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The Special Issue ‘Physical Metallurgy of High Manganese Steels’ addresses the highly fascinating class of manganese-alloyed steels with manganese contents well above 3 mass%. The book gathers manuscripts from internationally recognized researchers with stimulating new ideas and original results. It consists of fifteen original research papers. Seven contributions focus on steels with manganese contents above 12 mass%. These contributions cover fundamental aspects of process-microstrcuture-properties relationships with processes ranging from cold and warm rolling over deep rolling to heat treatment. Novel findings regarding the fatigue and fracture behavior, deformation mechanisms, and computer-aided design are presented. Additionally, the Special Issue also reflects the current trend of reduced Mn content (3-12 mass%) in advanced high strength steels (AHSS). Eight contributions were dedicated to these alloys, which are often referred to as 3rd generation AHSS, medium manganese steels or quenching and partitioning (Q&P/Q+P) steels. The interplay between advanced processing, mainly novel annealing variants, and microstructure evolution has been addressed using computational and experimental approaches. A deeper understanding of strain-rate sensitivity, hydrogen embrittlement, phase transformations, and the consequences for the materials’ properties has been developed. Hence, the topics included are manifold, fundamental-science oriented and, at the same time, relevant to industrial application.
n/a --- TRIP --- microstructure --- medium-manganese steel --- dislocation density --- V alloying --- ultrafine grains --- intercritical annealing --- medium manganese steel --- fracture --- precipitations --- twinning induced plasticity --- deformation behavior --- fatigue --- austenite-reversed-transformation --- medium-manganese --- Lüders band --- medium-Mn steel --- fatigue behavior --- alloy design --- austenitic high nitrogen steel (HNS) --- high-entropy alloys --- mechanical properties --- retained austenite --- high-manganese steel --- localized deformation --- phase transformation --- austenite stability --- processing --- strain-hardening behavior --- TWIP steel --- recrystallization annealing --- damage --- strengthening --- cold rolling --- ultrafine-grained microstructure --- serrated flow --- multiscale simulation --- deformation twinning --- annealing --- high-Mn steels --- corrosion resistance --- TWIP --- quenching and partitioning --- high manganese steel --- lightweight --- residual stresses --- in-situ DIC tensile tests --- crash box --- deep rolling --- high strength steel --- plastic deformation --- MMn steel X20CrNiMnVN18-5-10 --- neutron diffraction --- phase field simulation --- dynamic strain aging --- cold deformation --- near surface properties --- P steel --- continuous annealing --- texture --- hydrogen embrittlement --- hot-stamping --- warm rolling --- strain-rate sensitivity --- austenite reversion --- D& --- forging --- high-manganese steels --- grain refinement --- double soaking
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Machining remains one of the most important manufacturing processes in the metalworking industry. Studies on this process have investigated the machinability of different materials, the behaviour of tools, chip formation, surface integrity, forces involved, and its economic and environmental sustainability. New materials are constantly being developed, and machining research needs to closely follow these developments. This book examines recent research in the machining field, covering several aspects and presenting very interesting developments in this area of knowledge.
Technology: general issues --- magnesium alloy --- UNS M11917 --- AZ91D --- hole repair --- surface roughness --- dry drilling --- re-drilling --- thin plates --- thin-wall --- machining --- aluminium --- cutting forces --- roughness --- dry --- carbide tool --- Haynes 282 --- finishing turning --- UNS A97075 --- dry turning --- surface integrity --- straightness --- parallelism --- roundness --- concentricity --- circular run-out --- total run-out --- cylindricity --- tool edge preparation --- segmented chip --- machining simulation --- burr --- optimization --- turning process --- turning tools --- solid tools --- cemented carbide --- coated tools --- coated cemented carbide --- Physical Vapor Deposition (PVD) --- Chemical Vapor Deposition (CVD) --- multilayered coatings --- nanolayered coatings --- wear mechanism --- tool life --- minimum quantity Lubricant (MQL) --- cutting energy --- tool damage --- liquid nitrogen --- carbon dioxide snow --- vibrations --- part quality --- flexible vacuum fixture --- AA2024 floor milling --- chip segmentation --- damage modeling --- dynamic strain aging --- stainless steel --- Ca treatment --- machinability --- turning --- chip breakability --- weight distribution --- non-metallic inclusions --- AWJM (abrasive water jet machining) --- CFRTP (carbon fiber-reinforced thermoplastics) --- hybrid structure --- surface quality --- Ra --- Rz --- C/TPU (carbon/thermoplastic polyurethane) --- milling --- tool coating --- TiAlN --- TiAlN-based coatings --- multilayer --- nanolayer --- wear mechanisms --- n/a
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Machining remains one of the most important manufacturing processes in the metalworking industry. Studies on this process have investigated the machinability of different materials, the behaviour of tools, chip formation, surface integrity, forces involved, and its economic and environmental sustainability. New materials are constantly being developed, and machining research needs to closely follow these developments. This book examines recent research in the machining field, covering several aspects and presenting very interesting developments in this area of knowledge.
magnesium alloy --- UNS M11917 --- AZ91D --- hole repair --- surface roughness --- dry drilling --- re-drilling --- thin plates --- thin-wall --- machining --- aluminium --- cutting forces --- roughness --- dry --- carbide tool --- Haynes 282 --- finishing turning --- UNS A97075 --- dry turning --- surface integrity --- straightness --- parallelism --- roundness --- concentricity --- circular run-out --- total run-out --- cylindricity --- tool edge preparation --- segmented chip --- machining simulation --- burr --- optimization --- turning process --- turning tools --- solid tools --- cemented carbide --- coated tools --- coated cemented carbide --- Physical Vapor Deposition (PVD) --- Chemical Vapor Deposition (CVD) --- multilayered coatings --- nanolayered coatings --- wear mechanism --- tool life --- minimum quantity Lubricant (MQL) --- cutting energy --- tool damage --- liquid nitrogen --- carbon dioxide snow --- vibrations --- part quality --- flexible vacuum fixture --- AA2024 floor milling --- chip segmentation --- damage modeling --- dynamic strain aging --- stainless steel --- Ca treatment --- machinability --- turning --- chip breakability --- weight distribution --- non-metallic inclusions --- AWJM (abrasive water jet machining) --- CFRTP (carbon fiber-reinforced thermoplastics) --- hybrid structure --- surface quality --- Ra --- Rz --- C/TPU (carbon/thermoplastic polyurethane) --- milling --- tool coating --- TiAlN --- TiAlN-based coatings --- multilayer --- nanolayer --- wear mechanisms --- n/a
Choose an application
Machining remains one of the most important manufacturing processes in the metalworking industry. Studies on this process have investigated the machinability of different materials, the behaviour of tools, chip formation, surface integrity, forces involved, and its economic and environmental sustainability. New materials are constantly being developed, and machining research needs to closely follow these developments. This book examines recent research in the machining field, covering several aspects and presenting very interesting developments in this area of knowledge.
Technology: general issues --- magnesium alloy --- UNS M11917 --- AZ91D --- hole repair --- surface roughness --- dry drilling --- re-drilling --- thin plates --- thin-wall --- machining --- aluminium --- cutting forces --- roughness --- dry --- carbide tool --- Haynes 282 --- finishing turning --- UNS A97075 --- dry turning --- surface integrity --- straightness --- parallelism --- roundness --- concentricity --- circular run-out --- total run-out --- cylindricity --- tool edge preparation --- segmented chip --- machining simulation --- burr --- optimization --- turning process --- turning tools --- solid tools --- cemented carbide --- coated tools --- coated cemented carbide --- Physical Vapor Deposition (PVD) --- Chemical Vapor Deposition (CVD) --- multilayered coatings --- nanolayered coatings --- wear mechanism --- tool life --- minimum quantity Lubricant (MQL) --- cutting energy --- tool damage --- liquid nitrogen --- carbon dioxide snow --- vibrations --- part quality --- flexible vacuum fixture --- AA2024 floor milling --- chip segmentation --- damage modeling --- dynamic strain aging --- stainless steel --- Ca treatment --- machinability --- turning --- chip breakability --- weight distribution --- non-metallic inclusions --- AWJM (abrasive water jet machining) --- CFRTP (carbon fiber-reinforced thermoplastics) --- hybrid structure --- surface quality --- Ra --- Rz --- C/TPU (carbon/thermoplastic polyurethane) --- milling --- tool coating --- TiAlN --- TiAlN-based coatings --- multilayer --- nanolayer --- wear mechanisms --- magnesium alloy --- UNS M11917 --- AZ91D --- hole repair --- surface roughness --- dry drilling --- re-drilling --- thin plates --- thin-wall --- machining --- aluminium --- cutting forces --- roughness --- dry --- carbide tool --- Haynes 282 --- finishing turning --- UNS A97075 --- dry turning --- surface integrity --- straightness --- parallelism --- roundness --- concentricity --- circular run-out --- total run-out --- cylindricity --- tool edge preparation --- segmented chip --- machining simulation --- burr --- optimization --- turning process --- turning tools --- solid tools --- cemented carbide --- coated tools --- coated cemented carbide --- Physical Vapor Deposition (PVD) --- Chemical Vapor Deposition (CVD) --- multilayered coatings --- nanolayered coatings --- wear mechanism --- tool life --- minimum quantity Lubricant (MQL) --- cutting energy --- tool damage --- liquid nitrogen --- carbon dioxide snow --- vibrations --- part quality --- flexible vacuum fixture --- AA2024 floor milling --- chip segmentation --- damage modeling --- dynamic strain aging --- stainless steel --- Ca treatment --- machinability --- turning --- chip breakability --- weight distribution --- non-metallic inclusions --- AWJM (abrasive water jet machining) --- CFRTP (carbon fiber-reinforced thermoplastics) --- hybrid structure --- surface quality --- Ra --- Rz --- C/TPU (carbon/thermoplastic polyurethane) --- milling --- tool coating --- TiAlN --- TiAlN-based coatings --- multilayer --- nanolayer --- wear mechanisms
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