Conch-shell-inspired porcelain ceramic tile/Kevlar fabric composites with excellent combination of strength, toughness and shock resistance-Reference-Cited by-同舟云学术

Conch-shell-inspired porcelain ceramic tile/Kevlar fabric composites with excellent combination of strength, toughness and shock resistance

Published:2024 Issue:1 Volume:18 Page:20-28
ISSN:1820-6131
Container-title:Processing and Application of Ceramics
language:en
Short-container-title:PAC

Author:

Zhong Xinzi¹,Cao Liyun²,Huang Jianfeng³,Liu Yijun³,Shen Xuetao²,Zhao Yong³,Wang Dongping²,Cheng Zhiwen⁴,Liu Ting³,Zhang Shuai²,Zhang Chenlei³

Affiliation:

1. School of Material Science and Engineering, Shaanxi University of Science and Technology, Xian, PR China + Guangdong Provincial Key Laboratory of Large Ceramic Plates, Mona Lisa Group Co. Ltd, Foshan, PR China

2. School of Material Science and Engineering, Shaanxi University of Science and Technology, Xian, PR China

3. Guangdong Provincial Key Laboratory of Large Ceramic Plates, Mona Lisa Group Co. Ltd, Foshan, PR China

4. Xianyang Research & Design Institute of Ceramic Co. Ltd, Xianyang, PR China

Abstract

For various engineering applications in public, ceramics with exceptional strength, toughness and shock resistance are imminently required, but traditional ceramics struggle to meet these demands due to their fragility. Inspired by the shape of natural conch shells, this work offers a simple hot press approach to fabricate layered porcelain ceramic tile/Kevlar fabric composites, yielding excellent mechanical properties and the capacity for non-catastrophic failure. It was concluded that composites? excellent mechanical performance is attributed to the resin/fabric content. The composite with the resin/fabric content of 45.5 vol.% had an outstanding combination of high strength (310.5 ? 6.2MPa) and excellent fracture toughness (6.83 ? 0.09MPa?m1/2), whereas the sample with 36.4 vol.% resin/fabric content had the maximal impact energy of 2.04 ? 0.09 J, which is much better than those of traditional ceramics. The strong resistance to fracture is a result of the proper interfacial bonding and the presence of elastic component, which enables toughening mechanisms such as crack deflection, fibre pull-out and interfacial debonding. This finding provides useful guidance for replacing lowperformance ceramics in engineering applications with cost-effective ceramic composites.

Publisher

National Library of Serbia

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