LEADER 04816nam 2201069z- 450 001 9910557477303321 005 20210501 035 $a(CKB)5400000000043024 035 $a(oapen)https://directory.doabooks.org/handle/20.500.12854/68605 035 $a(oapen)doab68605 035 $a(EXLCZ)995400000000043024 100 $a20202105d2020 |y 0 101 0 $aeng 135 $aurmn|---annan 181 $ctxt$2rdacontent 182 $cc$2rdamedia 183 $acr$2rdacarrier 200 00$aPolymer Processing: Modeling and Correlations Finalized to Tailoring the Plastic Part Morphology and Properties 210 $aBasel, Switzerland$cMDPI - Multidisciplinary Digital Publishing Institute$d2020 215 $a1 online resource (232 p.) 311 08$a3-03928-754-0 311 08$a3-03928-755-9 330 $aThe analysis of polymer processing operations is a wide and complex subject; during polymer processing, viscoelastic fluids are forced to deform into desired geometries using non-homogeneous velocity and temperature fields down to solidification. The objective of analysis is the identification of processing conditions, which are finalized in the optimization of product final properties, which, in turn, are determined by the final part morphology. Depending on the operating conditions, the properties of the final part can change more than one order of magnitude. Properties of interest include the mechanical, optical, barrier, permeability, and biodegradability, and any other property of practical relevance including the characteristics of the surfaces as its finishing and wettability, which are connected to one another. The scope of this Special Issue is to select progress in or reviews of the understanding/description of the phenomena involved along the chain of processing-morphology-properties. Along this virtual chain, modeling may be a useful approach, and within the objective of understanding fundamental aspects, it may also be relevant to compare selected characteristics of the process and the material with the characteristics of the resulting morphology and then with the properties of the final part. This approach suggests the title: "Polymer Processing: Modeling and Correlations Finalized to Tailoring the Plastic Part Morphology and Properties". 517 $aPolymer Processing 606 $aHistory of engineering and technology$2bicssc 610 $a"skin-core-skin" structure 610 $a3D-printing 610 $aadditive manufacturing 610 $abirefringence 610 $abreakdown 610 $acellulose insulation pressboard 610 $achaotic manifold 610 $acomposite laminates 610 $aconversion 610 $acrystal morphology 610 $acylindrites 610 $adesign optimization 610 $aepoxy 610 $aextrusion 610 $afilm stretching 610 $afinite-time Lyapunov exponents (FTLE) 610 $aflow-induced crystallization 610 $afour-screw extruder 610 $afused filament fabrication 610 $ahighly-filled polymers 610 $ahydrophobicity 610 $ainjection molding 610 $akriging surrogate model 610 $alaser-assisted thermal imprinting 610 $amagnetron sputtering 610 $amaterial extrusion 610 $ametals and ceramics 610 $amicrofeature 610 $amicroinjection molding 610 $amicrolens array 610 $amold temperature 610 $amolecular orientation 610 $amorphology 610 $amorphology prediction 610 $amultiscale simulation 610 $anano structure 610 $ananofeature 610 $anatural fiber composites 610 $anumerical simulation 610 $apattern size 610 $aPoincare? section 610 $apolylactic acid 610 $apolymeric stent 610 $apolytetrafluoroethylene 610 $aPP/TiO2 nanocomposites 610 $apressure 610 $areplication 610 $aresidence time distribution 610 $aresidual stress 610 $aretardation 610 $ashear layer 610 $asilk fibers 610 $asimulation 610 $astress-optical rule 610 $athermoplastic polymer 610 $atwin screw extruder 610 $auniaxial/biaxial stretching 610 $awarpage 615 7$aHistory of engineering and technology 700 $aTitomanlio$b Giuseppe$4edt$067766 702 $aSperanza$b Vito$4edt 702 $aTitomanlio$b Giuseppe$4oth 702 $aSperanza$b Vito$4oth 906 $aBOOK 912 $a9910557477303321 996 $aPolymer Processing: Modeling and Correlations Finalized to Tailoring the Plastic Part Morphology and Properties$93025172 997 $aUNINA