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100   $a20081209d2007      ua             0
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200 00$aProbabilistic fracture mechanics$b[electronic resource] $emodels, parameters, and uncertainty treatment used in FAVOR version 04.1 /$fprepared by M. EricksonKirk ... [and others]
210  1$aWashington, DC :$cDivision of Fuel, Engineering, and Radiological Research, Office of Nuclear Regulatory Research, U.S. Nuclear Regulatory Commission,$d2007.
215   $a1 volume (various pagings) $cdigital, PDF file
300   $aTitle from title screen (viewed on Dec. 9, 2008).
300   $a"Date published: June 2007."
300   $a"NUREG-1807."
517   $aProbabilistic fracture mechanics 
606   $aNuclear pressure vessels$xMaterials$xFracture$xComputer programs
606   $aFracture mechanics$xComputer programs
615  0$aNuclear pressure vessels$xMaterials$xFracture$xComputer programs.
615  0$aFracture mechanics$xComputer programs.
701   $aEricksonKirk$b M$01400436
712 02$aU.S. Nuclear Regulatory Commission.$bDivision of Fuel, Engineering, and Radiological Research.
801  0$bGPO
801  1$bGPO
906   $aBOOK
912   $a9910697208203321
996   $aProbabilistic fracture mechanics$93467355
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LEADER 04079nam  22005893a 450 
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010   $a9783038974925
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024 8 $a10.3390/books978-3-03897-492-5
035   $a(CKB)4920000000095215
035   $a(oapen)https://directory.doabooks.org/handle/20.500.12854/45234
035   $a(ScCtBLL)4ab44775-9ef5-4ec5-a476-12f23d5ed63f
035   $a(OCoLC)1163840415
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135   $aurmn|---annan
181   $ctxt$2rdacontent
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200 00$aDiscontinuous Fiber Composites$fTim Osswald
210   $cMDPI - Multidisciplinary Digital Publishing Institute$d2019
210  1$aBasel, Switzerland :$cMDPI,$d2018.
215   $a1 electronic resource (210 p.)
311 08$a9783038974918 
311 08$a3038974919 
330   $aDiscontinuous fiber-reinforced polymers have gained importance in the transportation industries due to their outstanding material properties, lower manufacturing costs and superior lightweight characteristics. One of the most attractive attributes of discontinuous fiber reinforced composites is the ease with which they can be manufactured in large numbers, using injection and compression molding processes. Typical processes involving discontinuous fiber reinforced thermoplastic composite materials include injection and compression molding processes as well as extrusion. Furthermore, the automotive and appliance industries also use thermosets reinforced with chopped fibers in the form of sheet molding compound and bulk molding compound, for compression and injection-compression molding processes, respectively. A big disadvantage of discontinuous fiber composites is that the configuration of the reinforcing fibers is significantly changed throughout production process, reflected in the form of fiber attrition, excessive fiber orientation, fiber jamming and fiber matrix separation. This process-induced variation of the microstructural fiber properties within the molded part introduces heterogeneity and anisotropies to the mechanical properties, which can limit the potential of discontinuous fiber reinforced composites for lightweight applications. The main aim of this Special Issue is to collect various investigations focused on the processing of discontinuous fiber reinforced composites and the effect processing has on fiber orientation, fiber length and fiber density distributions throughout the final part. Papers presenting investigations on the effect fiber configurations have on the mechanical properties of the final composite products and materials are welcome in the Special Issue. Researchers who are modeling and simulating processes involving discontinuous fiber composites as well as those performing experimental studies involving these composites are welcomed to submit papers. Authors are encouraged to present new models, constitutive laws and measuring and monitoring techniques to provide a complete framework on these groundbreaking materials and facilitate their use in different engineering applications.
606   $aChemistry$2bicssc
610   $afiber attrition
610   $acompression molding
610   $afiber density distributions
610   $amicro computed tomography
610   $achopped fibers
610   $adiscontinuous fibers
610   $afiber orientation distributions
610   $asheet molding compound (SMC)
610   $afiber length distributions
610   $acompounding
610   $ashort fiber reinforced thermoplastics (SFT)
610   $along fiber reinforced thermoplastics (LFT)
610   $abulk Molding Compound (BMC)
610   $ainjection molding
615  7$aChemistry
700   $aOsswald$b Tim$0601429
801  0$bScCtBLL
801  1$bScCtBLL
906   $aBOOK
912   $a9910346842503321
996   $aDiscontinuous Fiber Composites$94318167
997   $aUNINA