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LEADER: 08852cam 2200565 a 4500
001 ocm57484934
003 OCoLC
005 20220919064544.0
008 050111s2006 enka f b 001 0 eng
040 $aUKM$beng$cUKM$dBAKER$dBWKUK$dYDXCP$dOCLCQ$dU3Q$dBTCTA$dOH@$dHDC$dOCLCF$dOCLCQ$dI8M$dOCLCQ$dNJR$dLND$dAU@$dOCLCQ$dIL4J6$dLVT$dOCLCO$dOCLCQ
015 $aGBA504332$2bnb
016 7 $a013085526$2Uk
019 $a1229624327
020 $a0750663812$q(pbk.)
020 $a9780750663816$q(pbk.)
020 $a9780080468631$q(ebook)
020 $a0080468632
024 3 $a9780750663816
035 $a(OCoLC)57484934$z(OCoLC)1229624327
050 4 $aTA403$b.A689 2006
082 04 $a620.1/1$222
100 1 $aAshby, M. F.
245 10 $aEngineering materials 2 :$ban introduction to microstructures, processing and design /$cMichael F. Ashby and David R.H. Jones.
250 $a3rd ed.
260 $aOxford ;$aBurlington, MA :$bButterworth-Heinemann,$c2006.
300 $axiii, 451 pages :$billustrations ;$c25 cm
336 $atext$btxt$2rdacontent
337 $aunmediated$bn$2rdamedia
338 $avolume$bnc$2rdacarrier
500 $aPrevious edition: 1998.
504 $aIncludes bibliographical references (pages 442-443) and index.
505 00 $tA Metals$g1 --$g1$tMetals$g3 --$tThe generic metals and alloys --$tIron-based, copper-based, nickel-based, aluminium-based and titanium-based alloys --$tDesign data --$g2$tMetal structures$g14 --$tThe range of metal structures that can be altered to get different properties: crystal and glass structure, structures of solutions and compounds, grain and phase boundaries, equilibrium shapes of grains and phases --$g3$tEquilibrium constitution and phase diagrams$g25 --$tHow mixing elements to make an alloy can change their structure --$tExamples: the lead-tin, copper-nickel and copper-zinc alloy systems --$g4$tCase studies in phase diagrams$g35 --$tChoosing soft solders --$tPure silicon for microchips --$tMaking bubble-free ice --$g5$tThe driving force for structural change$g48 --$tThe work done during a structural change gives the driving force for the change --$tExamples: solidification, solid-state phase changes, precipitate coarsening, grain growth, recrystallisation --$tSizes of driving forces --$g6$tKinetics of structural change: I -- diffusive transformations$g61 --$tWhy transformation rates peak -- the opposing claims of driving force and thermal activation --$tWhy latent heat and diffusion slow transformations down --$g7$tKinetics of structural change: II -- nucleation$g74 --$tHow new phases nucleate in liquids and solids --$tWhy nucleation is helped by solid catalysts --$tExamples: nucleation in plants, vapour trails, bubble chambers and caramel --$g8$tKinetics of structural change: III -- displacive transformations$g83 --$tHow we can avoid diffusive transformations by rapid cooling --$tThe alternative -- displacive (shear) transformations at the speed of sound --$g9$tCase studies in phase transformations$g97 --$tArtificial rain-making --$tFine-grained castings --$tSingle crystals for semiconductors --$tAmorphous metals --$g10$tThe light alloys$g108 --$tWhere they score over steels --$tHow they can be made stronger: solution, age and work hardening --$tThermal stability --$g11$tSteels: I -- carbon steels$g122 --$tStructures produced by diffusive changes --$tStructures produced by displacive changes (martensite) --$tWhy quenching and tempering can transform the strength of steels --$tThe TTT diagram --$g12$tSteels: II -- alloy steels$g135 --$tAdding other elements gives hardenability (ease of martensite formation), solution strengthening, precipitation strengthening, corrosion resistance, and austenitic (f.c.c.) steels --$g13$tCase studies in steels$g144 --$tMetallurgical detective work after a boiler explosion --$tWelding steels together safely --$tThe case of the broken hammer --$g14$tProduction, forming and joining of metals$g155 --$tProcessing routes for metals --$tCasting --$tPlastic working --$tControl of grain size --$tMachining --$tJoining --$tSurface engineering --$gB$tCeramics and glasses$g173 --$g15$tCeramics and glasses$g175 --$tThe generic ceramics and glasses: glasses, vitreous ceramics, high-technology ceramics, cements and concretes, natural ceramics (rocks and ice), ceramic composites --$tDesign data --$g16$tStructure of ceramics$g183 --$tCrystalline ceramics --$tGlassy ceramics --$tCeramic alloys --$tCeramic micro-structures: pure, vitreous and composite --$g17$tThe mechanical properties of ceramics$g193 --$tHigh stiffness and hardness --$tPoor toughness and thermal shock resistance --$tThe excellent creep resistance of refractory ceramics --$g18$tThe statistics of brittle fracture and case study$g202 --$tHow the distribution of flaw sizes gives a dispersion of strength: the Weibull distribution --$tWhy the strength falls with time (static fatigue) --$tCase study: the design of pressure windows --$g19$tProduction, forming and joining of ceramics$g213 --$tProcessing routes for ceramics --$tMaking and pressing powders to shape --$tWorking glasses --$tMaking high-technology ceramics --$tJoining ceramics --$tApplications of high-performance ceramics --$g20$tSpecial topic: cements and concretes$g227 --$tHistorical background --$tCement chemistry --$tSetting and hardening of cement --$tStrength of cement and concrete --$tHigh-strength cements --$gC$tPolymers and composites$g239 --$g21$tPolymers$g241 --$tThe generic polymers: thermoplastics, thermosets, elastomers, natural polymers --$tDesign data --$g22$tThe structure of polymers$g251 --$tGiant molecules and their architecture --$tMolecular packing: amorphous or crystalline? --$g23$tMechanical behaviour of polymers$g262 --$tHow the modulus and strength depend on temperature and time --$g24$tProduction, forming and joining of polymers$g279 --$tMaking giant molecules by polymerisation --$tPolymer "alloys" --$tForming and joining polymers --$g25$tComposites: fibrous, particulate and foamed$g289 --$tHow adding fibres or particles to polymers can improve their stiffness, strength and toughness --$tWhy foams are good for absorbing energy --$g26$tSpecial topic: wood$g306 --$tOne of nature's most successful composite materials --$gD$tDesigning with metals, ceramics, polymers and composites$g317 --$g27$tDesign with materials$g319 --$tThe design-limiting properties of metals, ceramics, polymers and composites --$tDesign methodology --$g28$tCase studies in design$g326 --$g1$tDesigning with metals: conveyor drums for an iron ore terminal --$g2$tDesigning with ceramics: ice forces on offshore structures --$g3$tDesigning with polymers: a plastic wheel --$g4$tDesigning with composites: materials for violin bodies --$g29$tEngineering failures and disasters -- the ultimate test of design$g352 --$gCase study 1$tThe Tay Bridge railway disaster -- 28 December 1879 --$gCase study 2$tThe Comet air disasters -- 10 January and 8 April 1954 --$gCase study 3$tThe Eschede railway disaster -- 5 June 1998 --$gCase study 4$tA fatal bungee-jumping accident --$gAppendix 1$tTeaching yourself phase diagrams$g380.
520 $a" ... This book provides a detailed understanding of the fundamental properties of engineering materials: how they are controlled by processing, then formed, joined and finsished, and how all of these factors influence the selection and design of materials in real-world engineering applications. New materials and features in the updated third edition include a new chapter on materials failures, expanded design coverage, additional exercises and examples with more real design situations, and an online Instructor's Solutions Manual, plus materials science tutorials."--Back cover.
650 0 $aMaterials.
650 6 $aMatériaux.
650 7 $aMaterials.$2fast$0(OCoLC)fst01011772
650 7 $aMaterials.$2nli
650 7 $aMicrostructure.$2nli
700 1 $aJones, David R. H.$q(David Rayner Hunkin),$d1945-
856 41 $uhttps://ebookcentral.proquest.com/lib/londonmet/detail.action?docID=4952362$zE-book - Full text from Ebook Central
856 41 $uhttps://liverpool.idm.oclc.org/login?url=http://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&db=nlabk&AN=319661$z<img src="/screens/gifs/go4.gif" alt="Go button" border="0" width="21" height="21" hspace="7" align="middle">View this e-book online
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938 $aBaker & Taylor$bBKTY$c54.95$d54.95$i0750663812$n0006199121$sactive
938 $aBaker and Taylor$bBTCP$nBK0006199121
938 $aYBP Library Services$bYANK$n2162792
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