Stress Intensity Factor of Notch/Crack Configuration under Bending Load for Brittle Materials

Feng Hui Wang

doi:10.4028/www.scientific.net/KEM.324-325.1051

Paper Titles

Crystal Plasticity Analysis of Thermal Deformation and Dislocation Accumulation in ULSI Cells
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Numerical Investigation on the Crack Propagation in a Flat Stiffened Panel
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Reconstruction of the Material Probabilistic S-N Relations under Fatigue Life Following Lognormal Distribution I-without Given Confidence
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Residual Stress and Damage Evolution in TBCs by Optical Method
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Stress Intensity Factor of Notch/Crack Configuration under Bending Load for Brittle Materials
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Behavior and Fracture Mechanism of Brittle Rock with Pre-Existing Parallel Cracks
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Prediction of Crack Propagation under Dynamic Loading Conditions by Using the Enhanced Point Collocation Meshfree Method
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A Numerical Study and Design of Turbine Blade under High Temperature and Rotational Speed Using FEM
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Experimental Study of Steel Fibre Bridging Action on Crack Propagation in Fibre Reinforced Concrete
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HomeKey Engineering MaterialsKey Engineering Materials Vols. 324-325Stress Intensity Factor of Notch/Crack...

Stress Intensity Factor of Notch/Crack Configuration under Bending Load for Brittle Materials

Abstract:

Stress intensity factor of crack ahead of notch is important for understanding the failure of this kind structure. In this paper, a model is proposed to calculate the stress intensity factor of crack ahead notch configuration under bending load, the modeling value were verified by the data from literatures and experimental data of this paper, the trend of the value from model is agreement with that from experiments.

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Periodical:

Key Engineering Materials (Volumes 324-325)

Pages:

1051-1054

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.324-325.1051

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Online since:

November 2006

Authors:

Feng Hui Wang

Keywords:

Brittle Materials, Notches, Stress Intensity Factor (SIF)

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