Numerical Discrete-Element Method Investigation on Failure Process of Recycled Aggregate Concrete

Numerical Discrete-Element Method Investigation on Failure Process of Recycled Aggregate Concrete

AbstractThis study numerically investigates the failure processes of recycled aggregate concrete (RAC) and natural aggregate concrete (NAC). A two-dimensional simulation based on a discrete-element method (DEM) is conducted with a universal distinct-element code (UDEC) program. RAC is modeled by a c...

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Bibliographic Details
Published in:Journal of materials in civil engineering Vol. 31; no. 1
Main Authors: Tan, Xin, Li, Wengui, Zhao, Minghua, Tam, Vivian W. Y
Format: Journal Article
Language:English
Published: New York American Society of Civil Engineers 01-01-2019
Subjects:
Building materials
Civil engineering
Coalescing
Computer simulation
Concrete aggregates
Deformation mechanisms
Digital imaging
Discrete element method
Failure mechanisms
Mathematical models
Microcracks
Mortars (material)
Nanoindentation
Recycled materials
Stress-strain curves
Stress-strain relationships
Technical Papers
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Summary:AbstractThis study numerically investigates the failure processes of recycled aggregate concrete (RAC) and natural aggregate concrete (NAC). A two-dimensional simulation based on a discrete-element method (DEM) is conducted with a universal distinct-element code (UDEC) program. RAC is modeled by a combination of rigid Voronoi blocks cemented to each other using contacts for interfaces. The determination procedure of contact microparameters is analyzed, and a series of microscopic contact parameters in different components of modeled recycled aggregate concrete (MRAC) is calibrated using nanoindentation results. The complete stress-strain curves, fracture process, and failure pattern of numerical model are verified by experimental results, proving its accuracy and validation. The initiation, propagation, and coalescence of microcracks and subsequent nonlinear deformation behaviors of cement mortar, modeled natural aggregate, and recycled aggregate concrete are captured through DEM numerical simulations and compared with digital image correlation (DIC) results. It is found that both the new interfacial transition zone and the old interfacial transition zone are the weak links in RAC, where most microcracks initiate and propagate into the cement mortar region. The failure behaviors of MRAC revealed by both experimental and numerical results can effectively provide insights into the failure mechanism and enhancement of RAC.
ISSN:0899-1561
1943-5533
DOI:10.1061/(ASCE)MT.1943-5533.0002562