LEADER 00893nam0-2200289 --450 
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010   $a978-88-467-5735-7
100   $a20231031d2019----kmuy0itay5050    ba
101 0 $aita
102   $aIT
105   $a        001yy
200 1 $aNew research on art in Fifteenth-century Naples$fedited by Adrian Bremenkamp and Sarah K. Kozlowoski
210   $aPisa$cETS$d2019
215   $a174 p., LXXXII p. di tav.$cill.$d21 cm
300   $aPredella n.17/18 (2018)
610 0 $aArte$aNapoli$aSec. 15.
676   $a709.024$v19
702  1$aBremenkamp,$bAdrian
702  1$aKozlowski,$bSarah Kathryn
801  0$aIT$bUNINA$gREICAT$2UNIMARC
901   $aBK
912   $a9910747798503321
952   $a709/C ETS 01 (02)$b2022/2485$fFLFBC
959   $aFLFBC
996   $aNew research on art in Fifteenth-century Naples$93574761
997   $aUNINA

LEADER 06229nam  2201525z- 450 
001 9910557392303321
005 20220111
035   $a(CKB)5400000000041975
035   $a(oapen)https://directory.doabooks.org/handle/20.500.12854/76860
035   $a(oapen)doab76860
035   $a(EXLCZ)995400000000041975
100   $a20202201d2021      |y         0
101 0 $aeng
135   $aurmn|---annan
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 00$aBehavior of Metallic and Composite Structures (Second Volume)
210   $aBasel, Switzerland$cMDPI - Multidisciplinary Digital Publishing Institute$d2021
215   $a1 online resource (325 p.)
311 08$a3-0365-1492-9 
311 08$a3-0365-1491-0 
330   $aVarious 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.
517   $aBehavior of Metallic and Composite Structures
606   $aTechnology: general issues$2bicssc
610   $a3D-printed sandwich
610   $a4 methods (CPT, FSDT, S-FSDT, FEM)
610   $aadhesion
610   $aadhesive bond strength
610   $aadhesive joint
610   $aadhesive layer thickness
610   $aage-adjusted effective modulus method
610   $aAlCrN
610   $aarc current
610   $aartificial neural networks
610   $aaxial compressive behaviour
610   $abeams
610   $abending response
610   $abolt
610   $aboundary strengthening
610   $aboundary structure
610   $aC-section
610   $aceramic-matrix composites (CMCs)
610   $acharacterization techniques
610   $acohesive law
610   $acomponents of transverse forces in bending
610   $acomposite stanchion
610   $acompression
610   $aconcrete creep
610   $aconcrete filled steel tube (CFST) columns
610   $aconfined concrete
610   $aconnection
610   $acrashworthiness
610   $acurved steel-concrete composite box beam
610   $adamage
610   $adeformation diagrams
610   $adeformation twin-boundary interaction
610   $adigital image correlation
610   $adislocation-boundary interaction
610   $adislocation-interface interaction
610   $adistortional mode
610   $adual adhesive
610   $adynamic pulse buckling
610   $aember-resistant alloys
610   $aenergy absorption
610   $aexperiment
610   $afailure
610   $aFE analysis
610   $aFEM
610   $afracture
610   $afracture mechanics
610   $ageometrical optimization
610   $aglued laminated timber
610   $ahardness
610   $aheight factor
610   $aI-shaped beam
610   $ainteractive buckling
610   $aknots
610   $aKoiter's theory
610   $aKolsky method
610   $alaboratory tests
610   $alocal compression
610   $along-term behavior
610   $amaterial tests
610   $amechanism maps
610   $amedium length
610   $amembrane components of transverse forces
610   $aminicomposite
610   $amixed mode I+II loading
610   $amodulus of elasticity
610   $amoisture content
610   $anatural composite
610   $anonlinear analysis
610   $anonlinear stability
610   $anumerical modeling
610   $apine wood
610   $aprediction
610   $areinforced concrete (RC)
610   $asandwich panels with corrugated channel core
610   $ashear forces
610   $asingle lap joints
610   $asize effect
610   $asquare plate
610   $asteel mesh
610   $asteel plate
610   $asteel-concrete composite bridge
610   $astructure
610   $atemperature
610   $atensile
610   $atest
610   $aTH-section
610   $athrough-beam joint
610   $atimber
610   $aturbine jet engine
610   $atwo-node finite beam element with 26 DOFs
610   $averification
610   $awear
610   $awood
610   $awood defects
610   $awood model
610   $awood species
615  7$aTechnology: general issues
700   $aSadowski$b Tomasz$4edt$0720981
702   $aAltenbach$b Holm$4edt
702   $aSadowski$b Tomasz$4oth
702   $aAltenbach$b Holm$4oth
906   $aBOOK
912   $a9910557392303321
996   $aBehavior of Metallic and Composite Structures (Second Volume)$93024501
997   $aUNINA