06229nam 2201525z- 450 991055739230332120220111(CKB)5400000000041975(oapen)https://directory.doabooks.org/handle/20.500.12854/76860(oapen)doab76860(EXLCZ)99540000000004197520202201d2021 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierBehavior of Metallic and Composite Structures (Second Volume)Basel, SwitzerlandMDPI - Multidisciplinary Digital Publishing Institute20211 online resource (325 p.)3-0365-1492-9 3-0365-1491-0 Various types of metallic and composite structures are used in modern engineering practice. For aerospace, car industry, and civil engineering applications, the most important are thin-walled structures made of di erent types of metallic alloys, brous composites, laminates, and multifunctional materials with a more complicated geometry of reinforcement including nanoparticles or nano bres. The current applications in modern engineering require analysis of structures of various properties, shapes, and sizes (e.g., aircraft wings) including structural hybrid joints, subjected to di erent types of loadings, including quasi-static, dynamic, cyclic, thermal, impact, penetration, etc.The advanced metallic and composite structures should satisfy multiple structural functions during operating conditions. Structural functions include mechanical properties such as strength, sti ness, damage resistance, fracture toughness, and damping. Non-structural functions include electrical and thermal conductivities, sensing, actuation, energy harvesting, self-healing capability, electromagnetic shielding, etc.The aim of this SI is to understand the basic principles of damage growth and fracture processes in advanced metallic and composite structures that also include structural joints. Presently, it is widely recognized that important macroscopic properties, such as macroscopic sti ness and strength, are governed by processes that occur at one to several scales below the level of observation. A thorough understanding of how these processes influence the reduction of sti ffness and strength forms the key to the design of improved innovative structural elements and the analysis of existing ones.Behavior of Metallic and Composite StructuresTechnology: general issuesbicssc3D-printed sandwich4 methods (CPT, FSDT, S-FSDT, FEM)adhesionadhesive bond strengthadhesive jointadhesive layer thicknessage-adjusted effective modulus methodAlCrNarc currentartificial neural networksaxial compressive behaviourbeamsbending responseboltboundary strengtheningboundary structureC-sectionceramic-matrix composites (CMCs)characterization techniquescohesive lawcomponents of transverse forces in bendingcomposite stanchioncompressionconcrete creepconcrete filled steel tube (CFST) columnsconfined concreteconnectioncrashworthinesscurved steel-concrete composite box beamdamagedeformation diagramsdeformation twin-boundary interactiondigital image correlationdislocation-boundary interactiondislocation-interface interactiondistortional modedual adhesivedynamic pulse bucklingember-resistant alloysenergy absorptionexperimentfailureFE analysisFEMfracturefracture mechanicsgeometrical optimizationglued laminated timberhardnessheight factorI-shaped beaminteractive bucklingknotsKoiter's theoryKolsky methodlaboratory testslocal compressionlong-term behaviormaterial testsmechanism mapsmedium lengthmembrane components of transverse forcesminicompositemixed mode I+II loadingmodulus of elasticitymoisture contentnatural compositenonlinear analysisnonlinear stabilitynumerical modelingpine woodpredictionreinforced concrete (RC)sandwich panels with corrugated channel coreshear forcessingle lap jointssize effectsquare platesteel meshsteel platesteel-concrete composite bridgestructuretemperaturetensiletestTH-sectionthrough-beam jointtimberturbine jet enginetwo-node finite beam element with 26 DOFsverificationwearwoodwood defectswood modelwood speciesTechnology: general issuesSadowski Tomaszedt720981Altenbach HolmedtSadowski TomaszothAltenbach HolmothBOOK9910557392303321Behavior of Metallic and Composite Structures (Second Volume)3024501UNINA