel 718 intermediate layers. The microstructure, chemical composition, tensile properties, and micro-hardness were characterized in the dissimilar materials using scanning electron microscopy, energy dispersive spectroscopy, tensile test with digital image correlation technique, and hardness tester. Results confirm excellent bonding when Inconel 718 intermediate layers are introduced.

['Kulkarni, P.M.', 'Karunakaran, K.P.', 'Tewari, Asim', 'Legesse, Fisseha', 'Rana, Dhirendra', 'Bernard, Alain']

2021-10-18T20:21:34Z

2021-10-18T20:21:34Z

2014

Mechanical Engineering

https://hdl.handle.net/2152/89231

eng

2014 International Solid Freeform Fabrication Symposium

Open

['directional heat condctuve', 'Additive Manufacturing', 'Hybrid Layered Manufacturing']

Additive Manufacturing of Directionally Heat Conductive Objects

Conference paper

https://repositories.lib.utexas.edu//bitstreams/4e433d7a-bce0-4854-b80f-12c723d9bedd/download

University of Texas at Austin

Purpose: Directionally Heat Conductive (DHC) objects are also known as thermal cables. DHC objects used in cooling solid state devices as large heat sinks. This paper presents Additive manufacturing (AM) as a new method for realization of DHC objects. AM can produce DHC objects accurately, rapidly and economically. Design/Methodology/Approach: It is very hard to realize DHC objects through conventional manufacturing. The authors describe the realization of metallic DHC objects using their AM process called Hybrid Layered Manufacturing (HLM). HLM, which uses GMAW deposition, can, in principle, produce DHC out of any metal for which welding wire is available. . Differential conductivity in HLM is achieved by appropriately distributing the air gaps among the beads. The air gap distribution depends on the layer thickness and step over increment. Findings: The authors have demonstrated the ability of HLM to produce DHC objects for Al alloy 4043. The thermal conductivity achieved on two orthogonal directions was 100.496 and 129.740 W m-1 K-1 as against 163 W m-1 K-1 for solid metal. These are significant variations. Research Limitations/Implications: HLM realize near net shape of DHC objects, further post processing namely machining is required. Originality Value: AM Specifically HLM for realization of DHC objects

['Chiroli, M.', 'Ciszek, F.', 'Baschung, B.']

2021-11-10T21:28:55Z

2021-11-10T21:28:55Z

2018

Mechanical Engineering

['https://hdl.handle.net/2152/90181', 'http://dx.doi.org/10.26153/tsw/17102']

eng

2018 International Solid Freeform Fabrication Symposium

Open

['energetic materials', '3D printing', 'additive manufacturing', 'defense industry']

Additive Manufacturing of Energetic Materials

Conference paper

https://repositories.lib.utexas.edu//bitstreams/4ca2a243-91de-479e-829f-193d798a5294/download

University of Texas at Austin

Over the last decade, additive manufacturing gained a lot of interest within the defense industry. However, printing energetic materials such as explosives or solid propellants remains a challenge. A research work with the aim to suggest appropriate materials and associated 3D printing techniques to produce energetic materials, is currently carried out. In interior ballistics, improved weapon performance ends in reaching higher muzzle kinetic energy. This can be achieved by adjusting the gas pressure released during the ballistic cycle by using specific propellant grains. A former study (Baschung, MRS Symposium H, Boston, 2005) highlighted the advantages of using co-layered propellant grains to achieve this goal. The difficulties in producing such kind of propellants can now be bypassed thanks to 3D printers. Our approach consists in deposing a viscous energetic paste, containing a solvent, with an adapted machine. The layer formation and the adhesion between them are investigated in this work.

['Pegues, Jonathan', 'Roach, Michael', 'Shamsaei, Nima']

2021-11-18T00:29:49Z

2021-11-18T00:29:49Z

2019

Mechanical Engineering

['https://hdl.handle.net/2152/90371', 'http://dx.doi.org/10.26153/tsw/17292']

eng

2019 International Solid Freeform Fabrication Symposium

Open

['laser powder bed fusion', 'crack nucleation', 'twin boundary', 'heat treatment']

Additive Manufacturing of Fatigue Resistant Materials: Avoiding the Early Life Crack Initiation Mechanisms During Fabrication

Conference paper

https://repositories.lib.utexas.edu//bitstreams/6601581c-bb73-4eb9-9ccf-c6ab4924a19b/download

University of Texas at Austin

The full potential of additive manufacturing (AM) has been limited by the process induced defects within the fabricated materials. Defects such as lack of fusions and gas entrapped pores act as stress concentrators and result in premature fatigue crack initiation, severely limiting the applicability of AM in fatigue-critical applications. However, by understanding the failure mechanisms associated with AM materials and leveraging the intimate localized thermal input (i.e. process conditions), the failure mechanisms for some materials may be avoided during the fabrication process. This study investigates the crack initiation behavior of an AM austenitic stainless steels subjected to fatigue testing. The microstructural features responsible for fatigue crack initiation are captured at the surface by ex-situ electron backscatter diffraction. Results show that the higher cooling rates during AM offer the opportunity to fabricate fatigue resistant austenitic stainless steel parts by avoiding the microstructural features that are most detrimental to fatigue performance.

['Kishore, Vidya', 'Chen, Xun', 'Ajinjeru, Christine', 'Hassen, Ahmed Arabi', 'Lindahl, John', 'Failla, Jordan', 'Kunc, Vlastimil', 'Duty, Chad']

2021-10-27T23:24:26Z

2021-10-27T23:24:26Z

2016

Mechanical Engineering

https://hdl.handle.net/2152/89642

eng

2016 International Solid Freeform Fabrication Symposium

Open

['semi-crystalline thermoplastics', 'PPS', 'PEKK', 'additive manufacturing']

Additive Manufacturing of High Performance Semicrystalline Thermoplastics and Their Composites

Conference paper

https://repositories.lib.utexas.edu//bitstreams/053177a7-2704-437e-b926-a1e66dd7731b/download

University of Texas at Austin

This work investigates the use of two semi-crystalline high performance thermoplastics, polyphenylene sulfide (PPS) and poly (ether ketone ketone) (PEKK), as feedstock for fused filament fabrication process. Composites of PPS and PEKK are emerging as viable candidates for several components in aerospace and tooling industries and additive manufacturing of these materials can be extremely beneficial to lower manufacturing costs and lead times. However, these materials pose several challenges for extrusion and deposition due to some of their inherent properties as well as thermal and oxidative responses. To better understand the properties of such systems specific to 3D printing and determine the critical parameters that make them “printable”, various rheological and thermal properties have been studied for neat as well as short fiber reinforced PPS and PEKK systems. Attempts were also made to print these materials in a customized high temperature fused filament fabrication system.

['Wasley, T.', 'Li, J.', 'Ta, D.', 'Shephard, J.', 'Stringer, J.', 'Smith, P.', 'Esenturk, E.', 'Connaughton, C.', 'Kay, R.']

2021-10-28T22:24:18Z

2021-10-28T22:24:18Z

2016

Mechanical Engineering

https://hdl.handle.net/2152/89718

eng

2016 International Solid Freeform Fabrication Symposium

Open

['additive manufacturing', 'process integration', 'multilayer embedded electronics', 'DLP stereolithography', 'material dispensing', 'flip chip packaging']

Additive Manufacturing of High Resolution Embedded Electronic Systems

Conference paper

https://repositories.lib.utexas.edu//bitstreams/3f61a9f4-3b44-4556-a47c-163d5ac2a159/download

University of Texas at Austin

Additive Manufacturing (AM) processes can facilitate the rapid iterative product development of electronic devices by optimising their design and functionality. This has been achieved by combining two additive manufacturing processes with conventional surface mount assembly to generate high resolution embedded multilayer electronic circuits contained within a 3D printed polymer part. Bottom-up DLP Stereolithography and material dispensing of isotropic conductive adhesives have been interleaved to deposit microscale features on photopolymer substrates. The material dispensing process has demonstrated the high density deposition of conductors attaining track widths of 134µm and produced interconnects suitable for directly attaching bare silicon die straight to the substrate. Interconnects down to a diameter of 149µm at a pitch of 457µm have been realized. In addition, this research developed a novel method for producing high aspect ratio z-axis connections. These were simultaneously printed with the circuit and component interconnects by depositing through-layer pillars with a maximum aspect ratio of 3.81. Finally, a method to accurately embed the packaged circuit layer within the printed part has been employed using bottom-up stereolithography.

['Cui, Wenyuan', 'Zhang, Xinchang', 'Liou, Frank']

2021-11-02T19:27:08Z

2021-11-02T19:27:08Z

2017

Mechanical Engineering

https://hdl.handle.net/2152/89874

eng

2017 International Solid Freeform Fabrication Symposium

Open

['additive manufacturing', 'high-entropy alloys', 'microstructures', 'mechanical properties']

Additive Manufacturing of High-Entropy Alloys - A Review

Conference paper

https://repositories.lib.utexas.edu//bitstreams/d710c88e-1341-4b52-8821-a0591387b3db/download

University of Texas at Austin

High-entropy alloys have attracted increasingly interest due to their unique compositions, microstructures and mechanical properties. Additive manufacturing has been recognized as a promising technology to fabricate the high-entropy alloys in the recent years. The purpose of this paper is to review the current research progress in high-entropy alloys by additive manufacturing process. It will first highlight the important theory of the high-entropy alloys. The next aspect is to summarize current additive manufacturing methods applied for the high entropy alloys. At last, the correlation between the microstructures and the mechanical properties of the high-entropy alloys will be examined and discussed.

Basak, Amrita

2021-11-18T00:34:01Z

2021-11-18T00:34:01Z

2019

Mechanical Engineering

['https://hdl.handle.net/2152/90372', 'http://dx.doi.org/10.26153/tsw/17293']

eng

2019 International Solid Freeform Fabrication Symposium

Open

["high-ℽ' nickel-based superalloys", 'additive manufacturing', 'selective laser melting', 'SLM', 'processing', 'microstructure', 'mechanical properties']

Additive Manufacturing of High-Gamma Prime Nickel-Based Superalloys through Selective Laser Melting (SLM)

Conference paper

https://repositories.lib.utexas.edu//bitstreams/766c204a-2eeb-4098-a48a-f8b33cbb492d/download

University of Texas at Austin

High-ℽ' nickel-based superalloys are abundantly used in the aerospace, marine, nuclear, and chemical industries where excellent corrosion and oxidation resistance, superior mechanical properties, and exceptional high-temperature performance are required. However, selective laser melting (SLM)-based additive manufacturing (AM) of high-ℽ' nickel-based superalloys pose significant challenges due to these alloys’ complex chemistry. With multiple alloying elements and high aluminum + titanium fraction, these materials when consolidated through SLM form various secondary phases severely affecting the processability leading to the formation of cracks. The objective of this review is to summarize the progress made so far on SLM of high-ℽ' nickel-based superalloys with a special emphasis towards elucidating the relationships between processing, microstructures, and properties in this alloy system.

['Platt, S.', 'Schnell, N.', 'Witt, G.', 'Kleszczynski, S.']

2024-03-27T03:31:38Z

2024-03-27T03:31:38Z

2023

Mechanical Engineering

['https://hdl.handle.net/2152/124467', 'https://doi.org/10.26153/tsw/51075']

en_US

2023 International Solid Freeform Fabrication Symposium

Open

['laser powder bed fusion', 'additive manufacturing', 'metal', 'sandwich sheets']

Additive manufacturing of hybrid sandwich sheets by laser powder bed fusion of metals

Conference paper

https://repositories.lib.utexas.edu//bitstreams/1eb07f93-e335-482c-a1bc-271f45ea5d9f/download

University of Texas at Austin

In the context of lightweight applications, laser powder bed fusion of metals allows the creation of high-complexity structures at minimal use of material. Traditional elements of lightweight construction are sandwich sheets, which comprise two cover sheets with a fine core structure joined in the centre. Thus, these lightweight elements contain both geometrically simple (cover sheets) and geometrically complex (core structure) elements. Conventional manufacturing of core structures is limited in terms of geometrical freedom. On the other hand, Additive Manufacturing of sheets has disadvantages in terms of economic efficiency. Therefore, a combined process consisting of additive and conventional cost-efficient manufacturing is proposed to eliminate both disadvantages. This publication presents a hybrid manufacturing route to produce metal sandwich sheets. The hybrid sandwich sheets are manufactured using a rolled cover sheet as a base plate and additive manufactured core structures including an upper cover sheet. For this purpose, a recently developed sheet mounting system for implementation in a laser powder bed fusion process is presented and evaluated concerning manufacturing criteria such as process stability and dimensional accuracy of the final components.

['Ho, Jason', 'Lough, Cody S.', 'Mulligan, Phillip', 'Kinzel, Edward C.', 'Johnson, Catherine E.']

2021-11-09T18:54:44Z

2021-11-09T18:54:44Z

2018

Mechanical Engineering

['https://hdl.handle.net/2152/90117', 'http://dx.doi.org/10.26153/tsw/17038']

eng

2018 International Solid Freeform Fabrication Symposium

Open

['shaped charge', 'liners', 'geometries', 'SS 304L', 'selective laser melting', 'additive manufacturing']

Additive Manufacturing of Liners for Shaped Charges

Conference paper

https://repositories.lib.utexas.edu//bitstreams/3a797230-2ced-40d8-909d-8c8ea4428ccc/download

University of Texas at Austin

A Shaped Charge (SC) is an explosive device used to focus a detonation in a desired direction, and has applications in demolition and oil extraction. The focusing relies on a void in the explosive mass, shaped by a metal liner that becomes a projectile during detonation. Additive Manufacturing (AM) allows greater design freedom and geometric complexity for the liner portion of the SC. Specifically, hierarchical structuring and functional grading can potentially provide greater velocity, directionality, and efficiency. In this work, Selective Laser Melting (SLM) is used to explore different geometries for an SC liner made out of SS 304L. These are detonated using the explosive Composition C-4 to evaluate performance metrics, depth and standoff, and are observed using high-speed imaging. The work shows the potential for advanced shaped charges produced using SLM.

['Grothaus, Bradley', 'Huck, Dane', 'Sutton, Austin']

2021-11-09T19:04:37Z

2021-11-09T19:04:37Z

2018

Mechanical Engineering

['https://hdl.handle.net/2152/90126', 'http://dx.doi.org/10.26153/tsw/17047']

eng

2018 International Solid Freeform Fabrication Symposium

Open

['bandpass filters', '304L', 'stainless steel', 'overhangs', 'radar receivers', 'selective laser melting', 'additive manufacturing']

Additive Manufacturing of Metal Bandpass Filters for Future Radar Receivers

Conference paper

https://repositories.lib.utexas.edu//bitstreams/974faf79-8274-404f-a250-e3e6d394639a/download

University of Texas at Austin

Selective laser melting (SLM) is a powder-bed fusion (PBF) process that bonds successive layers of powder with a laser to create components directly from computer-aided design (CAD) files. The additive nature of the SLM process in addition to the use of fine powders facilitates the construction of complex geometries, which has captured the attention of those involved in the design of bandpass filters for radar applications. However, a significant drawback of SLM is its difficulty in fabricating parts with overhangs necessitating the use of support structures, which, if not removed, can greatly impact the performance of bandpass filters. Therefore, in this study bandpass filters are manufactured in two stages with 304L stainless steel where each builds only a portion of the part to improve the reliability in manufacturing the overhangs present. The results show that the versatility of SLM can produce difficult-to-manufacture bandpass filters with high dimensional accuracy.

This work was funded by Honeywell Federal Manufacturing & Technologies under Contract No. DE-NA0002839 with the U.S. Department of Energy.

['Chen, Yitao', 'Liou, Frank']

2021-11-10T22:52:02Z

2021-11-10T22:52:02Z

2018

Mechanical Engineering

['https://hdl.handle.net/2152/90199', 'http://dx.doi.org/10.26153/tsw/17120']

eng

2018 International Solid Freeform Fabrication Symposium

Open

['additive manufacturing', 'functionally graded materials', 'mechanical properties', 'laser metal deposition', 'selective laser melting']

Additive Manufacturing of Metal Functionally Graded Materials: A Review

Conference paper

https://repositories.lib.utexas.edu//bitstreams/67e039e0-cf31-4dfe-9a1a-ad579c68cae9/download

University of Texas at Austin

Functionally graded materials (FGMs) have attracted a lot of research interest due to their gradual variation in material properties that result from the non-homogeneous composition or structure. Metal FGMs have been widely researched in recent years, and additive manufacturing has become one of the most important approaches to fabricate metal FGMs. The aim of this paper is to review the research progress in metal FGMs by additive manufacturing. It will first introduce the unique properties and the advantages of FGMs. Then, typical recent findings in research and development of two major types of metal additive manufacturing methods, namely laser metal deposition (LMD) and selective laser melting (SLM), for manufacturing different types of metal FGMs will be discussed. Finally, the major technical concerns in additive manufacturing of metal FGMs which are closely related to mechanical properties, and industrial applications of metal FGMs will be covered.

['Yang, Seongun', 'Xu, Donghua', 'Yan, Dongqing', 'Albert, Marc', 'Pasebani, Somayeh']

2024-03-26T23:04:04Z

2024-03-26T23:04:04Z

2023

Mechanical Engineering

['https://hdl.handle.net/2152/124440', 'https://doi.org/10.26153/tsw/51048']

en_US

2023 International Solid Freeform Fabrication Symposium

Open

['laser directed energy deposition', 'oxide dispersion strengthened alloy', '316L stainless steel']

Additive Manufacturing of ODS Steels Using Powder Feedstock Atomized with Elemental Yttrium

Conference paper

https://repositories.lib.utexas.edu//bitstreams/fa619bf3-45b6-446d-9705-74a37404ca1b/download

University of Texas at Austin

This study investigates the microstructure and mechanical properties of an austenitic ODS steel produced by the Laser Directed Energy Deposition (LDED) process using powder feedstock atomized with elemental yttrium. The Microstructure of the samples was characterized by electron microscopy, and mechanical properties were measured using a tensile test and nanoindentation. Further, the thermal stability of the LDEDproduced ODS steels were evaluated. As-printed samples showed a cellular structure with Si-Mn-Y-Oenriched nanoparticles that were found to be amorphous. After 100 hours at 1000°C in an argon atmosphere, a partially recrystallized microstructure with a decrease in the number density of Y-O-enriched nanoparticles with crystalline structure was revealed. The as-printed (600 W, 600 mm/min) samples exhibited an ultimate tensile strength of 774 MPa and an elongation at a break of 22%. A lower ultimate tensile strength of 592 MPa and higher elongation of 42% was measured after 100 hours at 1000°C.

['Yuan, Mengqi', 'Bourell, David']

2021-10-18T20:17:38Z

2021-10-18T20:17:38Z

2014

Mechanical Engineering

https://hdl.handle.net/2152/89230

eng

2014 International Solid Freeform Fabrication Symposium

Open

['additive manufacturing', 'laser sintered polyamide 12', 'lithophane', 'optical properties']

Additive Manufacturing of Optically Translucent Parts

Conference paper

https://repositories.lib.utexas.edu//bitstreams/333d3f68-3030-401f-9473-f81556b9ad06/download

University of Texas at Austin

A lithophane is a translucent image created by varying the plate thickness; the image is observed using a back lit light source. Additive manufacturing makes highly complex lithophane fabrication possible. Optical properties of laser sintered polyamide (PA) 12 translucent additive manufactured parts were analyzed and applied to the lithophane fabrication. Several parameters affecting lithophane manufacturing performance are discussed including brightness and contrast versus plate thickness and grayscale level, surface finish quality and manufacturing orientation. Moreover, other thermoplastic semi-crystalline materials were analyzed for LS optically translucent part production. Plates and lithophanes were built using a different AM platform: stereolithography (SL) with Somos® ProtoGen™ O- XT 18420 white resin. Different optical properties and lithophane performance were observed and compared with PA 12 parts. It was found laser sintered polyamide 12 optical properties varied with light wavelength and reached maximum transmission under green light. When building in the XY plane, thin layer thickness and large maximum plate thickness led to higher contrast and gray scale level. Lithophane quality was largely improved when fabricated in the ZX/ZY plane orientation. Lithophanes made from SL were analyzed but showed lower contrast due to the optical property characteristics of the white resin.

['Claybrook, F.R.', 'Southee, D.J.', 'Mohammed, M.I.']

2024-03-27T03:33:53Z

2024-03-27T03:33:53Z

2023

Mechanical Engineering

['https://hdl.handle.net/2152/124468', 'https://doi.org/10.26153/tsw/51076']

en_US

2023 International Solid Freeform Fabrication Symposium

Open

['additive manufacturing', 'diabetic foot insoles', 'diabetes']

ADDITIVE MANUFACTURING OF PERSON SPECIFIC DIABETIC FOOT INSOLES WITH ADJUSTABLE CUSHIONING PROPERTIES USING TPMS LATTICE STRUCTURES

Conference paper

https://repositories.lib.utexas.edu//bitstreams/ceed04fa-3dda-4d6c-883a-9fba1cfa5639/download

University of Texas at Austin

Complications associated with diabetes are numerous, including foot problems which in extreme cases can lead to amputations. Current management involves the use of foam diabetic foot insoles (DFI) to provide cushioning, however load bearing capacity is limited, and designs often do not provide a comfortable or efficacious fit. This study aspires to resolve problems using digital fabrication workflows. The exploration of potential 3D scanning of anatomical data, parametric modelling, and additive manufacturing was created for a patient specific DFI. This demonstrated that patient scanning data provides means to create a custom fitting insole template, improving overall fit. Demonstrating the use of triply periodic minimal surface (TPMS) structures, fabricated in Thermoplastic Polyurethane (TPU), as cushioning structures, whereby unique lattice designs allow regionally tailored mechanical loading properties of the insole concept. The final insole realises a superior alternative to tradition DFI.

['Radyjowski, P.P.', 'Bourell, D.L.', 'Kovar, D.', 'Ellzey, J.L.']

2021-12-01T21:46:51Z

2021-12-01T21:46:51Z

2021

Mechanical Engineering

['https://hdl.handle.net/2152/90625', 'http://dx.doi.org/10.26153/tsw/17544']

eng

2021 International Solid Freeform Fabrication Symposium

Open

['cermets', 'Si-SiC', 'combustion', 'combustor', 'additive manufacturing']

Additive Manufacturing of Si-SiC Cermets for Combustion Device Applications

Conference paper

https://repositories.lib.utexas.edu//bitstreams/35d6eee5-c128-48f9-bf85-9cd163494716/download

University of Texas at Austin

Traditional manufacturing methods for high-temperature devices are time intensive and limited to simple shapes. Additive manufacturing (AM) reduces lead times and opens the design space to more complex geometries. Indirect laser sintering of siliconized silicon carbide (Si-SiC) cermets was evaluated for creating devices compatible with combustion environments. Heat recirculating combustors especially benefit from geometric flexibility. Si-SiC process improvements are presented for the production of cermet combustors. The effect of flame on the material was studied by directly exposing samples to hot combustion products at 1000°C and 1260°C for 10 hours. Subsequently, three experimental Si-SiC combustors were manufactured and fired to evaluate the practical aspects of cermet applications. Each device was operated for 70 hours under excess-air methane flames with solid temperatures up to 1405°C. The surface oxidation and phase changes were assessed. Operating temperatures between 1200°C and 1350°C reduce damage to the material and give a promise of long-term, high-temperature operation.

['Saari, M.', 'Galla, M.', 'Cox, B.', 'Krueger, P.', 'Cohen, A.', 'Richer, E.']

2021-10-21T15:17:08Z

2021-10-21T15:17:08Z

2015

Mechanical Engineering

https://hdl.handle.net/2152/89392

eng

2015 International Solid Freeform Fabrication Symposium

Open

['thermoplastic elastomers', '3D printing', 'soft parts', 'composite parts', 'feed extrusion']

Additive Manufacturing of Soft and Composite Parts from Thermoplastic Elastomers

Conference paper

https://repositories.lib.utexas.edu//bitstreams/139a155e-64ae-420f-98bd-107c67b4dcf1/download

University of Texas at Austin

Thermoplastic elastomers (TPEs) are low-durometer materials that can support large strains without breaking, making them attractive materials for producing 3-D printed soft components. However, prefabricated TPE filament, especially those with low hardness, cannot be used in typical filament feed extrusion mechanisms that are popular in material extrusion-based 3-D printers today. Therefore, we have developed a mini-screw extruder, small enough to be incorporated on a typical 3-D printer system, and capable of extruding various TPE formulations directly from commercially available pellets. This paper presents the design and thermal analysis of the mini-extruder, experimental testing of the 3-D printing process for TPEs with nominal hardness in the range of 5 – 52 Shore A, and compression and tension tests of the properties of printed parts. By combining 3-D printing of soft TPEs with rigid thermoplastics, the new system also opens up new possibilities in additive manufacturing of soft and hard composite parts.

['Clymer, Daniel', 'Beuth, Jack', 'Cagan, Jonathan']

2021-11-01T20:48:43Z

2021-11-01T20:48:43Z

2016

Mechanical Engineering

https://hdl.handle.net/2152/89744

eng

2016 International Solid Freeform Fabrication Symposium

Open

['process design', 'process outcomes', 'metal-based additive manufacturing', 'additive manufacturing']

Additive Manufacturing Process Design

Conference paper

https://repositories.lib.utexas.edu//bitstreams/ac4c72e3-d199-483b-9062-8840e646a571/download

University of Texas at Austin

A current issue in metal-based additive manufacturing (AM) is achieving consistent, desired process outcomes in manufactured parts. When process outcomes such as strength, density, or precision need to meet certain specifications, these specifications can be met by changes in process variable selection. However, the changes required to achieve a better part performance may not be intuitive, particularly because process variable changes can simultaneously improve some outcomes while decreasing others. In this work, the tradeoffs between multiple process outcomes are formalized and the design problem is explored throughout the design space of process variables. User input for each process outcome is considered and the best combination of process variables is found to achieve a user’s desired outcome.

['Moylan, Shawn', 'Land, Joshua', 'Possolo, Antonio']

2021-10-21T19:50:55Z

2021-10-21T19:50:55Z

2015

Mechanical Engineering

https://hdl.handle.net/2152/89434

eng

2015 International Solid Freeform Fabrication Symposium

Open

['additive manufacturing', 'round robin studies', '3D printers', 'geometric performance']

Additive Manufacturing Round Robin Protocols: A Pilot Study

Conference paper

https://repositories.lib.utexas.edu//bitstreams/949b4f41-9aa1-4e15-acc5-35eb0babeeff/download

University of Texas at Austin

As the number of users of additive manufacturing (AM) steadily increases, and considering their demand for material and process specifications, the need for standard protocols for round robin studies is increasing accordingly. Researchers at the National Institute of Standards and Technology (NIST) have conducted and participated in several AM round robin studies with the aim not only to characterize the AM process, and material but also to improve the understanding of AM round robin studies themselves. One simple study, a pilot round robin study investigating geometric performance of NIST-owned consumer-grade 3D printers, provides excellent examples of typical results and lessons learned. While individual printers produced relatively consistent results, there was significant variability between the printers. This variability existed despite best efforts to ensure participants followed consistent procedures in building the test parts. Further, the variability made it apparent that collecting pedigree data from each build was required to draw any conclusions about potential causes of the variability.

['Porter, Daniel A.', 'Cohen, Adam L.', 'Krueger, Paul S.', 'Son, David']

2021-11-04T15:06:54Z

2021-11-04T15:06:54Z

2017

Mechanical Engineering

['https://hdl.handle.net/2152/89981', 'http://dx.doi.org/10.26153/tsw/16902']

eng

2017 International Solid Freeform Fabrication Symposium

Open

['stock ultraviolet curable silicone', 'stock UV curable silicone', '3D printing', 'extrude and cure additive manufacturing', 'ECAM']

Additive Manufacturing Utilizing Stock Ultraviolet Curable Silicone

Conference paper

https://repositories.lib.utexas.edu//bitstreams/277c930b-1308-4c06-8cb7-1ea667fa04de/download

University of Texas at Austin

Extrude and Cure Additive Manufacturing (ECAM) is a method that enables 3D printing (3DP) of common thermoset materials. Ultraviolet (UV)-curable silicone is an example of a thermoset material with a large number of industrial and medical applications. 3D printed silicone prototype parts are obtained using a custom high pressure ram, valve, and UV exposure system. This paper will address issues with printing stock UV curable silicone such as electrostatic repulsion, in-nozzle curing, and extrudate slumping. One solution that addresses two issues is adding carbon black (CB) to the mixture to reduce electrostatic repulsion while also inhibiting UV cure depth, hence preventing material from curing in the nozzle. Evidence shows that too much carbon black can be detrimental to the structural stiffness of the resulting part.

['Yigit, Ismail Enes', 'Isa, Mohammed', 'Lazoglu, Ismail']

2021-11-15T22:04:07Z

2021-11-15T22:04:07Z

2018

Mechanical Engineering

['https://hdl.handle.net/2152/90287', 'http://dx.doi.org/10.26153/tsw/17208']

eng

2018 International Solid Freeform Fabrication Symposium

Open

['support structures', 'modular', 'additive manufacturing', 'robotic']

Additive Manufacturing with Modular Support Structures

Conference paper

https://repositories.lib.utexas.edu//bitstreams/4274732c-1b94-4413-bdb6-3e516dabc4c3/download

University of Texas at Austin

Additive manufacturing is praised to have low material waste compared to conventional subtractive manufacturing methods. This is not always the case when the computer aided design (CAD) model consists of large overhangs. In such cases, fabrication of support structures are required to fill the space between the CAD model and the manufacturing bed. In post processing, these support structures must be removed from the model. These supports become waste and reduce the buy-to-fly ratio. In this paper, we present a pre-fabricated reusable modular support structure system which minimizes the fabrication of conventional support structures. The conventional supports are replaced with modular support blocks wherever possible. The blocks are stacked under the overhang with a robot arm until the overhang of the model is reached. Conventional supports can be fabricated on top when needed with fused filament fabrication. This strategy reduces fabrication of conventional supports. Thus, faster fabrication times are obtained with higher buy-to-fly ratios.

['Romero, L.', 'Guerrero, A.', 'Espinosa, M.M.', 'Jiménez, M.', 'Domínguez, I.A.', 'Domínguez, M.']

2021-10-12T20:37:49Z

2021-10-12T20:37:49Z

2014

Mechanical Engineering

['https://hdl.handle.net/2152/88735', 'http://dx.doi.org/10.26153/tsw/15669']

eng

2014 International Solid Freeform Fabrication Symposium

Open

['RepRap', '3D printer', 'open source rapid prototying', 'rapid prototyping', 'additive manufacturing']

Additive Manufacturing with RepRap Methodology: Current Situation and Future Prospects

Conference paper

https://repositories.lib.utexas.edu//bitstreams/f6b179cb-2d4b-4e0f-b0e8-b9f9e16f3b0d/download

University of Texas at Austin

In February 2004, Adrian Bowyer, from the University of Bath, began an open initiative called RepRap, with the purpose of creating an open source rapid prototyping machine which, moreover, could replicate itself. This article analyzes the current status of the RepRap initiative, commenting the basic components of RepRap machines, the differences between the different 3D printers developed by the RepRap community so far, and the technical possibilities that opens this technology from the engineering point of view. In addition we propose some improvements that could be perfectly feasible in the short term. For this purpose, the assembly of a RepRap Mendel Prusa was performed, but with some modifications.

['Chen, Yong', 'Zhou, Chi', 'Luo, Jingyuan']

2021-09-30T13:13:31Z

2021-09-30T13:13:31Z

2010

Mechanical Engineering

['https://hdl.handle.net/2152/88228', 'http://dx.doi.org/10.26153/tsw/15169']

eng

2010 International Solid Freeform Fabrication Symposium

Open

['additive manufacturing', '5-axis SFF', 'CNC accumulation', 'build around inserts']

Additive Manufacturing without Layers: A New Solid Freeform Fabrication Process based on CNC Accumulation

Conference paper

https://repositories.lib.utexas.edu//bitstreams/2d201dda-a4e9-40f2-9bb2-c19d3d1aea3a/download

University of Texas at Austin

Most current additive manufacturing processes are layer-based, that is building a physical model layer-by-layer. By converting 3-dimensional geometry into 2-dimensional contours, the layer-based approach can dramatically simplify the process planning steps. However, there are also drawbacks associated with the layer-based approach such as inconsistent material properties between various directions. In a recent NSF workshop on additive manufacturing, it is suggested to investigate alternative non-layer based approaches. In this paper, we present an additive manufacturing process without planar layers. In the developed testbed, an additive tool based on a fiber optics cable and a UV-LED has been developed. By merging such tools inside a liquid resin tank, we demonstrate its capability of building various 2D and 3D structures. The technical challenges related to the development of such a process are discussed. Some potential applications including part repairing and building around inserts have also been demonstrated.

Diewald, Evan P.

2021-12-01T22:11:49Z

2021-12-01T22:11:49Z

2021

Mechanical Engineering

['https://hdl.handle.net/2152/90634', 'http://dx.doi.org/10.26153/tsw/17553']

eng

2021 International Solid Freeform Fabrication Symposium

Open

['additive OS', 'open-source platform', 'data management', 'IP protection', 'AM data']

Additive OS: An Open-Source Platform for Additive Manufacturing Data Management & IP Protection

Conference paper

https://repositories.lib.utexas.edu//bitstreams/16cff5b7-663e-4109-8638-33cbe64335d7/download

University of Texas at Austin

The additive manufacturing (AM) digital thread presents unique challenges for data management and security. While proprietary software packages solve many issues, they can be expensive and lacking in customization. Additive OS is an open-source platform for importing, sharing, organizing, and querying AM data. Man-in-the-middle attacks, secure print licensing, and IP theft are addressed using custom smart contracts, ontology is preserved with a NoSQL database and directed acyclic graph (DAG) representations, and peer-to-peer content delivery facilitates low-latency file transfer. The application includes a browser-based graphical user interface, but developers can access the underlying API to invoke sophisticated queries, add functionality, or run the lightweight client on low-resource hardware.

['Frank, Matthew C.', 'Peters, Frank E.', 'Karthikeyan, Rajesh']

2021-09-30T14:17:24Z

2021-09-30T14:17:24Z

2010

Mechanical Engineering

['https://hdl.handle.net/2152/88254', 'http://dx.doi.org/10.26153/tsw/15195']

eng

2010 International Solid Freeform Fabrication Symposium

Open

['Rapid Pattern Manufacturing', 'additive techniques', 'subtractive techniques', 'injection mold tooling', 'seam-free laminated aluminum', 'casting patterns']

Additive/Subtractive Rapid Pattern Manufacturing for Casting Patterns and Injection Mold Tooling

Conference paper

https://repositories.lib.utexas.edu//bitstreams/5a4dfef5-1b9e-4d57-8c3b-360aa6c27eb6/download

University of Texas at Austin

This paper presents a Rapid Pattern Manufacturing system that involves both additive and subtractive techniques whereby slabs are sequentially bonded and milled using layered toolpaths. Patterns are grown in a bottom-up fashion, both eliminating the need for multi-axis operations and allowing small features in deep cavities. Similar approaches exist in the literature; however, this system is able to provide a larger range of both materials and sizes, from smaller conventional injection mold tooling to very large wood or urethane sand casting patterns. This method introduces a novel sacrificial support structure approach by integrating a flask into the pattern build process. The system has been implemented in an automated machine capable of producing patterns in excess of several thousand pounds in a build envelope over 1m3. In this current research, a new layer bonding method using friction stir welding of aluminum plates is presented. In this manner, one can create seam-free laminated aluminum injection mold tooling using a unique combination of industrial adhesives and friction stir spot welding to secure the slab initially, then continuous friction stir welding of layer perimeters that are subsequently machined in a layer-wise process.

['Lee, Seungjong', 'Ghiaasiaan, Reza', 'Shao, Shuai', 'Gradl, Paul R.', 'Shamsaei, Nima']

2023-01-25T13:52:26Z

2023-01-25T13:52:26Z

2022

Mechanical Engineering

['https://hdl.handle.net/2152/117285', 'http://dx.doi.org/10.26153/tsw/44166']

eng

2022 International Solid Freeform Fabrication Symposium

Open

['316L stainless steel', 'Laser powder directed energy deposition', 'Heat treatment', 'Microstructure', 'Tensile properties']

Additively Manufactured 316L Stainless Steel: Effect of Heat Treatment on Microstructure and Tensile Properties

Conference paper

https://repositories.lib.utexas.edu//bitstreams/0bc49a77-f38c-418a-ae13-c5d73326453b/download

The microstructure and tensile properties of 316L stainless steel (SS) fabricated using the laser powder directed energy deposition (LP-DED) after various heat treatment (HT) steps such as stress-relief (SR), solution annealing (SA), and hot isostatic pressing (HIP) are characterized. Microstructures before and after HTs are analyzed using both optical and scanning electron microscopy (SEM). Both quasi-static uniaxial tensile and hardness tests are performed to measure mechanical properties. The tensile results indicate that the non-heat treated (NHT) condition possesses higher strengths but lower ductility as compared to the other HT conditions (i.e., SR, SA, HIP, SR+SA, and SR+HIP). By employing the two-step HT conditions (i.e., SR+SA and SR+HIP), no significant changes on tensile properties as compared to the individual single-step HT conditions (i.e., SA or HIP) are observed. The findings suggest that two-step HTs are not required for LP-DED 316L SS unless HIP is needed to minimize volumetric defect contents.

['Debeau, D.A.', 'Seepersad, C.C.']

2021-11-04T19:37:30Z

2021-11-04T19:37:30Z

2017

Mechanical Engineering

['https://hdl.handle.net/2152/90012', 'http://dx.doi.org/10.26153/16933']

eng

2017 International Solid Freeform Fabrication Symposium

Open

['static mechanical performance', 'dynamic mechanical performance', 'honeycomb structures', 'conformal negative stiffness', 'additive manufacturing']

Additively Manufactured Conformal Negative Stiffness Honeycombs

Conference paper

https://repositories.lib.utexas.edu//bitstreams/fd8c96ba-b35d-44e4-893b-58f807f184ef/download

University of Texas at Austin

This study investigates the static and dynamic mechanical performance of conformal negative stiffness honeycomb structures. Negative stiffness honeycombs are capable of elastically absorbing a static or dynamic mechanical load at a predefined force threshold and returning to their initial configuration after the load is released. Most negative stiffness honeycombs rely on mechanical loading that is orthogonal to the base of the structure. In this study, a more three dimensional design is presented that allows the honeycomb to conform to complex surfaces and protect against impacts from multiple directions. The conformal designs are additively manufactured in nylon and stainless steel and subjected to quasi-static mechanical loading and dynamic mechanical impact tests that demonstrate their impact protection capabilities.

['Dressler, Amber', 'Scharnberg, William', 'Abousleiman, Anthony', 'Harris, Samantha', 'New, Phil']

2021-10-28T22:10:06Z

2021-10-28T22:10:06Z

2016

Mechanical Engineering

https://hdl.handle.net/2152/89714

eng

2016 International Solid Freeform Fabrication Symposium

Open

['fasteners', 'additive manufacturing', 'build-to-build', 'selective laser sintering']

Additively Manufactured Fasteners

Conference paper

https://repositories.lib.utexas.edu//bitstreams/a06d840c-6e88-4b1b-8cbf-c2008b514e01/download

University of Texas at Austin

Additive manufacturing (AM) has reached a critical point which enables production of complex, high resolution, custom parts from robust materials. However, traditional fasteners are still use to join these complex parts together. Integrating fasteners into additively manufactured parts is beneficial for part production but there is uncertainty in their design. To understand how the fasteners fit and function, mechanical property data was collected on the prototypes. This data along with insights gained while building and testing the prototypes increased the knowledge base of design for additive manufacturing and build-to-build variability in selective laser sintering (SLS).

['Slightam, Jonathon E.', 'Gervasi, Vito R.']

2021-10-11T22:44:26Z

2021-10-11T22:44:26Z

2013

Mechanical Engineering

['https://hdl.handle.net/2152/88673', 'http://dx.doi.org/10.26153/tsw/15607']

eng

2013 International Solid Freeform Fabrication Symposium

Open

['additively manufactured flexible fluidic actuators', 'Selective Laser Sintered Nylon 12', 'novel fluid power actuators', 'Magnetic Resonance Imaging', 'surgery', 'rehabilitation']

Additively Manufactured Flexible Fluidic Actuators For Precision Control in Surgical Applications

Conference paper

https://repositories.lib.utexas.edu//bitstreams/ce03f338-c232-421b-b86b-249750b14ad1/download

University of Texas at Austin

Previously, the Milwaukee School of Engineering (MSOE) demonstrated a dexterous tele-operational robotic system where actuators, joints, and linkages were fabricated simultaneously using Selective Laser Sintered Nylon 12. Primary motivation for this research was to conceive novel fluid power actuators that were inherently safe, compact, and Magnetic Resonance Imaging (MRI) compatible for surgery and rehabilitation. Although the concept of fabricating MRI compatible fluid power devices was demonstrated, further proof of precision control was needed. The design and implementation of additively manufactured flexible fluidic actuators (AMFFA) for precision control, best practices, and the comparison of these actuators with other actuation technologies are presented.

['Muhammad, Muztahid', 'Ghiaasiaan, Reza', 'Gradl, Paul R.', 'Schobel, Andre', 'Godfrey, Donald', 'Shao, Shuai', 'Shamsaei, Nima']

2021-12-06T22:20:58Z

2021-12-06T22:20:58Z

2021

Mechanical Engineering

['https://hdl.handle.net/2152/90696', 'http://dx.doi.org/10.26153/tsw/17615']

eng

2021 International Solid Freeform Fabrication Symposium

Open

['additive manufacturing', 'Hastelloy-X', 'microstructure', 'grain size', 'macrohardness']

Additively Manufactured Hastelloy-X: Effect of Post-Process Heat Treatment on Microstructure and Mechanical Properties

Conference paper

https://repositories.lib.utexas.edu//bitstreams/cad11fb7-0fd2-481a-a985-b9cf0c0861f3/download

University of Texas at Austin

In this study, the effect of post-process heat treatment on the microstructure and mechanical properties of Hastelloy-X superalloy fabricated via two different additive manufacturing technologies, namely, laser beam powder bed fusion (LB-PBF) and laser powder directed energy deposition (LP-DED), is investigated. Microstructure was examined using scanning electron microscopy (SEM) and electron backscattered diffraction (EBSD) analysis, while mechanical properties were evaluated by macro-hardness testing using the Rockwell B method. Microstructure of the alloys was studied thoroughly after several heat treatments that involve stress-relieving (at 1066°C for 1.5 hours), hot isostatic pressing (HIP at 1163°C for 3 hours under 103 MPa pressure), and/or solution treatment (at 1177°C for 3 hours). The results revealed that, for both LB-PBF and LP-DED Hastelloy-X, the post-process heat treatments resulted in uniform grain structure as well as partial dissolution of carbides, although they have different grain sizes.

['Muhammad, Muztahid', 'Ghiaasiaan, Reza', 'Gradl, Paul R.', 'Shao, Shuai', 'Shamsaei, Nima']

2021-12-06T22:23:59Z

2021-12-06T22:23:59Z

2021

Mechanical Engineering

['https://hdl.handle.net/2152/90697', 'http://dx.doi.org/10.26153/tsw/17616']

eng

2021 International Solid Freeform Fabrication Symposium

Open

['laser powder directed energy deposition', 'Haynes 230', 'microstructure', 'tensile behavior']

Additively Manufactured Haynes 230 by Laser Powder Directed Energy Deposition (LP-DED): Effect of Heat Treatment on Microstructure and Tensile Properties

Conference paper

https://repositories.lib.utexas.edu//bitstreams/622f2ad6-a83d-4f30-b043-383e4e240f31/download

University of Texas at Austin

The microstructure and tensile mechanical properties of Haynes 230 fabricated through laser powder directed energy deposition (LP-DED) were investigated, varying temperature heat treatments between 900°C to 1177°C following deposition. Scanning electron microscopy (SEM) was employed for microstructural analysis, whilst tensile testing was utilized to evaluate the room temperature mechanical properties of the alloy. In an as-deposited state, the initial microstructure consisted of cellular γ and M6C/M23C6 carbides. The cellular regions seem to be fully dissolved upon solutionizing at 1177°C for 3 hours. Following post-deposition heat-treatments, the carbides were observed to precipitate and grow along the grain boundaries as well as in the interior of grains. Solutionizing at 1177°C for 3 hours following stress-relieving yielded better ductility and had an insignificant effect on the strength.

['Zak, Gene', 'Wang, Wendy Xu']

2019-10-24T18:33:42Z

2019-10-24T18:33:42Z

2002

Mechanical Engineering

['https://hdl.handle.net/2152/77423', 'http://dx.doi.org/10.26153/tsw/4512']

eng

2002 International Solid Freeform Fabrication Symposium

Open

Adhesive Bonding

Adhesive Bonding of Sheet for Laminated Metal Tooling

Conference paper

https://repositories.lib.utexas.edu//bitstreams/779d4eea-4f48-4402-8f71-faf858d18c14/download

There exists a significant body of work on metal laminate tooling built by the “cut-stack-bond” approach; however, automation with this method is difficult. Building laminations by "stack-bond-cut" sequence, on the other hand, is more amenable to automation. Two main challenges of "stack-bond-cut" sequence are blind contour cutting and bonding of the sheet. In this study, we investigate the hot-roller method of thermoplastic adhesive bonding for the metal laminations. Metal sheet, having thermal characteristics significantly different from paper, poses its own specific problems. During the bonding process, in order to achieve good bond strength, appropriate heat and pressure must be applied. As the stack builds up, thermal and mechanical properties change. This inconsistency of process conditions can potentially lead to part warpage, unless carefully controlled. Temperature measurements with a thermocouple embedded into lamination stack showed the effect of bonding process parameters on the laminate temperature.

We gratefully acknowledge the financial support of Centre for Automotive Materials and Manufacturing, Ontario Innovation Trust, and Canada Foundation for Innovation.

['Utela, Ben', 'Anderson, Rhonda L.', 'Kuhn, Howard']

2020-02-28T16:30:17Z

2020-02-28T16:30:17Z

2006

Mechanical Engineering

['https://hdl.handle.net/2152/80117', 'http://dx.doi.org/10.26153/tsw/7138']

eng

2006 International Solid Freeform Fabrication Symposium

Open

Three-Dimensional Printing

Advanced Ceramic Materials and Processes for Three-Dimensional Printing (3DP)

Conference paper

https://repositories.lib.utexas.edu//bitstreams/f1e6819c-8031-4e53-8535-c0c9d4e002c9/download

The University of Washington and ExOne, Inc. are collaborating in the development of advanced ceramic materials and processes for three-dimensional printing (3DP). The focus of the research to be presented is work funded by the National Science Foundation to develop a biocompatible alumina-based system for medical and dental applications. Materials design, characterization, and processing considerations will be discussed.

['Lyons, Alan', 'Krishnan, Shankar', 'Mullins, John', 'Hodes, Marc', 'Hernon, Domhnaill']

2021-09-29T18:17:14Z

2021-09-29T18:17:14Z

2009

Mechanical Engineering

['https://hdl.handle.net/2152/88207', 'http://dx.doi.org/10.26153/tsw/15148']

eng

2009 International Solid Freeform Fabrication Symposium

Open

['heat sinks', 'heat sink designs', 'three-dimensional printing', 'monolithic copper structures']

Advanced Heat Sinks Enabled by Three-Dimensional Printing

Conference paper

https://repositories.lib.utexas.edu//bitstreams/8e6ba00c-afce-483f-a4e1-db50217237a8/download

University of Texas at Austin

With the rapid rise in power dissipated by integrated circuits, improved heat sinks designs are needed to decrease the thermal resistance between them and forced air streams. Manufacturing methods such as extrusion, machining and die-casting have been used to fabricate conventional longitudinal fin designs. Although these technologies add relatively little cost, they preclude the fabrication of more complex heat sink designs. We discuss novel heat sink designs which increase surface area and/or modulate air flow streams. Fabrication of these unconventional designs is enabled by using 3D printing technologies with the subsequent conversion of the printed parts into monolithic copper structures by investment casting.

['Weisensel, L.', 'Travitzky, N.', 'Greil, P.']

2020-02-13T19:41:42Z

2020-02-13T19:41:42Z

2004

Mechanical Engineering

['https://hdl.handle.net/2152/79967', 'http://dx.doi.org/10.26153/tsw/6992']

eng

2004 International Solid Freeform Fabrication Symposium

Open

Laminated Object Manufacturing

Advanced Laminated Object Manufacturing (LOM) of SiSiC Ceramics

Conference paper

https://repositories.lib.utexas.edu//bitstreams/389142a4-face-4589-a8c2-c3e52948915a/download

Carbon sheets were used as a starting material for fabrication of SiSiC composites by advanced LOM. This approach consists of three steps: First a preform was fabricated form phenolic resin coated carbon paper with a LOM-device. Second the preform was turned into a carbon preform by pyrolysis in N2-atmosphere. Third pressureless reactive melt infiltration of silicon into the as fabricated carbon preform, which finally yielded a dense SiSiC composite. SEM analysis revealed a microstructure consisting of uniformly dispersed β-SiC grains in a matrix of silicon. The LOM fabricated material exhibited an average four point bending strength and Youngs modulus of 115 MPa and 165 GPa, respectively.

['Petrzelka, Joseph E.', 'Frank, Matthew C.']

2021-09-28T19:58:30Z

2021-09-28T19:58:30Z

2009

Mechanical Engineering

['https://hdl.handle.net/2152/88167', 'http://dx.doi.org/10.26153/tsw/15108']

eng

2009 International Solid Freeform Fabrication Symposium

Open

['Subtractive Rapid Prototying', 'STL models', 'layer-based removal processing', 'tool accessibility']

Advanced Process Planning for Subtractive Rapid Prototyping

Conference paper

https://repositories.lib.utexas.edu//bitstreams/cfbe24e4-e8ab-4024-9751-eba262a2ec7d/download

University of Texas at Austin

This paper presents process planning methods for Subtractive Rapid Prototyping, which deals with multiple setup operations and the related issues of stock material management. Subtractive Rapid Prototyping (SRP) borrows from additive rapid prototyping technologies by using 2½D layer based toolpath processing; however, it is limited by tool accessibility. To counter the accessibility problem, SRP systems (such as desktop milling machines) employ a rotary fourth axis to provide more complete surface coverage. However, layer-based removal processing from different rotary positions can be inefficient due to double-coverage of certain volumes. This paper presents a method that employs STL models of the in-process stock material generated from slices of the part along the rotation axis. The developed algorithms intend to improve the efficiency and reliability of these multiple layer-based removal steps for rapid manufacturing.

['Hui, Du Zhao', 'Kai, Chua Chee', 'Sen, Chua Yew', 'Gek, Loh-Lee Keow', 'Tiak, Lim Ser']

2019-09-23T17:18:29Z

2019-09-23T17:18:29Z

2000

Mechanical Engineering

['https://hdl.handle.net/2152/75980', 'http://dx.doi.org/10.26153/tsw/3079']

eng

2000 International Solid Freeform Fabrication Symposium

Open

Manufacturing

Advanced Sheet Metal Manufacturing using Rapid Tooling 522

Conference paper

https://repositories.lib.utexas.edu//bitstreams/c2ff8c60-b253-4427-bcc4-6f8d12b8ddf3/download

A closed loop process is proposed for making sheet metal prototyping parts by using advanced computer aided techniques and computer controlled machines. The key aspect of this process is the method used to fabricate and modify the sheet metal forming tools, which are not necessarily for mass production but should be suitable for short run production or design evaluation of sheet metal products where the prototyping cost and lead-time are greatly reduced. Various approaches are investigated in the preparation of the tooling for onward embossing on a sheet metal. The three indirect approaches use Selective Laser Sintering (SLS), Stereolithography(SLA), and high speed Computer Numerical Controlled (CNC) milling to build the masters from computer data models. And the masters are then served in the vacuum casting process to generate the non-ferrous tooling. The direct approach uses DTM’s RapidSteel to produce the metal tooling without going through any secondary process. Comparisons on quality, leading time and cost are presented.

['Asiabanpour, Bahram', 'Khoshnevis, Behrokh', 'Palmer, Kurt', 'Mojdeh, Mehdi']

2019-11-08T15:30:24Z

2019-11-08T15:30:24Z

2003

Mechanical Engineering

['https://hdl.handle.net/2152/78323', 'http://dx.doi.org/10.26153/tsw/5410']

eng

2002 International Solid Freeform Fabrication Symposium

Open

SIS Process 25

Advancements in the SIS Process

Conference paper

https://repositories.lib.utexas.edu//bitstreams/a041cdf7-afe3-470d-b02c-43f25936d5c9/download

Selective Inhibition of Sintering (SIS) is a new layer-based rapid prototyping process. This paper reports the progress in research and development of the SIS process. Specific printer path generation method, experimentation with various powder and inhibitor materials, and systematic models leading to optimum performance given various factors affecting part strength, surface quality, and dimensional accuracy are presented.

['Mahela, T.', 'Cormier, D.', 'Harrysson, O.', 'Ervin, K.']

2020-03-09T15:23:46Z

2020-03-09T15:23:46Z

2007

Mechanical Engineering

['https://hdl.handle.net/2152/80197', 'http://dx.doi.org/10.26153/tsw/7216']

eng

2007 International Solid Freeform Fabrication Symposium

Open

Electron Beam Melting

Advances in Electron Beam Melting of Aluminum Alloys

Conference paper

https://repositories.lib.utexas.edu//bitstreams/92943da2-836d-4ab8-97fb-3aaf77fd0336/download

The high thermal conductivity and melt pool optical reflectivity associated with aluminum alloys can pose significant challenges for direct-metal SFF processes. The use of SFF processes to produce aluminum parts is often not cost effective relative to CNC machining for simple geometries. However, the use of SFF techniques for aluminum alloys is justified for some applications such as aerospace forgings or high surface area heat exchangers. This paper describes recent progress in processing aluminum alloys using the Electron Beam Melting process. Structure and properties will be discussed, as well challenges associated with high vapor pressure alloying elements such as zinc and magnesium.

['Dutson, Alan J.', 'Wood, Kristin L.', 'Beaman, Joseph J.', 'Crawford, Richard H.']

2019-10-23T15:17:08Z

2019-10-23T15:17:08Z

2002

Mechanical Engineering

['https://hdl.handle.net/2152/76758', 'http://dx.doi.org/10.26153/tsw/3847']

eng

2002 International Solid Freeform Fabrication Symposium

Open

Functional Testing

Advances in Functional Testing with SFF Parts

Conference paper

https://repositories.lib.utexas.edu//bitstreams/c4f9703f-d4d5-40e9-98e5-37dfd8accdd7/download

Functional testing of SFF parts represents an exciting area of research in solid freeform fabrication. One approach to functional testing is to use similitude techniques to correlate the behavior of an SFF model and a product. Previous research at UT Austin has resulted in development of an empirical similitude technique to correlate the behavior of parts of dissimilar materials and geometry. Advances in the empirical similitude technique are presented in this paper. Sources of coupling between material and geometry characteristics that produce errors in the current empirical similitude technique are outlined. A modified approach that corrects for such errors is presented. Numerical examples are used to illustrate both the current and the advanced empirical similitude methods.

['Tompkins, J.V.', 'Laabi, R.', 'Birmingham, B.R.', 'Marcus, H.L.']

2018-10-03T18:43:19Z

2018-10-03T18:43:19Z

1994

Mechanical Engineering

doi:10.15781/T2WS8J53D

http://hdl.handle.net/2152/68678

eng

1994 International Solid Freeform Fabrication Symposium

Open

['SALD', 'Solid free-form fabrication', 'DES']

Advances in Selective Area Laser Deposition of Silicon Carbide

Conference paper

https://repositories.lib.utexas.edu//bitstreams/e74dc268-0af2-46e9-85a1-85234b3b7907/download

Selective Area Laser Deposition (SALD) is a Solid Freeform Fabrication (SFF) technique which uses a scanning laser beam to produce solid material by locally decomposing a gas precursor. In this work, a focused C02 laser beam strikes a substrate in the presence oftetramethylsilane (TMS) or diethylsilane (DES), producing silicon carbide objects with high density and no binder phase. Recent investigation has yielded growth rates up to 2.7mlnJmin in the beam area, and has eliminated previously noted contamination ofthe optics by a byproduct which mass spectroscopy identifies as silicon dioxide. This paper reviews a cause of non-uniform growth and delTIOnstrates the addition of hydrogen and reduced scan speeds to lTIake lTIultilayer parts. In addition, it presents a lTIethod for in-situ measurement of height of deposited material.

['Amado, A.', 'Schmid, M.', 'Levy, G.', 'Wegener, K.']

2021-10-05T13:30:38Z

2021-10-05T13:30:38Z

2011

Mechanical Engineering

['https://hdl.handle.net/2152/88367', 'http://dx.doi.org/10.26153/tsw/15306']

eng

2011 International Solid Freeform Fabrication Symposium

Open

['Selective Laser Sintering', 'powder characterization', 'powder flow processing']

Advances in SLS Powder Characterization

Conference paper

https://repositories.lib.utexas.edu//bitstreams/7166d153-eff1-4b21-8889-c1a8a20c3b01/download

University of Texas at Austin

This paper introduces a new Selective Laser Sintering (SLS) powder characterization methodology. A better understanding regarding powder flow processing range is targeted. Intrinsic properties of polymers are given from the basic chemical structure and non-intrinsic ones describe characteristics caused from pre-processing and production. The non-intrinsic ones are dedicated to the powder. Understanding the particle size distribution and shape coupled with its ability to flow under the particular SLS processing conditions is desired. In this direction, a system called Revolution Powder Analyzer is employed and the dynamic powder behavior is characterized in nearly roll spreading conditions. This allows a sensitive differentiation of powders regarding their flow-ability and predicts, to a certain extent, the behavior under SLS conditions.

['Jacobs, Paul F.', 'Richter, Jan']

2018-04-17T16:41:04Z

2018-04-17T16:41:04Z

1991

Mechanical Engineering

doi:10.15781/T25T3GH0J

http://hdl.handle.net/2152/64329

eng

1991 International Solid Freeform Fabrication Symposium

Open

['SLA', 'Windownpane', 'Weave', 'SLA-250']

Advances in Stereolithography Accuracy

Conference paper

https://repositories.lib.utexas.edu//bitstreams/cbf7f76c-0bd2-4566-90d4-5a18ad3d3460/download

It has been almost four years since the SLA - 1 ushered in the new technology of StereoLithography, and about 2\ years since 3D Systems introduced the SLA-250. Since then, nearly 300 systems have been installed worldwide and are currently providing benefits in a range of applications which might well be summarized by the term "Rapid Prototyping and Manufacturing" or "RPM". During the past year the accuracy of parts built with stereoLithography has benefitted significantly from nine important technological advances. The research and development efforts which formed the foundation for this progress originated within the Process, Chemistry and Software departments of 3D Systems. The following is a listing, and brief description, of the key features of each of these advances.

['Sercombe, T.B.', 'Schaffer, G.B.']

2020-02-12T15:06:37Z

2020-02-12T15:06:37Z

2004

Mechanical Engineering

['https://hdl.handle.net/2152/79934', 'http://dx.doi.org/10.26153/tsw/6960']

eng

2004 International Solid Freeform Fabrication Symposium

Open

Selective Laser Sintering

Advances in the Production of Infiltrated Aluminium Parts Using Selective Laser Sintering

Conference paper

https://repositories.lib.utexas.edu//bitstreams/b41459fa-1a05-4505-9d85-699423d7b2c4/download

Recent advances in a rapid freeform fabrication process for the production of aluminium parts are considered. The methodology involves the formation of an unconstrained, resin bonded aluminium powder part by Selective Laser Sintering, the burnout of the resin, the partial transformation of the aluminium into a rigid aluminium nitride skeleton by reaction with the atmosphere under a magnesium/alumina blanket and the subsequent infiltration with a second aluminium alloy. Here we describe the process and consider potential applications. Strategies for controlling the growth of the aluminium nitride are also to be discussed.

['Liu, Fei', 'Jingchao, Wang', 'Zhi, Tan', 'Bin, Liu', 'Yue, Guo', 'Zhang, David Z.']

2021-11-09T18:57:26Z

2021-11-09T18:57:26Z

2018

Mechanical Engineering

['https://hdl.handle.net/2152/90119', 'http://dx.doi.org/10.26153/tsw/17040']

eng

2018 International Solid Freeform Fabrication Symposium

Open

['additive manufacturing', 'selective laser melting', 'upper-stage cabin structure', 'integrated design and manufacturing']

An Aerospace Integrated Component Application Based on Selective Laser Melting: Design, Fabrication and Fe Simulation

Conference paper

https://repositories.lib.utexas.edu//bitstreams/9cb14418-ea21-4a16-b179-4999448e6fd8/download

University of Texas at Austin

Developments in Additive Manufacturing (AM) technologies have enabled the integrated manufacturing of complex structures with multifunctional performances. Selective Laser Melting (SLM), as one of them, becomes the candidate for production of metallic aviation spaceflight structures because of its high precision for controlling architecture and excellent performance. An aerospace component named Upper-stage Cabin was selected for integrated design without connectors, and then manufactured by a SLM system using Ti-6Al-4V powder. The dimensional accuracy of the component was verified through testing; It’s mechanical response was analyzed under compressive loading test, compared with the results of numerical simulation. The study found that SLM technology is an effective means for integrated design and manufacture of Upper-stage Cabin structures for aerospace. The dimensional precision of the complex integrated structures formed by SLM meets the application requirements. The formed integrated components have achieved good mechanical properties, which promote the application of this technology in aerospace field.

['Cho, Uichung', 'Wood, Kristin L.', 'Crawford, Richard H.']

2019-03-07T18:09:52Z

2019-03-07T18:09:52Z

1999

Mechanical Engineering

['https://hdl.handle.net/2152/73566', 'http://dx.doi.org/10.26153/tsw/708']

eng

1999 International Solid Freeform Fabrication Symposium

Open

['rapid prototyping techniques', 'industries']

Agile Product Testing with Constrained Prototypes

Conference paper

https://repositories.lib.utexas.edu//bitstreams/8951b4bc-edc2-44c8-a19f-45538d564f4d/download

The means to acquire reliable functional information is a critical factor that differentiates product development time and cost. Thanks to advances in solid freeform fabrication techniques, industries can produce geometrically complex parts within dramatically reduced time and cost. Even though industries can save significant efforts by performing functional tests rapid prototypes, they still prefer full-scale product tests, especially in later design phases, due to inherent limitations in traditional similarity methods (TSM). This paper describes a new method to perform reliable functional tests with rapid prototypes that cannot be properly handled by the TSM.

['Wudy, K.', 'Drummer, D.']

2021-10-27T22:15:58Z

2021-10-27T22:15:58Z

2016

Mechanical Engineering

https://hdl.handle.net/2152/89631

eng

2016 International Solid Freeform Fabrication Symposium

Open

['aging behavior', 'bulk values', 'part properties', 'interrelation', 'polyamide 12']

Aging Behavior of Polyamide 12: Interrelation Between Bulk Characteristics and Part Properties

Conference paper

https://repositories.lib.utexas.edu//bitstreams/a249bd79-2a3a-4c30-97b3-4474c8b83901/download

University of Texas at Austin

The high process temperatures in combination with long building times during the laser sintering process lead to chemical and physical aging mechanisms on the polymeric feed material. The unmolten partcake material, which acts as a supporting structure, can be removed after each building process and reused for further processes. However, material as well as bulk properties are changed due to thermal and mechanical load during the laser sintering process. Within this paper the interrelation between the aging state, bulk values and resulting part properties like porosity, surface roughness and mechanical behavior are derived. Therefore, polyamide 12 powder is used for at least five processing cycles without refreshing. Before and after each building process, bulk characteristics and changes of the particle surface were determined. Specimens were manufactured during the laser sintering process in order to study the part density, roughness and mechanical behavior.

['Palomino, Donald', 'Bian, Shijie', 'Salcedo, Pedro', 'Navarro, Erick', 'Gopalaiah, Bharath', 'Otis4, Richard', 'Li, Bingbing']

2023-01-26T22:00:35Z

2023-01-26T22:00:35Z

2022

Mechanical Engineering

['https://hdl.handle.net/2152/117326', 'http://dx.doi.org/10.26153/tsw/44207']

eng

2022 International Solid Freeform Fabrication Symposium

Open

['Augmented Reality Training', 'Metal Additive Manufacturing', 'Text Recognition', 'Object Detection']

AI-Powered Augmented Reality Training for Metal Additive Manufacturing

Conference paper

https://repositories.lib.utexas.edu//bitstreams/4e9fea74-8767-4804-8338-8259b8eeb7c4/download

Metal additive manufacturing (AM) training can cost a company the considerable amount of time, cost, and resources. To resolve this challenge, the NSF funded HyperSkill platform was applied to create an innovative, immersive training program that integrates AI-powered object detection and text recognition into a comprehensive digital twin of the metal AM machine operation. This immersive digital twin will support the delivery of just-in-time guidance to trainees while also monitoring their actions and providing contextual and personalized feedback to accelerate training, foster retention, and maximize transfer to the actual job. The augmented reality (AR) training supports the import of 3D assets, no-code authoring of workflows, standard operating procedures (SOP), step-by-step instructions, and delivery across a wide variety of AR devices. For this study, the specific metal AM operation is based on the Renishaw AM400 in both its full and reduced build volume (RBV) configuration.

['Cawley, J.D.', 'Wei, P.', 'Liu, Z.E.', 'Newman, W.S.', 'Mathewson, B.B.', 'Heuer, A.H.']

2018-10-03T19:18:23Z

2018-10-03T19:18:23Z

1995

Mechanical Engineering

doi:10.15781/T2HH6CR12

http://hdl.handle.net/2152/68681

eng

1995 International Solid Freeform Fabrication Symposium

Open

['CAM-LEM', 'Solid free-form fabrication', 'powder synthesis']

Al2O3 Ceramics Made by CAM-LEM (Computer-Aided Manufacturing of Laminated Engineering Materials) Technology

Conference paper

https://repositories.lib.utexas.edu//bitstreams/a17c37da-e696-40a4-bedb-e7c9d2cef556/download

The concept of CAM-LEM technology is presented and discussed in the context of the fabrication of Al2O3 ceramics. Particular attention is paid to the interplay of green tape characteristics and the unit operations involved in CAM-LEM. Examples of ceramic shapes difficult to form by conventional methods are described.

['Weiss, C.M.', 'Marcus, H.L.']

2021-09-30T13:37:30Z

2021-09-30T13:37:30Z

2010

Mechanical Engineering

['https://hdl.handle.net/2152/88244', 'http://dx.doi.org/10.26153/tsw/15185']

eng

2010 International Solid Freeform Fabrication Symposium

Open

['SFF', 'Selective Area Laser Deposition', 'SALD joining', 'carbides', 'nitrides', 'ceramics', 'CVD gas decomposition', 'aluminum oxide']

Al2O3 Precursor Evaluation for SALD Joining

Conference paper

https://repositories.lib.utexas.edu//bitstreams/56ca323d-8241-49f2-9e4f-bb7a00a057d4/download

University of Texas at Austin

SFF technology is not limited to the creation of components and objects. Freeform technology can be a mechanism for joining of materials. By defining the space between two objects as the boundary for a free-form object it is possible to form a three dimensional joint fill. Selective Area Laser Deposition or SALD, has been used for free form and joining of carbides and nitrides but has the potential to make other classes of ceramics. By selecting a metal-organic precursor and an oxidizer, an oxide can be created by CVD gas decomposition. In this study such oxide joint fill precursors are studied, particularly for alumina.

['Bártolo, Paulo', 'Lagoa, Ricardo', 'Mendes, Ausenda']

2019-11-15T16:09:45Z

2019-11-15T16:09:45Z

2003

Mechanical Engineering

['https://hdl.handle.net/2152/78419', 'http://dx.doi.org/10.26153/tsw/5506']

eng

2003 International Solid Freeform Fabrication Symposium

Open

Alginate-Based

Alginate-Based Rapid Prototyping System

Conference paper

https://repositories.lib.utexas.edu//bitstreams/c5177bf3-78b8-40e3-beaa-ee65a0d8fba1/download

Alginate hydrogels are an import class of ionic biopolymers for medical and biotechnological applications, produced by the combination of alginate with a proper cross-linking agent. During the gel formation, cross-links can be formed between the alginate chains and cationic species, changing the elastic behaviour of the material that controls the volume change phenomena of the gels. This paper proposes a new rapid prototyping system to produce three-dimensional alginate structures by extruding, layer-by-layer, a previously prepared solution of sodium alginate in water mixed with a solution of calcium chloride, both of known concentration. The building process to obtain these gel structures is described, from a chemical point of view, and some obtained structures are shown. The alginate concentration over both the kinetics and accuracy effects of the process is investigated. The preliminary findings of this research work promise to open an exciting new area for medical applications.

['Arndt, Alexander', 'Hackbusch, Heike', 'Anderl, Reiner']

2021-10-21T18:40:31Z

2021-10-21T18:40:31Z

2015

Mechanical Engineering

https://hdl.handle.net/2152/89423

eng

2015 International Solid Freeform Fabrication Symposium

Open

['additive manufacturing', '3D nesting', 'optimization', 'algorithm']

An Algorithm-Based Method for Process-Specific Three-Dimensional Nesting for Additive Manufacturing Process

Conference paper

https://repositories.lib.utexas.edu//bitstreams/2cbf39ce-e17a-4ba0-b798-801640b56a89/download

University of Texas at Austin

To achieve optimal and high-quality results through additive manufacturing, the process-and technology-specific orientation and positioning of components within the virtual space, the so-called nesting, is essential. Primarily the nesting step is examined in this paper. From a scientific perspective it is a matter of examining this process and furthermore to analyze the optimal insertion of supporting structures, since the critical machine-specific parameters have been insufficiently studied. Within this paper a new multi-criteria optimization based on a conceptual algorithm is proposed. The most important point is the consideration of a technical and not only geometric nesting process. The objective is the demonstration of restrictions and boundary conditions and a first developing for a new approach for the nesting process. As an example, the influence of the orientation of the spring rate is presented with a sample component here. Furthermore, there will be a prototype implementation and a short validation. Finally, a brief conclusion and an outlook is given.

['Gardner, J.A.', 'Nethercott-Garabet, T.', 'Kaill, N.', 'Campbell, R.I.', 'Bingham, G.A.', 'Engstrøm, D.S.', 'Balc, N.O.']

2021-11-15T21:24:49Z

2021-11-15T21:24:49Z

2018

Mechanical Engineering

['https://hdl.handle.net/2152/90278', 'http://dx.doi.org/10.26153/tsw/17199']

eng

2018 International Solid Freeform Fabrication Symposium

Open

['additive manufacturing', '5-axis', 'tool path', 'material extrusion', 'G-code']

Aligning Material Extrusion Direction with Mechanical Stress via 5-Axis Tool Paths

Conference paper

https://repositories.lib.utexas.edu//bitstreams/71069994-e807-495b-9b05-b025680bc454/download

University of Texas at Austin

Mechanical properties of parts fabricated via the Material Extrusion (ME) process can be improved by optimising process settings, however, their properties are strongly influenced by build orientation due to the stair-stepping effect initiating cracks whilst under load. 5-axis ME enables the fabrication of parts without the layer-by-layer restrictions that conventional 3-axis strategies impose. By aligning extrusion direction with high stress tensors, 5-axis tool paths can be used to reduce the effects of weak inter-layer bonds. To establish performance differences between parts manufactured by either strategy, wave spring-inspired geometry was selected for production, due to the multi-directional tensile loads acting throughout the material. 5-axis and 3-axis tool paths were generated via the Grasshopper 3D virtual environment within Rhinoceros 3D and MakerBot Desktop, and manufactured using a 5AXISMAKER and a MakerBot Replicator 2, respectively. To evaluate performance differences between the two strategies, compression tests were conducted on the parts.

Drake, Samuel H.

2018-04-10T18:56:39Z

2018-04-10T18:56:39Z

1990

Mechanical Engineering

doi:10.15781/T22J68N1S

http://hdl.handle.net/2152/64247

eng

1990 International Solid Freeform Fabrication Symposium

Open

['Alpha_1', 'SFF techniques', 'NURBs']

ALPHA_I, Remote Manufacturing, and Solid Freeform Fabrication

Conference paper

https://repositories.lib.utexas.edu//bitstreams/c3ee93b8-37d9-4fa8-89ce-08c104274c3b/download

Alpha_l is a nonuniform rational B-spline (NURBs) based solid modeling system that has been developed at the University of Utah over the past 10 years. In addition to being useful in modeling objects that are described by simple rotation and extrusion operations, the real power of Alpha_l is demonstrated in the modeling of complex parts with sculptured surfaces. For the past several years, a major research thrust has been to use Alpha_l to semi-automatically generate process plan information and numerical control code to manufacture mechanical parts directly from the models. A long term goal is to support an on-line remote manufacturing facility for producing prototype parts. Recently, a 3D Systems stereo lithography machine has been added to the advanced manufacturing laboratory. The stereo lithography process and other SFF techniques are of particular interest for supporting a remote manufacturing facility in that these processes are inherently much safer than numerically controlled machining. Special Alpha_l interfaces including a new slicing algorithm are being developed for the SFF machine use. By generating a SFF part directly from its NURBs description, Alpha_l should facilitate the manufacture of complex parts while providing smoother surfaces.

['Schnell, N.', 'Siewert, M.', 'Kleszczynski, S.', 'Witt, G.', 'Ploshikhin, V.']

2021-11-18T17:27:19Z

2021-11-18T17:27:19Z

2019

Mechanical Engineering

['https://hdl.handle.net/2152/90437', 'http://dx.doi.org/10.26153/tsw/17358']

eng

2019 International Solid Freeform Fabrication Symposium

Open

['laser powder bed fusion of metals', 'LPBF-M', 'thermocouple', 'finite element modeling', 'FEM', 'validation', 'thermocouple', 'stainless steel 1.4542', 'GP1']

Alternative Approach on an In-Situ Analysis of the Thermal Progression During the LPBF-M Process Using Welded Thermocouples Embedded into the Substrate Plate

Conference paper

https://repositories.lib.utexas.edu//bitstreams/3947858f-d621-41fc-afb4-309cb7acbeee/download

University of Texas at Austin

Laser powder bed fusion (LPBF-M) is a very potent technology for creating highly individualized, complex, and functional metal parts. One of the major influencing factors is the thermal progression. It significantly determines size accuracy, microstructure and process stability. Therefore, creating an enhanced understanding of thermal phenomena through measurements and simulations is crucial to increase the reliability of the technology. Current research is mainly based on temperature measurements of the upper layer, leaving major scope for the conditions at the substrate-part-interface. This area is of utmost technical importance because it serves as the main heat sink. Insufficient heat dissipation leads to accumulations of heat, deformations, and process breakdowns. This contribution presents a simple and flexible method to analyze the thermal progression close to the part inside the substrate plate. The acquired data shows very high consistency. Additionally, the results are compared to a model created using an ISEMP developed FEM-Software which shows promising results for validation studies.

['Spratt, M.', 'Newkirk, J.', 'Chandrashekhara, K.']

2021-11-02T14:52:59Z

2021-11-02T14:52:59Z

2017

Mechanical Engineering

https://hdl.handle.net/2152/89817

eng

2017 International Solid Freeform Fabrication Symposium

Open

['syntactic foam', 'aluminum matrix', 'additive manufacturing', 'microsphere flotation', 'microsphere fracture']

Aluminum Matrix Syntactic Foam Fabricated with Additive Manufacturing

Conference paper

https://repositories.lib.utexas.edu//bitstreams/90e3d3fe-e31f-4d93-88e6-4540ebe39c4e/download

University of Texas at Austin

Syntactic foams are lightweight structural composites with hollow reinforcing particles embedded in a soft matrix. These materials have applications in transportation, packaging, and armor due to properties such as relatively high specific stiffness, acoustic dampening, and impact absorption. Aluminum matrices are the most widely studied of metal matrix syntactic foams, but there is little to no research in regards to processing the foams with additive manufacturing. It is theorized that the fast cooling rates and limited kinetic energy input of additive could reduce two issues commonly associated with processing syntactic foams: microsphere flotation in the melt and microsphere fracture during processing. In this study, 4047 aluminum blended with glass particles was deposited on a 4047 Al substrate using an additive process. Characterization of the foams include mechanical testing and microstructural analysis.

['Qi, Yang', 'Zhang, Hu', 'Zhu, Haihong', 'Nie, Xiaojia', 'Zeng, Xiaoyan']

2021-11-18T00:47:12Z

2021-11-18T00:47:12Z

2019

Mechanical Engineering

['https://hdl.handle.net/2152/90377', 'http://dx.doi.org/10.26153/tsw/17298']

eng

2019 International Solid Freeform Fabrication Symposium

Open

['aluminum-lithium', 'Al-Li', 'laser powder bed fusion', 'LPBF']

An Aluminum-Lithium Allloy Produced by Laser Powder Bed Fusion

Conference paper

https://repositories.lib.utexas.edu//bitstreams/a5ff4a4e-fb07-4515-84e6-6ef404dc0762/download

University of Texas at Austin

Aluminum-lithium (Al-Li) alloys are promising to replace traditional high-strength aluminum alloys in aerospace and military industries due to their low density, high specific strength, and excellent corrosion resistance. However, there is little research focused on the laser powder bed fusion (LPBF) of Al-Li alloys due to their poor weldability and high crack susceptibility. In this study, the feasibility of the Al-Li alloy fabricated by LPBF was investigated. The effect of the processing parameters on the densification and crack formation behavior was studied. Finally, after optimizing the processing parameters, crack-free and nearly fully dense 2195 Al-Li alloy 3D-printed samples were obtained. A relative density of 99.92% and a microhardness of 89.1 HV were achieved.

['Zhang, Y.', 'Bernard, A.']

2021-10-18T22:36:23Z

2021-10-18T22:36:23Z

2014

Mechanical Engineering

https://hdl.handle.net/2152/89274

eng

2014 International Solid Freeform Fabrication Symposium

Open

['Additive Manufacturing', 'feature based process planning', 'knowledge based process planning', 'CAPP system']

AM Feature and Knowledge Based Process Planning for Additive Manufacturing in Multiple Parts Production Context

Conference paper

https://repositories.lib.utexas.edu//bitstreams/1b6cee97-2bc9-4f92-8383-4f91e2b48493/download

University of Texas at Austin

Additive Manufacturing (AM) has played an important role in manufacturing, especially in customized production. It is an ideal 'Concurrent Manufacturing' which enables fabricating a group of same or even different multiple parts simultaneously within one build volume due to its unique layer by layer processing way. However, there is very few available methods or tools for users, e.g. the AM manufacturing service bureaus, to optimize the process and production plan in multiple parts production context. To deal with this problem, this paper introduces an AM feature and knowledge based systematic process planning strategy. The main contents and key issues of process planning for AM in multiple parts production context are analyzed. Then, a developing CAPP system based on a systematic process planning framework for AM in this multiple parts production context is presented. Finally, some test examples are applied to demonstrate the functions and effectiveness of some key modules of the developing system.

['Muhammad, M.', 'Masoomi, M.', 'Torries, B.', 'Shamsaei, N.', 'Haghsenas, M.']

2021-11-11T15:13:49Z

2021-11-11T15:13:49Z

2018

Mechanical Engineering

['https://hdl.handle.net/2152/90215', 'http://dx.doi.org/10.26153/tsw/17136']

eng

2018 International Solid Freeform Fabrication Symposium

Open

['instrumented indentation', 'additive manufacturing', 'Ti-6Al-4V', 'creep stress exponent']

Ambient-Temperature Indentation Creep of an Additively Manufactured Ti-6Al-4V Alloy

Conference paper

https://repositories.lib.utexas.edu//bitstreams/b54a5218-389f-470c-b578-71a926cc632b/download

University of Texas at Austin

Instrumented indentation testing technique is a robust, convenient, and non-destructive characterization method to study time-dependent plastic deformation in metals and alloys at ambient and elevated temperatures. In this current research, the depth-sensing indentation creep behavior of additively manufactured Ti-6Al-4V alloy and its mechanism were studied at ambient temperature for different additive manufacturing scan direction and scan size. Indentation creep tests were conducted through a dual-stage scheme (loading followed by a constant load-holding) at different peak load of 250, 350, and 450 mN with holding time of 400 s. In addition, microstructural quantitative analyses, using optical microscopy and scanning electron microscopy, were performed. Microstructural assessments and depth-sensing creep characterizations were then used to assess processing parameter/ microstructure/ creep properties relationships for this alloy.

['Espalin, David', 'Arcaute, Karina', 'Anchondo, Eric', 'Adame, Arturo', 'Medina, Francisco', 'Winker, Rob', 'Hoppe, Terry', 'Wicker, Ryan']

2021-09-29T22:38:08Z

2021-09-29T22:38:08Z

2010

Mechanical Engineering

['https://hdl.handle.net/2152/88222', 'http://dx.doi.org/10.26153/tsw/15163']

eng

2010 International Solid Freeform Fabrication Symposium

Open

['fused deposition model', 'additive manufacturing', 'bonding', 'bonding methods', 'thermoplastic material', 'FDM-manufactured parts', 'bonding strength']

Analysis of Bonding Methods for FDM-Manufactured Parts

Conference paper

https://repositories.lib.utexas.edu//bitstreams/0a483bbc-75f5-40b8-a1fb-0ec631bd9c3b/download

University of Texas at Austin

The fused deposition modeling (FDM) additive manufacturing (AM) technology has been valuable for producing a variety of concept models, functional prototypes, end-use parts and manufacturing tools using a range of durable thermoplastic materials. The largest individual component that can be produced in FDM depends on the dimensions of the build chamber for the specific FDM system being used, with a maximum build chamber size available of 914 x 610 x 914 mm. This limitation is not unique to FDM as all AM systems are constrained by a build chamber. However, by using thermoplastic materials, individual components can be bonded together using different methods to form a single piece. Bonding can be used to help reduce building time and support material use, and also allows for the fabrication and assembly of final products larger than the build chamber. This work investigated different methods for bonding FDM-manufactured parts, including the use of five different adhesives and solvents as well as two different welding techniques (hot air welding and ultrasonic welding). The available FDM materials investigated included acrylonitrile butadiene styrene (ABSi, ABS-M30, ABS-M30i), polycarbonate (PC, PC-ABS, PC-ISO), polyphenylsulfone (PPSF), and ULTEM 9085. Bonding strengths were characterized by comparing ultimate tensile strengths at break and analyzing the mode of failure. Overall, the bonding method of hot air welding produced the strongest bond for all the materials investigated except for ULTEM 9085 for which the strongest bond was achieved with the two-part epoxy adhesive Hysol E-20HP.

['Isa, Mohammed A.', 'Yiğit, Ismail Enes', 'Lazoglu, Ismail']

2021-11-11T16:22:27Z

2021-11-11T16:22:27Z

2018

Mechanical Engineering

['https://hdl.handle.net/2152/90235', 'http://dx.doi.org/10.26153/tsw/17156']

eng

2018 International Solid Freeform Fabrication Symposium

Open

['freeform overhangs', 'build direction', 'mutli-axis additive manufacturing', 'additive manufacturing']

Analysis of Build Direction in Deposition-Based Additive Manufacturing of Overhang Structures

Conference paper

https://repositories.lib.utexas.edu//bitstreams/5be8db77-3358-4b8c-af21-96a0a263d228/download

University of Texas at Austin

Additive manufacturing (AM) has gained repute as a direct method of fabrication of complex parts. However, the requirement for each layer to be structurally supported can make parts with overhangs hard to produce without alterations to the parts. This work proposes using multi-axis additive manufacturing to fabricate and analyze freeform overhangs such as bridge structures. Multi-axis AM allows reorientation of the build direction so that overhangs can be 3D printed. Consequently, decision on the build orientation is necessary and its result should be analyzed. The effect of the AM build direction with respect to the overhang’s local surface directions will be studied. A Rhinoceros® plugin is designed to generate the path of the multi-axis AM for the unsupported components like roofs, bridges and protrusions. The effects of the build direction on the surface quality and deformation of the components are studied.

['Fathi, S.', 'Dickens, P. M.', 'Hague, R. J. M.', 'Khodabkhski, K.', 'Gilbert, M.']

2020-03-11T15:13:14Z

2020-03-11T15:13:14Z

2008

Mechanical Engineering

['https://hdl.handle.net/2152/80248', 'http://dx.doi.org/10.26153/tsw/7267']

eng

2008 International Solid Freeform Fabrication Symposium

Open

['solid free-form fabrication', 'Ink-jetting']

Analysis of Droplet Train/Moving Substrate Interactions in Ink-Jetting Processes

Conference paper

https://repositories.lib.utexas.edu//bitstreams/774a34be-0bbd-40b7-9429-0bce1c54b30a/download

Ink-jetting technology has been applied to several processes in solid free-form fabrication (SFF) wherein droplets impinge onto a substrate to deposit the build material. Droplet impact behaviour on a surface has been the interest of many researchers; however, few studies have been undertaken to investigate the interaction of droplets with the moving substrate. This paper reports the impact behaviour of the droplets jetted at different frequencies onto a substrate moving over a range of velocities. The phenomena associated with the interaction were classified into three main regimes.

['Alqahtani, Hassan', 'Keller, Eric', 'Ray, Asok', 'Basak, Amrita']

2021-11-18T00:43:48Z

2021-11-18T00:43:48Z

2019

Mechanical Engineering

['https://hdl.handle.net/2152/90376', 'http://dx.doi.org/10.26153/tsw/17297']

eng

2019 International Solid Freeform Fabrication Symposium

Open

['fatigue damage', 'crack initiation', 'ultrasonic test', 'digital microscope', 'signal attenuation', 'discrete wavelet transform']

Analysis of Fatigue Crack Evolution Using In-Situ Testing

Conference paper

https://repositories.lib.utexas.edu//bitstreams/b292e60f-b871-4bbc-83bd-8c47207801ff/download

University of Texas at Austin

The objective of the current work is to investigate the feasibility of an in-situ technique to characterize the evolution of fatigue failure in conventionally manufactured aluminum parts in real time. An in-situ fatigue testing setup integrated with ultrasonic transducers and a digital microscope allows for the systematic study of fatigue crack evolution in aluminum specimens. The resulting data from experimentation, characterization, and analysis are integrated to gain unprecedented insights into the evolution of fatigue failure in wrought aluminum parts. The learning from this work will be further implemented on additively manufactured specimens.

['Gaytan, Sara M.', 'Cadena, Monica', 'Aldaz, Mayela', 'Herderick, Edward', 'Medina, Francisco', 'Wicker, Ryan']

2021-10-12T17:59:57Z

2021-10-12T17:59:57Z

2013

Mechanical Engineering

['https://hdl.handle.net/2152/88708', 'http://dx.doi.org/10.26153/tsw/15642']

eng

2013 International Solid Freeform Fabrication Symposium

Open

['ceramic fabrication', 'ferroelectric ceramics', 'binder jetting', 'dielectric capacitors', 'sensors', 'integrated circuits', 'M-Lab system', 'ExOne']

Analysis of Ferroelectric Ceramic Fabricated by Binder Jetting Technology

Conference paper

https://repositories.lib.utexas.edu//bitstreams/1329182a-eca5-470a-9bed-f0ab8c5ebb71/download

University of Texas at Austin

The M-Lab system from ExOne was used to fabricate 3D structures of BaTiO3 ceramic with applications that include dielectric capacitors, sensors, and integrated circuits. For this project, layer thicknesses of 15 and 30 μm and various percentages of binder saturation were used to fabricate components from powder. An organic binding agent was utilized during the printing process and later burned out at ~600°C prior to sintering. Multiple building parameters and sintering profiles were analyzed and compared in an attempt to obtain dense parts while examining shrinkage percentage variations.

['Rhodes, Andrew', 'Smith, Tyler', 'Sharpe, Christian', 'Kunc, Vlastimil', 'Duty, Chad']

2023-01-20T16:49:50Z

2023-01-20T16:49:50Z

2022

Mechanical Engineering

['https://hdl.handle.net/2152/117265', 'http://dx.doi.org/10.26153/tsw/44146']

eng

2022 International Solid Freeform Fabrication Symposium

Open

LFAM

Analysis of Fiber Attrition and Mechanical Performance in Large-Format Additive Manufacturing of Long-Fiber Reinforced Polymer Composites

Conference paper

https://repositories.lib.utexas.edu//bitstreams/c9008ad8-78ca-454a-849d-052bd8c36564/download

Understanding the residual fiber length of discontinuous fiber-reinforced thermoplastics in large-format additive manufacturing (LFAM) is of significant interest since the residual fiber length influences the mechanical properties of the final part. Currently, the attrition of long fiber reinforcement during screw-extrusion LFAM is an understudied subject, although the residual fiber length is among the most important microstructural properties of fiber-reinforced composites. A contributing factor the lack of focus in this area is the questionability and variety of convoluted fiber measurement methods. This study evaluates the relationship between printing speed, the final fiber length, and resultant mechanical properties for 4 mm pultruded thermoplastic polyurethane (TPU) pelletized feedstock and seeks to fully document a fiber length distribution (FLD) measurement method. Samples were printed at several processing speeds and subjected to fiber length analysis and tensile testing. Fiber length analysis was performed using a combination of novel and proven techniques for improved repeatability and reliability of results. This study seeks to improve understanding in the choice of machine design, material selection, and processing parameters for optimal mechanical properties.

['Cholewa, S.', 'Jacksch, A.', 'Drummer, D.']

2024-03-25T22:01:08Z

2024-03-25T22:01:08Z

2023

Mechanical Engineering

['https://hdl.handle.net/2152/124310', 'https://doi.org/10.26153/tsw/50918']

en_US

2023 International Solid Freeform Fabrication Symposium

Open

['flow', 'polymer', 'laser', 'powder bed', 'manufacturing', 'engineering', '2023 Solid Freeform Fabrication Symposium']

Analysis of Flow Additives in Laser-Based Powder Bed Fusion of Polymers: Implications for Flow Behavior, Processing, Temperature Profile, and Part Characteristics

Conference paper

https://repositories.lib.utexas.edu//bitstreams/6c4f9f85-4d9a-4bc9-966c-df447ff87c94/download

University of Texas at Austin

Powder bed fusion of polymers requires the use of flow additives to ensure adequate flowability of the feedstock material. However, information regarding flow additives and their load is limited, as is an understanding of their impact on processing conditions. This study investigates the flow behavior using static and dynamic measurements under process conditions, focusing on the influence of flow additives. Subsequently, processing studies are conducted using thermography to analyze the laser-material interaction. The characteristics of parts produced from Polypropylene and Polyamide 12 systems are also examined. The findings of this research enhance the understanding of the impact of flow additives on the processing conditions of laser-based powder bed fusion of polymers, potentially leading to optimized process parameters and improved part quality and mechanical properties.

Cunico, Marlon Wesley Machado

2021-11-04T18:14:34Z

2021-11-04T18:14:34Z

2017

Mechanical Engineering

['https://hdl.handle.net/2152/89994', 'http://dx.doi.org/10.26153/16915']

eng

2017 International Solid Freeform Fabrication Symposium

Open

['additive manufacturing', 'flexible manufacturing systems', 'production']

Analysis of Hybrid Manufacturing Systems Based on Additive Manufacturing Technology

Conference paper

https://repositories.lib.utexas.edu//bitstreams/72e89985-b1c1-41a8-ad6a-e3bfb9f83a30/download

University of Texas at Austin

Along the last year, additive manufacturing technologies has been proving to be a real game changer in several market segments. Nevertheless, the main foundation of production and flexible manufacturing systems generally considers classical technologies. For that reason, the present work aim to propose and investigate manufacturing systems which includes additive manufacturing technologies as part of the main or secondary production flow. As result, it was identified that several marketing segments, types of components and different annual volumes tend to be better attended by hybrid flexible manufacturing systems which includes additive manufacturing technologies.

['Pitz, K.', 'Anderl, R.']

2021-11-18T16:44:28Z

2021-11-18T16:44:28Z

2019

Mechanical Engineering

['https://hdl.handle.net/2152/90422', 'http://dx.doi.org/10.26153/tsw/17343']

eng

2019 International Solid Freeform Fabrication Symposium

Open

['dentures', 'CAD', 'CAM', 'layering strategies', 'thickness measurements']

Analysis of Layer Arrangements of Aesthetic Dentures as a Basis for Introducing Additive Manufacturing

Conference paper

https://repositories.lib.utexas.edu//bitstreams/63956822-c032-456c-9d57-856ef0b27503/download

University of Texas at Austin

Aesthetic dentures are highly individual products, needing to adapt to the patient’s natural dentition in both color and shape. In general, dentures are geometrically complex structures, consisting of several layers of different materials, which are applied consecutively. This is why efforts are being made to introduce additive manufacturing into the production process of aesthetic dentures which is to date largely based on manual work of skilled professionals. In order to successfully apply additive manufacturing accurate models of the denture to be produced are essential. In this paper the layer arrangements of dental crowns from real patient cases are analyzed. Different approaches, based on normal vectors, cylindrical coordinates, spherical coordinates and paraxial rays, are compared to each other. The emphasis of this comparison lies on transferring layering strategies from analyzed patient cases to future patient cases where the geometry might be slightly different but a similar optical impression is desired. The most suitable approach for this purpose has been identified, implemented and tested.

['Johnston, Scott R.', 'Reed, Marques', 'Wang, Hongqing V.', 'Rosen, David W.']

2020-03-02T14:58:38Z

2020-03-02T14:58:38Z

2006

Mechanical Engineering

['https://hdl.handle.net/2152/80129', 'http://dx.doi.org/10.26153/tsw/7150']

eng

2006 International Solid Freeform Fabrication Symposium

Open

Stereolithography Apparatus

Analysis of Mesostructure Unit Cells Comprised of Octet-truss Structures

Conference paper

https://repositories.lib.utexas.edu//bitstreams/1b33effd-6aba-4f63-a72b-b76eefdb89ea/download

A unit truss finite element analysis method allowing non-linear deformation is employed to analyze a unit cell comprised of n 3 octet-truss structures for their stiffness and displacement compared to their relative density under loading. Axial, bending, shearing, and torsion effects are included in the analysis for each strut in the octet-truss structure which is then related to the mesostructure level (unit cell). The versatility of additive manufacturing allows for the fabrication of these complex unit cell truss structures which can be used as building blocks for macro-scale geometries. The finite element calculations are compared to experimental results for samples manufactured on a Stereolithography Apparatus (SLA) out of a standard resin.

['Lopes, Amit J.', 'Ramos, Luis C.', 'Saenz, David', 'Morton, Philip', 'Terrazas, Cesar A.', 'Choudhuri, Ahsan', 'Wicker, Ryan']

2021-11-30T20:46:03Z

2021-11-30T20:46:03Z

2019

Mechanical Engineering

['https://hdl.handle.net/2152/90541', 'http://dx.doi.org/10.26153/tsw/17460']

eng

2019 International Solid Freeform Fabrication Symposium

Open

['powder removal', 'Ti-6Al-4V', 'electron beam powder bed fusion', 'electron beam melting']

Analysis of Powder Removal Methods for EBM Manufactured Ti-6Al-4V Parts

Conference paper

https://repositories.lib.utexas.edu//bitstreams/cc789d5f-dbb5-45cc-b3af-2770523a2fed/download

University of Texas at Austin

Additive Manufacturing (AM) allows the creation of complex geometries that are not achievable through subtractive manufacturing. Regardless of the advantages that 3D Printing offers, technology limitations often constraints the desired geometry. When fabricating Ti-6Al4V parts in Electron Beam Powder Bed Fusion (EBPBF), the electron beam is used to preheat the powder bed to maintain the desired temperature gradient during the build. One disadvantage of EBPBF during the fabrication process is the trapped powder within internal channels gets partially sintered and require extra processing. This research analyzes several powder removal methods and compares their effectiveness. This work utilizes two types of samples, both made of Ti-6Al4V in EBPBF; with geometries that resemble typical features when designing a component. The target weight of each cylinder is calculated based on dimensions and effective density of the sample. The results summarizing the effectiveness of each method are presented.

['Mireles, Jorge', 'Adame, Arturo', 'Espalin, David', 'Medina, Francisco', 'Winker, Rob', 'Hoppe, Terry', 'Zinniel, Bob', 'Wicker, Ryan']

2021-10-04T21:16:01Z

2021-10-04T21:16:01Z

2011

Mechanical Engineering

['https://hdl.handle.net/2152/88348', 'http://dx.doi.org/10.26153/tsw/15287']

eng

2011 International Solid Freeform Fabrication Symposium

Open

['Additive Manufacturing', 'fluid pressure', 'Fused Deposition Modeling', 'sealant', 'end-use applications']

Analysis of Sealing Methods for FDM-fabricated Parts

Conference paper

https://repositories.lib.utexas.edu//bitstreams/90d5327d-5b37-431e-b5a6-4ca3ac8f19c2/download

University of Texas at Austin

As a result of the layer-by-layer deposition characteristics of Additive Manufacturing (AM) processes, fabricated parts exhibit limiting qualities and have yet to achieve the requirements for end-use applications. Specifically, the use of AM-fabricated parts in fluid pressure applications is limited due to part porosity as well as non-optimized building variables (e.g., build orientation and material properties). In an effort to extend the use of AM in more applications involving fluid pressure, parts manufactured with Fused Deposition Modeling (FDM) were sealed with a variety of sealants and tested under applied pressure. Eleven sealants with diverse chemical properties were applied to multiple geometries of FDM-fabricated pressure caps through brushing or vacuum infiltration. The caps were installed on pressure vessels and subsequently tested while safety precautions were taken to avoid catastrophic failure (i.e., exploding) caused by pressure differentials. Results of the testing provides a sealing method using BJB TC-1614 that enables FDM-fabricated parts to withstand pressures up to ~276 kPa (40psi) through brushing and ~138 kPa (20 psi) through vacuum infiltration. Other noteworthy sealants (Minwax Sanding Sealer, Minwax Polyurethane Oil Based, PRO Finisher Water-Base Polyurethane) that are readily available to consumers and easy to apply (i.e. no mixing ratios to follow, long working times) also had notable results by withstanding pressures up to ~207 kPa (30 psi). In addition, an analysis on dimensional changes was performed to determine the absolute difference between as-built and surface-treated parts. Parts that were infiltrated with BJB TC-1614 showed less dimensional changes (average absolute change of 0.104 mm) than parts that were brushed (average absolute change of 0.231 mm) however one-part sealants had smaller dimensional changes (maximum absolute change for one-part sealants of 0.065 mm for infiltration and 0.171 for brushing) with noteworthy results in pressure testing. Benefits of filling voids within FDM-manufactured parts enables end-use applications such as hermetic housings for biomedical devices and pipes/covers for thermodynamic systems such as heat exchangers.

['Szucs, Tamas D.', 'Brabazon, Dermot']

2020-03-10T15:17:21Z

2020-03-10T15:17:21Z

2007

Mechanical Engineering

['https://hdl.handle.net/2152/80215', 'http://dx.doi.org/10.26153/tsw/7234']

eng

2007 International Solid Freeform Fabrication Symposium

Open

Tissue Engineering

Analysis of the Effects of 3DP Parameters on Part Feature Dimensional Accuracy

Conference paper

https://repositories.lib.utexas.edu//bitstreams/69be293d-1c59-4a0a-9067-76ca858d519f/download

3D printing (3DP) is a widely investigated scaffold manufacturing process for Tissue Engineering (TE). Useful scaffold geometries should have high porosity (60-80%) with small (100-500 μm) interconnected pores. Therefore dimensional accuracy on the micron level is one of the crucial parameters of the bone scaffolds. Previously it was shown that the behavior of scaffold geometries can be well simulated with Finite Element Modeling (FEM) however the prediction of actual strength and stiffness values are dependent on dimensional accuracy. This accuracy is in turn dependent on several parameters including particle size and shape, powderbinder interaction, and machine setup. In this work different scaffold strut sizes (0.3 - 0.5 mm) have been fabricated using two different plaster powders (zp102 and zp130) with variations in shell saturation levels, part print position, and part print orientation. The parameters for each powder were analyzed using a full 35 factorial experimental design. It was found that the part size and orientation had a significant effect on the dimensional accuracy while the influence of the shell saturation and position was relatively small. The results allow for better dimensional specification for scaffold geometry fabrication by defining the process parameters in 3DP that may be used further in scaffold accuracy optimization.

['Jamal, N.M.', 'Dalgarno, K.W.']

2019-10-24T17:41:54Z

2019-10-24T17:41:54Z

2002

Mechanical Engineering

['https://hdl.handle.net/2152/77404', 'http://dx.doi.org/10.26153/tsw/4493']

eng

2002 International Solid Freeform Fabrication Symposium

Open

Viscoelasticity

Analysis of the Influence of Viscoelasticity in Curl Development in SLS

Conference paper

https://repositories.lib.utexas.edu//bitstreams/a60491fb-caba-4435-8ebc-97a123fc11c2/download

Curl in selectively laser sintered parts arises mainly from thermal distortion of parts within the build volume during processing. This results in nominally flat surfaces which lie horizontally in the part bed becoming warped. This paper reports on the use of finite element techniques to model curl development in polymer materials, and in particular on the influence of viscoelasticity on how curl develops. The development of time-dependent material models is reported, and the results of the implementation of these models presented, together with a comparison of the results with experimental data.

['Hoppe, B.', 'Enk, S.', 'Schleifenbaum, J.H.']

2021-11-18T18:23:23Z

2021-11-18T18:23:23Z

2019

Mechanical Engineering

['https://hdl.handle.net/2152/90456', 'http://dx.doi.org/10.26153/tsw/17377']

eng

2019 International Solid Freeform Fabrication Symposium

Open

['laser powder bed fusion', 'schlieren', 'shadowgraph', 'process development', 'shielding gas flow', 'process stability', '316L stainless steel']

Analysis of the Shielding Gas Dependent L-PBF Process Stability by Means of Schlieren and Shadowgraph Techniques

Conference paper

https://repositories.lib.utexas.edu//bitstreams/2ab19423-1f87-496e-84db-218ae4a76bf5/download

University of Texas at Austin

Ensuring a robust and reproducible Laser Powder Bed Fusion (L-PBF) process depends on the design of the shielding gas flow in the corresponding manufacturing system. The gas flow assures the removal of particles from the process zone that emerge from the interaction with the laser irradiation. Minor disturbances may influence the stability of the L-PBF-Process and cause defects in final parts produced. The objective of this work comprises visualizing the convection processes and particle dynamics to analyze their influence on process stability. Therefore, a high speed camera based Schlieren and Shadowgraph setup is used to visualize convection flows as well as trajectories of metallic condensate and particles with up to 10,568 fps. This arrangement allowed investigating the influence of shielding gas flow conditions on single melt tracks. Corresponding results and studies on the interaction between laser irradiation and particles in varying shielding gas flow conditions are contents of this work.

['Lee, Cheol H.', 'Thomas, Charles L.']

2018-12-06T22:23:40Z

2018-12-06T22:23:40Z

1997

Mechanical Engineering

doi:10.15781/T28W38N9T

http://hdl.handle.net/2152/71436

eng

1997 International Solid Freeform Fabrication Symposium

Open

['CAD', 'manufacturability']

An Analysis Technique for Layered Manufacturing Based on Quasi-Wavelet Transforms

Conference paper

https://repositories.lib.utexas.edu//bitstreams/aacf7bed-19c8-4c46-892b-d0149cb090b9/download

An analysis technique based on the Wavelet transform (WT) has been recently introduced that allows the spatial frequency content of objects produced by layered manufacturing (LM) techniques to be interpreted in terms ofmanufacturable features. (Lee and Thomas, 1997) Using Haar's wavelet as a basis function, layers with vertical edges are modeled exactly. Using analysis, a 3D model can be transformed, filtered, and inverse transformed resulting in an image ofthe part as it would look if constructed from layers of a specific thickness. In order to extend this analysis to construction techniques using higher order edges (ruled surface edges or curved edges), the quasi-wavelet transform (QWT) is introduced. QWT analysis is conceptually the same as WT analysis, except that the basis function can be selected by the user, allowing exact analysis of layered manufacturing techniques using higher order construction algorithms. This work is supported by a grant from the University ofUtah Research Foundation.

Cunico, Marlon Wesley Machado

2021-11-03T20:19:15Z

2021-11-03T20:19:15Z

2017

Mechanical Engineering

https://hdl.handle.net/2152/89922

eng

2017 International Solid Freeform Fabrication Symposium

Open

['additive manufacturing', 'finite element method', 'anisotropy']

Analytical and Experimental Characterization of Anisotropic Mechanical Behaviour of Infill Building Strategies for Fused Deposition Modelling Objects

Conference paper

https://repositories.lib.utexas.edu//bitstreams/1e8c1d21-9e0d-453a-acfc-daf30e3ff795/download

University of Texas at Austin

As consequence of the 3d printing extraordinary rising along the last years, product development fields are facing new challenges. In addition, it is notary that low cost additive manufacturing, as such fused filament fabrication (FFF), result in objects with anisotropic mechanical behaviour. Nevertheless, there is still lacking studies that highlight a proper specification of those mechanical proprieties. For that reason, the main goal of this work is to present a mechanical characterization of anisotropic behaviour of FFF objects as a function of infill strategy using a finite element method. In this work, the main effect of building parameters were investigated in addition the identification of generalized elasticity and failure mode formulations. By the end, the general recommendation for objects building was sketched in order to support new strength based developments.

['Schonrath, Hanna', 'Wegner, Jan', 'Frey, Maximilian', 'Soares Barreto, Erika', 'Elspab, Arno', 'Schnell, Norman', 'Erdmann, Benjamin H.R.', 'Neises, Julian', 'Ellendt, Nils', 'Busch, Ralf', 'Kleszczynski, Stefan']

2024-03-26T16:56:27Z

2024-03-26T16:56:27Z

2023

Mechanical Engineering

['https://hdl.handle.net/2152/124372', 'https://doi.org/10.26153/tsw/50980']

en_US

2023 International Solid Freeform Fabrication Symposium

Open

['bulk metallic glasses', 'additive manufacturing', 'PBF-LB/M', 'Rosenthal model']

Analytical Modeling of Cooling Rates in PBF-LB/M of Bulk Metallic Glasses

Conference paper

https://repositories.lib.utexas.edu//bitstreams/bd4ba854-85d5-43e8-b351-4026847cb444/download

University of Texas at Austin

Additive manufacturing through laser powder bed fusion (PBF-LB/M) inheres great potential for the processing of bulk metallic glasses (BMGs). The size-independent high cooling rates during the process benefit the fabrication of large and elaborate amorphous components. Albeit, partial crystallization poses a challenge in additively manufactured BMGs, potentially limiting the resulting mechanical properties. In this matter, the complex thermal history during processing often states a remaining uncertainty. Besides in situ measurements and numerical estimations, analytical models can be used to achieve a deeper understanding of the transient temperature evolution. In this work, an iterative solution to the analytical Rosenthal equation is developed and applied to ZrCuAlNb- and CuTiZrNi-BMGs to predict melt pool dimensions and cooling rates during PBF-LB/M. Therefore, temperature-dependent thermal properties are determined via laser flash measurements. The effective absorptivity of the two materials is measured, and single-line experiments were performed as a validation for the approach.

['Lindermann, C.', 'Jahnke, U.', 'Moi, M.', 'Koch, R.']

2021-10-05T18:39:19Z

2021-10-05T18:39:19Z

2012

Mechanical Engineering

['https://hdl.handle.net/2152/88402', 'http://dx.doi.org/10.26153/tsw/15341']

eng

2012 International Solid Freeform Fabrication Symposium

Open

['additive manufacturing', 'product lifecycle', 'activity based costing', 'cost drivers']

Analyzing Product Lifecycle Costs for a Better Understanding of Cost Drivers in Additive Manufacturing

Conference paper

https://repositories.lib.utexas.edu//bitstreams/1e98472c-0a13-4fed-8db5-c965d9192dd1/download

University of Texas at Austin

The costs of additive manufactured parts often seem too high in comparison to those of traditionally manufactured parts, as the information about major cost drivers, especially for additive manufactured metal parts, is weak. Therefore, a lifecycle analysis of additive manufactured parts is needed to understand and rate the cost drivers that act as the largest contributors to unit costs, and to provide a focus for future cost reduction activities for the Additive Manufacturing (AM) technology. A better understanding of the cost structure will help to compare the AM costs with the opportunity costs of the classical manufacturing technologies and will make it easier to justify the use of AM manufactured parts. This paper will present work in progress and methodology based on a sample investigated with business process analysis / simulation and activity based costing. In addition, cost drivers associated with metal AM process will be rated.

['Yang, Zhuo', 'Lu, Yan', 'Lane, Brandon', 'Kim, Jaehyuk', 'Ndiaye, Yande', 'Krishnamruty, Sundar']

2021-12-01T22:32:45Z

2021-12-01T22:32:45Z

2021

Mechanical Engineering

['https://hdl.handle.net/2152/90640', 'http://dx.doi.org/10.26153/tsw/17559']

eng

2021 International Solid Freeform Fabrication Symposium

Open

['remelting conditions', 'melt pool monitoring', 'data fusion', 'overhang build', 'powder bed fusion']

Analyzing Remelting Conditions based on In-Situ Melt Pool Data Fusion for Overhang Building in Powder Bed Fusion Process

Conference paper

https://repositories.lib.utexas.edu//bitstreams/fcd09475-e9b1-4fe3-a93b-c67017633e90/download

University of Texas at Austin

Coaxial melt pool monitoring (MPM) images provide in-depth insights into the building process of laser powder bed fusion additive manufacturing. An in-situ MPM image captures the independent melting condition at specific positions within each build layer. However, identifying material defects such as horizontal lack-of-fusion using individual, discontinuous MPM images poses multiple challenges. This paper builds upon the authors’ previous work on data registration and data fusion to analyze material remelting conditions based on co-axial MPM images. MPM data are fused to formulate layerwise remelting ‘maps’ to evaluate printing quality. A 3D part with various overhang features was built to verify the method. A regular layer with solid support from the previous layers has around 30 % remelting ratio for the given laser scan conditions. In contrast, overhang regions remelted at about 10 % with the same process setting, whichis too low to provide sufficient material fusion, resulting in lack-of-fusion between melting tracks. The negative impact in remelting would not immediately disappear in subsequent layers following the overhang regions. Results shows three additional layers are required to fully recover the remelting condition back to normal. The remelting results from MPM are also visible within layerwise optical images of the same surface.

['de Smit, Bram', 'Broek, Han J.']

2020-02-17T14:42:54Z

2020-02-17T14:42:54Z

2004

Mechanical Engineering

['https://hdl.handle.net/2152/79999', 'http://dx.doi.org/10.26153/tsw/7024']

eng

2004 International Solid Freeform Fabrication Symposium

Open

Extruded Polystyrene Foam

Analyzing the Cutting Process of a Heated Flexible Blade in Extruded Polystyrene Foam

Conference paper

https://repositories.lib.utexas.edu//bitstreams/9eeff267-8a09-4c50-9f58-f6b46bcc52b7/download

For the “Free Form Thick Layered Object Manufacturing” technology that is being developed at the Delft University, it is vital that Extruded Polystyrene Foam (XPS) can be cut accurately with a heated blade. The shape of the blade is actively controlled during the cutting process, which results in double curved cutting surfaces. In order to make this cutting process controllable it must be known how the cutting behavior is under varying conditions, like cutting speed, cutting angle and heating power. The authors executed a range of experiments, analyzed the results and describe a practical model for the cutting process of XPS with a heated blade.

['Niebling, F.', 'Otto, A.', 'Geiger, M.']

2019-10-24T17:54:50Z

2019-10-24T17:54:50Z

2002

Mechanical Engineering

['https://hdl.handle.net/2152/77409', 'http://dx.doi.org/10.26153/tsw/4498']

eng

2002 International Solid Freeform Fabrication Symposium

Open

Macroscopic

Analyzing the DMLS Process by a Macroscopic FE-Model

Conference paper

https://repositories.lib.utexas.edu//bitstreams/8be69f88-0c09-4d79-a0d5-a8526a6a0722/download

The presented macroscopic FE-model allows to analyze the thermal fields and the resulting stress built up during Selective Laser Sintering. Process and material parameters are focused on Direct Metal Laser Sintering (DMLS). The FE-model is introduced and the assumptions for the model are given. Three different geometric models are discussed. The 3Dmodel shows the sintering of a single line, whereas 2D-models are used for longitudinal and crosscuts of the sintering process. Aim of the investigation is a more basic knowledge about the process, which will lead to a stabilization and optimization of the process.

These investigations were financially supported by the DFG.

['Hernandez, R.', 'Slaughter, D.', 'Whaley, D.', 'Tate, J.', 'Asiabanpour, B.']

2021-10-28T14:15:19Z

2021-10-28T14:15:19Z

2016

Mechanical Engineering

https://hdl.handle.net/2152/89645

eng

2016 International Solid Freeform Fabrication Symposium

Open

['tensile properties', 'compressive properties', 'flexural properties', 'ABS plastics', 'P430', '3D printing', 'printing orientation', 'fused deposition modeling']

Analyzing the Tensile, Compressive, and Flexural Properties of 3D Printed Abs P430 Plastic Based on Printing Orientation Using Fused Deposition Modeling

Conference paper

https://repositories.lib.utexas.edu//bitstreams/83296808-1f7d-4da6-9578-a5c0f923cecb/download

University of Texas at Austin

To achieve the optimum functionality and mechanical properties in the AM-based parts, it is vital to fully characterize parts under static mechanical loadings (tension, compression, and flexure) that are built in different orientations. This research reports the results of the compression (ASTM standard D695), 4-point flexure (ASTM D790), and tensile (ASTM D 638 Type I) tests on the ABS plastic specimens that are designed according to the ASTM standards and are built in different orientations using the uPrint SE Plus 3D printer. This study examined the effects that printing 3D parts in different orientations (build angles) has on the mechanical properties of ABS P430 plastic. A total of 45 samples (15 tension, 15 compression, and 15 flexure) were printed in 5 orientations; 0 degrees in the XY plane, 45 degrees in the XY plane, 90 degrees in the XY plane, 45 degrees in the Z plane, and 90 degrees in the Z plane. The hypothesis was that the samples printed 0 degrees in the XY plane would be the strongest in compression and flexure, and also have the greatest modulus of elasticity. The samples printed 90 degrees in the XY plane were predicted to be the strongest in tension, having the largest tensile strength and lowest modulus of elasticity. The findings showed that printing 90 degrees in the XY plane resulted in the highest tensile strength compared to the other orientations, but not by a significant margin. Printing 0 degrees in the XY plane significantly increased the compressive and flexure strengths of the material compared to other orientations.