0000000000015434

AUTHOR

Ian Sinclair

showing 2 related works from this author

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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Damage accumulation in a carbon/epoxy composite : Comparison between a multiscale model and computed tomography experimental results

2012

International audience; High-resolution computed tomography has been carried out for carbon/epoxy laminates loaded in situ to failure. The experimental data allows major damage mechanisms to be quantified in 3D, in an unambiguous and mechanically representative way, where previous experimental analysis is limited. A multi-scale model that predicts damage accumulation in tensile loaded composites is compared to the experimental analysis, to validate the underpinning assumptions within the model and overall performance. The model considers the random nature of fibre-strengths, stress transfer resulting from fibre breaks, fibre/matrix debonding and viscosity of the matrix. Assumptions within t…

Polymer-matrix composites (PMCs)Materials scienceComposite number[ SPI.MAT ] Engineering Sciences [physics]/MaterialsExperimental data02 engineering and technologyEpoxy021001 nanoscience & nanotechnologyStress transfer[SPI.MAT]Engineering Sciences [physics]/MaterialsStress (mechanics)Matrix (mathematics)Viscosity020303 mechanical engineering & transportsFracture0203 mechanical engineeringMechanics of Materialsvisual_artUltimate tensile strengthCeramics and Compositesvisual_art.visual_art_mediumFracture (geology)Composite material0210 nano-technologyComputed tomography
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