Academic literature on the topic 'Metallic Additive Manufacturing'
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Journal articles on the topic "Metallic Additive Manufacturing":
Jadhav, Nisha Ramesh. "Metallic Additive Manufacturing." International Journal for Research in Applied Science and Engineering Technology 10, no. 2 (February 28, 2022): 66–67. http://dx.doi.org/10.22214/ijraset.2022.40188.
Costa, José, Elsa Sequeiros, Maria Teresa Vieira, and Manuel Vieira. "Additive Manufacturing." U.Porto Journal of Engineering 7, no. 3 (April 30, 2021): 53–69. http://dx.doi.org/10.24840/2183-6493_007.003_0005.
Zhang, Chaoqun, Hongying Yu, Dongbai Sun, and Wen Liu. "Ultrasonic Additive Manufacturing of Metallic Materials." Metals 12, no. 11 (November 8, 2022): 1912. http://dx.doi.org/10.3390/met12111912.
Prashanth, Konda, Sergio Scudino, Riddhi Chatterjee, Omar Salman, and Jürgen Eckert. "Additive Manufacturing: Reproducibility of Metallic Parts." Technologies 5, no. 1 (February 22, 2017): 8. http://dx.doi.org/10.3390/technologies5010008.
Calignano, Flaviana. "Additive Manufacturing (AM) of Metallic Alloys." Crystals 10, no. 8 (August 15, 2020): 704. http://dx.doi.org/10.3390/cryst10080704.
XIONG, FeiYu, JiaWei CHEN, ChenYang HUANG, and YanPing LIAN. "Numerical simulation on metallic additive manufacturing." SCIENTIA SINICA Physica, Mechanica & Astronomica 50, no. 9 (August 13, 2020): 090007. http://dx.doi.org/10.1360/sspma-2020-0182.
Mohanty, Shalini, and Konda Gokuldoss Prashanth. "Metallic Coatings through Additive Manufacturing: A Review." Materials 16, no. 6 (March 14, 2023): 2325. http://dx.doi.org/10.3390/ma16062325.
Sarker, Avik, Martin Leary, and Kate Fox. "Metallic additive manufacturing for bone-interfacing implants." Biointerphases 15, no. 5 (September 2020): 050801. http://dx.doi.org/10.1116/6.0000414.
Zhang, Yi, Linmin Wu, Xingye Guo, Stephen Kane, Yifan Deng, Yeon-Gil Jung, Je-Hyun Lee, and Jing Zhang. "Additive Manufacturing of Metallic Materials: A Review." Journal of Materials Engineering and Performance 27, no. 1 (May 24, 2017): 1–13. http://dx.doi.org/10.1007/s11665-017-2747-y.
Alabort, Enrique, Daniel Barba, and Roger C. Reed. "Design of metallic bone by additive manufacturing." Scripta Materialia 164 (April 2019): 110–14. http://dx.doi.org/10.1016/j.scriptamat.2019.01.022.
Dissertations / Theses on the topic "Metallic Additive Manufacturing":
Coffigniez, Marion. "Additive manufacturing of 3D architectured metallic biomaterials by robocasting." Thesis, Lyon, 2021. http://www.theses.fr/2021LYSEI007.
Beyond the personalisation aspect that it can bring to the medical field, additive manufacturing also gives access to the elaboration of cellular structures. These structures, with controlled porosity, make it possible both to modulate the mechanical properties of the object and to promote the cellular invasion necessary in tissue engineering. Among the metals commonly used in orthopaedic surgery, titanium alloys are those with the rigidity least distant from that of bone. This study therefore focuses on the development of structures made of Ti6-Al-4V, but also of magnesium since it has the advantage of being resorbable in the body. The scaffolds are obtained by robocasting, a process consisting of extruding, layer by layer, a pasty ink made up of powder and binder. The structures have then to be debinded and sintered at high temperature to achieve their final properties. For Ti-6Al-4V structures, a parametric study is carried out to evaluate the possibilities and limits of the process in terms of structures (and microstructures), chemical compositions and mechanical properties obtained. After optimisation, it is possible to obtain parts with two levels of interconnected porosities (intra-filament (interconnected) microporosity, beneficial for cell adhesion according to the literature, and drawn macropores), keeping a specific yield strength higher than that of bone (105 MPa.cm³/g) and a Young's modulus close to that of bone (28-30 GPa). An intra-filament porosity gradient can also be obtained by varying the powder size within a single part. Concerning magnesium, a binder compatible with the reactivity of the powder (ethanol base) has been identified and the first steps of the process (printing, debinding) are therefore quite feasible for this material. However, conventional sintering of (pure) magnesium is complicated by its reactivity. Alternative sintering methods are therefore being investigated (liquid phase sintering, Spark Plasma Sintering)
Karmakar, Mattias. "Additive Manufacturing Stainless Steel for Space Application." Thesis, Luleå tekniska universitet, Materialvetenskap, 2019. http://urn.kb.se/resolve?urn=urn:nbn:se:ltu:diva-72901.
El, Mouhib Sabrina. "Effect of Stainless Steel Additive Manufacturing On Heat Conductivity and Urea Deposition." Thesis, KTH, Materialvetenskap, 2020. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-287314.
Hydroforming är den tillverkningsprocess Scania använder för att producera avgasrör som har en komplex form och hög hållbarhet. Selektiv lasersmältning är den process som används av konstruktörer för att skriva ut prototyprör och utföra utsläppstester före massproduktion. Resultat från tidigare utsläppstes- ter på Scania visade en överlägsen prestanda för 3D-tryckta rör jämfört med hydroformade komponenter, eftersom 3D-tryckta rör kunde överföra värme snabbare än hydroformade rör. För att förstå orsaken bakom denna skillnad undersöks effekten av selektiva lasersmältningsparametrar som energitäthet, relativ densitet, kornstorlek och värmeledningsförmåga. Dessa egenskaper har direkt inverkan på värmeöverföringen. 10 prover tillverkades med samma laserkraft och skikttjocklek, men med olika kombinationer av skanningshastighet och kläckavstånd. Proverna utsattes sedan för en mikrostrukturell analys med hjälp av ett optiskt mikroskop, samt genomsnittlig kornstorleksmätning med hjälp av bildanalysprogramvaran Imagej. Densiteten för varje prov mättes med Archimedesmetoden. Måttlig korrelation kunde identifieras mellan energitätheten och relativ densitet. Ingen rangordning av de selektiva lasersmältningsparametrarna med avseende på bildning av den högsta densiteten uppnåddes på grund av de höga osäkerhetsfaktorer som är involverade i densitetsmättekniken. Värmeledningsförmågan mättes med hjälp av den endimensionella värmeflödesekvationen, med en lämplig experimentell uppställning. Värmeledningsförmågan tycks påverkas mer av tryckskiktens relativa densitet och riktning än energidensiteten och kornstorleken. Denna slutsats är inte statistiskt signifikant på grund av hög osäkerhet i mätningen av värmeledningsförmåga. Mer avancerade och noggranna teknologier måste användas i framtiden för att mäta både densitet och värmeledningsförmåga, för att hitta de mest lämpliga selektiva lasersmältningsparametrarna för Scanias prototyprör.
Gullapalli, Vikranth. "Study of Metal Whiskers Growth and Mitigation Technique Using Additive Manufacturing." Thesis, University of North Texas, 2015. https://digital.library.unt.edu/ark:/67531/metadc804972/.
Zavala, Arredondo Miguel Angel. "Diode area melting : use of high power diode lasers in additive manufacturing of metallic components." Thesis, University of Sheffield, 2017. http://etheses.whiterose.ac.uk/18953/.
Hari, Vignesh. "Evaluating spreadability of metallic powders for powder bed fusion processes." Thesis, KTH, Materialvetenskap, 2020. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-283544.
Additiv tillverkning är teknologier som har stor uträckning inom flyg-, rymd och turbin industrier. Delar kan bli tillverkade direkt genom att lagervis addera material på varandra. En nyckelaspekt som är kritisk till kvalitén av den slutgiltiga komponenten är egenskaperna hos pulvret. De allmänna teknikerna för pulverkarakterisering hjälper till att förutspå flytförmågan hos pulver men relaterar ej till dess spridningsförmåga. För att kunna skapa högkvalitativa skikt av metallpulver är det nödvändigt att förstå pulvrets spridningsförmåga inom pulverbädds baserade additiva tillverkningsprocesser. Målet med denna studie var att skapa ett mått för spridningsförmågan genom bild- och massanalys. Ett experimentellt upplägg i labbskala konstruerades för att efterlikna en pulverbädds baserad additiv tillverkningsprocess. Effekten av bladets hastighet och lagrets tjocklek på fem olika pulver studerades genom användandet av de föreslagna mätetalen. De framtagna mätetalen jämfördes sedan med existerande pulver karakteriseringsmetoder såsom FT-4 Rheometer och pulver analys med hjälp av roterande trumma. Slutligen så jämförs flytbarhets parametrarna med spridbarhets mätetalen. Det visar sig att bildanalysen är tillräckligt bra på att förutspå spridningsförmågan hos pulvret när processparametrarna låtes vara varierande. Mer specifikt så var förhållandet mellan pulvrets yta och det konvexa höljet stort för pulver som visar bra spridning. De framtagna procent värden från massanalysdiagrammen fluktuerar vid olika processparametrar hos de olika pulvren, vilket kan betyda att massanalys kan vara ett potentiellt sätt för att mätta spridningsförmågan hos pulver. Det är förväntat att dessa föreslagna mätetal kommer vara början för utveckling av ytterligare karakteriseringstekniker. Till exempel, för att studera densiteten och tjockleken hos ett lager skulle man kunna skapa homogena lager. Vi förutser att dessa mätetal kommer att bli använda för att skapa standardiseringstekniker för att definiera och kvantifiera spridningsförmågan hos ett pulver och genom detta förbättra kvaliteten av den additiva tillverkningsprocessen.
Jönsson, David, and Mir Kevci. "Geometrical accuracy of metallic objects produced with Additive or Subtractive Manufacturing: a comparative in-vitro study." Thesis, Malmö högskola, Odontologiska fakulteten (OD), 2017. http://urn.kb.se/resolve?urn=urn:nbn:se:mau:diva-19934.
Purpose: To evaluate the production tolerance of objects produced by additive manufacturing systems (AM) for usage in dentistry and to compare with subtractive manufacturing system (SM) through reverse engineering. Materials and methods: Ten specimens of two geometrical objects were produced by five different AM machines and one SM machine. Object A mimics an inlay-shaped object, meanwhile object B reflects a four-unit bridge model. All the objects were divided into different measuring-axis; X, Y and Z. Measurements were performed with validated and calibrated equipment. Linear distances were measured with a digital calliper while corner radius and angle were measured with a digital microscope. Results: None of the additive manufacturing or subtractive manufacturing groups presented a perfect match to the CAD-file regarding all parameters included in present study. Considering linear measurements, the standard deviation for subtractive manufacturing group were consistent in all axis, except for X- and Y-axis in object A and Y-axis for object B. Meanwhile additive manufacturing groups had a consistent standard deviation in X- and Y- axis but not in Z-axis. Regarding corner radius measurements, SM group overall had the best accuracy for both object A and B comparing to AM groups. Conclusion: Within the limitations of this in vitro study, results support the hypothesis, considering AM had preferable capability to re-create complex and small geometry compare to SM. Meanwhile, SM were superior producing simple geometry and linear distances. Further studies are required to confirm these results.
Sjöström, Julia. "Linkage of Macro- and Micro-scale Modelling Tools for Additive Manufacturing." Thesis, KTH, Materialvetenskap, 2020. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-283603.
dditiva tillverkningsmetoder för stål tävlar mot kommersiell produktion i en ökande takt. Geometrifriheten tillsammans med hög styrka och slagseghet på grund av extrema kylhastigheter gör den här metoden intressant att använda för högpresterande komponenter. De önskvärda materialegenskaperna härstammar från den ultrafina mikrostrukturen. Processen följs ofta av en värmebehandlande härdning för att inducera utskiljningar av andra faser. Printing processen innebär dock flertalet utmaningar som exempelvis sprickbildning, porer, inneslutningar, restspänningar och förvrängningar. Det är därför intressant och viktigt att förutspå egenskaper såsom temperaturutveckling och restspänningar av den slutgiltiga komponenten för att minska tidskrävande ”trial-and-error” och onödigt materialsvin. För att länka ihop olika delar och längdskalor av processen kan ”the integrated computational materials engineering” strukturen användas där länkverktyg kopplar ihop resultat av olika längdskalor. 18Ni300 maraging stål är ett material som har använts till additivt tillverkade produkter i hög utsträckning men det finns fortfarande mycket utrymme för optimering av processen och egenskaperna. I den här avhandlingen, den ”integrated computational materials engineering” inspirerade tillvägagångssättet används för att länka processen med mikrostrukturen, vilken bestämmer egenskaperna. Temperaturutveckling påverkar kraftigt materialegenskaper, restspänningar och deformation vid additiv tillverkning. Förutsägelse av temperatur för ett selektivt lasersmält 18Ni300 stål har därför genomförts i Simufact Additive och länkats med mikrostruktursförutsägande redskapen Thermo-Calc och DICTRA. Olika maskinparametrar har undersökts och efterföljande temperaturer, kylhastigheter, segregeringar och martensitiska starttemperaturer jämförts för olika delar av geometrin. Tilläggningsvis var även restspänningar och deformationer undersökta i Simufact. Det konstaterades att högre energidensitet för lasern orsakade högre temperaturer och kylhastighet vilket generellt skapade mer segregeringar av legeringsämnen och lägre martensitisk starttemperatur i de intercellulära områdena. Det är däremot en gemensam påverkan av kylhastighet och temperatur vilket gör att energidensitet inte är den enskilda bestämmande parametern över segregeringarna. Genom att sänka temperaturen på basplattan uppnåddes lägre temperaturer under den martensitiska starttemperaturen vilket förenklar den martensistiska omvandlingen. Beräkningar av primär dendritisk armlängd användes för att validera kylhastigheterna. Cellstorleken överensstämde bra med litteraturen på <1 μm. Deformationer och restspänningar var väldigt små. Kalibreringarna baserades på litteraturvärden och kräver experimentella värden för att valideras. Den integrerade strukturen som demonstreras i den här avhandlingen förser en insikt i de förväntade egenskaperna av en additivt tillverkad del vilket kan minska och ersätta ”trial-and-error” metoder.
Corona, Galvan Luis. "Prototypage rapide de pièces en acier : étude du dépôt de matière et d'énergie lors de la fusion à l'arc d'un fil par le procédé MIG-CMT." Thesis, Montpellier, 2018. http://www.theses.fr/2018MONTS062/document.
A test bench specially dedicated to additive manufacturing by a new technology based on the electric arc melting of a metallic wire has been developed. This technology uses an electric arc welding process called Cold Metal Transfer (CMT) as energy source to ensure the controlled melting of the wire and the deposition of liquid metal droplets to produce mechanical parts by superposing weld beads. The developed technology was used to make specimens from a low alloyed steel wire. The influence of the many parameters controlling the arc welding source on the mechanism of wire melting and transfer of molten metal droplets to form weld beads was studied. The melting-transfer cycles of liquid metal were analyzed in particular with special interest in the energies generated during each of the cycle phases. This knowledge has made possible to find different process settings for increasing the metal deposition rate compared to the pre-recorded standard settings in the microprocessor of the CMT welding generator. Walls consisting of the superposition of a large number of weld beads were then made, and the influence of the addition of many layers on the geometry of the deposits were discussed. Finally, a method of online control of the process, based on the principle of control charts, has been developed. A detailed study of the representative waveforms of current and voltage of the melting / transfer cycle with the CMT process has allowed to identify the most relevant characteristics for detecting, from a control chart, a deviation on the process that may lead to the appearance of geometrical defects
Boissier, Mathilde. "Coupling structural optimization and trajectory optimization methods in additive manufacturing." Thesis, Institut polytechnique de Paris, 2020. http://www.theses.fr/2020IPPAX084.
This work investigates path planning optimization for powder bed fusion additive manufacturing processes, and relates them to the design of the built part. The state of the art mainly studies trajectories based on existing patterns and, besides their mechanical evaluation, their relevance has not been related to the object’s shape. We propose in this work a systematic approach to optimize the path without any a priori restriction. The typical optimization problem is to melt the desired structure, without over-heating (to avoid thermally induced residual stresses) and possibly with a minimal path length. The state equation is the heat equation with a source term depending on the scanning path. Two physical 2-d models are proposed, involving temperature constraint: a transient and a steady state one (in which time dependence is removed). Based on shape optimization for the steady state model and control for the transient model, path optimization algorithms are developed. Numerical results are then performed allowing a critical assessment of the choices we made. To increase the path design freedom, we modify the steady state algorithm to introduce path splits. Two methods are compared. In the first one, the source power is added to the optimization variables and an algorithm mixing relaxation-penalization techniques and the control of the total variation is set. In a second method, notion of topological derivative are applied to the path to cleverly remove and add pieces. eventually, in the steady state, we conduct a concurrent optimization of the part’s shape and of the scanning path. This multiphysics optimization problem raises perspectives gathering direct applications and future generalizations
Books on the topic "Metallic Additive Manufacturing":
Adaskin, Anatoliy, Aleksandr Krasnovskiy, and Tat'yana Tarasova. Materials science and technology of metallic, non-metallic and composite materials:the technology of manufacturing blanks and parts. Book 2. ru: INFRA-M Academic Publishing LLC., 2021. http://dx.doi.org/10.12737/1143897.
Additive Manufacturing (AM) of Metallic Alloys. MDPI, 2020. http://dx.doi.org/10.3390/books978-3-03943-141-0.
Joshi, Shrikant, Joel Andersson, and Robert Pederson. Additive Manufacturing of High-Performance Metallic Materials. Elsevier, 2023.
Joshi, Shrikant, Joel Andersson, and Robert Pederson. Additive Manufacturing of High-Performance Metallic Materials. Elsevier, 2023.
Gu, Dongdong. Laser Additive Manufacturing of Metallic Materials and Components. Elsevier, 2022.
Gu, Dongdong. Laser Additive Manufacturing of Metallic Materials and Components. Elsevier, 2022.
Additive Manufacturing—Nondestructive Testing—Intentionally Seeding Flaws in Metallic Parts. 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959: ASTM International, 2022. http://dx.doi.org/10.1520/iso/astmtr52906-eb.
Rafique, Muhammad Musaddique Ali. Bulk Metallic Glasses and Their Composites: Additive Manufacturing and Modeling and Simulation. de Gruyter GmbH, Walter, 2021.
Rafique, Muhammad Musaddique Ali. Bulk Metallic Glasses and Their Composites: Additive Manufacturing and Modeling and Simulation. de Gruyter GmbH, Walter, 2021.
Rafique, Muhammad Musaddique Ali. Bulk Metallic Glasses and Their Composites: Additive Manufacturing and Modeling and Simulation. de Gruyter GmbH, Walter, 2021.
Book chapters on the topic "Metallic Additive Manufacturing":
Joshi, Sanjay, Richard P. Martukanitz, Abdalla R. Nassar, and Pan Michaleris. "Metallic Feedstock." In Additive Manufacturing with Metals, 383–426. Cham: Springer International Publishing, 2023. http://dx.doi.org/10.1007/978-3-031-37069-4_14.
Marandi, Lakhindra, and Indrani Sen. "Effect of process parameters on mechanical properties of additively manufactured metallic systems." In Additive Manufacturing, 1–19. Boca Raton: CRC Press, 2022. http://dx.doi.org/10.1201/9781003258391-1.
Warton, James, Rajeev Dwivedi, and Radovan Kovacevic. "Additive Manufacturing of Metallic Alloys." In Robotic Fabrication in Architecture, Art and Design 2014, 147–61. Cham: Springer International Publishing, 2014. http://dx.doi.org/10.1007/978-3-319-04663-1_10.
Yin, Shuo, and Rocco Lupoi. "Cold Sprayed Nanostructured Metallic Deposits." In Springer Tracts in Additive Manufacturing, 135–51. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-73367-4_7.
Yang, Gaoqiang, Zheng Chen, Yaji Huang, Jingke Mo, Zhenye Kang, and Feng-Yuan Zhang. "Thermal Analysis During Metallic Additive Manufacturing." In Advanced Materials for Multidisciplinary Applications, 237–64. Cham: Springer International Publishing, 2023. http://dx.doi.org/10.1007/978-3-031-39404-1_9.
Joshi, Sanjay, Richard P. Martukanitz, Abdalla R. Nassar, and Pan Michaleris. "Properties and Characteristics of Metallic Materials Produced Using Additive Manufacturing." In Additive Manufacturing with Metals, 591–632. Cham: Springer International Publishing, 2023. http://dx.doi.org/10.1007/978-3-031-37069-4_20.
Singh, Davinder, Talwinder Singh, and Sandeep Singh. "Corrosion Performance of Additively Manufactured Metallic Biomaterials: A Review." In Additive Manufacturing of Bio-implants, 127–36. Singapore: Springer Nature Singapore, 2024. http://dx.doi.org/10.1007/978-981-99-6972-2_8.
Sankara Narayanan, T. S. N., and Hyung Wook Park. "Surface Finishing Post-treatments for Additive Manufactured Metallic Components." In Springer Tracts in Additive Manufacturing, 161–88. Cham: Springer International Publishing, 2022. http://dx.doi.org/10.1007/978-3-030-89401-6_8.
Yin, Shuo, and Rocco Lupoi. "Cold Sprayed Metallic Glass and High Entropy Alloy Deposits." In Springer Tracts in Additive Manufacturing, 153–65. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-73367-4_8.
Kumar, V., B. K. Roy, and A. Mandal. "Multi-Wire-Arc Additive Manufacturing (M-WAAM) of Metallic Components." In Futuristic Manufacturing, 91–126. London: CRC Press, 2023. http://dx.doi.org/10.1201/9781003270027-6.
Conference papers on the topic "Metallic Additive Manufacturing":
Fortuna, S. V., A. V. Filippov, E. A. Kolubaev, A. S. Fortuna, and D. A. Gurianov. "Wire feed electron beam additive manufacturing of metallic components." In PROCEEDINGS OF THE ADVANCED MATERIALS WITH HIERARCHICAL STRUCTURE FOR NEW TECHNOLOGIES AND RELIABLE STRUCTURES. Author(s), 2018. http://dx.doi.org/10.1063/1.5083335.
Graf, M., K. P. Pradjadhiana, A. Hälsig, Y. H. P. Manurung, and B. Awiszus. "Numerical simulation of metallic wire arc additive manufacturing (WAAM)." In PROCEEDINGS OF THE 21ST INTERNATIONAL ESAFORM CONFERENCE ON MATERIAL FORMING: ESAFORM 2018. Author(s), 2018. http://dx.doi.org/10.1063/1.5035002.
Sandeep, Kuriakose, Parenti Paolo, Cataldo Salvatore, and Annoni Massimiliano. "Micromilling of Metallic Feedstock Produced by Extrusion Additive Manufacturing." In WCMNM 2018 World Congress on Micro and Nano Manufacturing. Singapore: Research Publishing Services, 2018. http://dx.doi.org/10.3850/978-981-11-2728-1_92.
Kiener, Lionel, Hervé Saudan, Florent Cosandier, Gérald Perruchoud, Vaclav Pejchal, Julien Rouvinet, Florent Boudoire, and Nikola Kalentics. "Validation of compliant mechanisms made by metallic Additive Manufacturing." In Advances in Optical and Mechanical Technologies for Telescopes and Instrumentation V, edited by Roland Geyl and Ramón Navarro. SPIE, 2022. http://dx.doi.org/10.1117/12.2629199.
Yihong, Kok, S. B. Tor, and N. H. Loh. "Comparison of Two Metallic Additive Manufacturing Technologies: Selective Laser Melting and Electron Beam Melting." In 1st International Conference on Progress in Additive Manufacturing. Singapore: Research Publishing Services, 2014. http://dx.doi.org/10.3850/978-981-09-0446-3_033.
Li, Zongchen, Andre Gut, Iurii Burda, Silvain Michel, Dejan Romancuk, and Christian Affolter. "The Role of an Individual Lack-of-Fusion Defect in the Fatigue Performance of Additive Manufactured Ti-6Al-4V Part." In 2022 International Additive Manufacturing Conference. American Society of Mechanical Engineers, 2022. http://dx.doi.org/10.1115/iam2022-94120.
Dapino, Marcelo J. "Smart Structure Integration Through Ultrasonic Additive Manufacturing." In ASME 2014 Conference on Smart Materials, Adaptive Structures and Intelligent Systems. American Society of Mechanical Engineers, 2014. http://dx.doi.org/10.1115/smasis2014-7710.
Wang, Zhuo, Pengwei Liu, Zhen Hu, and Lei Chen. "Simulation-Based Process Optimization of Metallic Additive Manufacturing Under Uncertainty." In ASME 2019 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference. American Society of Mechanical Engineers, 2019. http://dx.doi.org/10.1115/detc2019-97492.
Choi, Shinhyuk, Zhi Zhao, Jiawei Zuo, Jing Bai, Yu Yao, and Chao Wang. "3D Color Printing by Additive Manufacturing of Metallic Thin Films." In CLEO: Science and Innovations. Washington, D.C.: Optica Publishing Group, 2022. http://dx.doi.org/10.1364/cleo_si.2022.sth4p.8.
Waddell, Taylor, Zheng Wang, Rayne Zheng, and Hayden Taylor. "Manufacturing of metallic components via computed axial lithography and hydrogel infusion additive manufacturing." In Advanced Fabrication Technologies for Micro/Nano Optics and Photonics XVII, edited by Georg von Freymann, Eva Blasco, and Debashis Chanda. SPIE, 2024. http://dx.doi.org/10.1117/12.3009478.
Reports on the topic "Metallic Additive Manufacturing":
Slattery, Kevin. Unsettled Aspects of Insourcing and Outsourcing Additive Manufacturing. SAE International, October 2021. http://dx.doi.org/10.4271/epr2021023.
Todorov, Evgueni, Roger Spencer, Sean Gleeson, Madhi Jamshidinia, and Shawn M. Kelly. America Makes: National Additive Manufacturing Innovation Institute (NAMII) Project 1: Nondestructive Evaluation (NDE) of Complex Metallic Additive Manufactured (AM) Structures. Fort Belvoir, VA: Defense Technical Information Center, June 2014. http://dx.doi.org/10.21236/ada612775.
Tekalur, Arjun, Jacob Kallivayalil, Jason Carroll, Mike Killian, Benjamin Schultheis, Anil Chaudhary, Zackery McClelland, Jeffrey Allen, Jameson Shannon, and Robert Moser. Additive manufacturing of metallic materials with controlled microstructures : multiscale modeling of direct metal laser sintering and directed energy deposition. Engineer Research and Development Center (U.S.), July 2019. http://dx.doi.org/10.21079/11681/33481.
Rios, Orlando, Balasubramaniam Radhakrishnan, George Caravias, and Matthew Holcomb. Additive Manufacturing/Diagnostics via the High Frequency Induction Heating of Metal Powders: The Determination of the Power Transfer Factor for Fine Metallic Spheres. Office of Scientific and Technical Information (OSTI), March 2015. http://dx.doi.org/10.2172/1224158.
Slattery, Kevin. Unsettled Topics on Surface Finishing of Metallic Powder Bed Fusion Parts in the Mobility Industry. SAE International, January 2021. http://dx.doi.org/10.4271/epr2021001.
(Archived), Irina Ward, and Farah Abu Saleh. PR-473-144506-R01 State of the Art Alternatives to Steel Pipelines. Chantilly, Virginia: Pipeline Research Council International, Inc. (PRCI), December 2017. http://dx.doi.org/10.55274/r0011459.