Search results for "Stress concentration"

showing 9 items of 39 documents

Strength and strain enhancements of concrete columns confined with FRP sheets

2004

The compressive behavior up to failure of short concrete members reinforced with fiber reinforced plastic (FRP) is investigated. Rectangular cross-sections are analysed by means of a simplified elastic model, able also to explain stress-concentration. The model allows one to evaluate the equivalent uniform confining pressure in ultimate conditions referred to the effective confined cross-section and to the effective stresses in FRP along the sides of section; consequently, it makes it possible to determine ultimate strain and the related bearing capacity of the confined member corresponding to FRP failure. The effect of local reinforcements constitute by single strips applied at corners bef…

Stress-concentrationMaterials scienceStrain (chemistry)business.industryMechanical EngineeringMaximum compressive strengthRectangular cross-sectionBuilding and ConstructionSTRIPSStructural engineeringFibre-reinforced plasticOverburden pressurelaw.inventionSettore ICAR/09 - Tecnica Delle CostruzioniMechanics of MaterialslawBearing capacityUltimate strainComposite materialReinforcementbusinessConfinementFRPCivil and Structural EngineeringStress concentrationStructural Engineering and Mechanics
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Benchmarking of strength models for unidirectional composites under longitudinal tension

2018

© 2018 Elsevier Ltd Several modelling approaches are available in the literature to predict longitudinal tensile failure of fibre-reinforced polymers. However, a systematic, blind and unbiased comparison between the predictions from the different models and against experimental data has never been performed. This paper presents a benchmarking exercise performed for three different models from the literature: (i) an analytical hierarchical scaling law for composite fibre bundles, (ii) direct numerical simulations of composite fibre bundles, and (iii) a multiscale finite-element simulation method. The results show that there are significant discrepancies between the predictions of the differe…

TechnologyMaterials scienceComposite numberMaterials Science02 engineering and technologyFiber-reinforced composite0901 Aerospace EngineeringEngineering0203 mechanical engineeringFragmentationUltimate tensile strengthMicro-mechanicsCOMPUTED-TOMOGRAPHYLOAD-TRANSFERComposite material0912 Materials EngineeringMaterialsStress concentrationEPOXY COMPOSITESTRESS-CONCENTRATIONSScience & TechnologyDAMAGE ACCUMULATIONTension (physics)FIBER-REINFORCED COMPOSITESPolymer-matrix compositesExperimental dataMicromechanics021001 nanoscience & nanotechnologyFinite element methodEngineering Manufacturing020303 mechanical engineering & transportsWIDE FAILURE EXERCISEMechanics of MaterialsMaterials Science CompositesHYBRID COMPOSITES[PHYS.COND.CM-MS]Physics [physics]/Condensed Matter [cond-mat]/Materials Science [cond-mat.mtrl-sci]Ceramics and CompositesStrength0210 nano-technologyFINITE-ELEMENT0913 Mechanical Engineering
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Fatigue fracture plane under Multiaxial Random Loadings - prediction by variance of equivalent stress based on the maximum shear and normal stresses

1992

It is assumed that the plane in which the maximum variance of the equivalent stress appears is critical for a material and the fatigue fracture should be expected in this plane. The equivalent stress is calculated according to the fatigue criterion of maximum shear and normal stresses in the fracture plane. It was demonstrated that for each stationary random stress state there is one or more critical planes where the fatigue fracture plane can be expected. The variance method together with the discussed fatigue criterion give good results for three analysed types of carbon steels under multiaxial cyclic loadings.

Variance methodMaterials sciencebusiness.industryMechanical EngineeringStructural engineeringFracture planeCondensed Matter PhysicsComputer Science::RoboticsEquivalent stressShear (geology)Mechanics of MaterialsGeneral Materials SciencebusinessStress intensity factorStress concentrationMaterialwissenschaft und Werkstofftechnik
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Effects of defects on the tensile strength of short-fibre composite materials

2014

Abstract. Heterogeneous materials tend to fail at the weakest cross-section, where the presence of microstructural heterogeneities or defects controls the tensile strength. Short-fibre composites are an example of heterogeneous materials, where unwanted fibre agglomerates are likely to initiate tensile failure. In this study, the dimensions and orientation of fibre agglomerates have been analysed from three-dimensional images obtained by X-ray microtomography. The geometry of the specific agglomerate responsible for failure initiation has been identified and correlated with the strength. At the plane of fracture, a defect in the form of a large fibre agglomerate was almost inevitably found.…

agglomerationMaterials scienceta114composite materialsMetallurgyWeak correlationX-ray microtomographyMechanics of MaterialsAgglomerateUltimate tensile strengthFracture (geology)General Materials ScienceComposite materialstrengthInstrumentationStress intensity factorStress concentrationMechanics of Materials
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Damage and fracture study of cold extrusion dies

2004

Abstract In the present paper die fracture in cold extrusion was investigated considering a few different die reduction zone geometries. A former finite element method (FEM) analysis of the process was developed to obtain the contact pressure distribution at the workpiece–die interface for each of the investigated geometries; subsequently a stress and strain analysis utilizing the BEM code Franc3D was carried out, with the aim to evaluate the crack propagation at each loading cycle, i.e. at each extrusion process. In this way the die life for each of the investigated extrusion die geometries was compared utilizing the Paris law and the values assumed by the stress concentration coefficient …

business.product_categoryMaterials scienceMechanical EngineeringStress–strain curveMechanical engineeringFracture mechanicscold extrusionFinite element methodStress (mechanics)Mechanics of MaterialsFracture (geology)Die (manufacturing)General Materials ScienceExtrusionComposite materialbusinessStress concentrationEngineering Fracture Mechanics
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Durability of a 3D woven composite assisted by finite element multi-scale modelling

2012

International audience; The textile composite studied is a 3D woven composite. A unit cell is defined by using microscopic examinations of the microstructure. A multiscale approach assisted by the finite element method is performed in order to estimate the effective properties of the composite and then to access to local stress field. This approach allows the determination of the kind of load to which warp yarns are subjected. Moreover, detailed analysis of damaged model using different configurations of broken yarns are treated. The evolution of the stress concentration coefficient highlight the load transfers due to consecutive yarn breaks.

multi-scale analysisfinite elementtextile composite[SPI.MECA.MEMA]Engineering Sciences [physics]/Mechanics [physics.med-ph]/Mechanics of materials [physics.class-ph][ PHYS.COND.CM-MS ] Physics [physics]/Condensed Matter [cond-mat]/Materials Science [cond-mat.mtrl-sci]durability[SPI.MAT] Engineering Sciences [physics]/Materialsstress concentration coefficient[SPI.MECA.MEMA] Engineering Sciences [physics]/Mechanics [physics.med-ph]/Mechanics of materials [physics.class-ph][SPI.MAT]Engineering Sciences [physics]/Materials
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Residual Stress Effects on Fatigue Crack Growth in Ti-6Al-4V Friction Stir Welds

2008

Recent studies have illustrated a predominant role of the residual stress on the fatigue crack growth in friction stir welded joints. In this study, the role of the residual stress on the propagation of fatigue cracks orthogonal to the weld direction in a friction stir welded Ti-6Al-4V joint was investigated. A numerical prediction of the fatigue crack growth rate in the presence of the residual stresses was carried out using AFGROW software; reasonable correspondence between the predictions and the experimental results were observed when the effects of residual stress were included in the simulation.

musculoskeletal diseasesMaterials scienceMechanical EngineeringMetallurgytechnology industry and agricultureAFGROWFracture mechanicsrespiratory systemParis' lawCrack closureMechanics of MaterialsResidual stressFriction stir weldingGeneral Materials ScienceFriction weldingComposite materialStress concentration
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Numerical experimental analysis of hybrid double lap aluminum-CFRP joints

2015

Abstract Due to their reliability and ease of assembly, both the adhesively bonded and the mechanical joints are commonly used in different fields of modern industrial design and manufacturing, to joint composite materials or composites with metals. As it is well known, adhesively bonded joints are characterized by high stiffness and good fatigue life, although delamination phenomena localized near the free edges may limit their use, especially for applications where corrosive environments and/or moisture can lead to premature failure of the bonding. In these cases, a possible alternative is given by the well-known mechanical joints. On the contrary, these last joints (bolted, riveted) requ…

musculoskeletal diseasesPolymer-matrix composites (PMCs)Materials sciencechemistry.chemical_elementIndustrial and Manufacturing EngineeringJoints/joiningSettore ING-IND/14 - Progettazione Meccanica E Costruzione Di MacchineAluminiumRivetComposite materialJoint (geology)Stress concentrationCarbon fiber reinforced polymerbusiness.industryMechanical EngineeringFinite element analysis (FEA)DelaminationHigh stiffnessStructural engineeringchemistryMechanics of MaterialsMechanical jointCeramics and CompositesPolymer-matrix composites (PMCs); Mechanical properties; Finite element analysis (FEA); Joints/joiningbusinessMechanical propertie
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Finite element multi-scale modeling of the failure mechanisms in a 3D woven composite

2013

International audience

textile compositefinite element[ SPI.MAT ] Engineering Sciences [physics]/Materialsmultiscale analysis[SPI.MAT] Engineering Sciences [physics]/Materialsstress concentration coefficientComputingMilieux_MISCELLANEOUS[SPI.MAT]Engineering Sciences [physics]/Materials
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