Machines and Mechanisms Applied Kinematic Analysis

Machines and Mechanisms Applied Kinematic Analysis
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David H. Myszka
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Machines and Mechanisms Applied Kinematic Analysis
Fourth Edition
David H. Myszka
University of Dayton
CONTENTS
1 Introduction to Mechanisms and
Kinematics 1
Objectives 1
1.1 Introduction 1
1.2 Machines and Mechanisms 1
1.3 Kinematics 2
1.4 Mechanism Terminology 2
1.5 Kinematic Diagrams 4
1.6 Kinematic Inversion 8
1.7 Mobility 8
1.7.1 Gruebler’s Equation 8
1.7.2 Actuators and Drivers 12
1.8 Commonly Used Links and Joints 14
1.8.1 Eccentric Crank 14
1.8.2 Pin-in-a-Slot Joint 14
1.8.3 Screw Joint 15
1.9 Special Cases of the Mobility Equation 16
1.9.1 Coincident Joints 16
1.9.2 Exceptions to the Gruebler’s
Equation 18
1.9.3 Idle Degrees of Freedom 18
1.10 The Four-Bar Mechanism 19
1.10.1 Grashof’s Criterion 19
1.10.2 Double Crank 20
1.10.3 Crank-Rocker 20
1.10.4 Double Rocker 20
1.10.5 Change Point Mechanism 20
1.10.6 Triple Rocker 20
1.11 Slider-Crank Mechanism 22
1.12 Special Purpose Mechanisms 22
1.12.1 Straight-Line Mechanisms 22
1.12.2 Parallelogram Mechanisms 22
1.12.3 Quick-Return Mechanisms 23
1.12.4 Scotch Yoke Mechanism 23
1.13 Techniques of Mechanism Analysis 23
1.13.1 Traditional Drafting Techniques 24
1.13.2 CAD Systems 24
1.13.3 Analytical Techniques 24
1.13.4 Computer Methods 24
Problems 25
Case Studies 29
2 Building Computer Models of
Mechanisms Using Working Model®
Software 31
Objectives 31
2.1 Introduction 31
2.2 Computer Simulation of Mechanisms 31
2.3 Obtaining Working Model Software 32
2.4 Using Working Model to Model a Four-Bar
Mechanism 32
2.5 Using Working Model to Model a SliderCrank Mechanism 37
Problems 41
Case Studies 42
3 Vectors 43
Objectives 43
3.1 Introduction 43
3.2 Scalars and Vectors 43
3.3 Graphical Vector Analysis 43
3.4 Drafting Techniques Required in Graphical
Vector Analysis 44
3.5 CAD Knowledge Required in Graphical Vector
Analysis 44
3.6 Trigonometry Required in Analytical Vector
Analysis 44
3.6.1 Right Triangle 44
3.6.2 Oblique Triangle 46
3.7 Vector Manipulation 48
3.8 Graphical Vector Addition 48
3.9 Analytical Vector Addition : Triangle
Method 50
3.10 Components of a Vector 52
3.11 Analytical Vector Addition : Component
Method 53
3.12 Vector Subtraction 55
3.13 Graphical Vector Subtraction 55
3.14 Analytical Vector Subtraction : Triangle
Method 57
3.15 Analytical Vector Subtraction :
Component Method 59
3.16 Vector Equations 60
(- 7)
(- 7)
(- 7)
(- 7)
(+ 7)
(+ 7)
(+ 7)
ivContents v
3.17 Application of Vector Equations 62
3.18 Graphical Determination of Vector
Magnitudes 63
3.19 Analytical Determination of Vector
Magnitudes 66
Problems 67
Case Studies 71
4 Position and Displacement
Analysis 72
Objectives 72
4.1 Introduction 72
4.2 Position 72
4.2.1 Position of a Point 72
4.2.2 Angular Position of a Link 72
4.2.3 Position of a Mechanism 73
4.3 Displacement 73
4.3.1 Linear Displacement 73
4.3.2 Angular Displacement 73
4.4 Displacement Analysis 74
4.5 Displacement: Graphical Analysis 74
4.5.1 Displacement of a Single Driving
Link 74
4.5.2 Displacement of the Remaining Slave
Links 75
4.6 Position: Analytical Analysis 79
4.6.1 Closed-Form Position Analysis Equations
for an In-Line Slider-Crank 81
4.6.2 Closed-Form Position Analysis
Equations for an Offset SliderCrank 84
4.6.3 Closed-Form Position Equations for a
Four-Bar Linkage 87
4.6.4 Circuits of a Four-Bar Linkage 87
4.7 Limiting Positions: Graphical Analysis 87
4.8 Limiting Positions: Analytical Analysis 91
4.9 Transmission Angle 93
4.10 Complete Cycle: Graphical Position
Analysis 94
4.11 Complete Cycle: Analytical Position
Analysis 96
4.12 Displacement Diagrams 98
4.13 Coupler Curves 101
Problems 101
Case Studies 108
5 Mechanism Design 109
Objectives 109
5.1 Introduction 109
5.2 Time Ratio 109
5.3 Timing Charts 110
5.4 Design of Slider-Crank Mechanisms 113
5.4.1 In-Line Slider-Crank Mechanism 113
5.4.2 Offset Slider-Crank Mechanism 114
5.5 Design of Crank-Rocker Mechanisms 115
5.6 Design of Crank-Shaper Mechanisms 117
5.7 Mechanism to Move a Link Between Two
Positions 118
5.7.1 Two-Position Synthesis with a Pivoting
Link 118
5.7.2 Two-Position Synthesis of the Coupler
of a Four-Bar Mechanism 118
5.8 Mechanism to Move a Link Between Three
Positions 119
5.9 Circuit and Branch Defects 119
Problems 120
Case Studies 121
6 Velocity Analysis 123
Objectives 123
6.1 Introduction 123
6.2 Linear Velocity 123
6.2.1 Linear Velocity of Rectilinear
Points 123
6.2.2 Linear Velocity of a General
Point 124
6.2.3 Velocity Profile for Linear
Motion 124
6.3 Velocity of a Link 125
6.4 Relationship Between Linear and Angular
Velocities 126
6.5 Relative Velocity 128
6.6 Graphical Velocity Analysis: Relative Velocity
Method 130
6.6.1 Points on Links Limited to Pure
Rotation or Rectilinear
Translation 130
6.6.2 General Points on a Floating
Link 132
6.6.3 Coincident Points on Different
Links 135
6.7 Velocity Image 137
6.8 Analytical Velocity Analysis: Relative Velocity
Method 137
6.9 Algebraic Solutions for Common
Mechanisms 142
6.9.1 Slider-Crank Mechanism 142
6.9.2 Four-Bar Mechanism 142
6.10 Instantaneous Center of Rotation 142vi Contents
6.11 Locating Instant Centers 142
6.11.1 Primary Centers 143
6.11.2 Kennedy’s Theorem 144
6.11.3 Instant Center Diagram 144
6.12 Graphical Velocity Analysis: Instant Center
Method 149
6.13 Analytical Velocity Analysis: Instant Center
Method 152
6.14 Velocity Curves 155
6.14.1 Graphical Differentiation 157
6.14.2 Numerical Differentiation 159
Problems 161
Case Studies 168
7 Acceleration Analysis 170
Objectives 170
7.1 Introduction 170
7.2 Linear Acceleration 170
7.2.1 Linear Acceleration of Rectilinear
Points 170
7.2.2 Constant Rectilinear Acceleration 171
7.2.3 Acceleration and the Velocity
Profile 171
7.2.4 Linear Acceleration of a General
Point 173
7.3 Acceleration of a Link 173
7.3.1 Angular Acceleration 173
7.3.2 Constant Angular Acceleration 173
7.4 Normal and Tangential Acceleration 174
7.4.1 Tangential Acceleration 174
7.4.2 Normal Acceleration 175
7.4.3 Total Acceleration 175
7.5 Relative Motion 177
7.5.1 Relative Acceleration 177
7.5.2 Components of Relative
Acceleration 179
7.6 Relative Acceleration Analysis: Graphical
Method 181
7.7 Relative Acceleration Analysis: Analytical
Method 188
7.8 Algebraic Solutions for Common
Mechanisms 190
7.8.1 Slider-Crank Mechanism 190
7.8.2 Four-Bar Mechanism 191
7.9 Acceleration of a General Point on a Floating
Link 191
7.10 Acceleration Image 196
7.11 Coriolis Acceleration 197
7.12 Equivalent Linkages 201
7.13 Acceleration Curves 202
7.13.1 Graphical Differentiation 202
7.13.2 Numerical Differentiation 204
Problems 206
Case Studies 213
8 Computer-Aided Mechanism
Analysis 215
Objectives 215
8.1 Introduction 215
8.2 Spreadsheets 215
8.3 User-Written Computer Programs 221
8.3.1 Offset Slider-Crank Mechanism 221
8.3.2 Four-Bar Mechanism 221
Problems 222
Case Study 222
9 Cams: Design and Kinematic
Analysis 223
Objectives 223
9.1 Introduction 223
9.2 Types of Cams 223
9.3 Types of Followers 224
9.3.1 Follower Motion 224
9.3.2 Follower Position 224
9.3.3 Follower Shape 225
9.4 Prescribed Follower Motion 225
9.5 Follower Motion Schemes 227
9.5.1 Constant Velocity 228
9.5.2 Constant Acceleration 228
9.5.3 Harmonic Motion 228
9.5.4 Cycloidal Motion 230
9.5.5 Combined Motion Schemes 236
9.6 Graphical Disk Cam Profile Design 237
9.6.1 In-Line Knife-Edge Follower 237
9.6.2 In-Line Roller Follower 238
9.6.3 Offset Roller Follower 239
9.6.4 Translating Flat-Faced
Follower 240
9.6.5 Pivoted Roller Follower 241
9.7 Pressure Angle 242
9.8 Design Limitations 243
9.9 Analytical Disk Cam Profile
Design 243
9.9.1 Knife-Edge Follower 244
9.9.2 In-Line Roller Follower 246
9.9.3 Offset Roller Follower 249
9.9.4 Translating Flat-Faced
Follower 249
9.9.5 Pivoted Roller Follower 250Contents vii
9.10 Cylindrical Cams 251
9.10.1 Graphical Cylindrical Cam Profile
Design 251
9.10.2 Analytical Cylindrical Cam Profile
Design 251
9.11 The Geneva Mechanism 252
Problems 254
Case Studies 258
10 Gears: Kinematic Analysis and
Selection 260
Objectives 260
10.1 Introduction 260
10.2 Types of Gears 261
10.3 Spur Gear Terminology 262
10.4 Involute Tooth Profiles 264
10.5 Standard Gears 266
10.6 Relationships of Gears in Mesh 268
10.6.1 Center Distance 268
10.6.2 Contact Ratio 269
10.6.3 Interference 270
10.6.4 Undercutting 271
10.6.5 Backlash 272
10.6.6 Operating Pressure Angle 273
10.7 Spur Gear Kinematics 273
10.8 Spur Gear Selection 275
10.8.1 Diametral Pitch 276
10.8.2 Pressure Angle 276
10.8.3 Number of Teeth 276
10.9 Rack and Pinion Kinematics 281
10.10 Helical Gear Kinematics 282
10.11 Bevel Gear Kinematics 285
10.12 Worm Gear Kinematics 286
10.13 Gear Trains 288
10.14 Idler Gears 290
10.15 Planetary Gear Trains 290
10.15.1 Planetary Gear Analysis by
Superposition 291
10.15.2 Planetary Gear Analysis by
Equation 293
Problems 295
Case Studies 299
11 Belt and Chain Drives 302
Objectives 302
11.1 Introduction 302
11.2 Belts 302
11.3 Belt Drive Geometry 304
11.4 Belt Drive Kinematics 305
11.5 Chains 308
11.5.1 Types of Chains 308
11.5.2 Chain Pitch 309
11.5.3 Multistrand Chains 309
11.5.4 Sprockets 310
11.6 Chain Drive Geometry 310
11.7 Chain Drive Kinematics 311
Problems 313
Case Studies 315
12 Screw Mechanisms 316
Objectives 316
12.1 Introduction 316
12.2 Thread Features 316
12.3 Thread Forms 316
12.3.1 Unified Threads 317
12.3.2 Metric Threads 317
12.3.3 Square Threads 317
12.3.4 ACME Threads 317
12.4 Ball Screws 317
12.5 Lead 317
12.6 Screw Kinematics 318
12.7 Screw Forces and Torques 322
12.8 Differential Screws 324
12.9 Auger Screws 325
Problems 325
Case Studies 328
13 Static Force Analysis 330
Objectives 330
13.1 Introduction 330
13.2 Forces 330
13.3 Moments and Torques 330
13.4 Laws of Motion 333
13.5 Free-Body Diagrams 333
13.5.1 Drawing a Free-Body Diagram 333
13.5.2 Characterizing Contact Forces 333
13.6 Static Equilibrium 335
13.7 Analysis of a Two-Force Member 335
13.8 Sliding Friction Force 341
Problems 343
Case Study 345
14 Dynamic Force Analysis 346
Objectives 346
14.1 Introduction 346viii Contents
14.2 Mass and Weight 346
14.3 Center of Gravity 347
14.4 Mass Moment of Inertia 348
14.4.1 Mass Moment of Inertia of Basic
Shapes 348
14.4.2 Radius of Gyration 350
14.4.3 Parallel Axis Theorem 350
14.4.4 Composite Bodies 351
14.4.5 Mass Moment of Inertia—
Experimental Determination 352
14.5 Inertial Force 352
14.6 Inertial Torque 357
Problems 363
Case Study 366
Answers to Selected Even-Numbered
Problems 367
References 370
Index 371
370
REFERENCES

  1. Barton, Lyndon, Mechanism Analysis: Simplified Graphical
    and Analytical Techniques, 2nd ed., Marcel Dekker Inc.,
    New York, 1993.
  2. Baumeister, Theodore III, Avallone, Eugene, and Sadegh,
    Ali, Mark’s Standard Handbook for Mechanical Engineers,
    11th ed., McGraw-Hill Book Company, New York, 2006.
  3. Chironis, Nicholas and Sclater, Neil, Mechanisms and
    Mechanical Drives Sourcebook, 4th ed., McGraw-Hill Book
    Company, New York, 2007.
  4. Erdman, Aurthur, Sandor, George, and Kota, Sridhar,
    Mechanism Design, Vol 1: Analysis and Synthesis, 4th ed.,
    Prentice Hall, Upper Saddle River, NJ, 2001.
  5. Kepler, Harold, Basic Graphical Kinematics, 2nd ed.,
    McGraw-Hill Book Company, New York, 1973.
  6. Jensen, Preben, Cam Design and Manufacture, 2nd ed.,
    Marcel Dekker, New York, 1987.
  7. Jensen, Preben, Classical Modern Mechanisms for Engineers
    and Inventors, Marcel Dekker, Inc., New York, 1991.
  8. Jones, Franklin, Holbrook, Horton, and Newell, John,
    Ingenious Mechanisms for Designers and Inventors, Vols. I–IV,
    Industrial Press Inc, New York, 1930.
  9. Mabie, Hamilton and Reinholtz, Charles, Mechanisms and
    Dynamics of Machinery, 4th ed., John Wiley and Sons Inc.,
    New York, 1987.
  10. Martin, George, Kinematics and Dynamics of Machines,
    2nd ed., Waveland Press Inc., Long Groove, IL, 2002.
  11. Norton, Robert, Design of Machinery, 4th ed., McGraw-Hill
    Book Company, New York, 2008.
  12. Uicker, John, Pennock, Gordon, and Shigley, Joseph, Theory
    of Machines and Mechanisms, 4th ed., Oxford University
    Press, New York, 2010.
  13. Townsend, Dennis and Dudley, Darle, Dudley’s Gear Handbook, 2nd ed., McGraw-Hill Book Company, New York,
    1991.
  14. Waldron, Kenneth and Kinzel, Gary, Kinematics, Dynamics,
    and Design of Machinery, 2nd ed., John Wiley and Sons Inc.,
    Hoboken, NJ, 2004.
  15. Wilson, Charles and Sadler, Peter, Kinematics and Dynamics
    of Machinery, 3rd ed., Pearson Education, Upper Saddle
    River, NJ, 2003.
  16. Working Model Demonstration Guide, Knowledge Revolution
    Inc., San Mateo, CA, 1995.A
    Absolute motion, 128
    Acceleration. See also Coriolis acceleration,
    Normal acceleration, Relative
    acceleration, Tangential acceleration,
    Total acceleration
    analysis of, 175
    general summary problems, 206
    kinematic analysis, 2
    paths of, 179–180, 180i
    point of interest, 4
    vector, 43
    velocity profile, 178–179, 179t, 206–207, 207i
    Working Model, 208i–209i, 213
    Acceleration curves
    description of, 202
    graphical differentiation, 202–203, 203i
    numerical differentiation, 204–205, 205
    summary problems, 206i–209i, 212–213
    Acceleration images, description of, 196–197
    ACME thread types, 314, 315i, 317t
    Actuators
    definition of, 4
    role of, 12–13
    types of, 12–13
    Addendum, gear terminology, 260, 260i, 263i
    Air/hydraulic motors, actuator type, 12
    Algebraic solution, common mechanism,
    142, 190–191
    American Gear Manufacturer’s Association
    (AGMA)
    diametrical pitch, 261
    gear quality, 273, 273t
    gear standardization, 264–266, 264t
    American National Standards Institute (ANSI),
    gear standardization, 265
    Analytical method
    cam follower displacement diagrams
    summary problems, 253–254
    cycle position analysis, 96–98, 97i, 98i
    cylindrical cam profile design, 250, 255
    disk cam profile design, 242–249, 243i–245i,
    247i, 249i
    disk cam profile design summary problems,
    254i–255i, 255
    displacement analysis, 79, 79i, 80–81
    displacement analysis summary problems,
    101i–105i, 106
    instant center location summary problems,
    162i–164i, 164–165
    instant center method, 123, 152, 153i
    instant center method summary problems,
    162i–164i, 165
    limiting positions analysis, 91–93, 92i
    limiting positions summary problems,
    101i–105i, 105–106
    mechanism analysis technique, 24
    motion curves summary problems, 254
    relative acceleration analysis, 188i,
    188–190, 190t
    relative acceleration summary problems,
    208i–209i, 210
    relative velocity method, 137–141, 138i,
    140i, 140i
    relative velocity method summary problems,
    162i–164i, 164–165
    vector component addition, 53–55, 54i, 54t
    vector component subtraction, 55–60,
    56i–57i, 59t
    vector magnitude determinations, 66–71,
    67i–70i, 66t
    vector triangle addition, 50–51, 51i, 53–54,
    59–60, 59i, 759, 69, 69i
    vector triangle subtraction, 57i, 55–57
    velocity curves summary problems,
    162i–164i, 165
    Angle method, 50–51
    Angle of contact
    belt drive, 303–304, 303t
    chain drive, 308–309
    Angular acceleration, 173, 174i
    Angular displacement, 73, 73i
    Angular inertia of a body, 355
    Angular position vector, 72–73
    Angular velocity
    and linear velocity, 126–127, 127i
    links, 125–126, 126i
    and relative velocity, 128–129
    Annular gears, 259
    “Archimedes Screw,” See Auger screws
    Assembly circuit
    branch defect, 120
    circuit defect, 119
    Auger screws, 323, 323i
    Automatic Dynamic Analysis of Mechanical
    Systems (ADAMS®), 24, 31
    Avoirdupois pound, 328
    B
    Backlash
    gear mesh relationship, 270–271
    gear terminology, 260
    Ball screws, 315, 317i, 321
    Base circle
    cam profile design, 237, 237i
    gear terminology, 260i, 262i–263i
    Base diameter, 260
    Bellcrank, 3i, 4
    Belt drive geometry, 302–303, 302i, 311
    Belt drive kinematics, 303–306, 303i, 305i, 311
    Belt drives
    description of, 300–301
    selection summary problems, 310
    types of, 300–301
    Belt length, 302, 303t
    Belt speed, 303–304
    Belts, 300–302, 301i–302i, 301t
    Bevel gear kinematics, 283–284, 283i
    Bevel gears, 259–260, 259i, 283
    Bull gear, 266
    INDEX
    Note: The letter ‘i’ and ‘t’ followed by locators refers to illustrations and tables cited in the text
    371
    C
    Cam follower displacement diagrams
    analytical summary problems, 253–254
    description of, 224–225, 238i
    graphical summary problems, 252–253
    Cam followers, 223
    motion scheme nomenclature, 227–228
    prescribed motion, 225–226
    types of, 224–225, 224i
    Cam followers motion scheme
    constant acceleration, 228, 228t, 229t, 230i
    constant velocity, 228, 228t
    cycloidal motion, 230–236, 233i, 234i,
    235i, 236i
    harmonic motion, 228–230, 228t, 230i
    Cam joint
    definition of, 3, 3i
    kinematic diagram symbol, 5t–6t
    Cams
    description of, 223, 224i, 226–227, 226i,
    types of, 223–224, 224i
    Case studies
    acceleration analysis, 213–214, 213i–214i
    belt/chain drives, 312–313, 312i–313i
    cam design/analysis, 255–257, 256i–257i
    displacement/position analysis, 108, 108i
    dynamic force analysis, 364, 364i
    gears, 297–299, 298i–299i
    kinematic motion/classification, 29–30, 30i
    machine analysis, 42, 42i
    machine design, 121–122, 121i–122i
    screw mechanisms, 326–327, 326i–327i
    spread sheets, 222, 222i
    static force analysis, 343, 343i
    vectors, 71, 71i
    velocity, 168–169, 168i–169i
    Center distance
    belt drive, 302–303
    chain drive, 308–309, 308i
    gear mesh relationship, 266i, 267
    Center of gravity, 345–346, 345i, 346t
    Chain drive
    description of, 300, 306–309
    selection summary problems, 312
    Chain drive geometry, 308i, 308–309, 312
    Chain drive kinematics, 309–310, 309
    Chain length, 308–309, 308i
    Chain pitch, 307, 307t
    Chain speed, 309
    Chains, types of, 306i, 306–307
    Change point, 19t, 20, 21
    Circular pitch, 260, 260i
    Clearance, 260
    Clockwise, 125
    Closed-form position analysis
    four-bar linkage, 87
    in-line slider-crank, 81–83, 81i–82i
    offset slider-crank, 84–86, 84i–85i
    Coarse pitch, 261t, 264t
    Cog belt, 301, 301iCoincident joint, 16–18
    Combined motion schemes
    comparisons, 237t
    computer software for, 236
    description, 236
    goals of, 236
    jerk, 236
    modified sinusoidal acceleration, 237
    modified trapezoidal acceleration, 236
    polynomial displacement, 236
    trapezoidal acceleration, 236
    Common mechanisms, algebraic solutions,
    142, 190–191
    Common units, 173, 329, 346, 348
    Commutative law of addition, 49
    Complex link, 3i, 4
    Component method
    analytical addition, 53–55, 754i, 54t
    analytical subtraction, 59–60, 59i, 59t
    Components, 4, 12
    Composite bodies, 349–350, 349i
    Computer methods/programs
    dynamic analysis programs, 31
    mechanism analysis technique, 24–25
    user–written programs, 221–222, 221i
    value of, 31
    Computer-aided design (CAD) systems
    mechanism analysis technique, 24–25
    vector analysis, 44
    Configuration, 74–75
    Connecting arm, 19
    Constant acceleration, 228, 229i–230i, 229t
    Constant angular acceleration, 173–174, 174i
    Constant rectilinear acceleration, 171
    Constant velocity, 228, 228t
    Contact forces, 331–332, 331i, 339–340
    Contact line, 262
    Contact ratio, 267–268
    Coriolis acceleration
    description of, 197–201
    summary problems, 210–212, 210i–211i
    Cosine, 44, 47
    Counterclockwise, 126
    Coupler, 19
    Coupler curve, 101, 101i
    Crank
    definition of, 3–4, 3i
    eccentric, 14, 14i
    slider-crank mechanism, 22
    Crank-rockers
    circuits of, 87, 87i
    four-bar mechanism, 19–20, 19t, 20i, 22
    machine design, 115–117, 117i
    summary problems, 120
    Crank-shapers
    analytical methods, 118
    graphical procedure, 117–118
    machine design, 117–118, 117i
    summary problems, 120
    Cross drives, 303, 303i
    Crossed helical gears, 280
    Cycle analysis
    analytical position, 96, 97i, 99, 100i
    description of, 94
    displacement diagram, 101–106, 101i–105i
    graphical position, 94–96, 94i–96i
    Cycloidal motion, follower motion scheme,
    230–236, 231t–232t, 231i–236i
    Cylinders, actuator type, 4
    Cylindrical cams
    analytical profile design, 250
    description of, 224, 224i, 362
    graphical profile design, 249–250, 250ii
    D
    D’Alembert’s principle, 351
    Dedendum, 260i, 260
    Degree of freedom
    beer crusher computation, 10i, 10–11
    description of, 8
    equation for, 74
    four-bar mechanism calculation, 19, 19i
    lift table computation, 15–16, 15i–16i
    mechanism types, 8, 8i
    outrigger computation, 13–14, 13i–14i
    shear press computation, 11–12, 11i–12i
    toggle clamp computation, 9i, 9–10
    Degree of freedom mechanical press, 17–18,
    17i–18i
    Diametral pitch
    gear terminology, 261
    spur gear selection, 273–279, 273t, 276i, 278i
    Differential screw, description of, 322–323,
    322i–323i, 326
    Disk cam profile design
    analytical method, 242–249
    design limitations, 241–242, 242i
    flat-faced follower, 239–240, 239i
    graphical features, 237i, 237
    in-line knife-edge follower, 238i, 237–238
    in-line roller follower, 238i, 238
    offset roller follower, 239, 239i
    pivoted roller follower, 240–241, 240i
    Disk cams, 223–224, 224i
    Displacement
    analytical method, 79–81, 80i
    analytical summary problems, 101i–105i, 106
    description of, 74
    general summary problems, 101, 101i–105i
    and linear velocity, 123
    graphical driver analysis, 74i, 74–75
    graphical problems, 76–78, 76i, 78i–79i, 80
    graphical slave links analysis, 75–76, 75i, 76i
    graphical summary problems, 101–106,
    101i–105i
    kinematic analysis, 2
    point of interest, 4
    types of, 73
    vector, 43
    Working Model problems, 101i–103i, 105i,
    107–108
    Displacement diagrams. See also Cam follower
    displacement diagrams
    cycle position analysis, 98–99, 99i–100i
    summary problems, 101i–103i, 105i, 107
    velocity curves, 155, 156i, 157–158, 158i
    Double crank, 20, 19t, 20i
    Double enveloping worm gear set, 284, 285i
    Double rocker, 20, 19t, 20i
    Drafting
    as technique, 24
    vector analysis, 43–44
    Driver, 98
    Driver link
    mechanism analysis, 73
    position analysis, 74i, 74–75
    Driver point, 73
    372 Index
    Drivers, 12–13, 15
    Drum cam, 224, 224i
    Dynamic Analysis of Dynamic Systems (DADS®),
    dynamic analysis program, 31
    Dynamic equilibrium, 328
    Dynamic force analysis
    design questions, 2
    purpose of, 344
    static force analysis, 343, 343i
    and static equilibrium, 328
    strategy for, 31
    Dynamic force analysis programs, 24
    E
    Eccentric crank, 14, 14i
    Efficiency, 321
    Elastic parts, 2
    Electric motors, 12
    Engines, actuator type, 4, 12
    Enveloping worm gear teeth, 284, 285i
    Epicyclic train, 288–293, 289i
    Equilibrium, 333–338, 334i–337i
    Equivalent linkage, 201
    F
    Face width, 260i, 260
    Fine pitch, 315, 316t
    Flat belt, 300, 301i
    Flat-faced follower
    analytical profile design, 248
    description of, 224i, 225
    profile design, 239–240, 239i
    Floating link
    relative acceleration analysis, 191i,
    191–192, 193i–194i, 195–196
    relative acceleration summary problems,
    210, 210i
    relative velocity method, 132–135, 133i–134i
    Follower, 19. See also Cam followers
    Follower motion, 224, 224i
    Follower position, 224–225, 224i
    Follower shape, 224i, 225
    Foot-pound, 328–329
    Force
    definition of, 328
    screw mechanisms, 320i–321i, 320–322
    summary problems, 341, 341i
    vector, 43
    Force analysis. See also Dynamic force analysis,
    Static force analysis
    and acceleration, 170
    machine design, 1
    Formula, spreadsheets, 215–218, 217i–218i
    Four-bar linkage, 87
    Four-bar mechanisms
    algebraic solutions, 142, 190–191
    categories of, 19t, 19–20
    circuits of, 87, 87i
    coupler two–point synthesis, 119i, 118–119
    description of, 19, 19i
    Grashof’s theorem, 19
    motion classification, 20–21, 21i, 29, 29i
    nomenclature, 19
    three-point synthesis, 119, 119i
    transmission angle, 93–94, 94i
    user-written programs, 221i, 221–222
    Working Model tutorial, 32–37, 33i–34i, 36iFrame
    definition of, 2
    four-bar mechanism, 19
    kinematic diagram, 8
    Free-body diagrams, 331–333, 331i–333i
    Friction
    coefficients of, 339, 339t
    force analysis, 1
    screw mechanisms, 320
    Friction force, 339
    Full joints, 3, 3i
    G
    Gear joint, 3, 3i, 5t–6t
    Gear kinematics
    gear function, 271–273, 271i–272i, 293
    Gear mesh relationship
    backlash, 270–271
    center distance, 266–267, 266i
    contact ratio, 267–268
    interference, 268–269, 268t
    operating pressure angle, 271
    undercutting, 269–270, 270i
    Gear rack, 259, 259i, 262, 279
    Gear selection, 294
    Gear standardization, 264–266, 264t
    Gear trains
    description of, 286–288, 286i
    design summary problems, 296
    summary problems, 295i–296i, 295–296
    Gear-driven mechanisms, summary
    problems, 296, 296i
    Gears
    description of, 258–259, 258i–259i
    terminology, 260i, 260–262, 261t, 262i
    types of, 259–260, 259i, 284
    General triangles, 46–48, 47i, 48i
    Geneva mechanism, 250–252, 250i, 252i, 255
    Graphical analysis
    cam follower displacement diagrams
    summary problems, 252–253
    cycle position, 94–96, 94i–96i
    cylindrical cam profile design, 250, 250i
    disk cam profile design, 237–242, 237i–242i
    disk cam profile design summary problems,
    254i–255i, 254–255
    displacement, 74–79, 74i–79i
    displacement diagrams summary
    problems,102i–105i, 107
    displacement summary problems, 101–106,
    101i–105i
    driver link displacement, 74i
    instant center location summary problems,
    162i–164i, 165
    instant center method, 123, 149–152,
    150i, 152i
    instant center method summary problems,
    162i–164i, 166
    limiting positions, 88i, 87–88
    mechanism analysis, 23–24
    relative acceleration analysis, 181–187,
    182i–183i, 185i–186i
    relative acceleration summary problems,
    208–209, 208i–209i
    relative velocity method, 130–137,
    130i–131i, 133i–136i
    relative velocity method summary
    problems, 162–164, 162i–164i
    slave links displacement, 75–76, 75i–76i
    vector addition, 48–50, 49i–50i
    vector magnitudes, 63–65, 63i–65i,
    70–71, 70i–71i
    vector subtraction, 55–57, 55i–57i
    Graphical differentiation
    acceleration curves, 202–203, 203i
    velocity curves, 157i, 157
    velocity curves summary problems,
    162i–164i, 167
    Graphical disk cam profile design
    features of, 237i, 237
    flat-faced follower, 239–240, 239i
    in-line knife-edge follower, 238i, 237–238
    in-line roller follower, 238i, 238
    offset roller follower, 239, 239i
    pivoted roller follower, 240–241, 240i
    Grashof’s theorem, 19
    Gruebler’s equation
    description of, 8
    exceptions to, 18
    special cases, 16–18, 16i–18i
    Gyration radius, 348
    H
    Half joint, 3, 3i
    Harmonic motion, 228–230, 228t–229t,
    229i–230i
    Helical gear kinematics, 280–282, 281i,
    281t–282t
    Helical gears, 259, 259i, 294–295
    Helix angle, 280, 281i
    Herringbone gears, 259, 259i
    Higher order joint, 3, 3i
    Hinge joint, 3, 3i
    Home position, 237, 237i
    Hydraulic cylinders, 13i, 12–13
    Hydraulic motors, 12
    I
    Idler gears, 288i, 288
    Idler pulley, 301
    In-line follower, 225, 224i
    In-line knife-edge follower, 238i, 237–238
    In-line roller follower
    analytical profile design, 245–247, 245i, 247i
    graphical profile design, 238i, 238
    In-line slider-crank
    closed-form analysis, 81–83, 81i–82i
    machine design, 113–114, 114i
    Inch-pound, 329
    Included angle
    screw efficiency, 321
    thread feature, 314, 314i
    Inertia, 170, 328
    Inertia-force method of dynamic
    equilibrium, 351
    Inertial forces
    description of, 350–355, 351i–352i, 354i
    summary problems, 362, 362i
    Inertial torques
    description of, 355–361, 355i–357i, 359i
    summary problems, 362–363, 362i–363i
    Input link, 19
    Instant center, 142, 142i
    Instant center diagram, 144–145, 145i
    Instant center method
    Index 373
    analytical velocity method, 123,
    152–154, 153i
    analytical velocity method summary
    problems, 162i–164i, 166–167
    graphical velocity method, 123, 149–152,
    150i, 152i
    graphical velocity method summary
    problems, 162i–164i, 166
    Instant centers
    locating, 142–149, 143i–149i, 146t, 148t
    summary problems, 162i–164i, 165–166
    Instantaneous center of rotation, 142
    Interference, 268–269, 268t
    Internal angle
    triangle addition problem, 51
    triangle subtraction problem, 57–58, 58i
    Internal gears, 259, 259i
    International Organization for
    Standardization (ISO)
    force unit, 328
    metric threads, 315
    moment unit, 329
    Inverted tooth/silent chain, 306i, 307
    Involute tooth profile, 262–264, 262i, 263i
    J
    Joint, definition of, 3, 3i
    Joints
    coincident, 16i, 16–17
    commonly used, 14–15
    K
    Kennedy’s theorem, instant centers,
    144–146, 147
    Kinematic analysis, 1i, 2, 3
    Kinematic diagram
    four-bar mechanism, 19, 19i
    manual water pump, 22
    symbol system, 4, 5t–6t
    Kinematic diagram problems
    beer crusher, 10i, 10–11
    lift table, 15i–16i, 15–16
    mechanical press, 17i–18i, 17–18
    nose wheel assemble, 20–21, 21i
    outrigger, 13–14, 13i–14i
    shear presses, 6–7, 6i–7i, 11–12, 11i–12i
    sketching diagrams, 25–28, 25i–28i
    toggle clamp, 9i, 9–10
    vice grip, 7, 7i
    Kinematic inversion, 8
    Kinematics, 2
    Knife-edge follower
    analytical profile design, 242–244, 243i–244i
    description of, 224i, 225
    L
    Law of cosines, oblique triangles, 46
    Law of sines, oblique triangles, 46
    Lead, 315–316
    Lead angle
    screw threads, 316
    thread feature, 314, 314i
    worm gears, 284, 285i
    Limiting positions
    analytical analysis, 91–93, 92i
    definition of, 87, 88iLimiting positions (Continued)
    graphical analysis, 88i, 87–88
    graphical analysis problems, 88–91, 88i–90i
    summary problems, 101i–105i, 106–107
    Line of center, 149, 150i
    Line of contact, 262, 262i
    Line of proportion, 149, 150i
    Linear acceleration, 170–173
    Linear cam, 224, 224i
    Linear displacement, 73
    Linear motion, 125i, 124–125
    Linear velocity
    and angular velocity, 126–127, 127i
    definition of, 123
    general point, 124, 124i
    rectilinear points, 124i, 123–124
    Link, angular position, 72
    Linkage acceleration. See also Timing charts
    Linkage, definition of, 2
    Linkage velocity analysis. See also Timing charts
    Links
    acceleration analysis, 170, 173–174, 210, 210i
    angular velocity, 125–126, 126i
    commonly used, 14
    definition of, 2
    four-bar mechanism tutorial, 32–33, 33i
    relative velocity method, 130i, 130–135,
    131i, 133i–134i
    resizing, 33
    slider-crank mechanism tutorial, 37–38, 38i
    types of, 3
    Locked mechanism, 8, 8i
    Long and short addendum system, 269
    Lowering a load (screw drive), 321
    Lubrication, chain drive kinematics, 309
    M
    Machine design
    crank-shaper, 117–118, 117i
    crank-rocker, 115, 116i, 117, 120
    slider-crank ratio, 113–115, 114i–115i, 120
    three point synthesis, 119, 119i, 121
    time ratio problems, 109–110, 120
    two position links, 118–121, 118i–119i
    Machines, 1
    Magnitude, 73, 73i
    Magnitude direction
    triangle addition, 52
    triangle subtraction, 57, 58i
    Major diameter, 314, 314i
    Manual force, 13
    Mass, 344, 361–362, 361i–362i
    Mass moment of inertia
    basic shapes, 346, 347i, 347t, 348
    composite bodies, 349i, 349–350
    description of, 346, 346i
    experiential determination, 350, 350i
    parallel axis theorem, 348i, 348–349
    radius of gyration, 348
    summary problems, 361–362, 361i–362i
    Mechanism
    basic components of, 2–4, 3i
    definition of, 1–2
    degrees of freedom computation, 74
    motion analysis, 73
    phases of, 80
    vectors, 43
    Mechanism analysis, 2, 23
    Metric thread, 314–315, 315i, 317t
    Minor diameter, 314, 314i
    Miter gears, 260, 259i, 283
    Mobility (M)
    equation, 8
    equation exceptions, 18
    special cases, 16–18, 16i–18i
    Mobility (M) calculation
    can crusher, 11
    four-bar mechanism, 19
    graphical displacement analysis, 76
    lift table, 16
    manual water pump, 22
    mechanical press, 17–18
    outrigger, 14
    shear press, 12
    sketching diagrams, 25i–29i, 29
    toggle clamp, 9–12, 14
    Module, 261, 261t
    Moment
    description, 328–331, 329i–330i
    summary problems, 341, 341i
    Moment of inertia
    basic shapes, 346–348, 347i, 347t
    composite bodies, 349i, 349–350
    description of, 346, 346i
    experiential determination,
    350, 350i
    parallel axis theorem, 348i, 348–349
    radius of gyration, 348
    summary problems, 361–362, 361i
    Motion
    laws of, 331, 350
    mechanism analysis, 1, 1i, 73
    Motor
    actuator types, 4
    four-bar mechanism tutorial, 35–36
    slider-crank mechanism tutorial, 41
    Multiple threads, 315–316, 317i
    Multiple-strand roller chain, 306, 306i
    Multi-strand chains, 307, 307t
    Multi-V-belt, 300, 301i
    N
    Newton, force magnitude unit, 328
    Newton, Sir Isaac, 170, 331
    Normal acceleration
    acceleration analysis, 174–177,
    175i–176i
    description of, 173, 173i
    summary problems, 206–207, 207i
    Normal circular pitch, 281, 281i
    Normal diametral pitch, 281
    Normal force, 339
    Normal module, 281
    Normal pressure angle, 281
    Normal section, 281, 281i
    Numerical differentiation
    acceleration curves, 204–205, 205i
    velocity analysis, 159–160, 160i
    O
    Oblique triangle, 46–48, 46i–48i
    Offset follower, 225, 224i
    Offset roller follower
    analytical profile design, 248
    graphical profile design, 239, 239i
    Offset sidebar roller chain, 306i, 307
    374 Index
    Offset slider-crank, 221i, 221
    closed-form analysis, 84–87, 84i–85i
    machine design, 114–115, 115i
    Off-set slider crank Mechanism, 221i, 221
    Open, 32
    Open-loop linkages, 8, 8i
    Operating pressure angle, 271
    Output link, 19
    P
    Parallel axis theorem, 248i, 348–349
    Parallelogram mechanisms, 22, 23i
    Phase, 94
    Pin, 3, 3i
    Pin joint
    kinematic diagram symbol, 5t
    four-bar mechanism tutorial, 33–35, 34i
    slider-crank mechanism tutorial, 38–41, 40i
    Pin-in-a-slot joint, commonly used, 14, 15i
    Pinion, 266, 266i. See also Gear rack
    Piston, 3, 3i
    Pitch
    thread features, 315, 315i
    worm gears, 284, 285i
    Pitch circle, 260, 260i, 262, 262i
    Pitch curve, 237, 237i
    Pitch diameter
    belt drive, 301i–302i, 302–303
    chain drive, 308, 308i
    gear terminology, 260, 260i
    thread feature, 314, 314i
    Pitch line
    gear terminology, 262, 262i
    spur gear kinematics, 271, 271i
    Pitch point, 260
    Pivot link, 118i, 118
    Pivoted followers, 224, 224i
    Pivoted roller follower
    analytical profile design, 249i, 248–249
    profile design, 240–241, 240i
    Planar mechanism, 2
    Planet gear, 288, 289i
    Planetary gear analysis
    equation, 291–292
    summary problems, 292–293
    superposition, 289
    summary problems, 289–291
    Planetary gear trains
    description of, 288–293, 289i, 290t–291t, 291i
    summary problems, 297, 297i
    Plate cams, 224, 224i
    Pneumatic cylinders, 13i, 12–13
    Point (P), 73i, 72–73
    Point of interest, 4
    Point of interest path, 37, 37i
    Point position measurement, 36–37
    Points
    linear acceleration, 173
    linear velocity, 124, 124i
    relative acceleration analysis, 274, 191–196,
    191i–194i
    relative acceleration summary problems,
    210, 210i
    Points/floating link, 132–135, 133i–134i
    Points/multiple, relative velocity method,
    135–137, 135i–136i
    Points/one link, relative velocity method,
    130–132, 130i–131iPoints of interest
    four-bar mechanism tutorial, 33, 34i
    slider-crank mechanism tutorial, 55i
    Position, 2, 72
    Position analysis
    analytical displacement, 80i, 80–81
    graphical displacement, 74–76, 74i–76i
    graphical displacement problems,
    76–79, 76i–79i
    in-line slider-crank, 81, 81i
    limiting positions, 91–93, 92i
    offset slider crank, 84, 84i
    purpose of, 72i, 72
    Position vector, 73i, 72
    Pound, 328
    Pressure angle
    description of, 241, 241i
    gear terminology, 262, 262i
    spur gear selection, 274–279, 276i, 278i
    Primary centers
    locating problems, 145–149, 145i–149i, 146t,
    148t
    rules of, 203i, 143–144, 143i–144i
    Primary joints, 3, 3i
    Prime circle, 237, 237i
    Prismatic joint, 3, 3i
    Pulleys, 301i, 301, 301t
    Pythagorean theorem, 45
    Q
    Quick-return mechanisms, 23, 23i
    R
    Rack, 259, 259i, 279
    Rack and pinion kinematics, 279–280, 280i, 294
    Radian, description of, 125–126
    Rectilinear points
    linear acceleration, 170–171
    linear velocity, 123–124, 124i,
    Rectilinear translation, 130–132, 130i–131i
    Relative acceleration
    components, 179–181, 180i, 197–201,
    197i–200i
    description of, 177–179, 178i, 179t
    summary problems, 207i, 207–208
    Relative acceleration analysis
    analytical method, 188i, 188–190, 190t
    analytical summary problems, 208i–209i,
    209–210
    graphical method, 181–187, 182i–183i,
    185i–186i
    graphical summary problems, 208–209,
    208i–209i
    Relative displacement, 317
    Relative motion
    definition of, 177
    description of, 128, 177
    Relative velocity, 128–129, 128i, 129i
    Relative velocity method
    analytical method, 137–141, 138i, 140i
    analytical method summary problems,
    162i–164i, 164–165
    graphical analysis, 130–137, 130i–131i,
    133i–136i
    graphical analysis summary problems,
    162–164, 162i–164i
    velocity analysis, 123, 137–141, 138i, 140i
    velocity image, 137, 137i
    Resultant
    definition of, 49
    graphical addition problems, 49, 49i, 50
    graphical subtraction problem, 56–57, 57i
    Resultant components, 53–55, 54i
    Resultant force, summary problems, 341, 341i
    Resultant magnitude
    triangle addition problem, 51
    triangle subtraction problem, 58, 58i
    Reversible gearset, 285
    Revolute joint, 3, 3i
    Richardson method (numerical differentiation)
    acceleration curves, 204
    velocity curves, 159
    Right triangle, 44–46, 44i–46i
    Ring gear, 288, 289i
    Rocker, 3i, 4
    Rocker arm link, 4
    Roller chain, 306, 306i
    Roller follower, 224i, 225
    Rotation
    instantaneous center of, 142, 142i
    kinematic analysis, 2
    relative velocity method, 130–132, 130i–131i
    S
    Scalar quantities, 43
    Scotch Yoke mechanism, 23, 23i
    Screw actuators, 13
    Screw forces/torques, 320–322, 320i–321i, 326
    Screw joints, 15, 15i
    Screw kinematics, 316–320, 318i–320i
    Screw mechanisms, 314
    Screw thread, 315, 314i–315i, 323–324
    Screw-driven acceleration, 326, 324i–325i
    Screw-driven displacement, 324–325, 324i–325i
    Screw-driven velocity, 325–326, 324i–325i
    Self-locking, 316
    Serpentine drives, 303, 303i
    Servomotors, 12
    Shaft angle, 283, 283i
    Sheaves, 301i, 301, 301t
    Simple link, 3, 3i, 5t
    Simulation
    four-bar mechanism, 32–37, 33i–37i
    slider-crank mechanism tutorial, 37–41,
    38i–40i
    Sine, 44, 46
    Sketching, practice problems, 25–28, 25i–28i
    Slave links, 75–76, 75i–76i
    Slider-crank
    transmission angle, 93–94, 94i
    Slider joint, symbol, 6t
    Slider-crank mechanisms
    algebraic solutions, 142, 190–191
    description of, 22
    limiting positions, 88i
    machine design, 113–115, 114i–115i
    summary problems, 120
    Working Model tutorial, 37–41, 38i–40i
    Sliding friction force, 339t, 339i–340i, 339–341
    Sliding joint, 3, 3i
    Sliding link, 38, 38i–39i
    Slot joints, 38, 39i
    Slug, derivation of, 344
    Software. See Computers methods/programs
    Solenoids, actuator type, 4
    Speed, 2
    Index 375
    Spherical-faced follower, description of,
    224i, 225
    Spreadsheets
    acceleration curves, 205i
    cycle position analysis, 97, 98i
    cycloidal motion, 235i
    displacement curve, 155, 156i
    displacement diagram, 100i
    general description, 215–220, 215i–220i
    in-line roller follower design, 247i
    knife-edge follower design, 244i
    mechanism analysis technique, 24
    summary problems, 222
    velocity analysis, 160i
    Sprocket, 307, 307i, 308t
    Spur gear geometry, summary problems, 293
    Spur gear kinematics
    gear function, 271–273, 271i–272i
    summary problems, 293
    Spur gear selection
    diametral pitch, 273–279, 273t, 276i, 278i
    pressure angle, 274–279, 276i, 278i
    set center distance summary problems, 294
    teeth number, 274–279, 276i, 278i
    Spur gears
    gear type, 259, 259i
    terminology, 260i, 260–262, 261t
    Square thread, 314–315, 315i
    Static equilibrium
    conditions of, 333
    definition of, 328
    Static machine forces, summary problems,
    341–343, 341i–343i
    Straight-line mechanisms, 22
    Peaucellier-Lipkin linkage, 22i
    Watt linkage, 22i
    Stroke, 88i, 88
    Stub teeth, 269
    Sun gear, 288, 289i
    Superposition method, 289
    Swing arm followers, 224, 224i
    Synthesis, 109
    T
    Tangent, right triangle, 44
    Tangential acceleration
    acceleration analysis, 174–175
    description of, 173, 173i, 175–177, 176i
    summary problems, 206–207, 207i
    Tangential velocity, 126
    Teeth. See also Involute tooth profile
    chain drive, 308, 308i
    gear terminology, 260–262
    spur gear selection, 273–279, 274t–275t,
    276i, 278i
    worm gears, 284, 285i
    Thread features, 314, 314i
    Thread forms, 314–315, 315i, 316t–317t
    Thread number, 315–316, 317i
    Three-point synthesis, machine design, 119,
    119i, 121
    Throw angle, 115
    Time ratio, 109–110, 120
    Timing belt, 301, 301i
    Timing charts
    problems, 112–113
    uses of, 110–111, 111i
    Tip-to-tail method, 48Torque
    definition of, 328, 329i
    screw mechanisms, 320–322, 320i–321i
    Total acceleration, 175–177, 176i
    Trace, 101
    Trace point, 237, 237i
    Translating followers, 224, 224i
    Transmission angle
    definition, 93
    mechanical advantage, 93
    Transverse section, 281, 281i
    Triangles
    summary problems, 67–69, 67i–68i
    trigonometric relationships, 44, 44i
    types of, 44, 46
    vector addition, 50–51, 51i
    vector subtraction, 57–60, 58i–60i, 59t
    Trigonometry, 44
    Triple rocker, 19t, 20, 20i
    Truss, 8, 8i
    Two-armed synchro loader, 4, 5t
    Two-force member, 333–338, 334i–337i
    Two-point synthesis
    coupler of four-bar mechanism, 119i, 118–119
    design class, 118
    pivot link, 118–119, 118i–119i
    single pivot summary problems, 120–121
    two pivots summary problems, 121
    U
    Undercutting, 269–270, 270i
    Unified thread, 314–315, 315i, 316t
    United States Customary System
    force unit, 328
    mass/weight, 344
    moment unit, 328–329
    threads per inch, 314
    V
    V-belt, belt type, 300–302, 301i–302i
    Vector analysis
    analytical magnitude determination, 66–67,
    66i,
    66t, 71, 71i
    component addition, 53–55, 54i, 54t
    component subtraction, 59–60, 59i–60i, 59t
    graphical addition, 48–50, 49i–50i
    graphical magnitude determination, 63–65,
    63i–65i
    graphical subtraction, 55–57, 55i–57i
    triangle addition, 50–51, 51i, 53–55,
    54i, 54t, 69i, 69
    triangle subtraction, 58i, 57–58
    Vector components, 52i, 52
    Vector diagram
    graphical addition problems, 49–50,
    49i–50i
    graphical subtraction problems, 55–56, 56i
    magnitude determination, 65, 63i–65i
    triangle addition problem, 51
    triangle subtraction problem, 58–59, 58i
    Vector equations, 60, 60i
    analytical magnitude determination,
    66–67, 71
    application of, 62
    formation of, 60–62, 61i–62i
    graphical magnitude determination,
    63–65, 70–71
    subtraction, 59
    Vector magnitude
    analytical determination, 66–67, 66i, 66t,
    71, 71i
    graphical determination, 63–65, 63i–65i,
    70–71, 70i–71i
    Vector problems
    analytical addition, 51–55, 51i–52i,
    54i, 54t, 69i, 69
    analytical magnitude determination, 66–67,
    66i, 66t, 70–71, 70i–71i
    analytical subtraction, 57–60, 58i–60i, 59t,
    69i, 70
    equations, 61–62, 70, 70i
    graphical addition, 49–50, 49i–50i, 69i, 69
    graphical magnitude determination, 63–65,
    63i–64i, 70i–71i, 70–71
    graphical subtraction, 55–57, 55i–57i, 69i, 69
    triangle addition, 51i, 51, 53
    triangle subtraction, 59–60, 59i–60i, 59t
    Vectors
    addition methods, 43, 48–55, 48i–52i, 54i, 54t
    mechanism characteristics, 43
    oblique/general triangles, 46–48
    right triangle, 44–46, 44i
    subtraction methods, 55–60, 55i–60i, 59t
    triangle types, 44–48, 44i–48i, 47i–48i
    Velocity
    kinematic analysis, 2
    point of interest, 4
    summary general problems, 161, 161i
    summary relative problems, 162, 162i
    vector property, 43
    Working Model, 162i–164i, 168
    Velocity analysis
    algebraic solutions, 142
    analytical methods, 137–141, 138i, 140i
    description of, 123
    graphical methods, 130–137,
    130i–131i, 133i–136i
    376 Index
    graphical methods summary problems,
    162–164, 162i–164i
    instant center analytical method,
    123, 152, 153i
    instant center graphical analysis, 123,
    149–152, 150i, 152i
    Velocity curves
    analytical summary problems, 162i–164i,
    167–168
    description of, 155–157, 156i
    graphical differentiation, 157–158, 157i–158i
    graphical summary problems, 162i–164i, 167
    numerical differentiation, 159–161, 160i
    Velocity image, 137, 137i
    Velocity profile
    acceleration, 171–172, 172i
    linear motion, 125i, 124–125
    Velocity ratio
    belt drive kinematics, 303
    chain drive kinematics, 309
    spur gear kinematics, 271–273, 271i–272i
    Volume, 323
    Volumetric acceleration, 323
    Volumetric flow, 323
    W
    Weight, 344
    Whole depth, 260
    Windshield wiper system, design concept, 1, 1i
    Wipe pattern, components, 1
    Working Model software
    acceleration, 208i–209i, 213
    computer simulation software, 31
    displacement problems, 101i–105i,
    107–108
    four-bar mechanism tutorial, 32–37,
    33i–37i
    practice problems, 41–42, 41i–42i
    purchase information, 32
    slider-crank mechanism, 37–41, 38i–40i
    velocity problems, 162i–164i, 168
    Worm, 284
    Worm gear kinematics, 284–286, 285i
    Worm gears, 259i, 260, 295
    Worm pitch diameter, 284, 285i
    Worm wheel, 284
    X
    X–axis
    angle addition, 53
    angle subtraction, 59t
    component determination, 66, 66t
    rotational equation, 15

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