Frequency Characteristics of High Strain Rate Compressions of Cf-MWCNTs/SiC Composites

IF 2.7 Q1 MATERIALS SCIENCE, CERAMICS
Kun Luan, Chen Ming, Xiaomeng Fang, Jianjun Liu
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Abstract

The incorporation of ductile reinforcements into ceramics helps restrain crack deflection, which can enhance ceramics’ toughness and overcome the matrix’s brittleness. In this paper, we produced a ceramic composite reinforced by carbon fibers coated by multi-wall carbon nanotubes (shortened by Cf-MWCNT/SiC composites) for enhanced impact resistance at a high strain rate that commonly occurs in composite materials used in astronautics, marine, and other engineering fields. The fabrication process involves growing multi-wall carbon nanotubes (MWCNTs) on a carbon fiber woven fabric (Cf) to create the fibril/fabric hybrid reinforcement. It is then impregnated by polymer solution (precursor of the ceramics), forming composites after the pyrolysis process, known as the liquid polymer infiltration and pyrolysis (PIP) technique. To assess the impact resistance of the Cf-MWCNT/SiC under high-strain rate compressions, the split Hopkinson pressure bar (SHPB) technique is employed. Since the failure behavior of the Cf-MWCNT/SiC composites in the absence of the ductile phase is not well understood, the study employs the Hilbert–Huang transform (HHT) to analyze the stress–time curves obtained from the SHPB experiments. By applying the HHT, we obtained the frequency–time spectrum and the marginal Hilbert spectrum of the stress signals. These analyses reveal the frequency characteristics of the Cf-MWCNT/SiC composite and provide insights into the relationship between transformed signal frequency and fracture behavior. By understanding the dynamic fracture behavior and frequency response of the Cf-MWCNT/SiC, it becomes possible to enhance its impact resistance and tailor its performance for specific protective requirements. Therefore, the findings of this study can guide the future design and optimization of Cf-MWCNT/SiC structures for various protective applications, such as body armor, civil structures, and protections for vehicles and aircraft.
Cf-MWCNTs/SiC复合材料高应变速率压缩频率特性研究
在陶瓷中加入韧性增强剂有助于抑制裂纹偏转,从而提高陶瓷的韧性,克服基体的脆性。在本文中,我们制备了一种陶瓷复合材料,该复合材料由碳纤维涂覆多壁碳纳米管(简称Cf-MWCNT/SiC复合材料)增强,以增强在高应变率下的抗冲击性,这通常出现在航天,船舶和其他工程领域的复合材料中。该制造工艺涉及在碳纤维机织织物(Cf)上生长多壁碳纳米管(MWCNTs),以创建纤维/织物混合增强材料。然后用聚合物溶液(陶瓷的前驱体)浸渍,经过热解过程形成复合材料,称为液态聚合物渗透热解(PIP)技术。为了评估Cf-MWCNT/SiC材料在高应变率压缩条件下的抗冲击性,采用了霍普金森压杆分离法(SHPB)。由于缺乏韧性相时Cf-MWCNT/SiC复合材料的破坏行为尚不清楚,因此本研究采用Hilbert-Huang变换(HHT)对SHPB实验得到的应力-时间曲线进行了分析。应用HHT,得到了应力信号的频时谱和边缘希尔伯特谱。这些分析揭示了Cf-MWCNT/SiC复合材料的频率特性,并为转换后的信号频率与断裂行为之间的关系提供了见解。通过了解Cf-MWCNT/SiC的动态断裂行为和频率响应,可以提高其抗冲击性,并根据特定的保护要求定制其性能。因此,本研究的发现可以指导Cf-MWCNT/SiC结构的未来设计和优化,用于各种防护应用,如防弹衣,土木结构,以及车辆和飞机的防护。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
3.00
自引率
7.10%
发文量
66
审稿时长
10 weeks
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