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stephenson david a.; agapiou john s. - metal cutting theory and practice

Metal Cutting Theory and Practice

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Dettagli

Genere:Libro
Lingua: Inglese
Editore:

CRC Press

Pubblicazione: 06/2016
Edizione: Edizione nuova, 3° edizione





Note Editore

A Complete Reference Covering the Latest Technology in Metal Cutting Tools, Processes, and Equipment Metal Cutting Theory and Practice, Third Edition shapes the future of material removal in new and lasting ways. Centered on metallic work materials and traditional chip-forming cutting methods, the book provides a physical understanding of conventional and high-speed machining processes applied to metallic work pieces, and serves as a basis for effective process design and troubleshooting. This latest edition of a well-known reference highlights recent developments, covers the latest research results, and reflects current areas of emphasis in industrial practice. Based on the authors’ extensive automotive production experience, it covers several structural changes, and includes an extensive review of computer aided engineering (CAE) methods for process analysis and design. Providing updated material throughout, it offers insight and understanding to engineers looking to design, operate, troubleshoot, and improve high quality, cost effective metal cutting operations. The book contains extensive up-to-date references to both scientific and trade literature, and provides a description of error mapping and compensation strategies for CNC machines based on recently issued international standards, and includes chapters on cutting fluids and gear machining. The authors also offer updated information on tooling grades and practices for machining compacted graphite iron, nickel alloys, and other hard-to-machine materials, as well as a full description of minimum quantity lubrication systems, tooling, and processing practices. In addition, updated topics include machine tool types and structures, cutting tool materials and coatings, cutting mechanics and temperatures, process simulation and analysis, and tool wear from both chemical and mechanical viewpoints. Comprised of 17 chapters, this detailed study: Describes the common machining operations used to produce specific shapes or surface characteristics Contains conventional and advanced cutting tool technologies Explains the properties and characteristics of tools which influence tool design or selection Clarifies the physical mechanisms which lead to tool failure and identifies general strategies for reducing failure rates and increasing tool life Includes common machinability criteria, tests, and indices Breaks down the economics of machining operations Offers an overview of the engineering aspects of MQL machining Summarizes gear machining and finishing methods for common gear types, and more Metal Cutting Theory and Practice, Third Edition emphasizes the physical understanding and analysis for robust process design, troubleshooting, and improvement, and aids manufacturing engineering professionals, and engineering students in manufacturing engineering and machining processes programs.




Sommario

IntroductionScope of the SubjectHistorical DevelopmentReferencesMetal Cutting OperationsIntroductionTurningBoringDrillingReamingMillingPlaning and ShapingBroachingTapping and ThreadingGrinding and Related Abrasive ProcessesRoller BurnishingDeburringExamplesProblemsReferencesMachine ToolsIntroductionProduction Machine ToolsCNC Machine Tools and CNC-Based Manufacturing SystemsMachine Tool StructuresSlides and GuidewaysAxis DrivesSpindlesCoolant SystemsTool Changing SystemsPalletsEnergy Use in CNC Machining CentersExamplesReferencesCutting ToolsIntroductionCutting Tool MaterialsTool CoatingsBasic Types of Cutting ToolsTurning ToolsBoring ToolsMilling ToolsDrilling ToolsReamersThreading ToolsGrinding WheelsMicrosizing and Honing ToolsBurnishing ToolsExamplesProblemsReferencesToolholders and WorkholdersIntroductionToolholding SystemsToolholder/Spindle ConnectionsCutting Tool Clamping SystemsBalancing Requirements for ToolholdersFixturesExamplesProblemsReferencesMechanics of CuttingIntroductionMeasurement of Cutting Forces and Chip ThicknessForce ComponentsEmpirical Force ModelsSpecific Cutting PowerChip Formation and Primary Plastic DeformationTool-Chip Friction and Secondary DeformationShear Plane and Slip Line Theories for Continuous Chip FormationShear Plane Models for Oblique CuttingShear Zone ModelsMinimum Work and Uniqueness AssumptionsFinite Element ModelsDiscontinuous Chip FormationBuilt-up Edge FormationExamplesProblemsReferencesCutting TemperaturesIntroductionMeasurement of Cutting TemperaturesFactors Affecting Cutting TemperaturesAnalytical Models for Steady-State TemperaturesFinite Element and Other Numerical ModelsTemperatures in Interrupted CuttingTemperatures in DrillingThermal ExpansionExamplesProblemsReferencesMachining Process AnalysisIntroductionTurningBoringMillingDrillingForce Equations and Baseline DataProcess Simulation Application ExamplesFinite Element Analysis for Clamping, Fixturing, and Workpiece DistortionApplicationsFinite Element Application ExamplesExamplesProblemsReferencesTool Wear and Tool LifeIntroductionTypes of Tool WearMeasurement of Tool WearTool Wear Mechanisms Tool Wear--Material ConsiderationsTool Life TestingTool Life EquationsPrediction of Tool Wear RatesTool Fracture and Edge ChippingDrill Wear and BreakageThermal Cracking and Tool Fracture in MillingTool Wear MonitoringExamplesProblemsReferencesSurface Finish, Integrity, and FlatnessIntroductionMeasurement of Surface FinishSurface Finish in Turning and BoringSurface Finish in MillingSurface Finish in Drilling and ReamingSurface Finish in GrindingResidual Stresses in Machined SurfacesWhite Layer FormationSurface Burning in GrindingMeasurement of Surface FlatnessSurface Flatness Compensation in Face MillingExamplesProblemsReferencesMachinability of MaterialsIntroductionMachinability Criteria, Tests, and IndicesChip ControlBurr Formation and ControlMachinability of Engineering MaterialsReferencesMachining DynamicsIntroductionVibration Analysis MethodsVibration of Discrete (Lumped Mass) SystemsTypes of Machine Tool VibrationForced VibrationSelf-Excited Vibrations (Chatter)Chatter PredictionVibration ControlActive Vibration ControlExamplesProblemsReferencesMachining Economics and OptimizationIntroductionRole of a Computerized Optimization SystemEconomic ConsiderationsOptimization of Manufacturing Systems--Basic FactorsOptimization of Machining ConditionsFormulation of the Optimization ProblemOptimization TechniquesExamplesProblemsReferencesCutting FluidsIntroductionTypes of Cutting FluidsCoolant ApplicationFilteringCondition Monitoring and Waste TreatmentHealth and Safety ConcernsDry and Near-Dry Machining MethodsTest Procedure for Cutting Fluid EvaluationReferencesMinimum Quantity LubricationIntroductionMQL System TypesMQL OilsMachine Tools for MQLMQL Cutting ToolsThermal Management and Dimensional ControlAir and Chip HandlingMQL Research AreasReferencesAccuracy and Error Compensation of CNC Machining SystemsIntroductionMachine Tool ErrorsMachine Tool Accuracy CharacterizationMachine Tool Performance EvaluationMethod for Compensating the Dimensional Accuracy of CNC Machining SystemExamplesReferences




Autore

David A. Stephenson is a technical specialist at Ford Powertrain Advanced Manufacturing Engineering in Livonia, Michigan. Earlier, Stephenson worked for several years at General Motors Research and General Motors Powertrain; he has also worked at Third Wave Systems, Inc., D3 Vibrations, Inc., the University of Michigan, and Fusion Coolant Systems. He is a member of the American Society of Mechanical Engineers (ASME) and a Fellow of the Society of Manufacturing Engineers (SME). He has served as a journal technical editor for both societies, and served on the ASME Manufacturing Science and Engineering Division Executive Commitee from 2002 to 2007. John S. Agapiou is a technical fellow at the Manufacturing Systems Research Lab at General Motors R&D Center, Warren, Michigan. He is also part time professor in the Department of Mechanical Engineering at Wayne State University. His research focus involves developing and implementing world-class manufacturing, quality, and process validation strategies in the production and development of the automotive Powertrain. He received his bachelor’s and master’s degrees in mechanical engineering at the University of Louisville in 1980 and 1981, respectively, and his PhD from the University of Wisconsin in 1985.










Altre Informazioni

ISBN:

9781466587533

Condizione: Nuovo
Dimensioni: 10 x 7 in Ø 4.10 lb
Formato: Copertina rigida
Illustration Notes:732 b/w images, 81 tables and 571 Equations
Pagine Arabe: 972


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