How to Get Closer to Reality in Pressure Test Simulations with the SPH Method

journal article in Scopus

English

The article describes an algorithm for the generation of the spatial geometry of concrete based on a photograph, and its subsequent use in cylindrical pressure test simulations using the Smoothed Particle Hydrodynamics (SPH) method. The aim of the article is to present several simple steps of the algorithm which enable the achievement of variability in the results of simulated pressure load tests conducted on concrete. The main aim is to achieve the best possible match with reality. The fact is that during real load tests it is never possible to obtain two identical results, e.g. the same stress–strain curves for two concrete specimens. They will always differ slightly. However, this is inconsistent with what happens in the case of numerical simulations, where the result is always the same unless there is a change in the input values. The idea of the algorithm is thus to generate the spatial geometry of the structure of a material based on the utilization of a suitably selected and optimized noise function. In a cutting plane through its space, the noise function is visually identical to the photograph of the material. A unique result can be obtained with every additional photograph of the material. The structure generated in this way can be discretized advantageously using the SPH method while also incorporating numerical heterogeneity, which is used to enhance material heterogeneities, e.g. in the area where aggregate and cement binder are in contact. The article describes the whole procedure via an example of a cylindrical pressure test performed on concrete. The functionality of the algorithm is supported by simulation results.

Concrete, heterogeneity, noise, Smoothed Particle Hydrodynamics

HUŠEK, M.; KALA, J.

1. 11. 2017

1998-4448

International Journal of Mechanics

2017

11

United States of America

226

233

8

http://www.naun.org/main/NAUN/mechanics/2017/a642003-aan.pdf