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| موضوع: كتاب Mechanisms and Mechanical Devices Sourcebook - Fifth Edition الأحد 24 سبتمبر 2023, 2:52 am | |
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أخواني في الله أحضرت لكم كتاب Mechanisms and Mechanical Devices Sourcebook Fifth Edition NEIL SCLATER
و المحتوى كما يلي :
CONTENTS PREFACE xi CHAPTER 1 BASICS OF MECHANISMS 1 Introduction 2 Physical Principles 2 Efficiency of Machines 2 Mechanical Advantage 2 Velocity Ratio 3 Inclined Plane 3 Pulley Systems 3 Screw-Type Jack 4 Levers and Mechanisms 4 Levers 4 Winches, Windlasses, and Capstans 5 Linkages 5 Simple Planar Linkages 5 Specialized Linkages 6 Straight-Line Generators 7 Rotary/Linear Linkages 8 Specialized Mechanisms 9 Gears and Gearing 10 Simple Gear Trains 11 Compound Gear Trains 11 Gear Classification 11 Practical Gear Configurations 12 Gear Tooth Geometry 13 Gear Terminology 13 Gear Dynamics Terminology 13 Pulleys and Belts 14 Sprockets and Chains 14 Cam Mechanisms 14 Classification of Cam Mechanisms 15 Cam Terminology 17 Clutch Mechanisms 17 Externally Controlled Friction Clutches 17 Externally Controlled Positive Clutches 17 Internally Controlled Clutches 18 Glossary of Common Mechanical Terms 18 CHAPTER 2 MOTION CONTROL SYSTEMS 21 Motion Control Systems Overview 22 Glossary of Motion Control Terms 28 Mechanical Components Form Specialized Motion-Control Systems 29 Servomotors, Stepper Motors, and Actuators for Motion Control 30 Servosystem Feedback Sensors 38 Solenoids and Their Applications 45CHAPTER 3 STATIONARY AND MOBILE ROBOTS 49 Introduction to Robots 50 The Robot Defined 50 Stationary Autonomous Industrial Robots 50 Some Robot History 51 The Worldwide Robot Market 51 Industrial Robots 51 Industrial Robot Advantages 52 Industrial Robot Characteristics 53 Industrial Robot Geometry 53 Four Different ABB Industrial Robots 56 IRB 2400 57 IRB 6400RF 57 IRB 6640 57 IRB 7600 57 Autonomous and Semiautonomous Mobile Robots 58 Options for Communication and Control 58 Land-based Mobile Robots Can Scout and Retrieve 58 Submersible Mobile Robots Can Search and Explore 58 Robotic Aircraft (Drones) Can Search and Destroy 58 Planetary Exploration Robots Can Examine and Report 59 Laboratory/Scientific Robots Can Mimic Human Behavior 59 Commercial Robots Can Deliver and Retrieve Goods 59 Consumer Robots Clean Floors and Mow Lawns 59 Some Robots Entertain or Educate 59 Seven Mobile Autonomous and Semiautonomous Robots 60 Two Robots Have Explored Mars for Six Years 60 This Robot Will Carry on the Work of Spirit and Opportunity 61 This Robot Responds to Civil Emergencies 62 Robot Delivers Hospital Supplies 62 A Military Remotely-Piloted Aircraft Can Observe and Attack the Enemy 63 Submarine Robot Searches for Underwater Mines and Obstructions 64 This System Offers Less Intrusive Surgery and Faster Recovery 65 Glossary of Robotic Terms 66 Modified Four-Limbed Robot Is a Better Climber 68 Six-Legged Robot Crawls on Mesh in Lunar Gravity 69 Two Robots Anchor Another Traversing Steep Slopes 70 Six-Legged Robot Can Be Steered While Hopping 71 CHAPTER 4 MECHANISMS FOR RENEWABLE POWER GENERATION 73 Overview of Renewable Energy Sources 74 Nuclear: The Unlikely Prime Renewable 74 Alternative Renewable Energy Sources 75 Baseload and Baseload Demand Power Plants 75 Windmills: Early Renewable Power Sources 75 Wind Turbines: Descendents of Windmills 76 Where Are Wind Turbines Located? 77 Concentrating Solar Thermal (CST) Systems 78 Parabolic Trough Mirror Solar Thermal (CST) Plants 78 Power-Tower Solar Thermal (CST) Plants 79 Linear Fresnel Reflector Thermal (CST) Plants 80 Parabolic Dish Stirling Solar Thermal (CST) Plants 81 How a Stirling Engine Works 82 The Outlook for CST Renewable Energy 83 ivHarnessing Moving-Water Power 84 Tidal Electric Power Generation 84 Ocean-Wave Power Generation 84 Another Possible Mechanical Hydropower Solution 84 The Relative Costs of Renewable Energy 85 Glossary of Wind Turbine Terms 86 Renewable Energy Resources 87 CHAPTER 5 LINKAGES: DRIVES AND MECHANISMS 89 Four-Bar Linkages and Typical Industrial Applications 90 Seven Linkages for Transport Mechanisms 92 Five Linkages for Straight-Line Motion 95 Six Expanding and Contracting Linkages 97 Four Linkages for Different Motions 98 Nine Linkages for Accelerating and Decelerating Linear Motions 99 Twelve Linkages for Multiplying Short Motions 101 Four Parallel-Link Mechanisms 103 Seven Stroke Multiplier Linkages 103 Nine Force and Stroke Multiplier Linkages 105 Eighteen Variations of Differential Linkage 107 Four-Bar Space Mechanisms 109 Seven Three-Dimensional Linkage Drives 111 Thirteen Different Toggle Linkage Applications 116 Hinged Links and Torsion Bushings Soft-Start Drives 118 Eight Linkages for Band Clutches and Brakes 119 Design of Crank-and-Rocker Links for Optimum Force Transmission 121 Design of Four-Bar Linkages for Angular Motion 124 Multibar Linkages for Curvilinear Motions 125 Roberts’ Law Helps to Design Alternate Four-Bar Linkages 128 Design of Slider-Crank Mechanisms 129 CHAPTER 6 GEARS: DEVICES, DRIVES, AND MECHANISMS 131 Gears and Eccentric Disk Provide Quick Indexing 132 Odd-Shaped Planetary Gears Smooth Stop and Go 133 Cycloid Gear Mechanism Controls Pump Stroke 136 Gears Convert Rotary-to-Linear Motion 137 Twin-Motor Planetary Gears Offer Safety and Dual-Speed 137 Eleven Cycloid Gear Mechanisms 138 Five Cardan-Gear Mechanisms 141 Controlled Differential Gear Drives 143 Flexible Face-Gears Are Efficient High-Ratio Speed Reducers 144 Rotary Sequencer Gears Turn Coaxially 145 Planetary Gear Systems 146 Noncircular Gears Are Balanced for Speed 153 Sheet-Metal Gears, Sprockets, Worms, and Ratchets for Light Loads 157 Thirteen Ways Gears and Clutches Can Change Speed Ratios 159 Gear and Clutch Shifting Mechanisms 161 Twinworm Gear Drive Offers Bidirectional Output 163 Bevel and Hypoid Gear Design Prevents Undercutting 164 Machining Method to Improve Worm Gear Meshing 165 Geared Speed Reducers Offer One-Way Output 166 Design of Geared Five-Bar Mechanisms 167 Equations for Designing Geared Cycloid Mechanisms 171 Design Curves and Equations for Gear-Slider Mechanisms 174 vCHAPTER 7 CAM, GENEVA, AND RATCHET DRIVES AND MECHANISMS 179 Cam-Controlled Planetary Gear System 180 Five Cam-Stroke-Amplifying Mechanisms 181 Cam-Curve-Generating Mechanisms 182 Fifteen Different Cam Mechanisms 188 Ten Special-Function Cams 190 Twenty Geneva Drives 192 Six Modified Geneva Drives 196 Kinematics of External Geneva Wheels 198 Kinematics of Internal Geneva Wheels 201 Star Wheels Challenge Geneva Drives for Indexing 205 Ratchet-Tooth Speed-Change Drive 208 Modified Ratchet Drive 208 Eight Toothless Ratchets 209 Analysis of Ratchet Wheels 210 CHAPTER 8 CLUTCHES AND BRAKES 211 Twelve Clutches with External or Internal Control 212 Spring-Wrapped Clutch Slips at Preset Torque 214 Controlled-Slip Expands Spring Clutch Applications 216 Spring Bands Improve Overrunning Clutch 217 Slip and Bidirectional Clutches Combine to Control Torque 218 Slip Clutches Serve Many Design Functions 219 Walking Pressure Plate Delivers Constant Torque 220 Seven Overrunning Clutches 221 One-Way Clutch Has Spring-Loaded Pins and Sprags 222 Roller Clutch Provides Two Output Speeds 222 Seven Overriding Clutches 223 Ten Applications for Overrunning Clutches 225 Eight Sprag Clutch Applications 227 Six Small Clutches Perform Precise Tasks 229 Twelve Different Station Clutches 231 Twelve Applications for Electromagnetic Clutches and Brakes 234 CHAPTER 9 LATCHING, FASTENING, AND CLAMPING DEVICES AND MECHANISMS 237 Sixteen Latch, Toggle, and Trigger Devices 238 Fourteen Snap-Action Devices 240 Remote Controlled Latch 244 Toggle Fastener Inserts, Locks, and Releases Easily 245 Grapple Frees Loads Automatically 245 Quick-Release Lock Pin Has a Ball Detent 246 Automatic Brake Locks Hoist When Driving Torque Ceases 246 Lift-Tong Mechanism Firmly Grips Objects 247 Perpendicular-Force Latch 247 Two Quick-Release Mechanisms 248 Shape-Memory Alloy Devices Release Latches 249 Ring Springs Clamp Platform Elevator into Position 250 Cammed Jaws in Hydraulic Cylinder Grip Sheet Metal 250 Quick-Acting Clamps for Machines and Fixtures 251 Nine Friction Clamping Devices 253 Detents for Stopping Mechanical Movements 255 Twelve Clamping Methods for Aligning Adjustable Parts 257 Spring-Loaded Chucks and Holding Fixtures 259 viCHAPTER 10 CHAIN AND BELT DEVICES AND MECHANISMS 261 Twelve Variable-Speed Belt and Chain Drives 262 Belts and Chains Are Available in Many Different Forms 265 Change Center Distance without Altering Speed Ratio 269 Motor Mount Pivots to Control Belt Tension 269 Ten Roller Chains and Their Adaptations 270 Twelve Applications for Roller Chain 272 Six Mechanisms for Reducing Pulsations in Chain Drives 276 CHAPTER 11 SPRING AND SCREW DEVICES AND MECHANISMS 279 Flat Springs in Mechanisms 280 Twelve Ways to Use Metal Springs 282 Seven Overriding Spring Mechanisms for Low-Torque Drives 284 Six Spring Motors and Associated Mechanisms 286 Twelve Air Spring Applications 288 Novel Applications for Different Springs 290 Applications for Belleville Springs 291 Vibration Control with Spring Linkage 292 Twenty Screw Devices 293 Ten Applications for Screw Mechanisms 296 Seven Special Screw Arrangements 297 Fourteen Spring and Screw Adjusting Devices 298 A Long-Stroke, High-Resolution Linear Actuator 299 CHAPTER 12 SHAFT COUPLINGS AND CONNECTIONS 301 Four Couplings for Parallel Shafts 302 Links and Disks Couple Offset Shafts 303 Disk-and-Link Couplings Simplify Torque Transmission 304 Interlocking Space-Frames Flex as They Transmit Shaft Torque 305 Coupling with Off-Center Pins Connects Misaligned Shafts 307 Universal Joint Transmits Torque 45° at Constant Speed 308 Ten Universal Shaft Couplings 309 Nineteen Methods for Coupling Rotating Shafts 311 Five Different Pin-and-Link Couplings 315 Ten Different Splined Connections 316 Fourteen Ways to Fasten Hubs to Shafts 318 Polygon Shapes Provide Superior Connections 320 CHAPTER 13 MOTION-SPECIFIC DEVICES, MECHANISMS, AND MACHINES 323 Timing Belts, Four-Bar Linkage Team Up for Smooth Indexing 324 Ten Indexing and Intermittent Mechanisms 326 Twenty-Seven Rotary-to-Reciprocating Motion and Dwell Mechanisms 328 Five Friction Mechanisms for Intermittent Rotary Motion 334 Nine Different Ball Slides for Linear Motion 336 Ball-Bearing Screws Convert Rotary to Linear Motion 338 Nineteen Arrangements for Changing Linear Motion 339 Eight Adjustable-Output Mechanisms 343 Four Different Reversing Mechanisms 345 Ten Mechanical Computing Mechanisms 346 Nine Different Mechanical Power Amplifiers 350 Forty-Three Variable-Speed Drives and Transmissions 353 Ten Variable-Speed Friction Drives 365 Four Drives Convert Oscillating Motion to One-Way Rotation 367 Eighteen Different Liquid and Vacuum Pumps 369 viiTen Different Pump Designs Explained 373 Glossary of Pump Terms 376 Bearingless Motor-Generators Have Higher Speed and Longer Life 377 Energy Exchange in Seawater Desalination Boosts Efficiency 378 Two-Cycle Engine Improves Efficiency and Performance 380 CHAPTER 14 PACKAGING, CONVEYING, HANDLING, AND SAFETY MECHANISMS AND MACHINES 381 Fifteen Devices That Sort, Feed, or Weigh 382 Seven Cutting Mechanisms 386 Two Flipping Mechanisms 388 One Vibrating Mechanism 388 Seven Basic Parts Selectors 389 Eleven Parts-Handling Mechanisms 390 Seven Automatic-Feed Mechanisms 392 Fifteen Conveyor Systems for Production Machines 395 Seven Traversing Mechanisms for Winding Machines 399 Vacuum Pickup for Positioning Pills 401 Machine Applies Labels from Stacks or Rollers 401 Twenty High-Speed Machines for Applying Adhesives 402 Twenty-Four Automatic Mechanisms for Stopping Unsafe Machines 408 Six Automatic Electrical Circuits for Stopping Textile Machines 414 Six Automatic Mechanisms for Assuring Safe Machine Operation 416 CHAPTER 15 TORQUE, SPEED, TENSION, AND LIMIT CONTROL SYSTEMS 419 Applications of the Differential Winch to Control Systems 420 Six Ways to Prevent Reverse Rotation 422 Caliper Brakes Keep Paper Tension in Web Presses 423 Control System for Paper Cutting 423 Warning System Prevents Overloading of Boom 424 Lever System Monitors Cable Tension 424 Eight Torque-Limiters Protect Light-Duty Drives 425 Thirteen Limiters Prevent Overloading 426 Seven Ways to Limit Shaft Rotation 429 Mechanical Systems for Controlling Tension and Speed 431 Nine Drives for Controlling Tension 435 Limit Switches in Machinery 438 Nine Automatic Speed Governors 442 Eight Speed Control Devices for Mechanisms 444 Cable-Braking System Limits Descent Rate 445 CHAPTER 16 INSTRUMENTS AND CONTROLS: PNEUMATIC, HYDRAULIC, ELECTRIC, AND ELECTRONIC 447 Twenty-Four Mechanisms Actuated by Pneumatic or Hydraulic Cylinders 448 Foot-Controlled Braking System 450 Fifteen Tasks for Pneumatic Power 450 Ten Applications for Metal Diaphragms and Capsules 452 Nine Differential Transformer Sensors 454 High-Speed Electronic Counters 456 Applications for Permanent Magnets 457 Nine Electrically Driven Hammers 460 Sixteen Thermostatic Instruments and Controls 462 Eight Temperature-Regulating Controls 466 Seven Photoelectric Controls 468 viiiLiquid Level Indicators and Controllers 470 Applications for Explosive-Cartridge Devices 472 Centrifugal, Pneumatic, Hydraulic, and Electric Governors 474 CHAPTER 17 3D DIGITAL PROTOTYPES AND SIMULATION 477 Introduction to 3D Digital Prototypes and Simulation 478 A Short History of Engineering Drawing 478 Transition from Board to Screen 479 CAD Product Features 480 3D Digital Prototypes vs. Rapid Prototyping 480 The Ongoing Role of 2D Drawings 480 Functions of Tools in 3D Digital Prototype Software 481 File Types for 3D Digital Prototypes 481 Computer-Aided Engineering (CAE) 482 Simulation Software 482 Simulated Stress Analysis 483 Glossary of Computer-Aided Design Terms 484 CHAPTER 18 RAPID PROTOTYPING 487 Rapid Prototyping Focuses on Building Functional Parts 488 Rapid Prototyping Steps 489 Commercial Rapid Prototyping Choices 490 Commercial Additive RP Processes 491 Subtractive and R&D Laboratory Processes 498 CHAPTER 19 NEW DIRECTIONS IN MECHANICAL ENGINEERING 501 The Role of Microtechnology in Mechanical Engineering 502 Micromachines Open a New Frontier for Machine Design 504 Multilevel Fabrication Permits More Complex and Functional MEMS 508 Electron Microscopes: Key Tools in Micro- and Nanotechnology 509 Gallery of MEMS Electron-Microscope Images 512 MEMS Actuators—Thermal and Electrostatic 516 MEMS Chips Become Integrated Microcontrol Systems 517 Alternative Materials for Building MEMS 519 LIGA: An Alternative Method for Making Microminiature Parts 520 The Role of Nanotechnology in Science and Engineering 521 Carbon: An Engineering Material with a Future 523 Nanoactuators Based on Electrostatic Forces on Dielectrics 528 The Lunar Electric Rover: A New Concept for Moon Travel 530 INDEX 533 INDEXThis page intentionally left blank.535 Actuators: centrifugal force, 263 hydraulic, 431–432 linear, 37 motor-based linear DC and AC, 37 precision direct drive (PLADD), 299 stepper-motor-based, 37 mechanical, 25 micromechanical, 518 nanoactuators, 528–529 piezoelectric, 62 rotary, 47, 288, 338, 431 bidirectional, solenoid type, 47 cartridge-operated, 338 shaft, air-spring, 288 tension and speed control, 433 Adjusters (5), 343–344 cam-motion, 343 double-cam, 343 eccentric pivot point, 344 linkage-motion, 343 piston-stroke, 344 shaft synchronizer, 344 three-dimensional, 343 valve-stroke, 343 Allotropes of carbon, 523 Amplifiers: impulse, 423 mechanical power (7), 350–352 applications, 350 broaching, nonlinear, 351 capstan-type, 350 linear, 27 load positioning, 351 metering and counting, remote, 352 pulse-width modulated (PWM), 27 routing, irregular, 352 servomotor drivers, 27 tensile testing machine, 351 winch control, hydraulic, 351 windlass, 352 Arrangements: belt drive, four different, 262 electric-eye and balancer, 385 electrical contact, 440 linear-motion changing (19), 339–342 linkage, 385 screw, special (7), 297 varying vibration amplitude, 385 weight-regulating, 385 Assemblies, cartridge, 472 Ball: bearing, reciprocating, 337 bearing screws, 338 Ball (Cont.): bushing, 337 cartridge, 336 curvilinear motion device, 337 reciprocating bearing, 336–337 slides, linear motion (9), 336–337 Bands: spiral clutch, 217 spring, 217 Baseload, power generation, for, 75 Bearings: air, 25 ball, 336–337 eccentric, 307 reciprocating, ball, 337 sleeve, 337 spherical, 339 Bellows, 26, 152 pressure sensing, 452, 464–465, 467 temperature sensing, 464–465 Belts, 14, 265–268, 275 bead chain, 256–257 cable-chain hybrid, 258 chains, with, different forms, 265–268 flat, 265 ladder chain, cable and plastic, 268 metal timing, NASA, 265 positive drive, 267 pulleys, with 14 slotted, 275 steel, 266–267 tensioning, 269 timing, 265–268 conventional, 265–268 hi-torque (HTD), 268 V-belt, 263, 265, 268 variable speed with chain (12), 262–264 Bolt, explosive, 472 Brake, braking: automatic hoist, 246 band, 119–120 cable brakes limit decent, 445 caliper (disk) to keep tension, 423 clutch/combinations, 119–120, 214–216, 234–235, 423 clutch, double-coil duplex, 235 electromagnetic with clutches reel, permanent magnet, 457 slip-clutch, 214, 235 springs, 216 system, foot-controlled, 450 variable-torque drag, 215–216 Broaching, nonlinear, 351 Bushing, ball, 337 Bushing, split, 319 Bushing, torsion, 118 Cable-braking system, 445 Cable cutter, 472 Cams, 14–17, 180–191 barrel, 183, 188, 190 barrel, increased stroke, 190–191 circular, 182 circular-arc, 185 classification of mechanisms, 15 comparisons with, 180 configurations, 15 conical, 16, 346 constant-diameter, 16 constant-velocity, 182 cut-out, 181 cycloidal curves, 184 cycloidal motion, 183–184 cycloids, generating, 184–185 cycloids, modified, 184 cylindrical, 16, 181 double-faced, 181 double-revolution, 190 dwell: adjustable, 190–191 compensating for, 185–186 quick-acting, 190 eccentric, 166 electronic, 15 end, 16 floating, quick-acting, 190 followers, 14, 17 generating curves for, 182–184 glossary of terms, 17 groove, grooved, 16, 188 indexing, 190 jaws, in hydraulic cylinder, 251 kinematic equivalent, 14 locking, 193 lug, adjustable, 191 mechanisms, 14–17, 181–189 pivot-point, adjustable, 190 plate, increased-stroke, 198 rack, with, 181 radial open, 15 reciprocal, reciprocating, 188 roll, 400 roller position, adjustable, 191 rotating reciprocator, 194 simple harmonic, 183 sliding, 181,189 slot, 189 special-function (10), 190–191 steel ball, 189 swash-plate, 189 three-dimensional, 346 translating, 16 Editor’s notes: 1. The number in parentheses in some entries refers to the number of related topics on the listed page(s). For example, an entry Eccentric cams (7) indicates seven related captioned figures. 2. Figures and captions in Chaps. 5 to 16 were obtained from many sources that did not uniformly apply words such as devices, drives, mechanisms, and machines. Thus, there may be multiple entries for similar subjects.536 Capacitor, parallel plate, 528 Capstan, 5, 350 Capsules and diaphragms applications (10), 452–453 diaphragms, with, 452–453 Carbon: allotropes, 523 atom, 523 buckyball (See also fullerenes), 523–524 diamond, 527 fullerenes, 523–524 graphite, 523 graphene, 526 applications, 526, 527 production, 526 engineering material, 523–525 gasses, 523 dioxide (CO2), 74, 523 monoxide (CO), 523 nanotubes, 522–526 applications, 524–525 characteristics, 524 fabrication, 525 multiwalled (MWNT), 524 single-walled (SWNT), 524 Cartesian coordinate geometry, 54 Cells: load, cantilever, 454 Peaucellier’s, 91 photo, 456 Center, lathe, 259 Chains: bead, 267 belts with 262–263 double-roller, 264 drives (See Drives) gears, with, 265–268 ladder, hybrid, 267–268 length changes, 269 parallel, 267 pinned, 267 positive, infinitely variable (PIV) drive, 264 roller (10), 264, 270–276 applications for (12), 272–273 double, 264 single, 264 sprockets, with, 14 Chemical mechanical polishing (CMP), 508–517 Chucks, spring-loaded, 259 Clamp, clamping: air spring, 288 center-support, 254 differential, 297 double, for spindle head, 253 friction (9), 253–254 hold-down, 281 magnetic, permanent, 458 methods for (12), 257–258 pedestal, 254 quick-acting, 251–252 right-angle, 254 slide, 253–254 specimen holder, 254 spring, 259 table, 254 turntable, 253 Clutches: automatic, 220 backstopping, 227, 228 bidirectional and slip, 218 brake combinations, 214 cam, 222 cam and roller, 213 centrifugal, automatic, 220, 474 cone, 17, 212, 425 controlled-slip, 216 detent slip, 218 dog, one-way, 221 double-spring, 367, 368 driving, 228 dual-spring slip, 214–215 duplex, single- and double-coil, 235 eddy current, 234–235 electrostatic, 235 expanding-shoe centrifugal, 17–18, 213 external or internal control, 212–213 externally controlled positive, 17–18 fixed-field, 234 free-wheeling, 235 friction, 17, 18, 230 externally controlled, 17 multiple-disk, 230 plate, 17, 18, 230 hysteresis, 234–235 indexing, 227 internally controlled, 18 jaw, 17, 212 lawnmower, 221 magnetic, friction, 234–235 magnetic, particle-and-fluid, 235 magnetostrictive, 235 mechanical, basic, 212–213 mechanisms, 17–18 mercury-gland, 213 multidisk, multiple-disk, 224, 230 multistation, 232–233 one-way, 222 overload relief, 230 overriding, 223–224 overrunning (7), 18, 217, 221, 223–224 applications for (10), 225–226 pawl and ratchet 212, 229 single-cycle Dennis, 229 single-cycle, dual-control, 229 spiral bands improve, 217 planetary transmission, 212, 230 plate, 212, 429 roller, 166, 217, 221–222 rotating-field, 234 shifting mechanism for, 161–162 sliding-key, 212 slip, 214–216, 218, 235 small, for precise service, 229–230 speed ratio change with gears, 159 sprag applications, 227–228 sprags, use of, 217, 221–222 spring, 214–216, 367 applications, 215–216 bands, 217 basic, 367 brake combinations, 214 dual, 214–215 slip, 221 stepped, 215 wrapped, 18, 213–216 Clutches (Cont.): spring and ball radial detent, 18, 213 station, one or two (12), 231–233 trip, 227, 228 wedging ball or roller, 221 external, 221 internal, 221 Compensator, expansion, 453 Components for electronic systems, 26 Computer-aided design (CAD), 478–480 digital prototype files types, 481–482 assembly, 481–482 drawing, 482 part, 481 presentation, 482 software, simulation, 482–483 digital prototypes, 3D, 478–483 glossary of terms, 484–485 parametric modeling, 481 role of 2D drawing, 481–482 applications for 481–482 transition, board to screen, 479 Computer-aided engineering (CAE), 482 Computer-aided simulation, 482–483 digital vs. rapid prototype, 498 Concentrating Solar Thermal (CST) plants, 78–84 Connections: fastening, hubs to shafts (14), 318–319 polygon shapes, 320–321 splined (10), 304–306, 316–317, 318 Controls (See also Motion control): automatic weighing and filling, 468 bimetallic-actuated, air piloted, 466 carburetor, 463 carton sorting, 468 closed-loop: systems, 22–24 techniques, 24 hydraulic winch, 351 inspection, automatic, photoelectric, 469 motion, kinds of, 24 open-loop systems, 24 paper-cutting, 423 photoelectric (7), 394, 410, 468–469 position-loop, 22 refrigerator, 465 room-temperature, heavy-duty, 465 snap-action, disk-type, enclosed, 466 speed for mechanisms (8), 444 temperature-regulating (8), 466–467 tension, 433, 435–437, 455 speed and, 431–434 thermostat, 468 thermostatic, 462–465 instruments, with, 462–465 relay, time-delay, 463 torque-loop, 22 velocity (speed) loop, 22 Controllers: actuators with, 431–434 differential, 434 float-switch, 470537 Controllers (Cont.): indicators, with, 470–471 level, liquid, 470–471 electrical level, 470 liquid, 470 magnetic, 471 switch-actuated, 471 motion (See Motion control) programmable logic (PLC), 22 Control systems, mechanical, 431–434 applications, differential winches, 420–421 hydraulic for control, 421 indicators, pressure and temperature, 421 cable tension monitor, lever system, 424 paper cutting, 423 paper tension in web presses, 423 reverse rotation prevention (6), 422 tension and speed, 431–434 controllers and actuators, 431 differential, 434 dimension, 433 indicators, 431 floating rolls, 433 primary, 431 secondary, 431–434 on-and-off, 431 proportioning, 431 proportioning-throttling, 432 warning, boom overload, 424 winch, differential, 420 Conversion (converters): Constantino torque, 364 rotary-to-linear motion, 137, 266–267, 338 rotary-to-oscillatory, 266–267 Conveyors, 227, 275, 395–398, 402, 469 light-duty trolley, 275 Coordinate system, six-degree of freedom, 22 Counters, 403, 456 electronic, high-speed, 456 magazine, 456 pulse, 456 Couplings: bellows, 26 Bendix-Weiss, 310 bent-pin, 110 Bossler, design of, 305–307 constant-velocity joint, 309–310 crossed-axis yoke, 302 disk-and link, for torque transmission, 304 flexible shaft, 310 four-bar, 187 geared, 302 grooved-sphere joint, 309 Hooke’s joint, 305, 309 light-duty, 310 links and disks for offset shafts, 303–304 magnetic fluid in, 428 off-center pins connect shafts, 307 Oldham, 302 parallel crank, 315 parallel link, 104, 218, 303 parallelgram, 304 pin and link (5), 315 Couplings (Cont.): pin-and-slot, 315 pinned-sleeve shaft, 309 pinned-sphere shaft, 309 power transmission, 118 pump-type, 304, 310 rotating shafts, methods for (19), 311–314 Rzeppa, 310 Schmidt, 303–304 shafts, for (4), 302 slip-spring, 221 space-frames, interlocking, 305–307 square-plate, 306 three-plate rectangular, 306 universal joints, 302, 308 universal shaft (10), 309 Cranks: double parallel, 167 fixed, 167 input, 167–168 nonparallel, 167 output, 167–168 reciprocating-space, 329 slide, 3D, 113 space, 114–115 spherical, 111 Cutters, 472 cable, 472 pipe, 472 Dashpot, oil, 463 Desalination of sea water, 378 energy recovery device, 378–379 pressure exchange unit (PSU), 378–379 reverse osmosis (SWRO), 378 Detector, jam, 469 Detents, 255–256 adjustable, 255 axial positioning, 256 coil spring loaded, 255–256 conical/wedge ended, 255 leaf spring, 255 magnetic, 256 notched, 255 positive, 255–256 radial arranged, 256 roller, 256 stopping movement for, 255–256 roller, 256 Devices: adjusting, spring and screw (14), 298 anti-backlash, 226 arrangements, weight-regulating, 385 electric-eye and balancer, 385 linkage, 385 vibration amplitude variation, 385 chain, lifting, 273 clamping, 253, 257–258 cushioning, 281 cutoff and transfer, 391 explosive-cartridge, applications for, 472 feeding, simple, 383–384 mixing, 384 parts, fixed number, 383 pausing, 384 separating, one-by-one, 384 gauging and callipering, 455 Devices (Cont.): geared cocking, 239 latch, toggle and trigger (16), 238–239 orienting, 382–383 cone-shaped parts, 382 dish-like parts, 382 pointed-end parts, 382 short, tubular parts, 382 stepped-disk parts, 383 U-shaped parts, 383 rack-and-pinion, 272 rotary-to-reciprocating, 293 rotation-to-translation, 293 Scotch-yoke, 183 screw (20), 293 snap-action, 242–243 sort, feed, or weigh (15), 382–384 sorting, 384–385 balls by size, 384 by height, 385 speed control, for mechanisms (8), 444 tilting, 189 time-delay switching, 338 toggle, 238–239 translation-to-rotation, 338 Diaphragms: capsules, applications (10), 452–453 Differentiator, 349 Differentials, 162, 346 bevel-gear, 346 rotating-link, 346 sliding-link, 346 spiderless, 162 Digital prototypes and simulation, 3D, 478–483 advantages of 3D solid modeling, 478, 483 CAD, 478–480 CAD/CAE, nine step process, 478, 483 CAD product features, 480 computer-aided engineering, (CAE), 482 digital vs. rapid prototyping, 498 file types for, 481–482 finite element method (FEM), 478,484 functions of tools in, 481 glossary of CAD terms, 484–485 history, engineering drawing, 478–479 parametric modeling, 481 role of 2D drawings, 481–482 simulation software, 482, 483 transition, board to screen, 479 Direct Metal Deposition (DMD) (See Rapid prototyping) Direct Shell Product Casting (DSPC) (See Rapid prototyping) Directed-Light Fabrication (DLF) (See Rapid prototyping) Direction changes, straight-line, 339–342 Disconnector, quick, 473 Driller, parallel-link, 104 Drives (drivers): adjustable, 355 cone, 353 disk, double and single, 355 harmonic, 140 angle-doubling, 105 ball, reciprocating, 368 ballscrew, 25538 Drives (drivers) (Cont.): bearings and roller, 329 belt, 262 belt-and-chain, variable-speed (12), 262, 264 bevel gear, 166 chain, 106, 264, 266–267, 276–277 double-roller, 264 ladder, differential, 267 reducing pulsations, for (6), 276–277 single-roller, 264 clutch, 166, 367–368 basic spring, 367 double, 368 double-shift, 159, 367 double spring, 368 roller, 166 combination, coupling, slide gear, 159 CMOS circuitry, 517 cone 353–354, 358 adjustable, 353 ball and, 358 belt, 353 electrically coupled, 353 Graham, 354 planetary, 354 ring and cone, 354 two-cone, 353 controlled output escapement, 194 controlling tension, for (9), 435–437 conversion, oscillate-to-rotate (4), 367–368 basic spring, 367 double-spring clutch, one-way, 367–368 full-wave rectifier, 367–368 reciprocating-ball, shuttle pinion, 367–368 crank slide, 3D, 113 curve-slider, 333 cycloid, (epicycloid): equations for, 171–172 reciprocator, 140 differential, controlled, 143 differentials, for controlling tension, 435 fixed, 148 robot, for, 64 disk, 329, 355, 361–362, 365 adjustable, 355 clutch, 159 cone, spherical, 366 curved, 361 drum and roller, 366 spring-loaded, 355 planetary, 355 roller, 329, 365 split pulleys, 366 two, 365–366 double, with six-sided Maltese cross, 327 double eccentric, 146, 187 double-shift, 159 double-spring clutch, 367–368 electrical, controlling tension 435–436 electrostatic charges, 505 elliptical motion, 140 epicycloids reciprocator, 140 flowmeter, drive, 459 Drives (drivers) (Cont.): friction, variable-speed (10), 365–366 full-wave rectification, 367–368 gear: compound spur-bevel, 151 coupling and slide, 149 gear oscillating, 333 geneva (20), 192–197 controlled-output escapement, 194 dual track, 193 external, 195 four-bar, 192 groove-cam, 192 intermittent counter, 195 internal, 138, 195 internal groove, 193 locking-arm, 192 locking-slide, 192 long-dwell, 138, 193 modified (6), 193, 196–197 parallel guidance, 194 planetary gear, 192 progressive oscillating, 194 rapid transfer, 193 rotating-cam, 194 sinusoidal reciprocator, 194 spherical, 195 twin, 192 Graham, 354 harmonic, 140 adjustable, 140 triple, 333 Hooke’s joint, skewed, 112 hydraulic, 436 impulse, 360 Morse, 360 variable-stroke, 360 zero-max, 360 leadscrew, 25 lever and cam, 101 light-duty, 425–426 low-torque, 284–295 lubricator, Torrington, 363 mechanical, 435 microchain, 515 missile silo cover, 146 multiple disk, 359 ball-and-disk, 359 oil-coated, 359 Sellers’, 361 multiple ratio, 160 multiplier, 103–104 multiplier, force and stroke, 105, 106 offset, 342 one-way rotation, 367–368 oscillating (oscillator): chain, 330 crank and planetary, 330 gear crank, 333 motion to one-way rotation (4), 367–368 progressive, 194 spherical-slide oscillator, 112 parallel-cable, 267–288 planet, planetary: coupled, 147 simple with inversions, 149 triple, 150 two-gear, 152 Drives (drivers) (Cont.): planocentric, 152 rack, 106 sector, 105 shuttle, 368 slider crank, 333 ratchet, modified, 208 ratios, four, six, and eight, 160 tooth, speed change, 208 reciprocating-ball, 368 reciprocating-table, 103 rectifier/rectification, full wave, 367–368 ring, 356 ring, double 356 ring with pulley, with, 356 rod, 99 sheave, 263 ball-controlled, 263 cam-controlled, 263 spring-loaded, 263 shift, double, 159 shuttle pinion, 367–368 six-bar dwell, 331 slide-elliptical, 115 slide-key, 159 slide oscillator, 112 sliding-change, 159 soft-start, hinged and torsion bushings, 118 space crank, 114 speed-change, ratchet-tooth, 208 sphere, spherical, 357–358 ball and cone, 358 crank, 111 disk with, 357 double- 357 roller with. 357 slide oscillator, 112 tilting-ball, 358 spring clutch, 367–368 swivel gear, 159 tape, 215 tension-controlling (9), 435–437 electrical, 435–436 hydraulic, 436–437 mechanical, 435 three-dimensional linkage (7), 111–115 crank-slide, 3D, 113 elliptical slide, 115 Hooke’s joint, 112, 309 space crank, 114 spherical crank, 111 spherical-slide oscillator, 112 variations, 115 universal joint, 113 three-gear, 331 toggle and cord, 102 toggle puncher, double, 106 torque, low (7), 284–285 Torrington lubricator, 349 tractor, Ford, 151 transmissions, 362–364 triple, shaft, 160 triple harmonic, 333 turbine, Lycoming, 151 twinworm gear, 163 typewriter, 106 unidirectional, 13539 Drives (drivers) (Cont.): universal, joint, 113 valve, 142 variable-speed, and transmissions (43), 353–364 cone, 353–354 disk, 355 impulse, 360 multiple disk, 359 ring, 356 spherical, 357–358 variations, 361 variable-stroke, 360 wheel and slider, 333 Whitworth quick-return, 9, 333 wobble-gear, 152 worm, 25, 327 zero-max, 360 Electric power generation: hydro, 74 nuclear, 74–75 ocean wave, 84 photovoltaic (PV), 5 tidal, 84 solar thermal (CST), 78 wind turbine, 76 (See Renewable energy power generation) Electrical circuits, stopping textile machines (6), 414–415 Electromagnetic force, 506 Electromagnets, 32, 45–47, 461 Electron microscopes (See Microscopes, electron) Electrostatic, 528 Encoders (See Sensors) End-effector (See Robots, stationary and mobile) Energy exchange in seawater desalination, 378–379 Engine, internal combustion, 2 Engine, two-cycle, 380 Engine Stirling solar generator, 81–83 how it works, 82–83 Epicycloid, cycloid, 138–140 Epitaxy, 506 Escapement, 194, 327 cam-operated, 327 controlled output, 194 electric meter, 327 ratchet-gear, 327 solenoid-operated, ratchet, 327 Fastener, toggle, 245 Fastening hubs to shafts (14), 318–319 Feeders (feeds): automatic feed mechanisms (7), 392–394 barrel hopper, 389 electronic components, 390 gravity for rods, 390 headed rivets, 390 label, 390 long cylinder, 389 paddle wheel, 389 parallel-link, 104 rapid and slow, screw, 297 reciprocating, 389 Feeders (feeds) (Cont.): rods, 390 rotary center blade, 389 rotary screw, 389 Filter, permanent magnet, 458 Fingers, holding, 430 Fingers, pinned limiting, 430 Fingers, shaft stopping, 430 Fingers two, rotation prevention, 430 Finite element analysis (FEA), 478, 484 Finite element method (FEM), 478, 484 Fixtures, holding, 259 cupped, 259 nest, spring-loaded, 259 Flat mirror tower solar thermal plants (See Concentrating solar thermal (CST) systems) Flowmeter, 455 Fuel mix, U.S. electric generation, 74 Functional generators, 346–347 Fused deposition modeling (FDM) (See Rapid prototyping) Gages, 101–102, 424, 453–454 float, direct-reading, 471 moving wire thickness, 455 pressure, 101–102, 453–454 absolute, 453 Bourdon, 453 differential, 453 strain, 424 Gears (gearing): bevel, 11–12, 157, 163, 166, 399 design, of with hypoid, 164 Humpage’s, 149 spiral, 12, 164 spur, 151 straddle-design of, 164 Cardan, 141–142 mechanisms (5), 141–142 circular, 133 classification, 11–12 compound trains, 11 computer-aided emulation of, 24 configurations 12–13 cycloid mechanisms (11), 136, 138–140, 171–172 designing, 171–172 definition, 10 differential, drives, 134, 143 eccentric, 152, 156 elliptical, 153–156 external, 11 face, 12, five bar mechanisms, 167–170 flexible, face, 144 gears and gearing, 10–13 geometry, tooth, 13 glossary of terms, 13 helical, 12, 163, 331, 367 herringbone, 12 hypocycloid curves, 138 hypoid, 12, 164 design of, with bevel, 164 idler, rolling, 166, 221 index, 132 indexing with eccentric disk, 132–133 internal/annual, 11, 12 logarithmic spiral, 153 Gears (gearing) (Cont.): noncircular, 133–135, 153–156 characteristics of systems, 156 nonflexing, 144 pinions, 11–12, 157, 162 rack-and-pinion, 11, 12, 340 sheet-metal, 157–158 planet (planetary), 12, 132–139, 142, 145, 147, 150, 152, 167–168, 171–174, 176, 180, 435, odd-shaped, 133 twin-motor, safety and dual-speed, 137 practical configurations, 12–13 quick indexing, with eccentric disk, 132 rack, 11–12, 161–163 rack-and-pinion, 12, 272, 340 ratio, 10, 13, 430 ring, 132, 136–137, 145, 147–148, 152, 162, 172, 176–177, 435 rolling, 172–173 rotary sequencer, 145 rotary-to-linear, conversion by, 137 sheet-metal, 157–158 simple trains, 11 sine function, 156 speed ratios, change (13), 159–160 speed reducers, 166 spiral, logarithmic, 156 spur, 11, 12, 121, 151, 228 spur, eccentric, 154 square, 154 sun, 132, 134, 137, 140, 152, 167–169, 171–173, 180 tooth geometry, 11 trains, 11 traveling, 166 twinworm, 163 types, eight common, 12 unidirectional drive, 13 velocity ratio, 10–11 wobble drive, 152 worm, 12, 136, 143, 157–158, 163, 165 Generators: DC, 435 function, 108, 346–347 Geneva: coupler-driven, 187 double with differentials, 186 drives (26), 138, 192–197 dual-track drive, 193 eight slot, 199 eight-station, 186 external wheel, 198 basic outline drawing, 198 charts for angular: acceleration, 199 position, 199 velocity, 199 five-slot, 192 formulas for, 192 four-bar drive, 184 four-slot, 192–194 196–197, 199, 201 groove-cam drive, 192 intermittent counter drive, 195 internal drive, 195540 Geneva (Cont.): internal-groove drive, 193 internal wheel, 201–204 kinematics for, external 190–200 kinematics of internal wheels, 201–204 basic outline, 201 charts for angular: acceleration, 203, displacement, 202 formulas for, 203 velocity, 203 locking arm drive, 192 locking slide drive, 192 long-dwell drive, 193 modified drives (7), 193, 196–197 planetary-gear drive, 192 rapid-transfer drive, 193 six-slot internal, 198, 202 slot-crank internal motion, 200 spherical, 195 twin drive, 192 wheel(s) (9), 198–204 Governors, 442–443, 474–475 acceleration, 474 automatic speed (9), 442–443 auxiliary piston, 442 centrifugal, 474 clutch, 474 constant-volume, 443 contacts, 474 differential, 474 electric, 475 pulse counter, 475 tachometers, AC and DC, 475 force-compensated, 442 hit-and-miss, 442 hydraulic, 475 pneumatic, 474–475 pressure-actuated, 443 typical, 444 valve, 474 varying differential, 443 velocity-type, 443, 475 cantilever, 443 coil spring, 443 Grapple, automatic, 245 Greenhouse gas, 74 carbon dioxide (CO2), 74 methane (CH4), 74 nitrous oxide (N2O), 74 sulfur dioxide (SO2), 74 Gripper, leaf-spring, 259 Guides, 25, 340 air-bearing, 25 ballscrew-driven, single-axis, 25 hydrostatic, 25 inclined bearing, 340 Hammers, electrically driven (9), 460–461 Hammers, spring-operated, 460, 461 Holding fixtures, 259 Hook release, emergency, 473 Hydraulics: control system, 421, 436 controller, 432 cylinders, 109, 250 drives, 436–437 fluid, 421 Hydraulics (Cont.): governor(s), 475 motors, 436–437 pumps, feed, 408 receiver, 421 sender, 421 sensors, 475 switch, pressure, 450 transducer, pressure, 424 valves, 408 winch control, 351 Hypocycloid, gear curves, 138 Idler, rolling, 166 Inclined plane, 3 Indexing (indexers): flat-spring, 281 intermittent, 326 quick, gears and eccentric disk, 132 smooth, timing belt and linkage, 324–325 star wheel, 205–207 Indicators: automotive, liquid level, 470 bellows-actuated, 470 bimetallic, 471 diaphragm-actuated, 470 liquid-level, automotive, 470 motion, 431 power, 431 pressure gage, 432, 471 primary, 431–432 secondary, 431–432 temperature, 421, 431–432, 462 Inductosyns (See Sensors) Instruments and controls: recording and controlling, 467 thermostatic (16), 462–465 Integrated circuits, CMOS, 518–519 Integrators, mechanical, 349 Jack, screw-type, 4 Jaws, cam-locked, 250 Joints: ball, 218 ball-and-socket, 308 Bendix-Weiss, 310 cam, 107–108 constant-velocity, 309–310 cylinder, 110 cylinder-plane, 110 grooved-sphere, 309 helix, 110 Hooke’s, skewed, 112, 309–310 plane, 110 prism, 110 revolute, 110 robots, industrial, 52–54 rotary, 107–108 Rzeppa, 308, 310 sliding, 107–108 sphere, 110 groove, 110 plane, 110 slotted, 110 torus, 110 torus-helix, 110 universal, 113, 302, 308 constant-speed, 308 Key, feather, 318 Key, mechanical, 427 Key, retracting, 427 Kinematics: external geneva wheel, 198–200 internal geneva wheel, 201–204 joint pairs, 110 Knee-joint tester, 121 Laminated-Object Manufacturing (LOM) (See Rapid prototyping) Lasers, 26, 43–44, 490–492, 494–496 carbon dioxide infrared (IR), 491–492, 496 interferometer, for closed-loop feedback, 26, 43–44 neodymium YAG, 495 ultraviolet (UV), 489, 491 Latches, 490–491, 492 cam-guided, 238 cocking with lever for, 239–240 door, 457 eccentric, 422 geared cocking, 239 locking, 116 operating sequence, 242 overcenter lock, 239 perpendicular-force, 247–248 remotely controlled, 244–245 rim, on the, 422 SMA actuated, release, 249 spring-loaded, cocking, 239 sleeve, 239 Levers: action, 4 classes, 4 mechanisms, 4 slotted, 339 spherical, 339 spring-loaded, 339 LIGA process (techniques), 519–520 Limiters, prevent overloading (13), 426–428 cammed sleeve connects, 427 cylinder, cut, 427 disengaging gears, 427 friction-clutch torque, 426 fluid coupling, 428 magnetic fluid coupler, 428 mechanical keys, 427 piezoelectric crystal, 428 retracting key, 427 shearing, 428 shear pin, 426, spring plunger, 428 steel shot, 428 Limiters, shaft rotation (7), 429–430 clutch plates, 429 gear ratio, large, 430 pin-finger engagement, 429 pinned fingers, 430 shaft finger, 430 traveling nut, 429 two fingers, 430 Limiters, torque, protect drives (8), 425–426 cone clutch, 425 flexible belt, 425 friction disks, 426 permanent magnets, 425541 Limiters, torque, protect drives (Cont.): ring, 426 rollers hold arms, 425 sliding wedges, 426 springs, 425 Linear Fresnel reflector solar thermal plants (See Renewable power plants) Linear guides (See Guides) Linear motion, arrangements for changing (19), 339–341 Linear resonator, 505 Linear variable differential transformers (LVDTs) (See Sensors) Linkage, links: accelerating/decelerating linear motions, for (9), 99–100 articulating, 118 band clutches and brakes, for (8), 119–120 basic, 6 bell-crank, 6 closed-loop, 60 crank and rocker, design of, 6, 7, 90, 121–123 D-curve, 98 D-drive, 96 defined, 5, 6 different motions (4), 98 differential, variations of (18), 107–108 door-check, 117 double parallel crank, 90 double-rocker, 6, 7 drag-link, 6, 91 eight-bar, 103 synthesis of, 127 elliptical gear, 91 expanding and contracting (6), 97 force and stroke multiplier (9), 105 four-bar, 6, 90–91, 96, 107, 111, 117, 121 design for angular motion, 124–125 fundamentals of, 5–8 multibar for curvilinear 125–127 Robert’s law design of, 128 screw device, 293 sliding member with, 90 typical applications, 89–91 high mechanical advantage, 116 high velocity ratio, 117 hinged, 118 isosceles, drag, 90 linear force airspring, 288 linear motions, accelerating decelerating (9), 99–100 linkages, fundamental, 5–8 multibar for curvilinear motions, 125–127 multiplier, stroke (7), 103 multiplying short motions, for (12), 101–102 nonparallel equal crank, 90 offset shaft coupling, 303 pantograph, 91 parallel (4), 103 parallel coupling, 104 parallel driller, 104 parallel feeder, 104 parallel-motion, 6, parallel plate driver, 104 Linkage, links (Cont.): parallelogram, 104 planar, simple, 5, 6 push-pull, 6 reciprocating linear force, air spring, 288 reverse-motion, 6 rotary force, air spring, 288 rotary-to-linear, 8 rotating crank, 91 sacrificing, 243 specialized, 6 spring-type, 292 straight-line for motion generation (5), 7–8, 95–96 Evans, 95 Peaucellier’s cell, 7, 91, 96 Robert’s, 91 Scott-Russell, 7 Tchebicheff’s, 91 Watt’s, 6, 90–95 straight sliding, 91 three-dimensional (7), 111 toggle, different applications (13), 116–117 transport mechanisms for (7), 92–94 trapezoidal, 90 treadle drive, 91 variable mechanical advantage, 117 Load cell, cantilever, 454 Lock pin, quick-release, 246 Lunar Electric Rover (LER), 530–531 leading specifications, 531 Machines: adhesive applications (20), 402–407 automatic shear, 415 coil-winding, 434 cutoff, 447 efficiency of, 2, 19 folder or yarder, 415 label application, 401 loom, 415 production, 395 riveting, 116–117 routing, irregular, 353 stone-crushing, 116 tensile testing, 351 vacuum pickup, pill position, 401 velocity ratio, 3 winding, 399–400 Magnets, magnetic: alnico, 30 ceramic, 30 clutches, 235 detent, 257 devices, 457–459 neodymium, rare earth, 30, 34, 68 permanent (PM), 26, 457–459 permanent (PM), applications for, 457–459 Mechanical: advantage, 2, 19 engineering, new directions in, 502–532 glossary of common terms, 18–20 Mechanisms: actuated by pneumatic or hydraulic cylinders (24), 448–449 Mechanisms (Cont.): adjustable output (adjuster) (5), 343–344 cam-motion, 343 double cam, 343 eccentric pivot point, 344 linkage-motion, 343 piston stroke, 344 shaft synchronizer, 344 three-dimensional, 343 valve stroke, 343 agitator, 113 automatic (operation): assuring safe machine operation (6), 416–417 feed (7), 392–394 stopping by electrical circuits textile machines (6), 414–415 stopping by unsafe machines (24), 408–413 ballscrew slide, 23 belt on pulley, 14 basics of, 2–20 cam mechanisms, 14–17, 181–189 automatic feed, 188 barrel, 188 circular grove, 162 constant-speed, 188 constant velocity, 182 continuous rotary motion, 189 cut-out, 181, 189 cycloidal motion, 183–184 different, 15, 188–189 double eccentric, 188 double-faced, 181 firing-pin, 239 function generator, 108 follower motion, fast cam, 332 glossary of terms, 17 groove and oval, 189 indexing, 188 mixing roller, 188 motion adjusters, 343–344 planetary, 180 simple-harmonic, 183 sliding, 181, 189 slot, 189 steel-ball, 189 stroke, amplifying (5), 181 stroke, multiplying, 181 swash-plate, 189 rack with cam, 180 tilting device, 189 Cardan-gear (5), 141–142 Scotch yoke, with, 141 valve drive, 142 chain: oscillating, 316 slider and, 316 clutch, 17–18 computing, mechanical, 10, 346–349 differentiators, 349 integrators, 349 resolvers, 347 counting (counter), 423 coupler (coupling): four-bar, 187 geneva-driven, 187542 Mechanisms (Cont.): crank: double-parallel, 90 gear, oscillating, 333 gear slider, 333 nonparallel equal, 90–91 reciprocating space, 315 rocker, 6 rotating, 91 crank-rocker, 121–123 four-bar, design of, 121–123 curve-generating, 182–187 curve-scribing, 104 cutting (cutter) (7), 386–387 clamping and, 386 curved-motion, 387 four-bar, 386 parallel cutter, 386 slicing, 387 vertical motion, 387 web, 386–387 cycloid, (cycloidal) (11), 126, 138–140, 171–173 curves, family of, 138 epicycloid, 138–140 equations, design of geared, 171–173 gear, 126, 136–140 generating, curves for, 182–187 hypocycloid, 138–140 parallelogram, 139 rocker, 139 reciprocator, 140 short-dwell rotary, 139 differential: bevel-gear, 346 planetary-gear, 107 rotating-link, 346 sliding-link, 346 spiderless, 162 differentiator, 349 double: drag-link, 6 lever, 91 parallel crank, 90 rocker, 6 dough-kneading, 112 drag-link, 6 drive: bearing-and-roller, 329 chain-oscillating, 330 chain-slider, 330 curve-slider, 333 disk-and-roller, 329 elliptical-motion drive, 140 oscillating crank and planetary, 330 three-gear, 331 triple harmonic, 333 wheel-and-slider, 333 Whitworth quick-return, 333 worm, 327 dwell: cam-helical, 331 cam-roller, 331 cam-worm, 330 double, 138 double-crank, 331 epicyclic, 330 intermittent, 332 long, 330–332 Mechanisms, dwell (Cont.): short, 333 rotary, short, 139 six-bar, 331 efficiency of, 2 epicycloid reciprocator, 140 escapement, electric meter, 327 fast-cam follower motion, 332 feeder, 125 firing-pin, 239 five-bar, design of, 167–170 four-bar space, 109 flipping (2), 388 turnover, 388 upside-down flipper, 388 friction for intermittent rotary motion (5), 334–335 gear, geared: bevel, 399 Cardan, 141–142 five-bar, design of, 167–170 Jensen’s ring and slider, 176 ring and slider, 176 slider, 174–177 gear-slider: design curves and equations, 174–177 modified, 176 generator, function, 108, 346–347 geneva: internal-drive, 138 long-dwell, 138 wheel escapement, 9 glossary of common terms, 8–10 guidance, parallel drive, 194 hammer, electrically driven (9), 460–461 harmonic drive, adjustable, 140 hydraulic cylinder actuated, 448–449 indexing, 324–325 indexing and intermittent (10), 326–327 intermittent-motion, 133 intermittent, “mutilated tooth,” 340 lever, 4 levers, double, 91 lift-tong, 367 linkage, 2 four-bar, 90, 91 transport mechanisms (7), 92–94 long-dwell, 330–331 mechanical computing, 346–347 motors, spring, 286–287 oscillating: chain, 328, 330 crank and planetary drive, 330 over-centering, 241 override, 284–285 parallel guidance, 19 parallel-link (4), 103 parallelogram, cycloidal, 139 parts-handling (11), 390–391 pericycloid, 38 pin-and-disk, 334 pin-and-disk, sliding, 336 pivot, 289 planetary gear, special, 12 pneumatic-cylinder actuated, 448–449 press, toggle, 117 pressure release, 458 Mechanisms (Cont.): pulsation reducing in chain drives, for, 276–277 quick-release, 248 positive locking, 248 quick-return, 9 swing-arm, 9 Whitworth’s, 9 rack-and-gear sector, 328 rack-and-pinion, robot gripper, 55 ratchet wheel, 10, 327 cam-driven, 327 solenoid operated, 327 reciprocator, 140, 194 cycloidal, 140 epicycloidal, 140 linear, 329 rotating-cam, 194 sinusoidal, 194 renewable power generation, 74–85 reversing, different (4), 345 automatic switching, 345 double-link, 345 modified Watt’s, 345 pivot switching, 345 toggle-link, 345 ring-gear and slider, Jenson’s, 176 rocker arm and disk, 335 rotary, cycloidal short-dwell, 139 rotary-to-linear, 8 rotary-to-linear, gears, 137 rotary-to-reciprocating motion and dwell (27), 328–333 bearing and roller drive, 329 cam-helical dwell, 331 cam-roller dwell, 331 cam-worm dwell, 330 chain and slider drive, 330 chain-slider drive, 330 curve-slider drive, 333, disk and roller drive, 329 double-crank dwell, 331 double-dwell, 138 epicyclic dwell, 330 fast cam follower motion, 332 four-bar slider, 328 gear oscillating crank, 333 gear-slider crank, 333 intermittent motion, 332 linear reciprocator, 329 long dwell, 330–332 drive, 138 oscillating crank and planetary drive, 330 oscillator-chain, 328 six-bar dwell, 331 rack and gear sector, 328 reciprocating space crank, 329 short-dwell, 333 three-gear drive, 331 three-gear stroke multiplier, 328 triple-harmonic drive, 333 wheel and slider drive, 333 Whitworth quick-return drive, 333 rotating crank, 81 Scotch-yoke, 8, 347 screw, applications (10), 296–297 double-handed, 93 jack, 4543 Mechanisms (Cont.): sector, rack and gear, 328 Sellers’ disks, 361 shifting, gear and clutch, 161–162 short-dwell, 333 slicing, 387 slide (slider): ballscrew-driven, 23, 26 four-bar, 328 slider crank, design of, 8, 139 sliding pin and disk, 335 space, four bar, 109–110 specialized, 9–10 spring (7), 284–285 overriding, for low-torque drives, 284–285 two-directional, limited travel override, 284 two-directional override, 284 two-directional 90° override, 285 unidirectional override, 284, 285 unidirectional 90° override, 285 unidirectional override, 284 stopping unsafe machines, automatic, 240 straight-line generators: Peaucellier’s, 7, 91 Roberts’, 91 Scott-Russell, 7 Tchebicheff’s, 8, 91 Watt’s, 7, 90 stroke-amplifying, 181 stroke-multiplying, 181 swing-arm quick-return, 9 three-dimensional, (3D) adjuster, 343 three-gear drive, 331 three-gear stroke multiplier, 328 toggle, link and disk, 335 toggle, press, 117 toggle, quick-release, 240 transport mechanisms, 92–94 traversing, for winding machines (7), 399–400 triple pivot, 103 turnover, 388 upside-down flipper, 388 vibrating (1), 388 web cutting, 367 wedge and disk, 334 Whitworth’s quick-return, 9, 333 MEMS (microelectromechanical systems), 502–503 acceleration sensors, 505 CMOS integration, 517 comb-drive actuator, 514 digital light processing chip (DLP), 503 digital micromirror device (DMD), 502–503 electrostatic forces in, 506 electron microscope images gallery, 512–515, 518 gear-reduction unit (drive), 515 gyroscope, 75, 502 images, gallery of, 512–515 inertial measurement systems, three-axis, 518 linear resonator, 505 machine design in, 502–503 MEMS (microelectromechanical systems) (Cont.): materials for, 505–506 alternate for, 519 piezoelectric films, 506–507 polysilicon, 512 tungsten interconnects, 518 microaccelerometers, 502, 504–505, 518 microactuators, 504–505, 515–516, 518 comb drives, 513–514, 518 electrostatic, 516 parallel plate, 516 thermal, V-shaped, 516 thermal ratcheting, 516 torsional ratcheting (TRA), 516 microcontrol systems, 517 microconverters, torque, 513 microchain, drive, 515 microchain link and sprocket, 515 microengine, steam, 515 microfluidics, 519, 522 micrographs, 512–516, 518 micromechanical actuators, 504, 518 micromirror device, digital, 503–503, 517 micromotors, 502–507, 512, 514–515, 529 rotary, 514 stepping, wedge, 512 microoscillator, dual mass, 513 micropumps, 504 microresonator, linear, 505 microstereolithography, 519 microtransducer, piezoelectric, 506–507 microtransmissions, 502–503, 514 gear reduction units, 514 microvalves, 504 multilevel fabrication of, 512 oscillator, dual-mass, 513 piezoelectric film, 506–507 processes (See Micromachining of MEMS) research and development, 517 resonators, 502 three-axis inertial system, 518 torque converter, 513 Microaccelerometers (See MEMS) Microactuators (See MEMS) Microcontrol systems (See MEMS) Microelectromechanical systems (See MEMS) Micrographs (SEM), (See MEMS) Micromachine power, 506 Micromachining (fabrication) of MEMS, 479–480 bulk, micromachining, 507 chemical-mechanical polishing (CMP), 508, 517 IMEMS technology, 517 iMEMS technology, 502 LIGA, 519–520 SUMMiT/SUMMiT V technology, 512 surface micromachining, 507 Microminiature systems (See MEMS) Microscopes, electron, 509–511 atomic force (AFM), 510–511 charge-coupled device (CCD) camera, 509 piezoelectric (PZT) scanner, 511 raster scanning, 509 Microscopes, electron (Cont.): scanning electron (SEM), 509, 510 scanning images (SEM), 480–483, 485 scanning tunneling (STM), 510 transmission electron (TEM), 509 Microtechnology in mechanical engineering, role, 502–503 Mold Shape Deposition Manufacturing (MSDM) (See Rapid prototyping) Motion control: classification, 22–24 closed-loop control, 22–24, 28 open-loop control, 24 position control, 23–24 torque-control, 23 velocity-control, 23 closed-loop control techniques, 24, 28 derivative control, 24 integral control, 24 PID control, 24 proportional control, 24 computer-aided emulation, in, 24 electric power advantage, 22 electronic components for, 26 feedback sensors for, 27, 28 (See also Sensors) glossary of terms for, 28 inspection, X-Y, 29 installation and operation, 28 interpolation, 24, 27 circular, 24 contouring, 24 linear, 24, 27 kinds of controlled motion, 24 incremental, 24 point-to-point, 24 sequencing, 24 speed (velocity), 24 torque, 24 mechanical components for, 24–26, 29, 33 microcomputer-controlled, X-Y table, 29 motor drivers (amplifiers) for, 27 motor selection for, 26 open-loop systems, 24 pick and place, X-Y, 29 punch press, 29 profile, trapezoidal velocity control, 23, 24 servomotors, stepper motors, and actuators for, 26, 27, 30–37 systems, 22–29 (See also Controls) table, X-Y microcomputer-controlled, 29 X-Y inspection in, 24, 29 Motor generators, 377 conical bearingless, 377 Motors: commutation, 34–35 brush type, 30–31 brushless, 32 Hall-effect (HED), 26–27, 32, 34 comparison of stepping and servo motors for motion control, 27 hydraulic,436–437 linear actuators, motorized, DC and AC, 37 microminiature (See MEMS) motion control, for 26–27, 30–38544 Motors (Cont.): piezoelectric, 62 selection of, 26 selsyn, 436 servomotors, linear, 27, 33, 34 advantages of linear vs. rotary, 35 coil assembly heat dissipation, 35 commutation, 34 heat control, 35 installation of, 35 iron-core, 34 ironless, 34 servomotors, rotary, PM DC, 26–27, 30–33 brushless, 26–27, 30, 32 characteristics of, 33 disadvantage, 33 position sensing, 33 brush-type PM DC, 26–27, 30, 31 cup/shell, 31 disk-type, 31 speed-torque curves, 30 spring-powered, 286–287 stepper (stepping), 26–27, 35–38 actuators, linear based on, 37 applications for, 36 hybrid, 36 permanent-magnet (PM), 36 variable reluctance (VR), 36 wedge, MEMS, 512–513 Multiplication of functions, 348 Multipliers: force and stroke, 105–106 stroke, linkages, 103 three-gear stroke, 328 Nanoactuators, 528–529 Nanometers, 521 measurement in, 521 Nanomotor, 529 Nanoparticles, 521 Nanotechnology, science, engineering, 521 Nanotubes, carbon, 523–525 National fuel mix, electric generation, 74 Nonrenewable energy power plants coal-fired, 74 natural gas, 74 nuclear, 74–75 petroleum, 74 Oscillators dual-mass, MEMS, 513 wide-angle, 105 Pantograph, 6, 91 Parabolic dish Stirling Solar Thermal plants (See Concentrating solar thermal (CST) systems) Parabolic trough mirror solar thermal plants (See concentrating solar thermal (CST) systems) Pericycloid, 128 Photoelectric cell, 409 Photoelectric controls (7), 468–469 photovoltaic (PV) solar panels, 75 Piezoelectric: actuator, 62 crystal, 428 films, 506–507 transducer, microminiature, 506–507, 518 Pinions (See Gears) Plane, inclined, 3 Plants, power: baseload and baseload demand, 75 linear Fresnel reflector solar thermal (CST), 79–80 nuclear, 74 parabolic dish Sterling solar thermal (CST) 81–82 parabolic trough mirror solar thermal (CST), 78 power-tower solar thermal (CST), 79 Platform, multi-axis, X-Y-Z, 22 Pneumatic: cylinders, 342, 448–449 power, tasks for (15), 450–452 valve, dump, 241 valve, two-way, 342 Poly-Jet Matrix 3D Printing (See Rapid prototyping) Polygon connections, 320–321 advantages of, 321 shaft hub, straight, 320 shaft hub, taper, 321 Potentiometer (See Sensors) Power: conversion unit (PCU) generation, nonrenewable (See Mechanisms for renewable power ) generation, renewable (See Mechanisms for renewable power generation) Preprocessing in simulation (See 3D digital prototypes and simulation) Press: direct-acting, air spring, 288 punch, 116 safeguards for, 468 toggle, 117 Pressure exchange unit (PEU), 378–379 Pressure plate, walking, 220 Profile, trapezoidal velocity, 23–24 Prototyping, digital, (See 3D digital prototypes and simulation) Prototyping, rapid, (See Rapid prototyping) Pulley, pulleys, 3, 262–263, 324 ball-controlled, 263 cam-controlled, 263 linkage-controlled, 262 spring-loaded variable pitch, 263 systems, 3 Pump(s), 369–375 articulated piston/compressor, 374 bent axis, 374 centrifugal /impeller, 370, 375 designs explained (18), 373–375 diaphragm pump/compressor, 374 external rotor (gear), 370 glossary of terms, 376 helical rotor, 371 high-vacuum, 371 hydraulic gear 370 hydraulic twin piston 370 linear, 374 micropump, 504 nanopump, 522 peristaltic, 371 operating principles of, 369 Ramelli, 372 Roots compressor, 372 Pump(s) (Cont.): rotary (rotating): compressor, 372 cylinder block, 371 flexible-vane, 373 idler-tooth, 369 reversible, 369 sliding-piston, 373 sliding-vane, 373 swinging-vane, 369 swashplate, 369 three-screw, 372 two-screw, 372 wobble-plate, 375 Puncher, double-toggle, 106 Rapid prototyping (RP), 488–500 build envelope, 489 building functional parts, 488 choices, commercial RP, 489–490 computer controlled (CNC) milling, 498 commercial additive RP processes, 491–497 Direct Metal Deposition (DMD), 495–496 Direct-Shell Production Casting (DSPC), 496–497 Directed-Light Fabrication (DLF), 495 Fused Deposition Modeling (FDM), 493 Laminated Object Manufacturing (LOM), 496 Poly-Jet Matrix 3D Printing, 494–495 Selective Laser Sintering (SLS), 491–493 Solid-Ground Curing (SGC), 497 Stereolithography (SLA), 491 Three-Dimensional Printing (3DP), 493–494 commercial subtractive RP, 498 desktop prototyping, 498 processes in RP, 488–489 research and development in, 498–500 Mold Shape Deposition Manufacturing (MSDM), 499 Shape Deposition Manufacturing (SDM), 498–499 Robocasting ceramic parts, 499–500 Ratchet wheels: analysis of, 210 cam-driven, 327, 341 drive, modified, 208 drive, speed-change, 208 friction, 10 internal, 221 pawl, with, 210, 229 sheet-metal, 158 solenoid-operated, 327 toothless, 209 Reciprocators: cycloidal, 140 epicycloid, 140 linear, 329 rotating-cam, 194 sinusoidal, 194 Recorders, 470–471 bubbler-type, 470 float, 471545 Regulator: nonindicating, remote bulb, 467 self-contained, 466 Renewable energy, power generation: concentrating solar thermal (CST), 78–84 linear Fresnel reflector, 80–81 locations for, 83–84 mechanical, 74–87 moving-water power generation, 84–85 ocean-wave power, 84–85 outlook for, 83–84 overview of sources, 74 parabolic dish Stirling, 81–83 parabolic trough mirror, 96–97 photovoltaic (PV) solar panels, 75 power tower, 79–80 tidal power, 84 water turbines/pumps, 84–85 wave-energy buoys, 85 wind turbines, 76–78 G E, specifications, 77 glossary of terms, 86 relative costs of, 85 Vestas, specifications for, 77 windmill, Dutch origins for, 74 Resources, renewable energy, 87 Reverse osmosis, sea water, 378–379 Reverse rotation prevention ways (6), 422 Robocasting, ceramic parts (See Rapid prototyping) Robots, general: autonomous industrial, 50–51 characteristics, 51 definition, 50 glossary of terms, 66–67 history, 51 introduction to, 50 worldwide market, 51 Robots, industrial, stationary
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