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Simulation of U-box test for fresh self-compacting concrete based on lattice Boltzmann method

Jinlei Mu, Yue Li, Caiyun Jin, Yunze Liu

2022Construction and Building Materials14 citationsDOIOpen Access PDF

Abstract

In this research, the numerical model of fresh self-compacting concrete (SCC) U-box test was established by combining lattice Boltzmann method (LBM) and Herschel-Bulkley (H–B) model. The flow behavior of fresh SCC in U-box was studied and its rheological mechanism was analyzed. The test results showed that the simulation model established based on U-box test had high simulation accuracy, and the average error was about 7 %. The effects of rheological parameters (power-law index n , consistency index k and yield stress σ 0 ) on the U-box test were explored. The numerical results demonstrated that σ 0 was the crucial rheological parameter that determined the passing ability of fresh SCC , and its increase resulted in weaker passing ability . n and k had less effect on the passing ability. At the early stage of U-box test ( t < 1.0 s), the increase of n , k and σ 0 all reduced the velocity of flow and the pressure exerted on the fresh SCC, with n bringing the most significant effect. The peak velocity and pressure of shear-thinning ( n = 0.6) SCC could reach 0.74 m/s and 4200 Pa at t = 0.1 s. The peak velocity of shear-thickening ( n = 1.4) SCC was less than half of the former, and a larger negative pressure appeared, up to about −1600 Pa. The speed of pulling up the partition gate ( u g ) only had an effect, which gradually diminished with the increase of u g , on the initial phase of U-box test ( t < 5.0 s). The cross-sectional area corresponding to the obstacles that could be passed by the SCC was the main factor affecting the early velocity and pressure of the concrete.

Topics & Concepts

Lattice Boltzmann methodsLattice (music)Materials scienceStructural engineeringComposite materialEngineeringMechanicsPhysicsAcousticsInnovations in Concrete and Construction MaterialsInnovative concrete reinforcement materialsLattice Boltzmann Simulation Studies