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Fracture Mechanics and Fatigue Design in Metallic Materials

dc.contributor.editorRozumek, Dariusz
dc.date.accessioned2022-01-11T13:53:25Z
dc.date.available2022-01-11T13:53:25Z
dc.date.issued2021
dc.identifierONIX_20220111_9783036527307_966
dc.identifier.urihttps://directory.doabooks.org/handle/20.500.12854/77135
dc.description.abstractThe accumulation of damage and the development of fatigue cracks under the influence of loads is a common phenomenon that occurs in metals. To slow down crack growth and ensure an adequate level of safety and the optimal durability of structural elements, experimental tests and simulations are required to determine the influence of various factors. Such factors include, among others, the impact of microstructures, voids, notches, the environment, etc. Research carried out in this field and the results obtained are necessary to guide development toward the receipt of new and advanced materials that meet the requirements of the designers. This Special Issue aims to provide the data, models and tools necessary to provide structural integrity and perform lifetime prediction based on the stress (strain) state and, finally, the increase in fatigue cracks in the material.
dc.languageEnglish
dc.subject.classificationthema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issuesen_US
dc.subject.otherfatigue
dc.subject.otherfracture
dc.subject.othervery-high cycle
dc.subject.otherhigh-entropy alloy
dc.subject.otherpowder metallurgy
dc.subject.otherfish eye
dc.subject.othercrack branching behavior
dc.subject.othermicromechanical analysis
dc.subject.othercrack propagation path
dc.subject.otherwelded joints
dc.subject.otherstress concentration
dc.subject.othervibration-based fatigue
dc.subject.otherultra-high frequency
dc.subject.othervery high cycle fatigue
dc.subject.otherfatigue test
dc.subject.othertitanium alloy
dc.subject.otherhydrogen re-embrittlement
dc.subject.otherenvironmentally assisted cracking
dc.subject.othergalvanic protection
dc.subject.otherhigh strength steel
dc.subject.othercrack front shape
dc.subject.otherstructural plates
dc.subject.otherthrough-the-thickness crack
dc.subject.othersteady-state loading conditions
dc.subject.othersmall-scale yielding
dc.subject.otherpearlitic steel
dc.subject.otherCFRP patches
dc.subject.othercrack retardation
dc.subject.otherfatigue crack growth
dc.subject.otherfailure analysis
dc.subject.otherfatigue variability
dc.subject.otheralloy 625
dc.subject.otherthin tube
dc.subject.otherfractography
dc.subject.othermicrostructure
dc.subject.otheraluminum hand-hole
dc.subject.othernonreinforced hand-hole
dc.subject.otherdesign S-N curve
dc.subject.otherhigh cycle fatigue
dc.subject.otherCP Ti
dc.subject.otherstress amplitude
dc.subject.otherfatigue crack propagation
dc.subject.othercrack growth rate
dc.subject.otherroughness-induced crack closure
dc.subject.otherfracture toughness
dc.subject.othermachine learning
dc.subject.otherartificial neural network
dc.subject.otherpredictor
dc.subject.otheryield stress
dc.subject.othertensile strength
dc.subject.otherspecimen size
dc.subject.other2524-T3 aluminum alloy
dc.subject.othercorrosion
dc.subject.othercrack propagation
dc.subject.othern/a
dc.titleFracture Mechanics and Fatigue Design in Metallic Materials
dc.typebook
oapen.identifier.doi10.3390/books978-3-0365-2731-4
oapen.relation.isPublishedBy46cabcaa-dd94-4bfe-87b4-55023c1b36d0
oapen.relation.isbn9783036527307
oapen.relation.isbn9783036527314
oapen.pages180
oapen.place.publicationBasel, Switzerland


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