Search results for "Finite element model"

showing 10 items of 43 documents

In Silico Evaluation of Treatment of Periprosthetic Fractures in Elderly Patients After Hip Arthroplasty

2021

The aim of this study was to investigate the soundness of in silico finite element model (FEM) in the assessment of strain in the femur and in the components fixing the periprosthetic fracture in elderly patients after hip arthroplasty. From a group of 55 patients, aged 27–95, treated due to fractures after hip replacement in 2012–2018, 18 patients were separated out, aged over 85, out of whom 7 had type C fractures, according to the Vancouver classification. These seven patients formed the study group. The fractures were stabilized with a locking compression plate system and wire loops or by replacement of the endoprosthesis stem. The FEM was performed by processing radiological images of …

Elderly patientsPeriprosthetic fractureEndoprosthesisIn silicoHip arthroplastyFinite element model

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Numerical prediction of the shear response of semi-prefabricated steel-concrete trussed beams

2016

Abstract In this study, the shear behavior of hybrid steel-trussed-concrete beams (HSTCBs) realized with prefabricated steel trusses embedded into a concrete core cast in situ, is investigated by means of Finite Element (FE) numerical simulations. HSTCBs do not behave as classical RC elements nor composite beams. Up to now, there are not specific design criteria in the building codes and the calculation of this type of beams is conducted by means of design-by-testing procedures. The knowledge of the material behavior as well as the understanding of the interaction between materials in contact is the first requirement for the definition of proper design procedures and calculation methods for…

EngineeringWork (thermodynamics)0211 other engineering and technologiesTruss020101 civil engineering02 engineering and technologyBendingConcrete damaged plasticity model0201 civil engineering021105 building & constructionGeneral Materials ScienceHybrid steel trussed-concrete beamShear behaviorVariable (mathematics)Civil and Structural EngineeringComputer simulationbusiness.industryCohesive steel-concrete interface; Concrete damaged plasticity model; Finite element model; Hybrid steel trussed-concrete beams; Shear behavior; Civil and Structural Engineering; Building and Construction; Materials Science (all)Structural engineeringBuilding and ConstructionFinite element methodShear (sheet metal)Settore ICAR/09 - Tecnica Delle CostruzioniHybrid steel trussed-concrete beamsCohesive steel-concrete interfaceMaterials Science (all)businessBeam (structure)Finite element model

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Finite element modelling of slipage between FRP rebar and concrete in pull-out test

2014

The paper presents numerical results of direct pull-out test of glass fiber-reinforced polymer (GFRP) rebars embedded in concrete. Rebars of three different cross-sections are considered: circular without longitudinal ribs and with two and four ribs. The design analyses of the rebar configurations embedded in concrete are investigated by the 3D finite element method (FEM), which takes into account the non-linearity using ANSYS software. The results of the numerical model with two ribs were compared with the experimental results. Then, the effect of different rebar geometries to the load-slip pull-out curves was studied. It is concluded that the influence of rib height and width on the pull-…

Engineeringlawbusiness.industryglass fiber-reinforced polymer (GFRP) rebar finite element modelling pull-out test load-slip behaviour ANSYSRebarAnsys softwareStructural engineeringComposite materialFibre-reinforced plasticbusinessFinite element methodlaw.inventionThe International Scientific Conference „Innovative Materials, Structures and Technologies"

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Design of RC joints equipped with hybrid trussed beams and friction dampers

2021

Abstract The challenge of this research consists in the first attempt to apply a dissipative friction connection to beam-to-column joints with semi-prefabricated Hybrid Steel-Trussed Concrete Beams (HSTCB) and RC pillars cast in-situ. Nowadays, HSTCBs are widely adopted in civil and industrial buildings and, therefore, it is required to evaluate their compliance with the capacity design criteria and their seismic energy dissipation capability. However, the design of the reinforcement of such beams usually lead to the adoption of large amount of steel within the panel zone which becomes potentially vulnerable to the effects of seismic cyclic actions and dramatically reduce the dissipation ca…

Finite element modelsComputer scienceShear force0211 other engineering and technologies020101 civil engineering02 engineering and technologyRC jointsSeismic energy dissipation0201 civil engineeringDamper021105 building & constructionmedicineTorqueCivil and Structural Engineeringbusiness.industryFriction dampersStiffnessStructural engineeringDissipationFinite element methodSettore ICAR/09 - Tecnica Delle CostruzioniCyclic behaviour; Earthquake design; Finite element models; Friction dampers; Hybrid steel-trussed-concrete beams; RC joints; Seismic energy dissipation; Structural designHybrid steel-trussed-concrete beamsStructural designBending momentCyclic behaviourEarthquake designmedicine.symptombusinessBeam (structure)Engineering Structures

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A new design problem in the formulation of a special moment resisting connection device for preventing local buckling

2021

In the present paper an improved formulation devoted to the optimal design problem of a special moment resisting connection device for steel frames is proposed. This innovative device is called a Limited Resistance Plastic Device (LRPD) and it has been recently proposed and patented by some of the authors. It is thought to be preferably located at the extremes of the beam, connecting the beam end cross section with the relevant column. The typical device is a steel element characterized by symmetry with respect to three orthogonal barycentric planes and constituted by a sequence of three portions with abrupt cross section changes. The main novelty of the present proposal is related to the d…

Fluid Flow and Transfer ProcessesTechnologyQH301-705.5Finite element modelsTPhysicsQC1-999Process Chemistry and TechnologyGeneral EngineeringSteel designEngineering (General). Civil engineering (General)Computer Science Applicationsmoment resisting connections; full plastic deformations; minimum volume design; finite element models; steel designChemistryFull plastic deformationsMoment resisting connectionsMinimum volume designGeneral Materials ScienceTA1-2040Biology (General)QD1-999Instrumentation

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Empirical Equations for the Direct Definition of Stress–Strain Laws for Fiber-Section-Based Macromodeling of Infilled Frames

2018

Equivalent strut macromodels are largely used to model the influence of infill walls in frame structures due to their simplicity and effectiveness from a computational point of view. Despite these advantages, which are fundamental to carrying out seismic simulation of complex structures, equivalent struts are phenomenological models and therefore have to conventionally account for the influence of really large amounts of geometrical and mechanical variables with a relatively simple inelastic response. Mechanical approaches, generally used to evaluate the force-displacement curve of a strut, are based on hypothesizing the damage mechanism that will occur for an infill-frame system subject to…

Infilled framesComputer science0211 other engineering and technologies020101 civil engineering02 engineering and technologyFiber section; Finite element modeling (FEM); Infilled frames; Masonry; OpenSees; Reinforced concrete; Mechanics of Materials; Mechanical Engineering0201 civil engineeringOpenSeesInfillPoint (geometry)MasonryOpenSee021110 strategic defence & security studiesbusiness.industryFiber (mathematics)OpenSeesMechanical EngineeringStress–strain curveFrame (networking)Structural engineeringFiber sectionFinite element modeling (FEM)MasonryStrength of materialsReinforced concreteSettore ICAR/09 - Tecnica Delle CostruzioniMechanics of MaterialsbusinessInfilled frameJournal of Engineering Mechanics

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Deformation and failure of MXene nanosheets

2020

This work is aimed at the development of finite element models and prediction of the mechanical behavior of MXene nanosheets. Using LS-Dyna Explicit software, a finite element model was designed to simulate the nanoindentation process of a two-dimensional MXene Ti3C2Tz monolayer flake and to validate the material model. For the evaluation of the adhesive strength of the free-standing Ti3C2Tz-based film, the model comprised single-layered MXene nanosheets with a specific number of individual flakes, and the reverse engineering method with a curve fitting approach was used. The interlaminar shear strength, in-plane stiffness, and shear energy release rate of MXene film were predicted using th…

Materials science02 engineering and technology010402 general chemistrylcsh:Technology01 natural sciencesArticleMonolayermedicineGeneral Materials ScienceComposite materiallcsh:Microscopylcsh:QC120-168.85Strain energy release ratelcsh:QH201-278.5lcsh:TTension (physics)MXene; mechanical behavior; finite element modelingStiffnessfinite element modelingNanoindentation021001 nanoscience & nanotechnologyFinite element method0104 chemical sciencesShear (sheet metal)lcsh:TA1-2040mechanical behaviorlcsh:Descriptive and experimental mechanicslcsh:Electrical engineering. Electronics. Nuclear engineeringDeformation (engineering)medicine.symptomlcsh:Engineering (General). Civil engineering (General)0210 nano-technologyMXenelcsh:TK1-9971

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Numerical simulations of the mechanical characteristics of glass fibre reinforced C-profiles

2006

A mechanical characterisation analysis on pultruded glass fibre reinforced C-shaped profiles, developed as modular construction elements to assemble fastening systems, such as doors, window frames and shutters is presented. The key idea is to perform the analysis, and all the related identification procedures of the material parameters, via a coupled approach, based on a limited number of standard laboratory tests and on the numerical finite element simulations of the same tests. The proposed approach allows one to identify all those material parameters which are difficult to detect, by means of simple laboratory experiments on specimens that are extracted from commercial products. It also …

Materials scienceComputer simulationDesign toolGlass fiberGeneral EngineeringE. Pultrusion.Modular constructionA. Polymer–matrix compositeFinite element methodSimple (abstract algebra)PultrusionCeramics and CompositesCalibrationComposite materialB. Mechanical characterisation C. Finite element modelling

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Finite element analysis of the out-of-plane behavior of FRP strengthened masonry panels

2017

Abstract In the present study a numerical model is proposed for the response of out-of-plane loaded calcarenite masonry walls strengthened with vertical CFRP strips applied on the substrate by means of epoxy resin. A simplified structural scheme is considered consisting in a beam fixed at one end, subjected to constant axial load and out-of-plane lateral force monotonically increasing. Two different constraint conditions are taken into account: in the first one, the panel is assumed free to rotate at the top end while, in the second one, the rotation is restrained. Three-dimensional finite elements are used for the calcarenite parts and an equivalent constitutive law available in the litera…

Materials scienceConstitutive equationShell (structure)FRP-masonry interfaceCeramics and CompositeFinite element modeling; FRP strengthening; FRP-masonry interface; Masonry panels; Out-of-plane behavior; Ceramics and Composites; Mechanics of Materials; Mechanical Engineering; Industrial and Manufacturing Engineering02 engineering and technology010402 general chemistry01 natural sciencesIndustrial and Manufacturing EngineeringFRP strengtheningMechanics of MaterialMasonry panelsComposite materialFinite element modelingMasonry panelbusiness.industryMechanical EngineeringLinear elasticityStructural engineeringMasonryFibre-reinforced plastic021001 nanoscience & nanotechnologyStrength of materialsFinite element method0104 chemical sciencesSettore ICAR/09 - Tecnica Delle CostruzioniMechanics of MaterialsCeramics and Composites0210 nano-technologybusinessBeam (structure)Out-of-plane behavior

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Mechanical and metallurgical effects of in process cooling during friction stir welding of AA7075-T6 butt joints

2010

This paper presents the results of a combined experimental and numerical investigation focused on the effects of an in process water cooling treatment aimed at improving the final quality of friction stir welded butt joints in terms of mechanical resistance and metallurgy of the processed material. Micro and macro observations, together with the evolution of an already developed finite element tool, have been used to analyze specimens obtained under different process conditions. Water cooling was found to enhance joint strength, reducing the material softening usually observed in the thermo-mechanically affected zone area, with no detrimental effect on nugget integrity.

Materials sciencePolymers and PlasticsFriction stir weldingMetallurgyMetals and AlloysWeldingFinite element methodElectronic Optical and Magnetic Materialslaw.inventionIn process cooling treatmentslawCeramics and CompositesButt jointWater coolingFriction stir weldingFriction weldingFinite element modelingJoint (geology)SofteningSettore ING-IND/16 - Tecnologie E Sistemi Di Lavorazione

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