Abstract

In this study, the strain rate-dependent dynamic tensile behavior of $$\hbox {ZrB}_{\mathrm {2}}$$ -20%SiC ceramic composite was investigated using experimental and numerical approaches. The split Hopkinson pressure bar apparatus was used to measure the dynamic splitting tensile response at strain rates of 17–67 $$\hbox {s}^{\mathrm {-1}}$$ . The experiment results demonstrate a significant strain rate dependence of the dynamic tensile behavior of the $$\hbox {ZrB}_{\mathrm {2}}$$ –SiC ceramic composite. The dynamic tensile strength increased linearly with the strain rate, from 288 MPa at 17 $$\hbox {s}^{\mathrm {-1}}$$ to 654 MPa at 67 $$\hbox {s}^{\mathrm {-1}}$$ . Moreover, a strain rate-dependent tensile strength was introduced into a modified JH-2 model to describe the dynamic tensile behavior and fracture process of $$\hbox {ZrB}_{\mathrm {2}}$$ –SiC ceramics. The numerical results of dynamic tensile strength agree well with the experimental result. Moreover, the fracture process of $$\hbox {ZrB}_{\mathrm {2}}$$ –SiC ceramics under dynamic tension was further studied by combining high-speed images and numerical results. The effect of strain rate on the fracture process and failure patterns of the $$\hbox {ZrB}_{\mathrm {2}}$$ –SiC ceramic composite could be verified by the modified JH-2 model.

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