STUDY ON TENSILE BEHAVIOR OF SiCf/TC17 COMPOSITES

doi:10.11900/0412.1961.2015.00127

Acta Metall Sin

2015, Vol. 51

Issue (9): 1025-1037 DOI: 10.11900/0412.1961.2015.00127

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STUDY ON TENSILE BEHAVIOR OF SiC_f/TC17 COMPOSITES

Xu ZHANG,Yumin WANG(

),Qing YANG,Jiafeng LEI,Rui YANG

Institute of Metal Research, Chinese Academy of Sciences, Shenyang 110016

Cite this article:

Xu ZHANG, Yumin WANG, Qing YANG, Jiafeng LEI, Rui YANG. STUDY ON TENSILE BEHAVIOR OF SiC_f/TC17 COMPOSITES. Acta Metall Sin, 2015, 51(9): 1025-1037.

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Abstract

Tensile properties and fracture mechanisms of SiC_f/TC17 composites at room temperature and 773 K were studied. The results show that fiber elastic deformation and matrix yielding contributed to the shapes of the stress-strain curves of SiC_f/TC17 composites, which were the bilinear appearance at 298 K and the slight curvature at 773 K. Major fracture mechanism of SiC_f/TC17 composites at room temperature were as follows: multiple fractures of the interfacial reaction layer, single fiber fracture, matrix brittle fracture etc.. Typical fracture mechanism of SiC_f/TC17 composites at elevated temperature were as follows: multiple fiber fracture, matrix plastic fracture, interface debonding etc.. Fiber cumulating damage theory was proved to be suitable for estimation of the fracture strength of this composite. The calculations of local loading sharing model while taking three or more fibers failure into account and global loading sharing model were close to the experimental values of room temperature and elevated temperature respectively. In addition, according to fracture mechanisms and strength prediction, tensile fracture process of SiC_f/TC17 composites at room and elevated temperature were explained in detail. At room temperature, multiple fractures of the interfacial reaction layer started at first, and then the weak fiber fractured gradually and randomly. After critical fiber cluster has been formed by nearby broken fibers, the crack extended into the matrix from these fibers. With the increase of load, the fibers and the matrix at the tip of crack gradually destroyed. At the same time, the cracks from other critical fiber clusters were also expanding and connecting to each other. When the crack area has reached the critical level, the remaining fiber and matrix quickly fractured. However, at elevated temperature the matrix yielded firstly, and then multiple fracture randomly of the interfacial reaction layer and the weak fiber occurred sequentially. The crack from broken fiber deflected at interface between fiber and matrix, caused interface debonding. With the increasing of broken fiber number, the micro-cavities of matrix emerged gradually in the stress concentration area. When the total crack area accumulated by the broken fibers and micro-cavities of matrix has reached the critical level, the remaining fiber and matrix quickly fractured.

Key words: titanium matrix composite SiC fiber tensile property fracture mechanism fracture process

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	Xu ZHANG
	Yumin WANG
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	Jiafeng LEI
	Rui YANG

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https://www.ams.org.cn/EN/10.11900/0412.1961.2015.00127 OR https://www.ams.org.cn/EN/Y2015/V51/I9/1025

Fig.1 Schematic of tensile specimen of SiC_f/TC17 composites(unit: mm)

Fig.2 Cross-section of the SiC_f/TC17 composites rod showing regular distribution of fibers (a) and overview of interface between fiber and matrix (b)

Table 1 Tensile properties of the SiC_f/TC17 composites and TC17 alloy at 298 and 773 K

Fig.3 Stress-strain curves for the SiC_f/TC17 composites and the TC17 alloy at 298 and 773 K (Curves for SiC_f/TC17 composites were plotted to fracture, curves for TC17 alloy were interrupted at 2% strain, some slight fluctuations in the straight line were marked by dotted square)

Fig.4 Fracture morphologies of the fracture surface of the SiC_f/TC17 composites at 298 K

(a) fracture surface divided into 5 regions by height

(b) dimples in the TC17 canning

(d) magnification of the area surrounded by black frame in Fig.4c

(e) irregular fracture region 4

(f) magnification of the area surrounded by black frame in Fig.4e

Fig.5 Fracture morphologies of the fracture surface of the SiC_f/TC17 composites at 773 K

(a) panorama of fracture surface

(b) dimples in the TC17 canning

(d) tunsgen "pull-out"

(e) longitudinal matrix cracks

(f) interface debonding and matrix damage in a ductile way

Fig.6 Typical morphologies of longitudinal section related to the flat fracture regions in fracture surface of the SiC_f/TC17 composites at room temperature

(a) partial macromorphology of longitudinal section

(b) multiple fracture of reaction layer near damaged fiber

(d) flat fracture surface of matrix

Fig.7 Typical morphologies of longitudinal section related to the irregular fracture region in fracture surface of the SiC_f/TC17 composites at room temperature

(a) partial macromorphology of longitudinal section

(b) multiple fracture of tungsten core and matrix plastic deformation near the damaged fiber

(d) irregular fracture surface and micro-cavities of matrix

Fig.8 Typical morphologies of longitudinal section of fracture surface of the SiC_f/TC17 composites at 773 K

(a) partial macromorphology of longitudinal section

(b) a damaged fiber with many fracture mechanisms

(d) irregular fracture surface and micro-cavities of matrix

Fig.9 Fiber fracture of the SiC_f/TC17 composites in tensile testing at elevated temperature

(a) formation of pancake structure

(b) formation of tungsten core pull-out

Table 2 Experimental and model prediction results of fracture strength for the SiCf/TC17 composites

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