Technique and technology of silicates Technique and technology of silicates Техника и технология силикатов 2076-0655 90810 10.62980/2076-0655-2024-35-46 ОСНОВНАЯ РУБРИКА MAIN RUBRIC ОСНОВНАЯ РУБРИКА MULTIMATERIAL 3D-PRINTING OF FUNCTIONAL CERAMIC DEVIC-ES МУЛЬТИМАТЕРИАЛЬНАЯ 3D-ПЕЧАТЬ ФУНКЦИОНАЛЬНЫХ КЕРАМИЧЕСКИХ ИЗДЕЛИЙ Рагуткин Александр Викторович Ragutkin Alexander Viktorovich ragutkin@mirea.ru

доктор технических наук;

doctor of technical sciences;

 Юшин Денис Игоревич Yushin Denis Igorevich yushin@mirea.ru Нетреба Анастасия Юрьевна Netreba Anastasia Yuryevna netreba@mirea.ru Санжаровский Александр Юрьевич Sanzharovskiy Alexander Yurievich a.sanzharovskiy@eipc.center ФГБОУ ВО "МИРЭА - Российский технологический университет" Москва Россия MIREA - Russian Technological University Moscow Russian Federation ФГБОУ ВО "МИРЭА - Российский технологический университет" Москва Россия MIREA - Russian Technological University Moscow Russian Federation ФГБОУ ВО "МИРЭА - Российский технологический университет" Москва Россия MIREA - Russian Technological University Moscow Russian Federation Научно-исследовательский институт «Центр экологической промышленной политики» Москва Россия Research Institute "Environmental Industrial Policy Centre" Moscow Russian Federation 21 11 2024 21 11 2024 31 1 35 46 20 02 2024 20 03 2024 https://tsilicates.ru/en/nauka/article/90810/view

В последние годы реализуется тренд на миниатюризацию функциональных керамических устройств при улучше-нии их характеристик. При этом сильно усложняется процесс их быстрого прототипирования и увеличивается себестоимость при использовании классических технологий производства. Являясь развивающейся технологией, мультиматериальная 3D-печать способна не только обеспечить создание керамических изделий сложных форм (включая недоступные при использовании классических технологий), но и на порядки ускорить скорость прототипирования при значительном снижении себестоимости. В данной статье рассматриваются последние достижения в области методов мультиматериальной 3D-печати, а также проводится всестороннее исследование функциональных керамических материалов и процессов, пригодных для 3D-печати, для различных функциональных керамических устройств, включая конденсаторы, многослойные под-ложки и микрополосковые антенны. Кроме того, определены ключевые проблемы и перспективы функциональных керамических устройств с 3D-печатью из нескольких материалов и обсуждены направления на будущее.

In recent years, there has been a trend towards miniaturization of functional ceramic devices while improving their characteristics. At the same time, the process of rapid prototyping becomes much more complicated and the cost increases when using classical production technologies. Being an evolving technology, multimaterial 3D printing is able not only to create ceramic products of complex shapes (including those inaccessible when using classical technologies), but also to accelerate the prototyping speed by orders of magnitude with a significant reduction in cost. This article reviews the latest developments in the field of multimaterial 3D printing techniques, as well as a compre-hensive study of functional ceramic materials and processes suitable for 3D printing for various functional ceramic devic-es, including capacitors, multilayer substrates and microstrip antennas. In addition, the key problems and prospects of functional ceramic devices with 3D printing from several materials were identified and future directions were discussed.

 аддитивные технологии керамика HTCC LTCC мультиматериальная 3D-печать additive technologies ceramics HTC LTCC multimaterial 3D-printing Работа выполнена в рамках Государственного Задания 075-01528-23-02 от 22.02.2023 «Исследования и разра-ботки методов аддитивного производства электроники» (руководитель – Рагуткин Александр Викторович.) The work was performed within the framework of the State Assignment 075-01528-23-02 from 22.02.2023 “Research and development of methods of additive manufacturing of electronics” (supervisor - Ragutkin Alexander Viktorovich.).

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