Abstract
The strain rate effect of engineering materials should be considered in the assessment of the performance of reinforced concrete (RC) structures under extreme dynamic loads such as blast and impact. However, the strain rate behavior of 500 MPa-grade anti-earthquake hot-rolled high-strength ribbed bar (HRB500E), used in critical RC members to improve the anti-earthquake performance, has not been investigated and reported in the open literature. That restricts its application in RC structures subjected to extreme dynamic loads. In this paper, dynamic tensile tests of HRB500E steel were conducted using an electromechanical universal testing machine and a servo-hydraulic high-speed testing machine. The stress–strain curves at strain rates ranging from 0.00025 to 550 s−1 were obtained where HRB500E steel was found significantly sensitive to strain rate. Existing formulations to evaluate the dynamic increase factor for yield stress (DIFy) are found to be not suitable for HRB500E steel, thus the widely used Cowper–Symonds and Malvar models for predicting the DIFy were modified based on the test results. Furthermore, the parameter of the Mander material model for describing engineering stress–strain relationship was also calibrated. Finally, the Johnson-Cook and proposed constitutive models for the true stress–strain relationship were examined. The proposed constitutive model can provide better prediction accuracy for yield stress than the Johnson-Cook model.
Highlights
The application of high-strength reinforcing bars to reinforced concrete (RC) structures has been increasing gradually
4b, and it canThe be maximum data acquisition rate in the tests was seen that HRB500E steel is significantly sensitive to the strain rate
A series of dynamic tensile tests on HRB500E reinforcing bar were conducted over a wide strain rate range (0.00025–550 s−1)
Summary
The application of high-strength reinforcing bars to reinforced concrete (RC) structures has been increasing gradually. Understanding the strain rate behavior and obtaining the rate-dependent constitutive model of reinforcing bar are of significance for the design and performance evaluation of RC structures under such extreme dynamic loads. The strain rate behavior of 500 MPa-grade reinforcing bars from different manufacturers from different countries has been studied, and various formulations to evaluate the dynamic increase factor for yield stress (DIFy ) were established based on the test results [7,15,16,17]. These wide variations in DIFy are most likely due to the different chemical composition and microstructure To this end, it is dubious to assess the strain rate behavior of HRB500E reinforcing bar based on the existing research results, and it is essential to conduct a new experimental to understand the dynamic behavior. Based on the test results, the models of dynamic increase factors for yield stress and ultimate tensile strength, as well as constitutive models for the engineering stress−strain relationship
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