Research on the Damage Evolution Law and Dynamic Damage Constitutive Model of High-Performance Equal-Sized-Aggregate Concrete Materials
Publication: Journal of Materials in Civil Engineering
Volume 34, Issue 5
Abstract
High-performance equal-sized-aggregate (HPESA) concrete materials are mainly used as wall-off filling materials for underground engineering to meet the functional requirements of explosion prevention and shock absorption. However, the promotion and application of materials in underground engineering requires further understanding of its behavior in terms of damage evolution under impact load. A dynamic damage constitutive model able to describe the characteristics of material failure and deformation is thus required. According to the optimal energy-consumption ratio parameters of HPESA concrete materials, specimens that could meet the requirements of static pressure tests and split Hopkinson bar (SHPB) impact tests were prepared. The quasi-static testing parameters at a constant strain rate of and the dynamic stress-strain curves at strain ratios from 25 to were obtained. Then, from the bulk failure characteristics of the HPESA concrete materials under uniaxial impacting compression, the damage evolution mechanism of the material during its transformation from the structural phase to the damage phase was clarified, and an exponential model describing the evolution of damage with clear physical significance was obtained. Finally, when the damage variable of the HPESA concrete material was used in the Zhu-Wang-Tang (ZWT) rate-type constitutive equation, a uniaxial dynamic damage constitutive model that could describe the response of the HPESA concrete materials was obtained. The response characteristic parameters of the theoretical model were found by nonlinear fitting, which lays a foundation for numerical analysis of this material in underground engineering scenarios.
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Data Availability Statement
Some or all data, models, or code that support the findings of this study are available from the corresponding author upon reasonable request:
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Some basic physical and mechanical parameters of the material.
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Some pictures of the material destruction recorded by high-speed photography test system.
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Some data of the incident, reflected, and transmitted waves that were obtained by SHPB tests.
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All data of the stress-strain curves.
Acknowledgments
The authors thank the Postdoctoral Research Fund for Jiangsu Planned Projects (Grant No. 2018K047A), the China Postdoctoral Science Foundation Fund (Grant Nos. 2018M643854 and 2018M643853), the Jiangsu Province Natural Science Foundation (Grant No. BK20211229), and the Chinese National Natural Science Foundation (Grant Nos. 52008391 and 12002385) for their financial support.
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Received: May 6, 2021
Accepted: Sep 2, 2021
Published online: Feb 16, 2022
Published in print: May 1, 2022
Discussion open until: Jul 16, 2022
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