Print Email Facebook Twitter Simulation of dynamic behavior of quasi-brittle materials with new rate dependent damage model Title Simulation of dynamic behavior of quasi-brittle materials with new rate dependent damage model Author Pereira, Luis (TU Delft Applied Mechanics; Academia da Forca Aerea Portuguesa) Weerheijm, J. (TU Delft Applied Mechanics; TNO) Sluys, Lambertus J. (TU Delft Applied Mechanics) Contributor Saouma, V. (editor) Bolander, J. (editor) Landis, E. (editor) Date 2016 Abstract Stress-based nonlocal model, Damage, Rate dependency, Dynamic crack-branching Abstract. In concrete often complex fracture and fragmentation patterns develop when subjected to high straining loads. The proper simulation of the dynamic cracking process in concrete is crucial for good predictions of the residual bearing capacity of structures in the risk of being exposed to extraordinary events like explosions, high velocity impacts or earthquakes. As it is well known, concrete is a highly rate dependent material. Experimental and numerical studies indicate that the evolution of damage is governed by complex phenomena taking place simultaneously at different material scales, i.e. micro, meso and macro-scales. Therefore, the constitutive law, and its rate dependency, must be adjusted to the level of representation. For a proper phenomenological (macroscopic) representation of the reality, the constitutive law has to explicitly describe all phenomena taking place at the lower material scales. Macro-scale inertia effects are implicitly simulated by the equation of motion. In the current paper, dynamic crack propagation and branching is studied with a new rate-dependent stress-based nonlocal damage model. The definition of rate in the constitutive law is changed to account for the inherent meso-scale structural inertia effects. This is accomplished by a new concept of effective rate which governs the dynamic delayed response of the material to variations of the deformation (strain) rate, usually described as micro-inertia effects. The proposed model realistically simulates dynamic crack propagation and crack branching phenomena in concrete. Subject Stress-based nonlocal modelDamageRate dependencyDynamic crack-branching To reference this document use: http://resolver.tudelft.nl/uuid:7c3c1c21-7fa5-43ba-8654-06d1cdd27673 DOI https://doi.org/10.21012/FC9.036 Source 9th International Conference on Fracture Mechanics of Concrete and Concrete Structures Event 9th International Conference on Fracture Mechanics of Concrete and Concrete Structures, 2016-05-22 → 2016-05-25, University of California, Berkeley, United States Part of collection Institutional Repository Document type conference paper Rights © 2016 Luis Pereira, J. Weerheijm, Lambertus J. Sluys Files PDF LPereira_FRAMCOS2016_Simu ... _model.pdf 1.31 MB Close viewer /islandora/object/uuid:7c3c1c21-7fa5-43ba-8654-06d1cdd27673/datastream/OBJ/view