01089nam0 22002771i 450 UON0006358020231205102319.76320020107d1975 |0itac50 baengUS|||| 1||||Japanese urbanismIndustry and politics in Kariya, 1872-1972Gary D. AllisonBerkeleyUniversity of California Press1975XIV, 276 p.24 cmGIAPPONEPOLITICAUONC002803FIIndustriaGiapponeUONC004747FIUSBerkeleyUONL000021GIA XIGIAPPONE - ARCHITETTURA E URBANISTICAAALLISONGary D.UONV040647656295University of California PressUONV247423650ITSOL20250704RICASIBA - SISTEMA BIBLIOTECARIO DI ATENEOUONSIUON00063580SIBA - SISTEMA BIBLIOTECARIO DI ATENEOSI GIA XI 002 SI SA 1427 7 002 Japanese urbanism1171681UNIOR04104nam 2200949z- 450 991058594420332120220812(CKB)5600000000483036(oapen)https://directory.doabooks.org/handle/20.500.12854/91156(oapen)doab91156(EXLCZ)99560000000048303620202208d2022 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierFracture, Fatigue, and Structural Integrity of Metallic Materials and Components Undergoing Random or Variable Amplitude LoadingsBaselMDPI - Multidisciplinary Digital Publishing Institute20221 online resource (190 p.)3-0365-4692-8 3-0365-4691-X Most metallic components and structures are subjected, in service, to random or variable amplitude loadings. There are many examples: vehicles subjected to loadings and vibrations caused by road irregularity and engine, structures exposed to wind, off-shore platforms undergoing wave-loadings, and so on. Just like constant amplitude loadings, random and variable amplitude loadings can make fatigue cracks initiate and propagate, even up to catastrophic failures. Engineers faced with the problem of estimating the structural integrity and the fatigue strength of metallic structures, or their propensity to fracture, usually make use of theoretical, numerical, or experimental approaches. This reprint collects a series of recent scientific contributions aimed at providing an up-to-date overview of approaches and case studies-theoretical, numerical or experimental-on several topics in the field of fracture, fatigue strength, and the structural integrity of metallic components subjected to random or variable amplitude loadings.History of engineering and technologybicsscTechnology: general issuesbicsscanalytical frameworkcrack closurecrack growthdiscontinuous displacementsFALSTAFF flight load spectrafatiguefatigue crackfatigue crack growthfatigue damagefatigue life predictionfracture analysisheight digital image correlationhelicopter flight load spectrahigh-temperature fatigueinvestment castinglattice structuresmetallic materialsmetallographyn/anickel-based superalloynonstationary random loadingsoptical profilometryplasticitypower spectral density (PSD)random loadingrandom loadingsrepair welding thermal shockresidual strengthretardation effectrun testservo-hydraulicshaker tableshort-time Fourier transformsmall cracksspectral methodsspectrum loadingstructural dynamic responsesurface topographytesting systemstriaxial displacementsturbine bladevibration fatigue testingwelded jointwelding linear energyXFEMHistory of engineering and technologyTechnology: general issuesBenasciutti Denisedt1293867Whittaker MarkedtDirlik TuranedtBenasciutti DenisothWhittaker MarkothDirlik TuranothBOOK9910585944203321Fracture, Fatigue, and Structural Integrity of Metallic Materials and Components Undergoing Random or Variable Amplitude Loadings3022800UNINA