03854nam 2200997z- 450 991055749650332120220111(CKB)5400000000042866(oapen)https://directory.doabooks.org/handle/20.500.12854/77135(oapen)doab77135(EXLCZ)99540000000004286620202201d2021 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrierFracture Mechanics and Fatigue Design in Metallic MaterialsBasel, SwitzerlandMDPI - Multidisciplinary Digital Publishing Institute20211 online resource (180 p.)3-0365-2730-3 3-0365-2731-1 The 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.Technology: general issuesbicssc2524-T3 aluminum alloyalloy 625aluminum hand-holeartificial neural networkCFRP patchescorrosionCP Ticrack branching behaviorcrack front shapecrack growth ratecrack propagationcrack propagation pathcrack retardationdesign S-N curveenvironmentally assisted crackingfailure analysisfatiguefatigue crack growthfatigue crack propagationfatigue testfatigue variabilityfish eyefractographyfracturefracture toughnessgalvanic protectionhigh cycle fatiguehigh strength steelhigh-entropy alloyhydrogen re-embrittlementmachine learningmicromechanical analysismicrostructuren/anonreinforced hand-holepearlitic steelpowder metallurgypredictorroughness-induced crack closuresmall-scale yieldingspecimen sizesteady-state loading conditionsstress amplitudestress concentrationstructural platestensile strengththin tubethrough-the-thickness cracktitanium alloyultra-high frequencyvery high cycle fatiguevery-high cyclevibration-based fatiguewelded jointsyield stressTechnology: general issuesRozumek Dariuszedt1294157Rozumek DariuszothBOOK9910557496503321Fracture Mechanics and Fatigue Design in Metallic Materials3022944UNINA