Failure Mechanisms in Alloys
Pantazopoulos, George
Failure Mechanisms in Alloys - MDPI - Multidisciplinary Digital Publishing Institute 2020 - 1 electronic resource (476 p.)
Open Access
The era of lean production and excellence in manufacturing, advancing with sustainable development, demands the rational utilization of raw materials and energy resources, adopting cleaner and environmentally-friendly industrial processes. In view of the new industrial revolution, through digital transformation, the exploitation of smart and sophisticated materials systems, the need of minimizing scrap and increasing efficiency, reliability and lifetime and, on the other hand, the pursuit of fuel economy and limitation of carbon footprint, are necessary conditions for the imminent growth in a highly competitive economy. Failure analysis is an interdisciplinary scientific topic, reflecting the opinions and interpretations coming from a systematic evidence-gathering procedure, embracing various important sectors, imparting knowledge, and substantiating improvement practices. The deep understanding of material/component role (e.g., rotating shaft, extrusion die, gas pipeline) and properties will be of central importance for fitness for purpose in certain industrial processes and applications. Finally, it is hoped and strongly believed that the accumulation of additional knowledge in the field of failure mechanisms and the adoption of the principles, philosophy, and deep understanding of failure analysis process approach will strongly promote the learning concept, as a continuously evolving process leading to personal and social progress and prosperity.
Creative Commons
English
books978-3-03928-277-7 9783039282760 9783039282777
10.3390/books978-3-03928-277-7 doi
thermal-sprayed coatings n/a hydrogen-assisted cracking corrosion thermal aging modeling fracture plane macroscopic strength criterion lubrication slow-rate machining fracture parametric accelerated life testing constitutive equations austenitic stainless steels refractory steels crack growth micro flexible rolling tensile deformation shape high temperature fatigue tensile tests biaxial tensile test post-necking hardening EIS 3D Voronoi modelling SOHIC extrusion failures chip root cast duplex stainless steels bake hardening elastic moduli strip marking method wear flow loop austenitizing furnace failure analysis surface modification techniques creep fatigue pipeline steel yield strength convection tubes temperature low temperatures shear angle sensitization API 5L-X65 dent resistance numerical simulation metal components linear Mohr-Coulomb criterion W-30Cu conveying system failure study texture finite element modeling AISI 304 stainless steel self-equalizing bearing surface-cracking process carbides potentiodynamic polarization cast reformer tubes aging reformer tubes multilinear regression softening polynomial regression GISSMO Model strength brass extrusion bendability degradation of protective layers inverse modeling G-phase forward slip prediction EBSD grain boundary quality improvement quality assessment smooth particle hydrodynamics hardfacings helix upper dispenser furnace component failure elevated temperature isotropic metals creep reliability design fracture mechanisms Titanium alloy machining failure mechanism mechanical properties faulty designs dynamic compression strength ductility automotive steels steam reforming cleavage fracture impingement automotive ductile irons erosion corrosion surface treatment HP-Mod impact toughness press hardening cold-working process chip formation nitrocarburizing built-up edge microhardness HV 6063 Alloy cutting forces tensile stress thermal distortion tribological properties plastic deformation processing CFD simulation wear scar nanocrystalline materials spinodal decomposition fractography microstructure homogeneity finite element analysis hot stamping iterative FEM Method thickness transition area fracture mechanics
Failure Mechanisms in Alloys - MDPI - Multidisciplinary Digital Publishing Institute 2020 - 1 electronic resource (476 p.)
Open Access
The era of lean production and excellence in manufacturing, advancing with sustainable development, demands the rational utilization of raw materials and energy resources, adopting cleaner and environmentally-friendly industrial processes. In view of the new industrial revolution, through digital transformation, the exploitation of smart and sophisticated materials systems, the need of minimizing scrap and increasing efficiency, reliability and lifetime and, on the other hand, the pursuit of fuel economy and limitation of carbon footprint, are necessary conditions for the imminent growth in a highly competitive economy. Failure analysis is an interdisciplinary scientific topic, reflecting the opinions and interpretations coming from a systematic evidence-gathering procedure, embracing various important sectors, imparting knowledge, and substantiating improvement practices. The deep understanding of material/component role (e.g., rotating shaft, extrusion die, gas pipeline) and properties will be of central importance for fitness for purpose in certain industrial processes and applications. Finally, it is hoped and strongly believed that the accumulation of additional knowledge in the field of failure mechanisms and the adoption of the principles, philosophy, and deep understanding of failure analysis process approach will strongly promote the learning concept, as a continuously evolving process leading to personal and social progress and prosperity.
Creative Commons
English
books978-3-03928-277-7 9783039282760 9783039282777
10.3390/books978-3-03928-277-7 doi
thermal-sprayed coatings n/a hydrogen-assisted cracking corrosion thermal aging modeling fracture plane macroscopic strength criterion lubrication slow-rate machining fracture parametric accelerated life testing constitutive equations austenitic stainless steels refractory steels crack growth micro flexible rolling tensile deformation shape high temperature fatigue tensile tests biaxial tensile test post-necking hardening EIS 3D Voronoi modelling SOHIC extrusion failures chip root cast duplex stainless steels bake hardening elastic moduli strip marking method wear flow loop austenitizing furnace failure analysis surface modification techniques creep fatigue pipeline steel yield strength convection tubes temperature low temperatures shear angle sensitization API 5L-X65 dent resistance numerical simulation metal components linear Mohr-Coulomb criterion W-30Cu conveying system failure study texture finite element modeling AISI 304 stainless steel self-equalizing bearing surface-cracking process carbides potentiodynamic polarization cast reformer tubes aging reformer tubes multilinear regression softening polynomial regression GISSMO Model strength brass extrusion bendability degradation of protective layers inverse modeling G-phase forward slip prediction EBSD grain boundary quality improvement quality assessment smooth particle hydrodynamics hardfacings helix upper dispenser furnace component failure elevated temperature isotropic metals creep reliability design fracture mechanisms Titanium alloy machining failure mechanism mechanical properties faulty designs dynamic compression strength ductility automotive steels steam reforming cleavage fracture impingement automotive ductile irons erosion corrosion surface treatment HP-Mod impact toughness press hardening cold-working process chip formation nitrocarburizing built-up edge microhardness HV 6063 Alloy cutting forces tensile stress thermal distortion tribological properties plastic deformation processing CFD simulation wear scar nanocrystalline materials spinodal decomposition fractography microstructure homogeneity finite element analysis hot stamping iterative FEM Method thickness transition area fracture mechanics