ISBN-13: 9781118933282 / Angielski / Twarda / 2016 / 720 str.
ISBN-13: 9781118933282 / Angielski / Twarda / 2016 / 720 str.
Kinematics, Dynamics, and Design of Machinery, Third Edition, presents a fresh approach to kinematic design and analysis and is an ideal textbook for senior undergraduates and graduates in mechanical, automotive and production engineering
The third edition of Kinematics, Dynamics, and Design of Machinery has been comprehensively reorganized to emphasize the design of mechanisms before analysis. To facilitate the design emphasis, the authors have introduced the relatively new concept of Graphical Constraint Programming (GCP) in the second chapter of the book.
Preface xiii
1 Introduction 1
1.1 Historical Perspective, 1
1.2 Kinematics, 3
1.3 Design: Analysis and Synthesis, 4
1.4 Mechanisms, 4
1.5 Planar Linkages, 6
1.6 Visualization, 9
1.7 Constraint Analysis, 12
1.8 Constraint Analysis of Spatial Linkages, 18
1.9 Idle Degrees of Freedom, 22
1.10 Overconstrained Linkages, 24
1.11 Uses of the Mobility Criterion, 28
1.12 Inversion, 28
1.13 Reference Frames, 29
1.14 Motion Limits, 30
1.15 Continuously Rotatable Joints, 31
1.16 Coupler–Driven Linkages, 35
1.17 Motion Limits for Slider–Crank Mechanisms, 35
1.18 Interference, 38
1.19 Practical Design Considerations, 41
References, 44
Problems, 45
2 Techniques in Geometric Constraint Programming 59
2.1 Introduction, 59
2.2 Geometric Constraint Programming, 60
2.3 Constraints and Program Structure, 61
2.4 Initial Setup for a GCP Session, 64
2.5 Drawing a Basic Linkage Using GCP, 66
2.6 Troubleshooting Graphical Programs Developed Using GCP, 79
References, 80
Problems, 81
Appendix 2A Drawing Slider Lines, Pin Bushings, and Ground Pivots, 85
2A.1 Slider Lines, 85
2A.2 Pin Bushings and Ground Pivots, 87
Appendix 2B Useful Constructions When Equation Constraints Are Not Available, 88
2B.1 Constrain Two Angles to Be Integral Multiples of Another Angle, 89
2B.2 Constrain a Line to Be Half the Length of Another Line, 89
2B.3 Construction for Scaling, 90
2B.4 Construction for Square Ratio v2/r, 91
2B.5 Construction for Function x yz=r, 91
3 Planar Linkage Design 93
3.1 Introduction, 93
3.2 Two–Position Double–Rocker Design, 96
3.3 Synthesis of Crank–Rocker Linkages for Specified Rocker Amplitude, 100
3.4 Motion Generation, 114
3.5 Path Synthesis, 133
References, 148
Problems, 150
4 Graphical Position, Velocity, and Acceleration Analysis for Mechanisms with Revolute Joints or Fixed Slides 169
4.1 Introduction, 169
4.2 Graphical Position Analysis, 170
4.3 Planar Velocity Polygons, 171
4.4 Graphical Acceleration Analysis, 173
4.5 Graphical Analysis of a Four–Bar Mechanism, 175
4.6 Graphical Analysis of a Slider–Crank Mechanism, 183
4.7 Velocity Image Theorem, 186
4.8 Acceleration Image Theorem, 189
4.9 Solution by Geometric Constraint Programming, 194
References, 205
Problems, 205
5 Linkages with Rolling and Sliding Contacts, and Joints on Moving Sliders 221
5.1 Introduction, 221
5.2 Reference Frames, 222
5.3 General Velocity and Acceleration Equations, 223
5.4 Special Cases for the Velocity and Acceleration Equations, 228
5.5 Linkages with Rotating Sliding Joints, 230
5.6 Rolling Contact, 235
5.7 Cam Contact, 243
5.8 General Coincident Points, 250
5.9 Solution by Geometric Constraint Programming, 257
Problems, 263
6 Instant Centers of Velocity 279
6.1 Introduction, 279
6.2 Definition, 280
6.3 Existence Proof, 280
6.4 Location of an Instant Center from the Directions of Two Velocities, 281
6.5 Instant Center at a Revolute Joint, 282
6.6 Instant Center of a Curved Slider, 282
6.7 Instant Center of a Prismatic Joint, 282
6.8 Instant Center of a Rolling Contact Pair, 282
6.9 Instant Center of a General Cam–Pair Contact, 282
6.10 Centrodes, 283
6.11 The Kennedy–Aronhold Theorem, 285
6.12 Circle Diagram as a Strategy for Finding Instant Centers, 287
6.13 Using Instant Centers to Find Velocities: The Rotating–Radius Method, 287
6.14 Finding Instant Centers Using Geometric Constraint Programming, 295
References, 300
Problems, 300
7 Computational Analysis of Linkages 315
7.1 Introduction, 315
7.2 Position, Velocity, and Acceleration Representations, 316
7.3 Analytical Closure Equations for Four–Bar Linkages, 319
7.4 Analytical Equations for a Rigid Body after the Kinematic Properties of Two Points Are Known, 326
7.5 Analytical Equations for Slider–Crank Mechanisms, 329
7.6 Other Four–Bar Mechanisms with Revolute and Prismatic Joints, 338
7.7 Closure or Loop Equation Approach for Compound Mechanisms, 341
7.8 Closure Equations for Mechanisms with Higher Pairs, 347
7.9 Notational Differences: Vectors and Complex Numbers, 352
Problems, 354
8 Special Mechanisms 361
8.1 Special Planar Mechanisms, 361
8.2 Spherical Mechanisms, 374
8.3 Constant–Velocity Couplings, 381
8.4 Automotive Steering and Suspension Mechanisms, 382
8.5 Indexing Mechanisms, 387
References, 392
Problems, 392
9 Computational Analysis of Spatial Linkages 395
9.1 Spatial Mechanisms, 395
9.2 Robotic Mechanisms, 401
9.3 Direct Position Kinematics of Serial Chains, 403
9.4 Inverse Position Kinematics, 410
9.5 Rate Kinematics, 410
9.6 Closed–Loop Linkages, 416
9.7 Lower–Pair Joints, 418
9.8 Motion Platforms, 421
References, 423
Problems, 423
10 Profile Cam Design 431
10.1 Introduction, 431
10.2 Cam–Follower Systems, 432
10.3 Synthesis of Motion Programs, 434
10.4 Analysis of Different Types of Follower–Displacement Functions, 436
10.5 Determining the Cam Profile, 448
References, 482
Problems, 482
11 Spur Gears 489
11.1 Introduction, 489
11.2 Spur Gears, 490
11.3 Condition for Constant–Velocity Ratio, 491
11.4 Involutes, 492
11.5 Gear Terminology and Standards, 494
11.6 Contact Ratio, 497
11.7 Involutometry, 501
11.8 Internal Gears, 504
11.9 Gear Manufacturing, 505
11.10 Interference and Undercutting, 508
11.11 Nonstandard Gearing, 510
11.12 Cartesian Coordinates of an Involute Tooth Generated with a Rack, 514
References, 520
Problems, 520
12 Helical, Bevel, and Worm Gears 523
12.1 Helical Gears, 523
12.2 Worm Gears, 536
12.3 Involute Bevel Gears, 540
References, 547
Problems, 547
13 Gear Trains 549
13.1 General Gear Trains, 549
13.2 Direction of Rotation, 549
13.3 Simple Gear Trains, 550
13.4 Compound Gear Trains, 552
13.5 Planetary Gear Trains, 558
13.6 Harmonic Drive Speed Reducers, 570
References, 572
Problems, 572
14 Static Force Analysis of Mechanisms 579
14.1 Introduction, 579
14.2 Forces, Moments, and Couples, 580
14.3 Static Equilibrium, 581
14.4 Free–Body Diagrams, 582
14.5 Solution of Static Equilibrium Problems, 585
14.6 Transmission Angle in a Four–Bar Linkage, 587
14.7 Friction Considerations, 590
14.8 In–Plane and Out–of–Plane Force Systems, 597
14.9 Conservation of Energy and Power, 601
14.10 Virtual Work, 605
14.11 Gear Loads, 607
Problems, 613
15 Dynamic Force Analysis of Mechanisms 623
15.1 Introduction, 623
15.2 Problems Solvable Using Particle Kinetics, 625
15.3 Dynamic Equilibrium of Systems of Rigid Bodies, 633
15.4 Flywheels, 639
Problems, 641
16 Static and Dynamic Balancing 645
16.1 Introduction, 645
16.2 Single–Plane (Static) Balancing, 646
16.3 Multi–Plane (Dynamic) Balancing, 649
16.4 Balancing Reciprocating Masses, 654
16.5 Expressions for Inertial Forces, 661
16.6 Balancing Multi–Cylinder Machines, 663
16.7 Static Balancing of Mechanisms, 671
16.8 Reactionless Mechanisms, 675
References, 676
Problems, 676
17 Integration of Computer Controlled Actuators 685
17.1 Introduction, 685
17.2 Computer Control of the Linkage Motion, 686
17.3 The Basics of Feedback Control, 687
17.4 Actuator Selection and Types, 688
17.5 Hands–On Machine–Design Laboratory, 694
References, 696
Problems, 696
Index 699
Kenneth Waldron is Professor at the University of Technology, Sydney and Professor Emeritus of Stanford University. He has taught subjects in machine design and engineering mechanics over a career spanning more than forty years. He has also conducted research in kinematics of machinery, robotics, biomechanics and machine dynamics. He has received a number of awards including the American Society of Mechanical Engineers (ASME) Machine Design, Leonardo da Vinci and Ruth and Joel Spira Outstanding Design Educator Awards, and the Robotics Industries Association Joseph Engelberger Award.
Professor Waldron has served as the Technical Editor of the ASME Transactions Journal of Machine Design. He served two terms as President of IFToMM, the International Federation for the Promotion of Machine and Mechanism Science, as well as holding many offices within ASME.
Professor Waldron is excited by the many new developments in the field and the challenge of keeping this book up to date.
Gary Kinzel is an emeritus professor in the Department of Mechanical and Aerospace Engineering at The Ohio State University. He received his PhD from Purdue in 1973. After graduation, he worked for six years at Battelle and was a regular faculty member at Ohio State until he retired in 2011. His research was in design, education, and manufacturing. He has more than 150 research publications, has coauthored two books, has one patent, and has supervised to completion the research of more than one hundred graduate students. He taught courses in machine design, kinematics, stress analysis and form synthesis and received ten research and teaching awards, including the OSU Alumni Teaching Award, the ASME Ruth and Joel Spira Outstanding Design Educator Award, and the ASEE Ralph Coates Roe Award.
Sunil Agrawal has authored more than 175 archival journal papers, 225 refereed conference papers, 2 books, and 13 US patents. His work is well cited by the research community and can be viewed at Google Scholar at (scholar.google.com/citations). He has graduated 20 PhD and 25 MS students. Currently, there are 10 PhD students working under his guidance.
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