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In order to reduce automobile body weight and improve crashworthiness, the use of high-strength steels has increased greatly in recent years. An optimal combination of both crash safety performance and lightweight structure has been a major challenge in automobile body engineering. In this study, the Cockcroft-Latham fracture criterion was applied to predict the fracture of high-strength steels. Marciniak-type biaxial stretching tests for high-strength steels were performed to measure the material constant of the Cockcroft-Latham fracture criterion. Furthermore, in order to improve the simulation accuracy, local anisotropic parameters based on the plastic strain (strain dependent model of anisotropy) were measured using the digital image grid method and were incorporated into Hill's anisotropic yield condition by the authors. In order to confirm the validity of the Cockcroft-Latham fracture criterion, uniaxial tensile tests were performed.

In order to evaluate the crashworthiness of impact energy absorbing parts for automobiles, it is very important to obtain accurate stress-strain (s-s) relationships for steel sheets under various strain rates. However, at high strain rates over 10/s, stress wave interference in the load cell obstructs precise measurement of the s-s relationship with conventional tensile testing equipment. Various new tensile testing machines have been developed to obtain accurate s-s relationships at high strain rates. Six of these machines (coaxial Split Hopkinson Pressure Bar method, Non-coaxial Split Hopkinson Pressure Bar method, One Bar method, Sensing Block Testing System, and two types using the Hydraulic Servo method) were used to obtain s-s relationships for high strength steel sheets. In this paper, the s-s relationships are compared and the characteristic of the curves was discussed.