Your search keyword '"failure phenomena"' showing total 7 results

1. Effect of the selected parameters in idealizing material failures under tensile loads: Benchmarks for damage analysis on thin-walled structures

Author

Prabowo Aditya Rio, Ridwan Ridwan, Tuswan Tuswan, Sohn Jung Min, Surojo Eko, and Imaduddin Fitrian

Subjects

finite element method, tensile test, rupture strain, failure phenomena, ship collision modeling, Mechanics of engineering. Applied mechanics, TA349-359

Abstract

The development of the global economy has led to a rise in ship traffic. As a result, the risk of accidents, such as collisions between ships and grounding, has also increased. Different failure criteria to capture these accidents have been introduced by researchers. Therefore, the purpose of this study was to determine the essential distinction between these failure criteria. The simulations suggest that failure criteria based on the maximum stress result in a slightly higher rupture strain value, greater crack propagation, and higher internal energy than those based on the maximum strain. Furthermore, using a larger mesh size compared with the size of the test specimen appears to greatly affect the validity of the simulation results.

Published

2022

2. Excavation response and reinforcement practice of large underground caverns within high-stress hard rock masses: The case of Shuangjiangkou hydropower Station, China.

Author

Liu, Xiu-Yang, Xu, Ding-Ping, Jiang, Quan, and Ma, Xing-Dong

Subjects

*ROCK music, *CAVES, *WATER power, *UNDERGROUND construction, *FIELD research

Abstract

The construction of large-scale underground caverns poses numerous challenges due to their massive scale and high complexity. Among them, stability has always been a major concern during the construction process of large underground caverns within high-stress hard rock masses. It is not only influenced by the geological background of the project but also by the engineering activities during construction. This study takes the construction of the Shuangjiangkou (SJK) hydropower station as a case study and combines field investigations to summarize engineering issues and solutions under high geostress in three aspects. Firstly, it focuses on estimating and modifying the in-situ stress field of the underground caverns in the deep-cut valley area using limited geostress testing data and the observed failure phenomena in the pilot tunnel. Secondly, it discusses the typical failure phenomena of caverns under high geostress, including global stress-induced failures and local vein-controlled failures, as well as the corresponding failure mechanisms and treatment measures. Finally, it addresses the special failure phenomena occurring in the protective layer of the rock-anchored beam and optimizes the excavation scheme based on the observed failure patterns. The research results and solutions provided in this study, based on the case of the SJK hydropower station, are expected to serve as a reference for subsequent construction of large underground caverns within high-stress hard rock masses. [ABSTRACT FROM AUTHOR]

Published

2024

3. The Theory Research of Tunnels Seismic Damage

Author

Shengbao, Zheng, Shuping, Jiang, Xiaowen, Wang, Zhi, Lin, and Zhang, Wei, editor

Published

2012

4. Fiber break model for tension-tension fatigue of unidirectional composites

Author

Fazlali, Babak, Lomov, Stepan V., and Swolfs, Yentl

Subjects

Technology, Materials science, Fiber break and cluster development, PREDICTION, Materials Science, Engineering, Multidisciplinary, Fatigue damage, Synergetic effect, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Industrial and Manufacturing Engineering, Stress level, MECHANISMS, FAILURE PHENOMENA, Engineering, ROUGHNESS, Fatigue life, Fiber, Composite material, Stress concentration, Weibull distribution, STRESS-CONCENTRATIONS, DAMAGE, Science & Technology, Tension (physics), Mechanical Engineering, 021001 nanoscience & nanotechnology, Fiber-matrix debond growth, REINFORCED POLYMERS, 0104 chemical sciences, LIFE, Stress redistribution, Mechanics of Materials, Materials Science, Composites, DEBOND GROWTH, Fatigue loading, Ceramics and Composites, Weibull, 0210 nano-technology, FINITE-ELEMENT

Abstract

Damage progression in unidirectional (UD) composites in tension-tension fatigue is vital to understanding fatigue in more complex laminates and loading conditions. We therefore developed the UD fatigue model that considers fiber breaks, fiber-matrix debond growth, fiber fatigue as well as interactions of these damage modes. The contribution of each mode of damage in fatigue is assessed and those that dominate fatigue damage are identified. The model accounts for Weibull statistics of fiber strength and stress redistribution around fiber breaks. The predictions for fatigue loading indicate a significantly higher density of fiber breaks and clusters compared to quasi-static loading at the same stress level. The model predicts S–N curves in pure uniaxial tension-tension fatigue loading and does not consider stress concentrations caused near the grips; the predictions therefore tend to overpredict fatigue life compared to experimental S–N curves available in the literature. The model has potential to be developed for different loading conditions.

Published

2021

5. Analysis of failure mechanism of bitumen films

Author

Poulikakos, L.D., Tiwari, M.K., and Partl, M.N.

Subjects

*BITUMEN, *THIN films, *VISCOELASTICITY, *SEPARATION (Technology), *BINDING agents, *NUCLEATION

Abstract

Abstract: The failure phenomena of a viscoelastic thin film of bitumen and polymer modified bitumen under direct tension tests is investigated in detail, experimentally and theoretically. Using video recording and image processing techniques, the time evolution of failure and film disintegration and separation phenomena were studied. The following failure stages were identified and recorded: Initial (=stage 1), necking (=stage 2), filamentation with void nucleation (=stage 3) and separation (=stage 4). The technique allowed the identification of an additional failure stage for the pure bitumen than the four identified for binders, namely light transparent thinning before void nucleation. The determination of stages to final separation allowed behavioral distinction between the straight run bitumen and the polymer modified bitumen. As the direct tensile tests proceed, in addition to shear forces demonstrative of viscous effects, gravity and capillary forces act on the binder film. In order to understand the relative effect of these forces the order of magnitude of relevant dimensionless numbers, representing ratios of these forces is considered and discussed. The analysis of the above numbers confirms that the flow in bitumen is dominated by viscous effects although capillary forces do play a role at later stages of the experiment with negligible inertia and gravitational effects. The detailed analysis of micromechanical behavior of straight run bitumen and polymer modified bitumen provided further indication corroborating the superior field performance of polymer modified bitumen in porous asphalt. [Copyright &y& Elsevier]

Published

2013

6. Stress redistribution around clusters of broken fibres in a composite

Author

Luc St-Pierre, Ned J. Martorell, Silvestre T. Pinho, Engineering & Physical Science Research Council (EPSRC), Solid Mechanics, Imperial College London, Department of Mechanical Engineering, Aalto-yliopisto, and Aalto University

Subjects

Technology, Materials science, Monte Carlo method, Composite number, Materials Science, 02 engineering and technology, MODEL COMPOSITES, Carbon fibres, UNIDIRECTIONAL CFRP COMPOSITES, 09 Engineering, Monte Carlo simulations, FAILURE PHENOMENA, Mathematics::Algebraic Geometry, 0203 mechanical engineering, Ultimate tensile strength, Cluster (physics), Fiber bundle, LOAD-TRANSFER, COMPUTED-TOMOGRAPHY, Composite material, TENSILE-STRENGTH, ta216, Materials, Civil and Structural Engineering, Stress concentration, Stress concentrations, ta214, Science & Technology, Finite element analysis (FEA), 021001 nanoscience & nanotechnology, Finite element method, Stress field, 020303 mechanical engineering & transports, Materials Science, Composites, MICROMECHANISMS, Ceramics and Composites, SHEAR-LAG, REINFORCED EPOXY COMPOSITE, 0210 nano-technology, FINITE-ELEMENT

Abstract

A key aspect of the longitudinal tensile failure of composites is the stress redistribution that occurs around broken fibres. Work on this topic has focussed mainly on the stress field surrounding a single broken fibre; however, this is an important limitation as unstable failure in carbon fibre bundles occurs when a cluster of about 16 or more broken fibres is formed. Therefore, we have developed a detailed Finite Element (FE) model to investigate how stress redistribution varies with the number of broken fibres in a cluster. The results show that both the recovery length and stress concentration factor increase significantly with increasing number of broken fibres in a cluster. We have also developed an analytical model, suitable to be included in existing or new fibre bundle models, that captures how the recovery length and stress concentration factor vary with the broken cluster size, and validated its predictions against our FE simulations. Finally, we extended our FE model to predict the survival probability of fibre bundles using Monte Carlo simulations, and found that these predictions were in good agreement with experimental and analytical results on microcomposites.

Published

2017

7. Effects of debonding and fiber strength distribution on fatigue-damage propagation in carbon fiber-reinforced epoxy

Author

Gamstedt, E. Kristofer and Gamstedt, E. Kristofer

Abstract

In order to design new fatigue-resistant composites, the underlying fatigue damage mechanisms must be characterized and the controlling microstructural properties should be identified. The fatigue-damage mechanisms of a unidirectional carbon fiber-reinforced epoxy has been studied under tension-tension loading. A ubiquitous form of damage was one or a few planar fiber breaks from which debonds or shear yield zones grew in the longitudinal direction during fatigue cycling. This leads to a change in stress profile of the neighboring fibers, and an increase in failure probability of these fibers. The breakage of fibers in the composite is controlled by the fiber strength distribution. The interaction between the fiber strength distribution and debond propagation leading to further fiber breakage was investigated by a numerical simulation. It was found that a wider distribution of fiber strength and a higher debond rate lead to more distributed damage and a higher fracture toughness. Implications to fatigue life behavior are discussed, with reference to constituent microstructure., QC 20100525

Published

2000