Broadband and High-temperature-resistant Microwave Absorber Using Additively Manufactured Ceramic Substrate

Chinese Journal of Mechanical Engineering: Additive Manufacturing Frontiers Pub Date : 2023-10-18 DOI:10.1016/j.cjmeam.2023.100096

Baihong Chi , Kuan Lu , Pengfei Wang , Mengzhu Li , Yuanyuan Li , Xinyu Geng , Guangsheng Deng

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Abstract

This paper presents an approach to achieve broadband absorption and temperature resistance using ceramic substrates. A specially formulated slurry suitable for additive manufacturing technology was developed to fabricate ceramic substrates with lattice structures. The lattice structure not only reduces the weight of the absorber but also facilitates the broadening of the absorption bandwidth. The experimental results demonstrate that the proposed structure exhibits absorption rates exceeding 88% within the frequency range of 19.9–30.41 GHz, with a relative absorption bandwidth of 41.8% under normal incidence. Furthermore, the absorber's performance was assessed under high temperatures of up to 200 ℃, revealing absorption spectra that closely match the initially measured spectrum. Additive-manufactured ceramic lattice structures present a promising avenue for designing multifunctional broadband microwave absorbers capable of withstanding elevated temperatures.

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增材制造陶瓷基板的宽带耐高温微波吸收器

本文提出了一种利用陶瓷衬底实现宽带吸收和耐温的方法。开发了一种适用于增材制造技术的专用浆料，用于制备具有晶格结构的陶瓷基板。晶格结构不仅减轻了吸收剂的重量，而且有利于吸收带宽的拓宽。实验结果表明，该结构在19.9 ~ 30.41 GHz频率范围内的吸收率超过88%，正常入射下的相对吸收带宽为41.8%。此外，在高达200℃的高温下对吸收剂的性能进行了评估，揭示了与最初测量的光谱密切匹配的吸收光谱。增材制造的陶瓷晶格结构为设计能够承受高温的多功能宽带微波吸收器提供了一条有前途的途径。

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Chinese Journal of Mechanical Engineering: Additive Manufacturing Frontiers

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