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| موضوع: كتاب Fundamentals of Metal Machining and Machine Tools الخميس 04 نوفمبر 2010, 11:09 pm | |
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تذكير بمساهمة فاتح الموضوع : أخواني في الله أحضرت لكم كتاب Fundamentals of Machining and Machine Tools Second Edition Geoffrey Boothroyd Winston A. Knight University of Rhode Island Kingston, Rhode Island
و المحتوى كما يلي : Contents Preface iii Conventions Used in This Book xi Standardization xi Introduction to the International (SI) System of Units xiv 1 Machine Tools and Machining Operations 1 1.1 Introduction 1 1.2 Generating Motions of Machine Tools 2 1.3 Machines Using Single-Point Tools 5 1.4 Machines Using Multipoint Tools 26 1.5 Machines Using Abrasive Wheels 47 1.6 Summary of Machine Tool Characteristics and Machining Equations 58 Problems 66 Reference 71 f2 Mechanics of Metal Cutting 73 2.1 Introduction 73 2.2 Terms and Definitions 75 2.3 Chip Formation 77 2.4 The Forces Acting on the Cutting Tool and Their Measurement 81 2.5 Specific Cutting Energy 82 2.6 Plowing Force and the "Size Effect" 83 2.7 The Apparent Mean Shear Strength of the Work Material 86 2.8 Chip Thickness 90 2.9 Friction in Metal Cutting 99 Problems 104 References 107 3 Temperatures in Metal Cutting 109 3.1 Heat Generation in Metal Cutting 109 3.2 Heat Transfer in a Moving Material 110 3.3 Temperature Distribution in Metal Cutting 112 3.4 The Measurement of Cutting Temperatures 121Problems 125 References 127 4 Tool Life and Tool Wear 129 4.1 Introduction 129 4.2 Progressive Tool Wear 130 4.3 Forms of Wear in Metal Cutting 130 4.4 The Tool Material 140 4.5 The Work Material 148 Problems 151 References 152 5 Cutting Fluids and Surface Roughness 155 5.1 Cutting Fluids 155 5.2 The Action of Coolants 156 5.3 The Action of Lubricants 156 5.4 Application of Cutting Fluids 163 5.5 Surface Roughness 166page_vii Page vii Problems 173 References 173 6 Economics of Metal-Cutting Operations 175 6.1 Introduction 175 6.2 Choice of Feed 177 6.3 Choice of Cutting Speed 178 6.4 Tool Life for Minimum Cost and Minimum Production Time 182 6.5 Estimation of Factors Needed to Determine Optimum Conditions 184 6.6 Example of a Constant-Cutting-Speed Operation 185 6.7 Machining at Maximum Efficiency 188 6.8 Facing Operations 191 6.9 Operations with Interrupted Cuts 194 6.10 Economics of Various Tool Materials and Tool Designs 195 6.11 Machinability Data Systems 200 Problems 200 References 204 7 Nomenclature of Cutting Tools 205page_vii 7.1 Introduction 205 7.2 Systems of Cutting-Tool Nomenclature 207 7.3 International Standard 213 Problems 223 References 224 8 Chip Control 225 8.1 Introduction 225 8.2 Chip Breakers 226 8.3 Prediction of Radius of Chip Curvature 230 8.4 Tool Wear During Chip Breaking 234 Problems 237 References 237 9 Machine Tool Vibrations 239 9.1 Introduction 239 9.2 Forced Vibrations 240page_viii 9.3 Self-Excited Vibrations (Chatter) 245 9.4 Determination of Frequency Response Loci 264 9.5 Dynamic Acceptance Tests for Machine Tools 269 9.6 Improving Machine Tool Stability 270 Problems 277 References 279 10 Grinding 281 10.1 Introduction 281 10.2 The Grinding Wheel 281 10.3 Effect of Grinding Conditions on Wheel Behavior 286 10.4 Determination of the Density of Active Grains 290 10.5 Testing of Grinding Wheels 290 10.6 Analysis of the Grinding Process 290 10.7 Thermal Effects in Grinding 303 10.8 Cutting Fluids in Grinding 307 10.9 Grinding-Wheel Wear 308 10.10 Nonconventional Grinding Operations 311page_viii Problems 315 References 315 11 Manufacturing Systems and Automation 317 11.1 Introduction 317 11.2 Types of Production 318 11.3 Types of Facilities Layout 319 11.4 Types of Automation 321 11.5 Transfer Machines 324 11.6 Automatic Machines 328 11.7 Numerically Controlled (NC) Machine Tools 331 11.8 Comparison of the Economics of Various Automation Systems 338 11.9 Handling of Components in Batch Production 339 11.10 Flexible Manufacturing Systems 340 Problems 350 References 351 12 Computer-Aided Manufacturing 353 12.1 Introduction 353 12.2 Scope of CAD/CAM 354page_viii 12.3 Process-Planning Tasks 356page_x Page x Problems 514 References 514 Nomenclature 517 Index 53 Index A Abrasive grains, chip formation by, 284 Abrasive jet machining, 478-80 applications of, 480 Abrasive particles, 281 Abrasives, hardness of, 285 Abrasive slurry, 475 Abrasive water-jet machining, 476-7 Abrasive wear, 130 Abrasive wheels, 47 Accelerated wear test, 149 Accuracy, cost of increased, 432-436 Active force control, 272-3 Active grains in grinding, 290 determination of density of, 290 plowing action of, 282-284 Adaptive control, 336, 337 Adhesion wear, 130 Air film barrier in grinding, 307-8 Aluminum oxide, 147, 284 Amonton's law of friction, 100, 159 AGVs (see Automatic guided vehicles) APT, 379, 380-7 auxiliary statements in, 385 languages based on, 380-7Arc of contact in milling, 262 Area of contact, apparent, 101 real, 159 Asperities, 101, 159 Assembly of components, 432 Automatically Programmed Tools (see APT) Automatic guided vehicles, 341, 346-7 Automatic lathes, 328, 329 multispindle, 328 single-spindle, 328 Automatic machines, 328-30 economics of, 330 Automation, 317-51 fixed, 322-3 types of, 321-4economics of different systems, 338-9 B Back engagement, 10, 37 Bonds for grinding wheels, 285 metallic, 285 resinoid, 285 rubber, 285 shellac, 285 silicate, 285 vitrified, 285 Boring, 11, 15 Boring bar, 20 Boring machines, 19-20 horizontal 19-20 Boundary lubrication, 156-9 Broaching machine, 43 Built-up-edge, 80, 168 continuous chip with, 80 effect of speed and feed on, 140 effect on surface roughness, 168 effect on tool life, 136 effect on tool wear, 136 C CAD, 353 CAD/CAM, 354-5 scope of, 354-5 CAM, 353-97coated, 146 titanium, 145 tungsten, 145 Carbide tool inserts brazed, 135 cost of sharp cutting edge, 185, 186 throw away, 135 cost of sharp cutting edge, 185 Carbon tetrachloride, 160 as a cutting fluid, 160-1 Carriage of a lathe, 5 Cast alloy tools, 145 Cellular layout of machines, 321 Center drilling, 32 Center lathe (see Engine lathe) Ceramic tools, 147 Ceramic-ceramic composites, 147 Cermet tools, 147 Chemical blanking, 480 Chemical machining, 480-3 applications of, 482-3 etchants for, 481 masks for, 481 Chemical milling, 480 Chip, 2, 73 continuous, 79, 225 discontinuous, 80Chip breakers, 226-30 groove type, 226, 233, 235 obstruction type, 226, 230, 235 Chip breaking, tool wear during, 234-6 Chip control, 225-37 Chip flow angle, 207, 228 Chip formation, 77-81 by grains in grinding, 284 Chip radius of curvature, 230 Chips bulk ratio of, 225 classification of, 230 overbroken, 230 underbroken, 230 various forms of, 226 standard coding system for, 226-7 types of arc type, 230 conical type helical, 228 connected arc, 230 ribbon, 226 spiral, 226 straight, 226 tubular, 226 washer type helical, 226 Chip thickness, 90-7 Start of Citation[PU]Marcel Dekker, Inc.[/PU][DP]1989[/DP]End of Citationtheory of Ernst and Merchant, 90-4 theory of Lee and Shafer, 97 undeformed, 10 Chip thickness coefficient, 256, 263 Chuck, 5, 15 CIM, 356 Classification of machined parts, 403-32 Clearance angle of tool, 76 tool normal, 217 working normal, 76, 217 CNC systems, 336 Coated carbide tools, 146 Coefficient of merit of machine tools, 269-70 Collet, 16 Comparative performance of cutting processes, 511-4 Compound rest of lathe, 17 Computer-aided design (see CAD) Computer-aided design and manufacturing (see CAD/CAM) Computer-aided manufacturing (see CAM) Computer-aided NC processing, 375-9 Computer-aided process planning, 354, 359-363 generative systems for, 360-3 retrieval systems for, 360-1 variant systems for, 360-1 Computer-integrated manufacturing (see CIM) Computer numerical control systems (see CNC) Computers in NC, 335-7real area of, 159 Continuous chip, 79, 225 with built-up-edge, 80 Coolants action of, 156 effect on tool life, 156 Costs of increased accuracy and surface finish, 432-6 of machine and operator, 184 of sharp cutting edge for regrindable tools, 185, 186 for disposable insert tools, 185 Crater wear, 130-1, 234 effect of speed and feed on, 140 Creep feed grinding, 312 Cross feed in grinding, 49 Cross receptance, 259 Cubic boron nitride (CBN), 147, 284 Cut off, 11, 15 Cutter location (CL) file, 375 Cutting edge angle major, 10 tool 217 working, 217 Cutting edge of tool, 2, 8, 75 major cutting edge, 8, 205, 214 minor cutting edge, 8, 205, 214working, 217 Cutting fluids application of, 163-6 flood, 165 manual, 165 mist, 165 in grinding, 307-9 neat, 155, 307 general characteristics of, 163 guide to selection of, 164 water-miscible, 155, 307-309 general characteristics of, 156, 157 guide to selection of, 156, 158 carbon tetrachloride as a, 160, 161 Cutting force, 81 measurement of, 81-2 Cutting force dynamometer, 81 Cutting processes, comparative performance of, 511-14 Cutting ratio, 89, 90Cutting speed, 9 choice of, 178 effect on cratering and built-up-edge, 140 effect on tool life, 134-5 for minimum cost, 181, 402 for minimum production time, 182 Cutting temperatures, measurement of, 121-5 Cutting tool (see Tool), 2 Cutting tool nomenclature, 205-24 British maximum rake system for, 207, 208-11 example of calculation for, 221 German (DIN) system for, 211-12 ISO system for 205, 213-23 systems for, 207-13 tool and working systems, mathematical relationship between, 218-21 tool-in-hand system for, 213, 218-221 tool-in-use system for, 213, 218-221 Cylindrical grinding machine, 55-57 Cylindrical plunge grinding, idealized model of, 291 Cylindrical turning, 7, 11 D Data base design and manufacturing, 356-7 machinability, 200 Deformation zone primary, 79, 110, 112 temperatures in, 114-6Depth of cut, 10 in milling, 36 Design and manufacturing data base, 356-7 Designation of grinding wheels, 286 Design for machining, 399-465 summary of guidelines, 436-8 Design for manufacture, 399 Design guidelines for machined parts, 436-8 Dies, 45 Diffusion wear, 130 Direct numerical control (see DNC systems) Discontinuous chip, 80 DNC systems, 336, 342 Dog, 16 Dressing of grinding wheels, 283 Drilling, 27 center, 32 Drilling machine, 26-28 Dynamic acceptance tests for machine tools, 269-70 Dynamometer for cutting forces, 81 E Early cost estimating for machining, 438-65 Economics of metal cutting operations, 175-204 comparison of automation systems, 338-9 of facing operations, 191-4 of operations with interrupted cuts, 194-5 of various tool designs, 195-200Electrical discharge machining (EDM), 491-9 applications of, 498-9 dielectrics for, 496-7 electrodes for, 493 metal removal rate for, 495 process parameters for, 497-8 tool materials for, 493-4 tool wear for, 493-4 Electrochemical machining (ECM), 483-9 applications of, 488-9 metal removal rate for, 485-6tool feed speed for, 485 tools for, 488 Electrolytic grinding, 489-91 metal removal rate for, 489 Electron beam machining, 505-11 Electromagnetic vibrator, 266-9 for milling machine, 269 Engine lathe, 5-18 Equivalent diameter of grinding wheels, 299 EXAPT, 379, 387-94 F Face of tool, 8, 75 Face plate, 16 Facilities layout, types of, 319-22 cellular layout, 321 functional layout, 319 group layout, 321 line layout, 319 process layout, 319 Facing, 11, 14 economics of, 191-94 Feed, 7 choice of, 177 effect on built-up-edge formation, 140 effect on crater wear, 140 per tooth, 27, 35 Feed engagement, 10, 27, 35Fixed automation, 322-23 Fixed cycles, 371-2 Flank of tool, 8, 76 Flank wear, 131-2 Flexible manufacturing cell, 342 Flexible manufacturing systems (see FMS) Flexible transfer line, 343 Flow angle of chip, 207, 228 FMS, 321, 340-350 features of, 341-2 flexibility in, 342, 345 layouts for, 347 machine tools in, 345 pallets and fixtures for, 349-50 tooling in, 347 work handling in, 345 AGVs, 347 rail carts, 347 roller conveyors, 347 tow carts, 347 Form cutting, 38 Free machining metals, 151 Frequency response cross, 345 determination of, 264-8 direct, 345 polar diagram of, 242Amonton's law of, 100, 159 angle, 102 coefficient of, 101, 102 force, 101 in metal cutting, 99 Functional layout of machines, 319 G Grain aspect ratio, 288 Grains, 281 Grain size, 285 Grain types, 284 aluminum oxide, 284 cubic boron nitride, 284 silicon carbide, 284 Grinding, 281-316 active grains in, 290 air film barrier in, 307-8 analysis of process, 290 creep feed, 312 cross feed in, 49 geometry of chip removal in, 289 high speed, 311-2 infeed in, 49, 53, 56, 57 low stress, 312-4 metal removal rate in, 293 metal removal parameter for, 293 Start of Citation[PU]Marcel Dekker, Inc.[/PU][DP]1989[/DP]End of Citationdifficult-to-grind materials, 303 easy-to-grind materials, 300 plunge, 49, 56 idealized model of, 291 residual stresses in, 306, 313, 314 specific cutting energy for, 295 thermal effects in, 303-7 wheel-workpiece contact zone, 291 length of, 299 workpiece removal parameter in, 293 Grinding cycles, 296-8 cylindrical 296 surface grinding, 298 Grinding fluids (see also Cutting fluids) application of, 307-8 air deflector nozzle, 308 flooding, 308 high-pressure jet, 308 Grinding machine cylindrical, 55-7 horizontal spindle surface, 49-52 internal, 57-8 Grinding ratio, 295, 308 Grinding wheel behavior, effect of grinding conditions, 286 Grinding wheels, 47, 281-6 action of, 283equivalent diameter of, 298 grain size in, 285 hard behavior, 283 ISO standard marking system for, 286 removal parameter for, 293 self sharpening characteristics of, 282 soft behavior of, 283 structure of, 282, 286 testing of, 290 wear in, 290, 308-10 Group layout of machines, 321 Group technology, 360 H Handling of components in batch production, 339 Hardness, of abrasive grains, 285 changes in tool steels, 124-5 of tool materials, 143 Harmonic receptance locus, 242 Harmonic response locus, 242 Headstock, 5 Heat generation in metal cutting, 109-10 Heat transfer in a moving material, 110-12 High-speed grinding, 311-12 High-speed steel, 143-5 coated, 143 Horizontal boring machine, 19-20Hot hardness of tool materials, 143 I Infeed in grinding, 49, 53, 56, 57 International Standards Organization (see ISO) Internal grinding machine, 57-8 ISO recommended roughness values, 173 standard for tool life testing, 134 standard marking system for grinding wheels, 286 system for tool nomenclature, 205 tool life test for turning, 149 L Languages for NC processing, 379-87 APT, 379, 380-87 EXAPT, 379, 387-94 Laser beam machining, 501-5 applications of, 505 cutting operations with, 504-5percussion drilling by, 503-4 trepanning with, 504-5 Lasers, types of, 503 Lathe automatic, 18, 323 single-spindle, 328 multispindle, 328 carriage of, 5 center (see Engine lathe) compound rest of, 17 engine, 5-11 turret, 19 types of operation, 11 Limit of stability of machine tools, 258, 260, 263 Line layout of machines, 219 Low-stress grinding, 312-14 Lubricants, action of, 156-63 Lubrication boundary, 156-9 characteristics of efficient, 161-3 in metal cutting, 159-63 M Machinability, 148, 443 factors affecting, 150-1 index or number for, 148 testing for, 149 Machinability data systems, 200Machined components classification of, 403-32 shape of, 403-32 Machine depreciation rate, 184 Machined surface, 11 Machine tool chatter, 240, 253-64 analysis of, 253-64 Machine tool instability, 245-80 improvement of, 269-72 Machine tools automatic, 328-30 axes of, 3 chatter of, 240, 253-64 coefficient of merit for, 269-71 description of operations, 1-71 dynamic acceptance tests for, 269-71 generating motions of, 2-5 limit of stability of, 258, 260, 263 summary of characteristics, 58-66 summary of machining equations, 58-66 types of, 1-71 using abrasive wheels, 47-66 using multi-point tools, 26-46 using single-point tools, 5-25 vibrations of, 239-79 Machine tool vibrations, 239-79 MachiningMachining center, 333, 342 Machining costs, 442-5 cost of handling between machine, 442-3 cost of machine loading and unloading, 442 material cost, 442 minimum cost for production, 402 nonproductive costs, 442 Machining data, 447-51 Machining time in broaching, 43 in drilling, 28 in face milling, 41 in internal plunge grinding, 57 in internal traverse grinding, 57 of lathe, 7 for maximum power, 450 in milling, 87 in plunge grinding, 51 of shaper, 23 in traverse grinding, 50 in vertical surface grinding, 54 Manual data input NC programming, 394-5 Manual programming of NC machines, 369-71 Manufacturing cells, 321 flexible, 342Manufacturing systems, 317-51 Materials requirements planning (MRP), 355 Maximum rate of profit, 189 Mechanics of metal cutting, 73-108 Metal cutting forms of wear in, 130-2 friction in, 99 heat generation in, 109-10 lubrication in, 159-63 mechanics of, 73-108 temperature distribution in, 112-13 Metal removal rate in broaching, 44 in cylindrical grinding, 56 in drilling, 28 for electrical discharge machining, 495 for electrochemical machining, 456 for electrolytic grinding, 489 in grinding, 293 in internal plunge grinding, 57 in internal traverse grinding, 57 in milling, 38 of shaper, 23 in traverse grinding, 49 in turning, 12 in vertical milling, 38 in vertical surface grinding, 53arc of contact in, 262 angular, 39 face, 40 gang, 39 straddle, 39 Milling cutters, variable pitch, 269, 272 Milling machine horizontal, 33-40 Mode coupling instability, 264, 249-50, 254 Modes of vibration closely coupled, 245 of a horizontal milling machine structure, 245, 250 natural, 245 Multi-point tools, 26 modification of stability analysis for, 261 N NC, 323-4 NC controller, 331, 332 economics of, 337-8 main features of, 331-3 NC machines, 331-8 NC motions, 333-5 continuous path, 335 linear, 333 point-to-point, 333 positional, 333 NC processor, 375NC programming languages for, 379-80 APT-based, 380-87 free format, 380 fixed format, 380 manual data input, 394-5 tasks for, 363-8 technological languages for, 387-94 Nonconventional machining processes, 467-515 range of processes, 468-9 reasons for choosing, 467-8 Normal rake angle recommended for roughing, 139 Normal wedge angle, 217 Numerical control (see NC) O Oblique cutting, 75, 207 Operative receptance, 258, 259 locus, 258Opitz classification system, 405-11 Optimum cutting conditions, factors needed for, 184 Optimum spindle speed, 193 Orthogonal cutting, 75, 207, 226, 251, 253 Overlap factor, 257 P Photo-chemical machining, 481 Planing machine, 24-5 Plant layout (see Facilities layout) Plasma arc cutting, 509-11 applications of, 509-11 Plowing action of grinding grains, 282-4 Plowing force, 83-6 Plunge grinding, 49, 56 Polycrystalline tools, 147-8 diamond, 147 cubic boron nitride (CBN), 147 Postprocessor, 375 functions of, 375-6 Premature tool failure, 135 Primary deformation zone, 79, 110, 112 temperatures in, 114-16 Primary motion of machine tools, 2 of tool, 8 Process layout of machines, 319 Process planning, 256-63retrieval systems for, 360-61 tasks for, 256-57 variant systems for, 360-61 Product cycle, 354-5 Production large batch, 318 mass or continuous, 318 small batch, 319 types of, 318-20 Production cost, 175 Production rate, maximum, 181 Production time, 175 cutting speed for minimum, 182 tool life for minimum, 183 Productivity, 317 Programmable automation, 323 Programming of NC machines, 363-95 tasks for, 367-8 Program point of tool, 367-8 Program sequence control, 323 Progressive flank wear, 131 Progressive tool wear, 130 Q Quick stopping device, 77-9 R Radial arm drilling machine, 33Rake tool normal, 217 working normal, 76, 217 Rake angle, 76 effect on tool wear, 137 recommended for roughing, 139 Rapid wear test, 149 Real area of contact, 101 Reaming, 32 Receptance cross, 259 operative, 258, 259 Regenerative effect, 252 modification of, 272 Regenerative instability, 248, 253, 269 Regrindable tools cost of sharp cutting edge, 185, 186 Residual stresses in grinding, 306, 313, 314 Resonance, 241 Start of Citation[PU]Marcel Dekker, Inc.[/PU][DP]1989[/DP]End of CitationResultant cutting motion, 9 Resultant cutting speed, 10 angle of, 9 Resultant tool force, 81 Robots, 339, 340-1, 347 S Screw cutting, 15 Secondary deformation zone, 80, 110, 112 temperatures in, 116-7 Self-excited vibrations, 245-64 Shaping machine (shaper), 21 Shear angle, 87 Shear plane, 87 Shear plane model of continuous cutting, 87-90 Shear strength of work material, 86-90 Shear zone, 110 Shop floor control, 355 Silicon nitride, 147 Single-degree-of-freedom system, 240 vibrations of, 240-5 Single point tools, 8-10 corner of, 8 cutting part of, 8 Size effect, 83-6, 284 Slab milling, 33 Sliding region of tool-chip contact, 102 Slotting, 38Sparking out time, 52, 296 Specific cutting energy, 82-3 of grinding process, 295 Spot facing, 33 Stability analysis, 259-62 modification for multiedge tools, 261 Stability charts, 253, 263 for horizontal milling machine, 252, 254 for irregular pitch milling cutters, 27 with vibration absorber, 275 Stabler's chip flow law, 207 Standardization, 400-1 Sticking region of tool-chip contact, 102 Surface flaws in, 172 lay of, 172 profile of, 172 waviness of, 172 Surface asperities, 101, 159 Surface roughness, 166-73 arithmetic mean value for, 166 contributions to, 170 cost of improved, 432-6 effect of built-up-edge, 168 effect of cutting speed on, 170 ideal, 166 for sharp cornered tool, 166T Tailstock of lathe, 5 redesign for improved stability, 271, 273 Taps, 45 Taylor's tool life relationship, 134, 178, 183, 191-2, 326, 446 Technological languages for NC processing, 387-94 Temperatures in metal cutting, 107-27 distribution in, 112-13 effect of cutting speed on, 121 example of calculation of, 117-21 measurement of, 121-5 in primary deformation zone, 114- 16 in secondary deformation zone, 116-17 Thermal damage in grinding, 305-7 Thermal effects in grinding, 303-7Thermal number, 111 Thick shear-zone model of metal cutting, 100 Threading, 11, 15 Threshold of stability (see Limit of stability) Thrust force, 81 Time nonproductive, 175 total machining, 178 total to change worn tools, 178 Titanium carbide, 146 Tool changing time for, 185 face of, 8, 75 flank of, 8 holder for, 7 included angle of, 217 post for, 7 Tool angles calculation from working angles, 222-3 effect on tool wear, 137 Tool-in-hand planes, 214, 215 Tool-in-use planes, 216 Tool materials cast alloy, 145 ceramic, 147 ceramic-ceramic composites, 147 cermets, 147diamond, 147 high-speed steel, 143-5 coated, 143 hot hardness of, 143 titanium carbide, 145 tungsten carbide, 145 Tool life, 129-53 criteria for, 132-4 effect of built-up-edge on, 136 effect of cutting speed on, 134-5 effect of coolants on, 156 for minimum cost, 182, 402 for minimum production time, 182 Taylor's relationship for, 134, 178, 183, 191-2 Tool life testing ISO standard for, 134 ISO test for turning, 149 Tool materials, 140 basic requirements of, 140-4 major classes of, 142 Tool path coordinates, 367, 368, 372-5 Tool replacement costs, 445-7 Tool wear, 129-53 crater, 130-31, 234 during chip breaking, 234-6 effect of built-up-edge on, 136 effect of rake angle on, 137for electrical discharge machining, 494-4 forms of, 130-2 for single point tools, 133 Tools cast alloy, 145 cemented carbide, 145 ceramic, 147 cermet, 147 coated carbide, 146 multipoint, 26 polycrystalline, 147-8 titanium-carbide, 145 tungsten-carbide, 145 Transfer machines, 324-8 economics of, 324-8 in-line, 324, 325 rotary, 324, 325 Transfer line, 323 flexible, 343 Transient surface, 11 Traverse, 49, 53 Traverse grinding, 49, 56, 57 Tungsten carbide, 145 Turning approximate cost model for, 453-5 application to a typical component, 455-7 effect of component size on costs, 457-9 effect of work material on costs, 459-61 Twist drill, 27 U Ultrasonic machining, 469-75 applications of, 475 basic features of, 469 tools for, 474-5 transducers for, 469-74 magnetostrictive transducers, 473-4 piezoelectric transducers, 469-73 Undeformed chip thickness, 10, 76 V Variable-pitch milling cutters, 272 Vertical boring machine, 19 Vertical milling machine, 40 Vertical spindle surface grinding machine, 52 Vibration absorber, 272 Vibrations effects on cutting process, 256 free, 239 forced, 239, 240-45 of complex structures, 245 of machine tools, 242 of single-degree-of-freedom system, 240-45 of machine tools, 239-79transient, 239 W Water-jet machining, 475-78 applications of, 477-8 Wear abrasive, 130 adhesion, 130 crater, 130-31, 234 criteria for high speed steel and ceramic tools, 134 for sintered carbide tools, 134 flank, 131-2 forms of in metal cutting, 130-2 in grinding wheels, 290, 308-10 Wear test accelerated, 149 rapid, 149 Wedge angle, 76 Wire-electrical discharge machining, 499-501 Word address format for NC machines, 369 Work engagement, 36 Work-in-progress, 319 Work material, 140-50 choice of, 401-3 effect of turning on costs, 459-61 Workpiece, 2 Workpiece removal parameter inWork-tool-thermocouple, 121-3 Conventions Used in This Book xi Standardization xi Introduction to the International (SI) System of Units xiv 1 Machine Tools and Machining Operations 1 1.1 Introduction 1 1.2 Generating Motions of Machine Tools 2 1.3 Machines Using Single-Point Tools 5 1.4 Machines Using Multipoint Tools 26 1.5 Machines Using Abrasive Wheels 47 1.6 Summary of Machine Tool Characteristics and Machining Equations 58 Problems 66 Reference 71 f2 Mechanics of Metal Cutting 73 2.1 Introduction 73 2.2 Terms and Definitions 75 2.3 Chip Formation 77 2.4 The Forces Acting on the Cutting Tool and Their Measurement 81 2.5 Specific Cutting Energy 82 2.6 Plowing Force and the "Size Effect" 83 2.7 The Apparent Mean Shear Strength of the Work Material 86 2.8 Chip Thickness 90 2.9 Friction in Metal Cutting 99 Problems 104 References 107 3 Temperatures in Metal Cutting 109 3.1 Heat Generation in Metal Cutting 109 3.2 Heat Transfer in a Moving Material 110 3.3 Temperature Distribution in Metal Cutting 112 3.4 The Measurement of Cutting Temperatures 121Problems 125 References 127 4 Tool Life and Tool Wear 129 4.1 Introduction 129 4.2 Progressive Tool Wear 130 4.3 Forms of Wear in Metal Cutting 130 4.4 The Tool Material 140 4.5 The Work Material 148 Problems 151 References 152 5 Cutting Fluids and Surface Roughness 155 5.1 Cutting Fluids 155 5.2 The Action of Coolants 156 5.3 The Action of Lubricants 156 5.4 Application of Cutting Fluids 163 5.5 Surface Roughness 166page_vii Page vii Problems 173 References 173 6 Economics of Metal-Cutting Operations 175 6.1 Introduction 175 6.2 Choice of Feed 177 6.3 Choice of Cutting Speed 178 6.4 Tool Life for Minimum Cost and Minimum Production Time 182 6.5 Estimation of Factors Needed to Determine Optimum Conditions 184
6.6 Example of a Constant-Cutting-Speed Operation 185 6.7 Machining at Maximum Efficiency 188 6.8 Facing Operations 191 6.9 Operations with Interrupted Cuts 194 6.10 Economics of Various Tool Materials and Tool Designs 195 6.11 Machinability Data Systems 200 Problems 200 References 204 7 Nomenclature of Cutting Tools 205page_vii 7.1 Introduction 205 7.2 Systems of Cutting-Tool Nomenclature 207 7.3 International Standard 213 Problems 223 References 224 8 Chip Control 225 8.1 Introduction 225 8.2 Chip Breakers 226 8.3 Prediction of Radius of Chip Curvature 230 8.4 Tool Wear During Chip Breaking 234 Problems 237 References 237 9 Machine Tool Vibrations 239 9.1 Introduction 239 9.2 Forced Vibrations 240page_viii 9.3 Self-Excited Vibrations (Chatter) 245 9.4 Determination of Frequency Response Loci 264 9.5 Dynamic Acceptance Tests for Machine Tools 269 9.6 Improving Machine Tool Stability 270 Problems 277 References 279 10 Grinding 281 10.1 Introduction 281 10.2 The Grinding Wheel 281 10.3 Effect of Grinding Conditions on Wheel Behavior 286 10.4 Determination of the Density of Active Grains 290 10.5 Testing of Grinding Wheels 290 10.6 Analysis of the Grinding Process 290 10.7 Thermal Effects in Grinding 303 10.8 Cutting Fluids in Grinding 307 10.9 Grinding-Wheel Wear 308 10.10 Nonconventional Grinding Operations 311page_viii Problems 315 References 315 11 Manufacturing Systems and Automation 317 11.1 Introduction 317 11.2 Types of Production 318 11.3 Types of Facilities Layout 319 11.4 Types of Automation 321 11.5 Transfer Machines 324 11.6 Automatic Machines 328 11.7 Numerically Controlled (NC) Machine Tools 331 11.8 Comparison of the Economics of Various Automation Systems 338 11.9 Handling of Components in Batch Production 339 11.10 Flexible Manufacturing Systems 340 Problems 350 References 351 12 Computer-Aided Manufacturing 353 12.1 Introduction 353 12.2 Scope of CAD/CAM 354page_viii 12.3 Process-Planning Tasks 356page_x Page x Problems 514 References 514 Nomenclature 517 Index 531 page_531 Page 531 Index A Abrasive grains, chip formation by, 284 Abrasive jet machining, 478-80 applications of, 480 Abrasive particles, 281 Abrasives, hardness of, 285 Abrasive slurry, 475 Abrasive water-jet machining, 476-7 Abrasive wear, 130 Abrasive wheels, 47 Accelerated wear test, 149 Accuracy, cost of increased, 432-436 Active force control, 272-3 Active grains in grinding, 290 determination of density of, 290 plowing action of, 282-284 Adaptive control, 336, 337 Adhesion wear, 130 Air film barrier in grinding, 307-8 Aluminum oxide, 147, 284 Amonton's law of friction, 100, 159 AGVs (see Automatic guided vehicles) APT, 379, 380-7 auxiliary statements in, 385 languages based on, 380-7 geometric statements in, 381 motion statements in, 381-4 Arc of contact in milling, 262 Area of contact, apparent, 101 real, 159 Asperities, 101, 159 Assembly of components, 432 Automatically Programmed Tools (see APT) Automatic guided vehicles, 341, 346-7 Automatic lathes, 328, 329 multispindle, 328 single-spindle, 328 Automatic machines, 328-30 economics of, 330 Automation, 317-51 fixed, 322-3 types of, 321-4 Page 532 economics of different systems, 338-9 B Back engagement, 10, 37 Bonds for grinding wheels, 285 metallic, 285 resinoid, 285 rubber, 285 shellac, 285 silicate, 285 vitrified, 285 Boring, 11, 15 Boring bar, 20 Boring machines, 19-20 horizontal 19-20 Boundary lubrication, 156-9 Broaching machine, 43 Built-up-edge, 80, 168 continuous chip with, 80 effect of speed and feed on, 140 effect on surface roughness, 168 effect on tool life, 136 effect on tool wear, 136 C CAD, 353 CAD/CAM, 354-5 scope of, 354-5 CAM, 353-97 Canned cycles, 372-3 Carbide coated, 146 titanium, 145 tungsten, 145 Carbide tool inserts brazed, 135 cost of sharp cutting edge, 185, 186 throw away, 135 cost of sharp cutting edge, 185 Carbon tetrachloride, 160 as a cutting fluid, 160-1 Carriage of a lathe, 5 Cast alloy tools, 145 Cellular layout of machines, 321 Center drilling, 32 Center lathe (see Engine lathe) Ceramic tools, 147 Ceramic-ceramic composites, 147 Cermet tools, 147 Chemical blanking, 480 Chemical machining, 480-3 applications of, 482-3 etchants for, 481 masks for, 481 Chemical milling, 480 Chip, 2, 73 continuous, 79, 225 discontinuous, 80 helix angle of, 228 length of, 88 Chip breakers, 226-30 groove type, 226, 233, 235 obstruction type, 226, 230, 235 Chip breaking, tool wear during, 234-6 Chip control, 225-37 Chip flow angle, 207, 228 Chip formation, 77-81 by grains in grinding, 284 Chip radius of curvature, 230 Chips bulk ratio of, 225 classification of, 230 overbroken, 230 underbroken, 230 various forms of, 226 standard coding system for, 226-7 types of arc type, 230 conical type helical, 228 connected arc, 230 ribbon, 226 spiral, 226 straight, 226 tubular, 226 washer type helical, 226 Chip thickness, 90-7 Page 533 theory of Ernst and Merchant, 90-4 theory of Lee and Shafer, 97 undeformed, 10 Chip thickness coefficient, 256, 263 Chuck, 5, 15 CIM, 356 Classification of machined parts, 403-32 Clearance angle of tool, 76 tool normal, 217 working normal, 76, 217 CNC systems, 336 Coated carbide tools, 146 Coefficient of merit of machine tools, 269-70 Collet, 16 Comparative performance of cutting processes, 511-4 Compound rest of lathe, 17 Computer-aided design (see CAD) Computer-aided design and manufacturing (see CAD/CAM) Computer-aided manufacturing (see CAM) Computer-aided NC processing, 375-9 Computer-aided process planning, 354, 359-363 generative systems for, 360-3 retrieval systems for, 360-1 variant systems for, 360-1 Computer-integrated manufacturing (see CIM) Computer numerical control systems (see CNC) Computers in NC, 335-7 Contact apparent area of, 101 real area of, 159 Continuous chip, 79, 225 with built-up-edge, 80 Coolants action of, 156 effect on tool life, 156 Costs of increased accuracy and surface finish, 432-6 of machine and operator, 184 of sharp cutting edge for regrindable tools, 185, 186 for disposable insert tools, 185 Crater wear, 130-1, 234 effect of speed and feed on, 140 Creep feed grinding, 312 Cross feed in grinding, 49 Cross receptance, 259 Cubic boron nitride (CBN), 147, 284 Cut off, 11, 15 Cutter location (CL) file, 375 Cutting edge angle major, 10 tool 217 working, 217 Cutting edge of tool, 2, 8, 75 major cutting edge, 8, 205, 214 minor cutting edge, 8, 205, 214 Cutting edge inclination tool, 217 working, 217 Cutting fluids application of, 163-6 flood, 165 manual, 165 mist, 165 in grinding, 307-9 neat, 155, 307 general characteristics of, 163 guide to selection of, 164 water-miscible, 155, 307-309 general characteristics of, 156, 157 guide to selection of, 156, 158 carbon tetrachloride as a, 160, 161 Cutting force, 81 measurement of, 81-2 Cutting force dynamometer, 81 Cutting processes, comparative performance of, 511-14 Cutting ratio, 89, 90 Page 534 Cutting speed, 9 choice of, 178 effect on cratering and built-up-edge, 140 effect on tool life, 134-5 for minimum cost, 181, 402 for minimum production time, 182 Cutting temperatures, measurement of, 121-5 Cutting tool (see Tool), 2 Cutting tool nomenclature, 205-24 British maximum rake system for, 207, 208-11 example of calculation for, 221 German (DIN) system for, 211-12 ISO system for 205, 213-23 systems for, 207-13 tool and working systems, mathematical relationship between, 218-21 tool-in-hand system for, 213, 218-221 tool-in-use system for, 213, 218-221 Cylindrical grinding machine, 55-57 Cylindrical plunge grinding, idealized model of, 291 Cylindrical turning, 7, 11 D Data base design and manufacturing, 356-7 machinability, 200 Deformation zone primary, 79, 110, 112 temperatures in, 114-6 secondary, 80, 110, 112 temperatures in, 116-7 Depth of cut, 10 in milling, 36 Design and manufacturing data base, 356-7 Designation of grinding wheels, 286 Design for machining, 399-465 summary of guidelines, 436-8 Design for manufacture, 399 Design guidelines for machined parts, 436-8 Dies, 45 Diffusion wear, 130 Direct numerical control (see DNC systems) Discontinuous chip, 80 DNC systems, 336, 342 Dog, 16 Dressing of grinding wheels, 283 Drilling, 27 center, 32 Drilling machine, 26-28 Dynamic acceptance tests for machine tools, 269-70 Dynamometer for cutting forces, 81 E Early cost estimating for machining, 438-65 Economics of metal cutting operations, 175-204 comparison of automation systems, 338-9 of facing operations, 191-4 of operations with interrupted cuts, 194-5 of various tool designs, 195-200 of various tool materials, 195-200 Economics of transfer machines, 324-8 Electrical discharge machining (EDM), 491-9 applications of, 498-9 dielectrics for, 496-7 electrodes for, 493 metal removal rate for, 495 process parameters for, 497-8 tool materials for, 493-4 tool wear for, 493-4 Electrochemical machining (ECM), 483-9 applications of, 488-9 metal removal rate for, 485-6 tool feed speed for, 485 tools for, 488 Electrolytic grinding, 489-91 metal removal rate for, 489 Electron beam machining, 505-11 Electromagnetic vibrator, 266-9 for milling machine, 269 Engine lathe, 5-18 Equivalent diameter of grinding wheels, 299 EXAPT, 379, 387-94 F Face of tool, 8, 75 Face plate, 16 Facilities layout, types of, 319-22 cellular layout, 321 functional layout, 319 group layout, 321 line layout, 319 process layout, 319 Facing, 11, 14 economics of, 191-94 Feed, 7 choice of, 177 effect on built-up-edge formation, 140 effect on crater wear, 140 per tooth, 27, 35 Feed engagement, 10, 27, 35 Feed motion, 3, 7, 9 Feed speed, 9 Fixed automation, 322-23 Fixed cycles, 371-2 Flank of tool, 8, 76 Flank wear, 131-2 Flexible manufacturing cell, 342 Flexible manufacturing systems (see FMS) Flexible transfer line, 343 Flow angle of chip, 207, 228 FMS, 321, 340-350 features of, 341-2 flexibility in, 342, 345 layouts for, 347 machine tools in, 345 pallets and fixtures for, 349-50 tooling in, 347 work handling in, 345 AGVs, 347 rail carts, 347 roller conveyors, 347 tow carts, 347 Form cutting, 38 Free machining metals, 151 Frequency response cross, 345 determination of, 264-8 direct, 345 polar diagram of, 242 of single degree of freedom system, 243 Friction Amonton's law of, 100, 159 angle, 102 coefficient of, 101, 102 force, 101 in metal cutting, 99 Functional layout of machines, 319 G Grain aspect ratio, 288 Grains, 281 Grain size, 285 Grain types, 284 aluminum oxide, 284 cubic boron nitride, 284 silicon carbide, 284 Grinding, 281-316 active grains in, 290 air film barrier in, 307-8 analysis of process, 290 creep feed, 312 cross feed in, 49 geometry of chip removal in, 289 high speed, 311-2 infeed in, 49, 53, 56, 57 low stress, 312-4 metal removal rate in, 293 metal removal parameter for, 293 Page 536 difficult-to-grind materials, 303 easy-to-grind materials, 300 plunge, 49, 56 idealized model of, 291 residual stresses in, 306, 313, 314 specific cutting energy for, 295 thermal effects in, 303-7 wheel-workpiece contact zone, 291 length of, 299 workpiece removal parameter in, 293 Grinding cycles, 296-8 cylindrical 296 surface grinding, 298 Grinding fluids (see also Cutting fluids) application of, 307-8 air deflector nozzle, 308 flooding, 308 high-pressure jet, 308 Grinding machine cylindrical, 55-7 horizontal spindle surface, 49-52 internal, 57-8 Grinding ratio, 295, 308 Grinding wheel behavior, effect of grinding conditions, 286 Grinding wheels, 47, 281-6 action of, 283 bonds for, 285 designation of, 286 equivalent diameter of, 298 grain size in, 285 hard behavior, 283 ISO standard marking system for, 286 removal parameter for, 293 self sharpening characteristics of, 282 soft behavior of, 283 structure of, 282, 286 testing of, 290 wear in, 290, 308-10 Group layout of machines, 321 Group technology, 360 H Handling of components in batch production, 339 Hardness, of abrasive grains, 285 changes in tool steels, 124-5 of tool materials, 143 Harmonic receptance locus, 242 Harmonic response locus, 242 Headstock, 5 Heat generation in metal cutting, 109-10 Heat transfer in a moving material, 110-12 High-speed grinding, 311-12 High-speed steel, 143-5 coated, 143 Horizontal boring machine, 19-20 Horizontal milling machine, 33-40 Horizontal spindle surface grinding machine, 49-52 Hot hardness of tool materials, 143 I Infeed in grinding, 49, 53, 56, 57 International Standards Organization (see ISO) Internal grinding machine, 57-8 ISO recommended roughness values, 173 standard for tool life testing, 134 standard marking system for grinding wheels, 286 system for tool nomenclature, 205 tool life test for turning, 149 L Languages for NC processing, 379-87 APT, 379, 380-87 EXAPT, 379, 387-94 Laser beam machining, 501-5 applications of, 505 cutting operations with, 504-5 Page 537 percussion drilling by, 503-4 trepanning with, 504-5 Lasers, types of, 503 Lathe automatic, 18, 323 single-spindle, 328 multispindle, 328 carriage of, 5 center (see Engine lathe) compound rest of, 17 engine, 5-11 turret, 19 types of operation, 11 Limit of stability of machine tools, 258, 260, 263 Line layout of machines, 219 Low-stress grinding, 312-14 Lubricants, action of, 156-63 Lubrication boundary, 156-9 characteristics of efficient, 161-3 in metal cutting, 159-63 M Machinability, 148, 443 factors affecting, 150-1 index or number for, 148 testing for, 149 Machinability data systems, 200 data base systems, 200 mathematical model systems, 200 Machined components classification of, 403-32 shape of, 403-32 Machine depreciation rate, 184 Machined surface, 11 Machine tool chatter, 240, 253-64 analysis of, 253-64 Machine tool instability, 245-80 improvement of, 269-72 Machine tools automatic, 328-30 axes of, 3 chatter of, 240, 253-64 coefficient of merit for, 269-71 description of operations, 1-71 dynamic acceptance tests for, 269-71 generating motions of, 2-5 limit of stability of, 258, 260, 263 summary of characteristics, 58-66 summary of machining equations, 58-66 types of, 1-71 using abrasive wheels, 47-66 using multi-point tools, 26-46 using single-point tools, 5-25 vibrations of, 239-79 Machine tool vibrations, 239-79 Machining definition of, 5 for maximum efficiency, 188 Machining center, 333, 342 Machining costs, 442-5 cost of handling between machine, 442-3 cost of machine loading and unloading, 442 material cost, 442 minimum cost for production, 402 nonproductive costs, 442 Machining data, 447-51 Machining time in broaching, 43 in drilling, 28 in face milling, 41 in internal plunge grinding, 57 in internal traverse grinding, 57 of lathe, 7 for maximum power, 450 in milling, 87 in plunge grinding, 51 of shaper, 23 in traverse grinding, 50 in vertical surface grinding, 54 Manual data input NC programming, 394-5 Manual programming of NC machines, 369-71 Manufacturing cells, 321 flexible, 342 Page 538 Manufacturing systems, 317-51 Materials requirements planning (MRP), 355 Maximum rate of profit, 189 Mechanics of metal cutting, 73-108 Metal cutting forms of wear in, 130-2 friction in, 99 heat generation in, 109-10 lubrication in, 159-63 mechanics of, 73-108 temperature distribution in, 112-13 Metal removal rate in broaching, 44 in cylindrical grinding, 56 in drilling, 28 for electrical discharge machining, 495 for electrochemical machining, 456 for electrolytic grinding, 489 in grinding, 293 in internal plunge grinding, 57 in internal traverse grinding, 57 in milling, 38 of shaper, 23 in traverse grinding, 49 in turning, 12 in vertical milling, 38 in vertical surface grinding, 53 Microstructure, changes in tool steels with temperature, 124-25 Milling arc of contact in, 262 angular, 39 face, 40 gang, 39 straddle, 39 Milling cutters, variable pitch, 269, 272 Milling machine horizontal, 33-40 Mode coupling instability, 264, 249-50, 254 Modes of vibration closely coupled, 245 of a horizontal milling machine structure, 245, 250 natural, 245 Multi-point tools, 26 modification of stability analysis for, 261 N NC, 323-4 NC controller, 331, 332 economics of, 337-8 main features of, 331-3 NC machines, 331-8 NC motions, 333-5 continuous path, 335 linear, 333 point-to-point, 333 positional, 333 NC processor, 375 NC program, 331, 363-95 processing of, 363-68 NC programming languages for, 379-80 APT-based, 380-87 free format, 380 fixed format, 380 manual data input, 394-5 tasks for, 363-8 technological languages for, 387-94 Nonconventional machining processes, 467-515 range of processes, 468-9 reasons for choosing, 467-8 Normal rake angle recommended for roughing, 139 Normal wedge angle, 217 Numerical control (see NC) O Oblique cutting, 75, 207 Operative receptance, 258, 259 locus, 258 Page 539 Opitz classification system, 405-11 Optimum cutting conditions, factors needed for, 184 Optimum spindle speed, 193 Orthogonal cutting, 75, 207, 226, 251, 253 Overlap factor, 257 P Photo-chemical machining, 481 Planing machine, 24-5 Plant layout (see Facilities layout) Plasma arc cutting, 509-11 applications of, 509-11 Plowing action of grinding grains, 282-4 Plowing force, 83-6 Plunge grinding, 49, 56 Polycrystalline tools, 147-8 diamond, 147 cubic boron nitride (CBN), 147 Postprocessor, 375 functions of, 375-6 Premature tool failure, 135 Primary deformation zone, 79, 110, 112 temperatures in, 114-16 Primary motion of machine tools, 2 of tool, 8 Process layout of machines, 319 Process planning, 256-63 computer aided systems for, 359-63 generative systems for, 360-63 retrieval systems for, 360-61 tasks for, 256-57 variant systems for, 360-61 Product cycle, 354-5 Production large batch, 318 mass or continuous, 318 small batch, 319 types of, 318-20 Production cost, 175 Production rate, maximum, 181 Production time, 175 cutting speed for minimum, 182 tool life for minimum, 183 Productivity, 317 Programmable automation, 323 Programming of NC machines, 363-95 tasks for, 367-8 Program point of tool, 367-8 Program sequence control, 323 Progressive flank wear, 131 Progressive tool wear, 130 Q Quick stopping device, 77-9 R Radial arm drilling machine, 33 Radiation methods of temperature measurement, 124 Radius of curvature of chips, 230 Rake tool normal, 217 working normal, 76, 217 Rake angle, 76 effect on tool wear, 137 recommended for roughing, 139 Rapid wear test, 149 Real area of contact, 101 Reaming, 32 Receptance cross, 259 operative, 258, 259 Regenerative effect, 252 modification of, 272 Regenerative instability, 248, 253, 269 Regrindable tools cost of sharp cutting edge, 185, 186 Residual stresses in grinding, 306, 313, 314 Resonance, 241 Page 540 Resultant cutting motion, 9 Resultant cutting speed, 10 angle of, 9 Resultant tool force, 81 Robots, 339, 340-1, 347 S Screw cutting, 15 Secondary deformation zone, 80, 110, 112 temperatures in, 116-7 Self-excited vibrations, 245-64 Shaping machine (shaper), 21 Shear angle, 87 Shear plane, 87 Shear plane model of continuous cutting, 87-90 Shear strength of work material, 86-90 Shear zone, 110 Shop floor control, 355 Silicon nitride, 147 Single-degree-of-freedom system, 240 vibrations of, 240-5 Single point tools, 8-10 corner of, 8 cutting part of, 8 Size effect, 83-6, 284 Slab milling, 33 Sliding region of tool-chip contact, 102 Slotting, 38 Solid-state diffusion, 130 Sparking out, 52, 296 Sparking out time, 52, 296 Specific cutting energy, 82-3 of grinding process, 295 Spot facing, 33 Stability analysis, 259-62 modification for multiedge tools, 261 Stability charts, 253, 263 for horizontal milling machine, 252, 254 for irregular pitch milling cutters, 27 with vibration absorber, 275 Stabler's chip flow law, 207 Standardization, 400-1 Sticking region of tool-chip contact, 102 Surface flaws in, 172 lay of, 172 profile of, 172 waviness of, 172 Surface asperities, 101, 159 Surface roughness, 166-73 arithmetic mean value for, 166 contributions to, 170 cost of improved, 432-6 effect of built-up-edge, 168 effect of cutting speed on, 170 ideal, 166 for sharp cornered tool, 166 for round nosed tool, 168 natural, 168 T Tailstock of lathe, 5 redesign for improved stability, 271, 273 Taps, 45 Taylor's tool life relationship, 134, 178, 183, 191-2, 326, 446 Technological languages for NC processing, 387-94 Temperatures in metal cutting, 107-27 distribution in, 112-13 effect of cutting speed on, 121 example of calculation of, 117-21 measurement of, 121-5 in primary deformation zone, 114- 16 in secondary deformation zone, 116-17 Thermal damage in grinding, 305-7 Thermal effects in grinding, 303-7 Page 541 Thermal number, 111 Thick shear-zone model of metal cutting, 100 Threading, 11, 15 Threshold of stability (see Limit of stability) Thrust force, 81 Time nonproductive, 175 total machining, 178 total to change worn tools, 178 Titanium carbide, 146 Tool changing time for, 185 face of, 8, 75 flank of, 8 holder for, 7 included angle of, 217 post for, 7 Tool angles calculation from working angles, 222-3 effect on tool wear, 137 Tool-in-hand planes, 214, 215 Tool-in-use planes, 216 Tool materials cast alloy, 145 ceramic, 147 ceramic-ceramic composites, 147 cermets, 147 coated carbides, 146 cubic boron nitride (CBN), 147 diamond, 147 high-speed steel, 143-5 coated, 143 hot hardness of, 143 titanium carbide, 145 tungsten carbide, 145 Tool life, 129-53 criteria for, 132-4 effect of built-up-edge on, 136 effect of cutting speed on, 134-5 effect of coolants on, 156 for minimum cost, 182, 402 for minimum production time, 182 Taylor's relationship for, 134, 178, 183, 191-2 Tool life testing ISO standard for, 134 ISO test for turning, 149 Tool materials, 140 basic requirements of, 140-4 major classes of, 142 Tool path coordinates, 367, 368, 372-5 Tool replacement costs, 445-7 Tool wear, 129-53 crater, 130-31, 234 during chip breaking, 234-6 effect of built-up-edge on, 136 effect of rake angle on, 137 effect of tool angles on, 137 flank, 131-2 for electrical discharge machining, 494-4 forms of, 130-2 for single point tools, 133 Tools cast alloy, 145 cemented carbide, 145 ceramic, 147 cermet, 147 coated carbide, 146 multipoint, 26 polycrystalline, 147-8 titanium-carbide, 145 tungsten-carbide, 145 Transfer machines, 324-8 economics of, 324-8 in-line, 324, 325 rotary, 324, 325 Transfer line, 323 flexible, 343 Transient surface, 11 Traverse, 49, 53 Traverse grinding, 49, 56, 57 Tungsten carbide, 145 Turning approximate cost model for, 453-5 application to a typical com ponent, 455-7 effect of component size on costs, 457-9 effect of work material on costs, 459-61 Twist drill, 27 U Ultrasonic machining, 469-75 applications of, 475 basic features of, 469 tools for, 474-5 transducers for, 469-74 magnetostrictive transducers, 473-4 piezoelectric transducers, 469-73 Undeformed chip thickness, 10, 76 V Variable-pitch milling cutters, 272 Vertical boring machine, 19 Vertical milling machine, 40 Vertical spindle surface grinding machine, 52 Vibration absorber, 272 Vibrations effects on cutting process, 256 free, 239 forced, 239, 240-45 of complex structures, 245 of machine tools, 242 of single-degree-of-freedom system, 240-45 of machine tools, 239-79 self-excited, 240 steady state, 241 transient, 239 W Water-jet machining, 475-78 applications of, 477-8 Wear abrasive, 130 adhesion, 130 crater, 130-31, 234 criteria for high speed steel and ceramic tools, 134 for sintered carbide tools, 134 flank, 131-2 forms of in metal cutting, 130-2 in grinding wheels, 290, 308-10 Wear test accelerated, 149 rapid, 149 Wedge angle, 76 Wire-electrical discharge machining, 499-501 Word address format for NC machines, 369 Work engagement, 36 Work-in-progress, 319 Work material, 140-50 choice of, 401-3 effect of turning on costs, 459-61 Workpiece, 2 Workpiece removal parameter in grinding, 293 Work surface, 11 Work-tool-thermocouple
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