Machine Design /

By:

Paul H. Black-O.Eugene Adams Jr

Publication details: Mc Graw hillEdition: 1Description: 677 páginas Ilustraciones, Tablas y Gráficas 21 cm x 15 cmISBN:

0070850372

Contents:

Preface v 1 Introduction 1 2 Machine-design Computations 7 3 Stress and Deflection Analysis 16 4 Stress Concentration in Machine Members 59 5 Design Criteria 81 6 Residual Stresses 109 7 Engineering Materials 122 8 Mechanical Fabrication and Processes 144 9 Detachable Fastenings 179 10 Springs 206 11 Pressure Cylinders 234 12 Translation Screws 249 13 Shafting 263 14 Belt Drives and Hoists 273 15 Power-transmission Chains 300 16 Shaft Couplings 313 17 Clutches and Brakes 322 18 Spur and Parallel Helical Gears 345 19 Gears for Nonparallel Shafts 378 20 Surface Finish, Friction, and Wear 399. 21 Sliding-contact Bearings 419 22 Rolling-contact Bearings 459 23 Metal Fits and Tolerances 481 24 Vibration and Vibration Control 498 25 Motor Selection 514 APPENDIX I Abbreviations 523 II Elements of Sections 525 III Bending-moment and Deflection Formulas 526 IV Values of d³/16 and d³/32 527 V Properties of Materials 528 VI Tensile Strength and Yield Point versus Brinell Hardness for Steel 529 VII Endurance Limit versus Tensile Strength 530 VIII Yield Points for Steel 531 IX Hardness Numbers Conversion Chart 533 X Curves for Stress-concentration Factors 534 XI WR for Rotating Bodies 550 XII Method for Determining Lewis Factor 551 XIII-A Graphical Integration 552 ESTRAND XIII-B Shaft Deflection by Digital Computer 556 XIII-C Rupture-stress Diagram Curve for Elevated-temperature Systems 560 XIV Table of Wire Sizes 561 XV-A Decimal Equivalents of Fractions 562 XV-B Conversion Factors, U.S. and Metric Units 563 XVI Horsepower Ratings of USAS Standard Roller Chain, Single Strand 564 XVII Case Histories 573 Problems 589 Name Index 667 Subject Index 671

Summary: Mechanical engineering is the branch of engineering that is concerned with the conversion of energy and with the design of machines. The designer of machines is a versatile person, not a specialist, because he must have knowledge of science, "to know," and a knowledge of engineer-ing, "to produce." For instance, the design of the machinery for missile launching requires, in part, considerable knowledge of physics, mechanics, aerodynamics, performance of materials in high-intensity, short-time use, electronics, and safety requirements. The engineering design process begins with the awareness of a human need or want. In Fig. 1-1, this is indicated as the GOAL (1). The goal should be stated in words as clearly as possible at this stage of the design process. When the goal is stated in general terms, it is then necessary to develop more specific and quantitative information which determines the TASK SPECIFICATION (2) necessary to achieve the goal. The next step is the framing of a CONCEPT (3) with which the final form R. J. McCrory, The Design Method, Mech. Eng., May, 1963, p. 30.

Holdings
Cover image	Item type	Current library	Collection	Call number	Copy number	Status	Date due	Barcode
	Libro	CI Gustavo A. Madero 2 Sala General	Colección General	LCC	1	Available

Incluye Referencias Bibliográficas

Preface v

1 Introduction 1

2 Machine-design Computations 7

3 Stress and Deflection Analysis 16

4 Stress Concentration in Machine Members 59

5 Design Criteria

81

6 Residual Stresses

109

7 Engineering Materials 122

8 Mechanical Fabrication and Processes

144

9 Detachable Fastenings

179

10 Springs 206

11 Pressure Cylinders

234

12 Translation Screws

249

13 Shafting 263

14 Belt Drives and Hoists 273

15 Power-transmission Chains 300

16 Shaft Couplings 313

17 Clutches and Brakes 322

18 Spur and Parallel Helical Gears 345

19 Gears for Nonparallel Shafts 378

20 Surface Finish, Friction, and Wear 399.

21 Sliding-contact Bearings 419

22 Rolling-contact Bearings 459

23 Metal Fits and Tolerances 481

24 Vibration and Vibration Control 498

25 Motor Selection 514

APPENDIX I Abbreviations 523

II Elements of Sections 525

III Bending-moment and Deflection Formulas 526

IV Values of d³/16 and d³/32 527

V Properties of Materials 528

VI Tensile Strength and Yield Point versus Brinell Hardness for Steel 529

VII Endurance Limit versus Tensile Strength 530

VIII Yield Points for Steel 531

IX Hardness Numbers Conversion Chart 533

X Curves for Stress-concentration Factors 534

XI WR for Rotating Bodies 550

XII Method for Determining Lewis Factor 551

XIII-A Graphical Integration 552

ESTRAND

XIII-B Shaft Deflection by Digital Computer 556

XIII-C Rupture-stress Diagram Curve for Elevated-temperature Systems 560

XIV Table of Wire Sizes 561

XV-A Decimal Equivalents of Fractions 562

XV-B Conversion Factors, U.S. and Metric Units 563

XVI Horsepower Ratings of USAS Standard Roller Chain, Single Strand 564

XVII Case Histories 573

Problems 589

Name Index 667

Subject Index 671

Mechanical engineering is the branch of engineering that is concerned with the conversion of energy and with the design of machines. The designer of machines is a versatile person, not a specialist, because he must have knowledge of science, "to know," and a knowledge of engineer-ing, "to produce." For instance, the design of the machinery for missile launching requires, in part, considerable knowledge of physics, mechanics, aerodynamics, performance of materials in high-intensity, short-time use, electronics, and safety requirements.

The engineering design process begins with the awareness of a human need or want. In Fig. 1-1, this is indicated as the GOAL (1). The goal should be stated in words as clearly as possible at this stage of the design process. When the goal is stated in general terms, it is then necessary to develop more specific and quantitative information which determines the TASK SPECIFICATION (2) necessary to achieve the goal. The next step is the framing of a CONCEPT (3) with which the final form

R. J. McCrory, The Design Method, Mech. Eng., May, 1963, p. 30.

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