Bibliographic Details
| Title: |
Specimen geometry and specimen size dependence of the $${\mathcal {R}}$$ -curve and the size effect law from a cohesive model point of view. |
| Authors: |
Ortega, Adrián, Maimí, Pere, González, Emilio, Trias, Daniel |
| Source: |
International Journal of Fracture; Jun2017, Vol. 205 Issue 2, p239-254, 16p |
| Subject Terms: |
COHESIVE strength (Mechanics), TENSION loads, FRACTURE mechanics, STRAINS & stresses (Mechanics), PREDICTION models |
| Abstract: |
An analytic model has been developed for a Compact Tension specimen subjected to a controlled displacement and corresponding load within a cohesive model framework. The model is able to capture the material response while the Fracture Process Zone is being developed, obtaining the evolution of multiple variables such as the crack opening and the cohesive stresses, for an arbitrary Cohesive Law shape. The crack growth prediction based on the $${\mathcal {R}}$$ -curve and the nominal strength prediction based on Bažant's Size Effect Law have been implemented using the output variables available from the proposed analytic model. The minimum specimen size has been found in order to properly apply $${\mathcal {R}}$$ -curve based methods. The study has concluded that only the cohesive model is able to properly capture the changes of the Specimen Geometry and Specimen Size, as unlike in other theories, no Linear Elastic Fracture Mechanics assumptions are made. [ABSTRACT FROM AUTHOR] |
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| Database: |
Complementary Index |
