Wire Feed Electron Beam Additive Manufacturing of Metallic Components
| Parent link: | AIP Conference Proceedings Vol. 2051 : Advanced Materials with Hierarchical Structure for New Technologies and Reliable Structures 2018 (AMHS’18).— 2018.— [020092, 5 p.] |
|---|---|
| Autor Corporativo: | |
| Outros Autores: | , , , , |
| Resumo: | Title screen The results of the research show that it is possible to make axisymmetric blanks of satisfying quality and geometrical sizes using the process of wire feed electron additive manufacturing (3D-printing). Yield strength of blank's material achieves 317 MPa, which is higher than that of base cast metal (SS321). It was figured out that varying the additive manufacturing parameters such as wire feed rate and substrate rotation rate one may finally obtain printed components of various microstructure and mechanical characteristics. In other words, the parameters of the process can be operated and combined in order to gain needed mechanical characteristics' anisotropy of the material manufactured by wire feed 3D printing. Режим доступа: по договору с организацией-держателем ресурса |
| Idioma: | inglês |
| Publicado em: |
2018
|
| Assuntos: | |
| Acesso em linha: | https://doi.org/10.1063/1.5083335 |
| Formato: | Recurso Eletrônico Capítulo de Livro |
| KOHA link: | https://koha.lib.tpu.ru/cgi-bin/koha/opac-detail.pl?biblionumber=659170 |
Registros relacionados
Surface Morphology of 321 Stainless Steel Obtained by Electron-Beam Wire-Feed Additive Manufacturing Technology
Publicado em: (2018)
Publicado em: (2018)
Structure formation features of large block-shaped samples from the copper and aluminum alloy produced by the wire-feed electron-beam additive technology
Publicado em: (2020)
Publicado em: (2020)
Development of electron-beam equipment and technology of layer welding of the wire in the conditions of additive technologies
Publicado em: (2019)
Publicado em: (2019)
Development of electron-beam equipment and technology of layer welding of the wire in the conditions of additive technologies
Publicado em: (2019)
Publicado em: (2019)
Electron Beam Additive Manufacturing of TiCx/Ti-6Al-4V Composite
por: Builuk A. Artem
Publicado em: (2019)
por: Builuk A. Artem
Publicado em: (2019)
Development of Electron-beam Equipment and Technology for Additive Layer-wise Wire Cladding
Publicado em: (2019)
Publicado em: (2019)
Surface Modification of 3D-Printed Ti-6Al-4V Parts by Continuous Electron Beam
Publicado em: (2018)
Publicado em: (2018)
Закономерности формирования микроструктуры в 3D-напечатанных изделиях, полученных методом электронно-лучевого плавления проволоки титанового сплава Ti-6Al-4V с добавлением порошковой смеси Ti+TiC
por: Буйлук А. О.
Publicado em: (2019)
por: Буйлук А. О.
Publicado em: (2019)
Capabilities of Laser Printers with Different Power
Publicado em: (2016)
Publicado em: (2016)
Modal Analysis of Additive Manufactured Carbon Fiber Reinforced Polymer Composite Framework: Experiment and Modeling
Publicado em: (2016)
Publicado em: (2016)
Современные технологии изготовления трехмерных электронных устройств: Учеб. Пособие
por: Кондрашин А. А.
Publicado em: (Москва, Техносфера, 2019)
por: Кондрашин А. А.
Publicado em: (Москва, Техносфера, 2019)
Разработка составов бетонной смеси для 3D печати
por: Гетманская В. В.
Publicado em: (2018)
por: Гетманская В. В.
Publicado em: (2018)
Electron beam absorption in 3D-printed polymer samples with different infill densities
Publicado em: (2019)
Publicado em: (2019)
The comparison results of the electron beam depth dose distribution formed by standard and 3d-printed boluses
Publicado em: (2023)
Publicado em: (2023)
Электронно-лучевая аддитивная технология получения композита TiC/ Ti-6Al-4V
por: Буйлук А. О.
Publicado em: (2019)
por: Буйлук А. О.
Publicado em: (2019)
Additive Manufacturing Technologies. Rapid Prototyping to Direct Digital Manufacturing
por: Gibson I. Ian
Publicado em: (New York, Springer, 2010)
por: Gibson I. Ian
Publicado em: (New York, Springer, 2010)
Роль технологий 3D печати в жизни человека
por: Неудахина А. И.
Publicado em: (2014)
por: Неудахина А. И.
Publicado em: (2014)
Formation of electron beam fields with 3D printed filters
Publicado em: (2016)
Publicado em: (2016)
Numerical Simulation of the Microtron Electron Beam Absorption by the Modified ABS-Plastic
Publicado em: (2016)
Publicado em: (2016)
3D-печать с помощью SketchUp
por: Ридланд М.
Publicado em: (Москва, ДМК Пресс, 2020)
por: Ридланд М.
Publicado em: (Москва, ДМК Пресс, 2020)
Закономерности формирования структуры в процессе 3D-печати титановых сплавов
por: Буйлук А. О.
Publicado em: (2018)
por: Буйлук А. О.
Publicado em: (2018)
Impact Toughness of Ti-6Al-4V Parts Fabricated by Additive Manufacturing
Publicado em: (2019)
Publicado em: (2019)
Разработка оборудования и технологии электронно-лучевого селективного сплавления и наплавки проволоки
Publicado em: (2019)
Publicado em: (2019)
Clinical electron beam modulation by plastic samples produced with 3D printing approach
Publicado em: (2021)
Publicado em: (2021)
Comparison of structure and tribotechnical properties of extrudable uhmwpe composites fabricated by additive manufacturing technologies
Publicado em: (2018)
Publicado em: (2018)
Nanocad Plus 10. Адаптация к учебному процессу
por: Кувшинов Н. С.
Publicado em: (Москва, ДМК Пресс, 2019)
por: Кувшинов Н. С.
Publicado em: (Москва, ДМК Пресс, 2019)
Определение рецептуры трехкомпонентных полимер-полимерных композитов на основе СВМПЭ с заданными свойствами для аддитивных технологий
Publicado em: (2019)
Publicado em: (2019)
Материалы используемые в технологиях 3D прототипирования
por: Чудинова А. О.
Publicado em: (2014)
por: Чудинова А. О.
Publicado em: (2014)
Структура и свойства титановых деталей, формируемых при электронно-лучевой аддитивной технологии
Publicado em: (2017)
Publicado em: (2017)
Transverse profile forming for high energy electron beams using 3D-printed plastic samples
Publicado em: (2021)
Publicado em: (2021)
3D принтеры в металлургии. Подготовка модели
por: Липчанский Д. С.
Publicado em: (2014)
por: Липчанский Д. С.
Publicado em: (2014)
3D принтеры в металлургии
Publicado em: (2014)
Publicado em: (2014)
Electron beam surface treatment of 3D-printed Ti-6Al-4V parts
Publicado em: (2018)
Publicado em: (2018)
Достоинства и недостатки 3D технологий
por: Некрасова А. А.
Publicado em: (2014)
por: Некрасова А. А.
Publicado em: (2014)
Investigation of the mobility of a concrete mixture as a fundamental factor in the formation of mixtures for 3D-printing
por: Sorokina E. A.
Publicado em: (2017)
por: Sorokina E. A.
Publicado em: (2017)
Development of models, algorithms and software for evaluating the effective characteristics of materials obtained by using additive technologies using multiscale physical modeling
por: Privalov A. N.
Publicado em: (2017)
por: Privalov A. N.
Publicado em: (2017)
3D-печать. Практическое руководство
por: Рэдвуд Б.
Publicado em: (Москва, ДМК Пресс, 2020)
por: Рэдвуд Б.
Publicado em: (Москва, ДМК Пресс, 2020)
Dynamic response of three-dimensional multi-domain piezoelectric structures via bem
Publicado em: (2017)
Publicado em: (2017)
Determining of Electron Beam Percentage Depth Dose in Media with Varied Density by Longitudinal Arranged Dosimetry Film: Simulation Results
Publicado em: (2019)
Publicado em: (2019)
Технологии аддитивного производства учебное пособие
por: Руктуев А. А.
Publicado em: (Новосибирск, НГТУ, 2023)
por: Руктуев А. А.
Publicado em: (Новосибирск, НГТУ, 2023)