玻-碳混杂复合材料开孔拉伸力学行为

doi:10.7527/S1000-6893.2025.32312

Abstract

Abstract:

The carbon/glass hybrid effect causes more complex mechanical responses at the interfaces during the tensile process of composites. In order to study the effect of carbon/glass hybridization on the interlaminar properties， two kinds of specimens， bonded and unbonded， were designed and fabricated， and the tensile mechanical behavior of open-hole was studied. First， using strain gauges and high-speed cameras， we monitored the loading process and the mechanical behavior of the materials at the moment of failure. Subsequently， finite element simulation was used to calculate the interlayer stress. Finally， through theoretical modeling， the interlaminar stress was numerically derived. The results show that there are stresses σ₃， τ₁₃ and τ₂₃ in the adhesive layer during the loading process， but according to the strain acquisition and simulation calculation results， the values are lower than the interlaminar strength. After the specimen damages， destruction of part of the material will rebound. The resilience force is linearly related to the elastic modulus and the maximum failure strain of the material， and is greater than the maximum shear stress between layers， which is the main reason for the delamination failure of the material.

Key words: composite materials, carbon/glass hybrid, open-hole tension, high-speed cameras, mechanical behavior

CLC Number:

V257

Qiang ZHANG, Lei LI, Guangqi HUANG, Jiahui XIE, Guibin SONG. Open-hole tensile mechanical behavior of carbon/glass hybrid composites[J]. Acta Aeronautica et Astronautica Sinica, 2025, 46(21): 532312.

Figures/Tables 21

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Table 1

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位置	τ₁₃/MPa	τ₂₃/MPa	σ₃/MPa
单元1	0.792	0.858	1.154
单元2	0.792	0.858	1.154
单元3	-0.279	-0.004	-2.483

Open-hole tensile mechanical behavior of carbon/glass hybrid composites

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