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Plates (Engineering) --- Shells (Engineering) --- Mechanical engineering. --- Engineering, Mechanical --- Engineering --- Machinery --- Steam engineering --- Structural shells --- Elastic plates and shells --- Structural analysis (Engineering) --- Disks (Mechanics) --- Panels --- Structural plates
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Plates (Engineering) --- Disks (Mechanics) --- Panels --- Structural plates --- Elastic plates and shells --- Structural analysis (Engineering) --- Shells (Engineering) --- Stability. --- Dynamics --- Mechanics --- Motion --- Vibration --- Benjamin-Feir instability --- Equilibrium
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This groundbreaking book resolves the main lacuna in Kirchhoff theory of bending of plates in the Poisson-Kirchhoff boundary conditions paradox through the introduction of auxiliary problem governing transverse stresses. The book highlights new primary bending problem which is formulated and analyzed by the application of developed Poisson theory. Analysis with prescribed transverse stresses along faces of the plate, neglected in most reported theories, is presented with an additional term in displacements. The book presents a systematic procedure for the analysis of unsymmetrical laminates. This volume will be a useful reference for students, practicing engineers as well as researchers in applied mechanics. .
Mechanical engineering. --- Mechanics. --- Mechanics, Applied. --- Vibration. --- Dynamical systems. --- Dynamics. --- Mechanical Engineering. --- Solid Mechanics. --- Vibration, Dynamical Systems, Control. --- Dynamical systems --- Kinetics --- Mathematics --- Mechanics, Analytic --- Force and energy --- Mechanics --- Physics --- Statics --- Cycles --- Sound --- Applied mechanics --- Engineering, Mechanical --- Engineering mathematics --- Classical mechanics --- Newtonian mechanics --- Dynamics --- Quantum theory --- Engineering --- Machinery --- Steam engineering --- Plates (Engineering) --- Flexure. --- Elastic plates and shells --- Mathematical models. --- Elastic shells --- Plates, Elastic --- Shells, Elastic --- Elastic waves --- Elasticity --- Plasticity --- Disks (Mechanics) --- Panels --- Structural plates --- Structural analysis (Engineering) --- Shells (Engineering)
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This book covers the essentials of developments in the area of plate structures and presents them so that the readers can obtain a quick understanding and overview of the subject. Several theoretical models are employed for their analysis and design starting from the classical thin plate theory to alternatives obtained by incorporation of appropriate complicating effects or by using fundamentally different assumptions. The book includes pedagogical features like end-of-chapter exercises and worked examples to help students in self-learning. The book is extremely useful for the senior undergraduate and postgraduate students of aerospace engineering and mechanical engineering.
Mechanics. --- Mechanics, Applied. --- Mechanical engineering. --- Vibration. --- Dynamical systems. --- Dynamics. --- Structural materials. --- Solid Mechanics. --- Mechanical Engineering. --- Vibration, Dynamical Systems, Control. --- Structural Materials. --- Cycles --- Mechanics --- Sound --- Engineering, Mechanical --- Engineering --- Machinery --- Steam engineering --- Applied mechanics --- Engineering mathematics --- Classical mechanics --- Newtonian mechanics --- Physics --- Dynamics --- Quantum theory --- Architectural materials --- Architecture --- Building --- Building supplies --- Buildings --- Construction materials --- Structural materials --- Materials --- Dynamical systems --- Kinetics --- Mathematics --- Mechanics, Analytic --- Force and energy --- Statics --- Plates (Engineering) --- Disks (Mechanics) --- Panels --- Structural plates --- Elastic plates and shells --- Structural analysis (Engineering) --- Shells (Engineering)
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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 issues --- fatigue --- fracture --- very-high cycle --- high-entropy alloy --- powder metallurgy --- fish eye --- crack branching behavior --- micromechanical analysis --- crack propagation path --- welded joints --- stress concentration --- vibration-based fatigue --- ultra-high frequency --- very high cycle fatigue --- fatigue test --- titanium alloy --- hydrogen re-embrittlement --- environmentally assisted cracking --- galvanic protection --- high strength steel --- crack front shape --- structural plates --- through-the-thickness crack --- steady-state loading conditions --- small-scale yielding --- pearlitic steel --- CFRP patches --- crack retardation --- fatigue crack growth --- failure analysis --- fatigue variability --- alloy 625 --- thin tube --- fractography --- microstructure --- aluminum hand-hole --- nonreinforced hand-hole --- design S-N curve --- high cycle fatigue --- CP Ti --- stress amplitude --- fatigue crack propagation --- crack growth rate --- roughness-induced crack closure --- fracture toughness --- machine learning --- artificial neural network --- predictor --- yield stress --- tensile strength --- specimen size --- 2524-T3 aluminum alloy --- corrosion --- crack propagation --- n/a
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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 issues --- fatigue --- fracture --- very-high cycle --- high-entropy alloy --- powder metallurgy --- fish eye --- crack branching behavior --- micromechanical analysis --- crack propagation path --- welded joints --- stress concentration --- vibration-based fatigue --- ultra-high frequency --- very high cycle fatigue --- fatigue test --- titanium alloy --- hydrogen re-embrittlement --- environmentally assisted cracking --- galvanic protection --- high strength steel --- crack front shape --- structural plates --- through-the-thickness crack --- steady-state loading conditions --- small-scale yielding --- pearlitic steel --- CFRP patches --- crack retardation --- fatigue crack growth --- failure analysis --- fatigue variability --- alloy 625 --- thin tube --- fractography --- microstructure --- aluminum hand-hole --- nonreinforced hand-hole --- design S-N curve --- high cycle fatigue --- CP Ti --- stress amplitude --- fatigue crack propagation --- crack growth rate --- roughness-induced crack closure --- fracture toughness --- machine learning --- artificial neural network --- predictor --- yield stress --- tensile strength --- specimen size --- 2524-T3 aluminum alloy --- corrosion --- crack propagation --- n/a
Choose an application
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.
fatigue --- fracture --- very-high cycle --- high-entropy alloy --- powder metallurgy --- fish eye --- crack branching behavior --- micromechanical analysis --- crack propagation path --- welded joints --- stress concentration --- vibration-based fatigue --- ultra-high frequency --- very high cycle fatigue --- fatigue test --- titanium alloy --- hydrogen re-embrittlement --- environmentally assisted cracking --- galvanic protection --- high strength steel --- crack front shape --- structural plates --- through-the-thickness crack --- steady-state loading conditions --- small-scale yielding --- pearlitic steel --- CFRP patches --- crack retardation --- fatigue crack growth --- failure analysis --- fatigue variability --- alloy 625 --- thin tube --- fractography --- microstructure --- aluminum hand-hole --- nonreinforced hand-hole --- design S-N curve --- high cycle fatigue --- CP Ti --- stress amplitude --- fatigue crack propagation --- crack growth rate --- roughness-induced crack closure --- fracture toughness --- machine learning --- artificial neural network --- predictor --- yield stress --- tensile strength --- specimen size --- 2524-T3 aluminum alloy --- corrosion --- crack propagation --- n/a
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