Your search keyword '"Eliáš, Jan"' showing total 2 results

1. Modeling of mode-I fatigue crack growth in quasibrittle structures under cyclic compression

Author

Eliáš, Jan and Le, Jia-Liang

Subjects

*MATHEMATICAL models, *FATIGUE crack growth, *BRITTLENESS, *STRUCTURAL analysis (Engineering), *MATERIALS compression testing, *TENSILE tests, *FRACTURE mechanics

Abstract

Abstract: A cyclic cohesive zone model is proposed to simulate the mode-I crack growth in quasibrittle structures under compressive fatigue. The constitutive behavior of the cohesive elements is formulated for both tension and compression regimes. A strain-softening cohesive law is adopted for the tension regime whereas a plastic-type cohesive behavior is considered for the compression regime. It is shown that the proposed model is able to capture some essential fracture behaviors of quasibrittle structures under compressive fatigue, which include the onset of fatigue crack growth, the gradual decrease in crack growth rate, and the exhaustion of residual tensile stress over the cycles. Based on a fracture process zone (FPZ)-equivalence principle, it is further shown that the existing kinetics equation for tensile fatigue crack can be extended to the crack growth under cyclic compression. [Copyright &y& Elsevier]

Published

2012

2. Improved sequentially linear solution procedure

Author

Eliáš, Jan, Frantík, Petr, and Vořechovský, Miroslav

Subjects

*SEQUENTIAL analysis, *FRACTURE mechanics, *SIMULATION methods & models, *MECHANICAL behavior of materials, *MECHANICAL loads, *STRESS concentration, *BRITTLENESS

Abstract

Abstract: The article proposes an improvement over the widely used sequentially linear solution procedure often utilized for fracture simulations. In the classical secant version of this method, a partial solution of a step is scaled to reach a stress limit in exactly one element and the mechanical properties of the critical element are reduced. Non-proportional loading is generally unfeasible due to avalanches of ruptures caused by stress redistribution. Because only one loading vector can be scaled at a time, all others have to remain constant during the step. However, the constant load vectors do not allow proper determination of the critical element. A modified procedure based on redistribution of released stresses is developed here. It preserves the linearity of each step. After rupture of the critical element, a sequentially linear redistribution process of stress release takes place until a static equilibrium state is reached. During the redistribution, other elements may break. The proposed enhanced sequential procedure is also compared with another recently published “event-by-event” linear method for non-proportional loading. It is shown here, with the help of simple examples, that the proposed redistribution method yields correct results for non-proportional loading, unlike the other methods under comparison. [Copyright &y& Elsevier]

Published

2010