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The mechanics of fracture and fatigue have produced a huge body of research work in relation to applications to metal materials and structures. However, a variety of non-metallic materials (e.g., concrete and cementitious composites, rocks, glass, ceramics, bituminous mixtures, composites, polymers, rubber and soft matter, bones and biological materials, and advanced and multifunctional materials) have received relatively less attention, despite their attractiveness for a large spectrum of applications related to the components and structures of diverse engineering branches, applied sciences and architecture, and to the load-carrying systems of biological organisms. This book covers the broad topic of structural integrity of non-metallic materials, considering the modelling, assessment, and reliability of structural elements of any scale. Original contributions from engineers, mechanical materials scientists, computer scientists, physicists, chemists, and mathematicians are presented, applying both experimental and theoretical approaches.

History of engineering & technology --- Ethylene-propylene diene monomer rubber EPDM --- grommet --- physical properties --- optimization of shape design --- reliability of rocks --- fatigue load --- strain energy --- red sandstone --- distribution of strain energy --- indices --- multi-scale simulation --- fatigue loading --- road bridge decks --- stagnant water --- fracture toughness --- blast furnace slag --- particle size --- compressive strength --- concrete --- concrete cracking --- crack patterns --- carbon fiber-reinforced polymers—CFRP --- RC strengthening (in bending and shear) --- RC beams --- soft materials --- polymers --- strain rate --- defect tolerance --- digital image correlation --- stress concentrators --- notch blunting --- lightning strike --- composite reinforced panel --- blow-off impulse --- electric-thermal coupling --- boundary effect --- size effect --- tensile strength --- physical modelling test --- rock structure --- fracture --- deformation --- mining --- neutral axis --- self-healing --- successive strain gauge --- flexural test --- bridge decks --- pseudo-cracking method --- data assimilation --- triaxial compression test --- sandstone --- rock mechanics --- rock fracture --- energy evolution --- rock-like material --- crack propagation --- discrete element --- strain rate tensor --- velocity field --- jointed rock --- uniaxial tension loading --- numerical analysis --- discrete element method --- strata structural behavior --- numerical simulation --- tension weakening --- fractures --- goaf consolidation --- fatigue life --- modified asphalt mixture --- four-point bending beam fatigue test --- two-point trapezoidal beam fatigue test --- overlay tester --- embedment --- shale rock --- proppant pack --- fracture width --- fly ash --- fineness --- fracture energy --- critical stress intensity factor --- assessment --- bridge evaluation --- compressive membrane action --- concrete bridges --- fatigue --- fatigue assessment --- live loads --- prestressed concrete --- punching shear --- scale model --- CFRP --- Low Velocity Impacts --- Cohesive Zone Model (CZM) --- Finite Element Analysis (FEA) --- VUMAT --- inter-laminar damage --- intra-laminar damage --- chemical grouting --- flowing water --- water plugging rate --- joint roughness coefficient --- damage model --- mode-II microcracks --- thermodynamics --- reinforced concrete beam --- impact and quasi-static loading --- retrofitting --- mineral grain shape --- particle flow code --- uniaxial compression simulation --- rock mechanical property --- mesostructure --- finite element analysis --- cohesive zone model --- high performance concrete --- fibre-reinforced high performance concrete --- compressive stress --- compressive modulus of elasticity --- maximum compressive strain --- tension --- pressure-tension apparatus --- nondestructive testing --- ultrasonic pulse velocity --- ABAQUS FEA --- high-temperature wedge splitting test --- fracture parameters --- reducing condition --- carbon-containing refractories --- strain-softening --- failure probability --- diamond composite --- material failure characteristics --- reliability --- rock cutting picks --- civil engineering --- fiber-reinforced composite laminate --- multi-directional laminate --- delamination --- elastic interface --- energy release rate --- mixed-mode fracture --- enhanced PG-NEM --- functionally graded material (FGM) --- stress intensity factor (SIF) --- modified interaction integral --- metallic glasses --- shear bands --- mechanical properties --- fracture mechanism --- small wind turbine --- stall regulation --- pitch regulation --- aeroelastic simulation --- n/a --- Fatigue --- Fracture mechanics --- Structural integrity --- Polymers --- Composites --- Ceramics --- Concrete --- Rock --- Soft matter --- Advanced materials. --- carbon fiber-reinforced polymers-CFRP

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• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

The mechanics of fracture and fatigue have produced a huge body of research work in relation to applications to metal materials and structures. However, a variety of non-metallic materials (e.g., concrete and cementitious composites, rocks, glass, ceramics, bituminous mixtures, composites, polymers, rubber and soft matter, bones and biological materials, and advanced and multifunctional materials) have received relatively less attention, despite their attractiveness for a large spectrum of applications related to the components and structures of diverse engineering branches, applied sciences and architecture, and to the load-carrying systems of biological organisms. This book covers the broad topic of structural integrity of non-metallic materials, considering the modelling, assessment, and reliability of structural elements of any scale. Original contributions from engineers, mechanical materials scientists, computer scientists, physicists, chemists, and mathematicians are presented, applying both experimental and theoretical approaches.

History of engineering & technology --- Ethylene-propylene diene monomer rubber EPDM --- grommet --- physical properties --- optimization of shape design --- reliability of rocks --- fatigue load --- strain energy --- red sandstone --- distribution of strain energy --- indices --- multi-scale simulation --- fatigue loading --- road bridge decks --- stagnant water --- fracture toughness --- blast furnace slag --- particle size --- compressive strength --- concrete --- concrete cracking --- crack patterns --- carbon fiber-reinforced polymers—CFRP --- RC strengthening (in bending and shear) --- RC beams --- soft materials --- polymers --- strain rate --- defect tolerance --- digital image correlation --- stress concentrators --- notch blunting --- lightning strike --- composite reinforced panel --- blow-off impulse --- electric-thermal coupling --- boundary effect --- size effect --- tensile strength --- physical modelling test --- rock structure --- fracture --- deformation --- mining --- neutral axis --- self-healing --- successive strain gauge --- flexural test --- bridge decks --- pseudo-cracking method --- data assimilation --- triaxial compression test --- sandstone --- rock mechanics --- rock fracture --- energy evolution --- rock-like material --- crack propagation --- discrete element --- strain rate tensor --- velocity field --- jointed rock --- uniaxial tension loading --- numerical analysis --- discrete element method --- strata structural behavior --- numerical simulation --- tension weakening --- fractures --- goaf consolidation --- fatigue life --- modified asphalt mixture --- four-point bending beam fatigue test --- two-point trapezoidal beam fatigue test --- overlay tester --- embedment --- shale rock --- proppant pack --- fracture width --- fly ash --- fineness --- fracture energy --- critical stress intensity factor --- assessment --- bridge evaluation --- compressive membrane action --- concrete bridges --- fatigue --- fatigue assessment --- live loads --- prestressed concrete --- punching shear --- scale model --- CFRP --- Low Velocity Impacts --- Cohesive Zone Model (CZM) --- Finite Element Analysis (FEA) --- VUMAT --- inter-laminar damage --- intra-laminar damage --- chemical grouting --- flowing water --- water plugging rate --- joint roughness coefficient --- damage model --- mode-II microcracks --- thermodynamics --- reinforced concrete beam --- impact and quasi-static loading --- retrofitting --- mineral grain shape --- particle flow code --- uniaxial compression simulation --- rock mechanical property --- mesostructure --- finite element analysis --- cohesive zone model --- high performance concrete --- fibre-reinforced high performance concrete --- compressive stress --- compressive modulus of elasticity --- maximum compressive strain --- tension --- pressure-tension apparatus --- nondestructive testing --- ultrasonic pulse velocity --- ABAQUS FEA --- high-temperature wedge splitting test --- fracture parameters --- reducing condition --- carbon-containing refractories --- strain-softening --- failure probability --- diamond composite --- material failure characteristics --- reliability --- rock cutting picks --- civil engineering --- fiber-reinforced composite laminate --- multi-directional laminate --- delamination --- elastic interface --- energy release rate --- mixed-mode fracture --- enhanced PG-NEM --- functionally graded material (FGM) --- stress intensity factor (SIF) --- modified interaction integral --- metallic glasses --- shear bands --- mechanical properties --- fracture mechanism --- small wind turbine --- stall regulation --- pitch regulation --- aeroelastic simulation --- n/a --- Fatigue --- Fracture mechanics --- Structural integrity --- Polymers --- Composites --- Ceramics --- Concrete --- Rock --- Soft matter --- Advanced materials. --- carbon fiber-reinforced polymers-CFRP

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The European Structural Integrity Society (ESIS) Technical committee on Fatigue of Engineering Materials and Structures (TC3) decided to compile a Special Technical Publication (ESIS STP) based on the 115 papers presented at the 6th International Conference on Biaxial/Multiaxial Fatigue and Fracture. The 25 papers included in the STP have been extended and revised by the authors. The conference was held in Lisbon, Portugal, on 25-28 June 2001, and was chaired by Manual De Freitas, Instituto Superior Tecnico, Lisbon. The meeting, organised by the Instituto Superior Tecnico and sponsored by the Portuguese Minesterio da Cienca e da Tecnologia and by the European Structural Integrity Society, was attended by 151 delegates from 20 countries. The papers in the present book deal with the theoretical, numerical and experimental aspects of the Multiaxial fatigue and fracture of engineering materials and structures. They are divided in to the following six sections; Multiaxial Fatigue of Welded Structures; High cycle Multiaxial fatigue; Non proportional and Variable-Amplitude loading; Defects, Notches, Crack Growth; Low Cycle Multiaxial Fatigue; Applications and Testing Methods. As is well-known, most engineering components and structures in the mechanical, aerospace, power generation, and other industries are subjected to multiaxial loading during their service life. One of the most difficult tasks in design against fatigue and fracture is to translate the information gathered from uniaxial fatigue and fracture tests on engineering materials into applications involving complex states of cyclic stress-strain conditions. This book is the result of co-operation between many researchers from different laboratories, universities and industries in a number of countries.