Beer And Johnston's Mechanics Of Materials Is The Uncontested Leader For The Teaching Of Solid Mechanics. Used By Thousands Of Students Around The Globe Since Publication, Mechanics Of Materials, Provides A Precise Presentation Of The Subject Illustrated With Numerous Engineering Examples That Students Both Understand And Relate To Theory And Application. The Tried And True Methodology For Presenting Material Gives Your Student The Best Opportunity To Succeed In This Course. From The Detailed Examples, To The Homework Problems, To The Carefully Developed Solutions Manual, You And Your Students Can Be Confident The Material Is Clearly Explained And Accurately Represented. Mcgraw-hill Is Proud To Offer Connect With The Seventh Edition Of Beer And Johnston's Mechanics Of Materials. This Innovative And Powerful System Helps Your Students Learn More Effectively And Gives You The Ability To Assign Homework Problems Simply And Easily. Problems Are Graded Automatically, And The Results Are Recorded Immediately. Track Individual Student Performance - By Question, Assignment, Or In Relation To The Class Overall With Detailed Grade Reports. Connectplus Provides Students With All The Advantages Of Connect, Plus 24/7 Access To An Ebook Beer And Johnston's Mechanics Of Materials, Seventh Edition, Includes The Power Of Mcgraw-hill's Learnsmart--a Proven Adaptive Learning System That Helps Students Learn Faster, Study More Efficiently, And Retain More Knowledge Through A Series Of Adaptive Questions. This Innovative Study Tool Pinpoints Concepts The Student Does Not Understand And Maps Out A Personalized Plan For Success -- Preface. 1. Introduction : Concept Of Stress -- 2. Stress And Strain : Axial Loading -- 3. Torsion -- 4. Pure Bending -- 5. Analysis And Design Of Beams For Bending -- 6. Shearing Stresses In Beams And Thin-walled Members -- 7. Transformations Of Stress And Strain -- 8. Principal Stresses Under A Given Loading -- 9. Deflection Of Beams -- 10. Columns -- 11. Energy Methods -- Appendices. Ferdinand P. Beer (late Of Lehigh University), E. Russell Johnston, Jr. (late Of University Of Connecticut), John T. Dewolf (university Of Connecticut), David F. Mazurek (united States Coast Guard Academy). Revised Edition Of: Mechanics Of Materials / Ferdinand Beer [and Others]. 2011. Includes Bibliographical References And Index.

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Mechanics of Materials, Seventh Edition

Ferdinand Pierre Beer, E. Russell Johnston, Jr., John T. DeWolf, David Mazurek

John T. DeWolf; David Mazurek; Ferdinand P. Beer; E. Russell Johnston, Jr.

Ferdinand P Beer; E. Russell Jr Johnston; John T DeWolf; David F Mazurek

Ferdinand P. Beer, et al.

McGraw-Hill School Education Group

Irwin Professional Publishing

Oracle Press

United States, United States of America

Seventh edition, New York, NY, 2015

7th Edition, Jan 24, 2014

lg3061058

producers:
Foxit PDF SDK DLL 3.1 - Foxit Software

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Cover 1
Title 2
Copyright 3
Contents 5
Preface 10
Guided Tour 14
List of Symbols 16
1 Introduction—Concept of Stress 20
1.1 Review of The Methods of Statics 21
1.2 Stresses in the Members of a Structure 24
1.3 Stress on an Oblique Plane Under Axial Loading 44
1.4 Stress Under General Loading Conditions; Components of Stress 45
1.5 Design Considerations 48
Review and Summary 61
2 Stress and Strain—Axial Loading 72
2.1 An Introduction to Stress and Strain 74
2.2 Statically Indeterminate Problems 95
2.3 Problems Involving Temperature Changes 99
2.4 Poisson's Ratio 111
2.5 Multiaxial Loading: Generalized Hooke's Law 112
*2.6 Dilatation and Bulk Modulus 114
2.7 Shearing Strain 116
2.8 Deformations Under Axial Loading—Relation Between E, v, and G 119
*2.9 Stress-Strain Relationships For Fiber-Reinforced Composite Materials 121
2.10 Stress and Strain Distribution Under Axial Loading: Saint-Venant's Principle 132
2.11 Stress Concentrations 134
2.12 Plastic Deformations 136
*2.13 Residual Stresses 140
Review and Summary 150
3 Torsion 164
3.1 Circular Shafts in Torsion 167
3.2 Angle of Twist in the Elastic Range 184
3.3 Statically Indeterminate Shafts 187
3.4 Design of Transmission Shafts 202
3.5 Stress Concentrations in Circular Shafts 204
*3.6 Plastic Deformations in Circular Shafts 212
*3.7 Circular Shafts Made of an Elastoplastic Material 213
*3.8 Residual Stresses in Circular Shafts 216
*3.9 Torsion of Noncircular Members 226
*3.10 Thin-Walled Hollow Shafts 228
Review and Summary 240
4 Pure Bending 254
4.1 Symmetric Members in Pure Bending 257
4.2 Stresses and Deformations in the Elastic Range 261
4.3 Deformations in a Transverse Cross Section 265
4.4 Members Made of Composite Materials 276
4.5 Stress Concentrations 280
*4.6 Plastic Deformations 290
4.7 Eccentric Axial Loading in a Plane of Symmetry 308
4.8 Unsymmetric Bending Analysis 319
4.9 General Case of Eccentric Axial Loading Analysis 324
*4.10 Curved Members 336
Review and Summary 351
5 Analysis and Design of Beams for Bending 362
5.1 Shear and Bending-Moment Diagrams 365
5.2 Relationships Between Load, Shear, and Bending Moment 377
5.3 Design of Prismatic Beams for Bending 388
*5.4 Singularity Functions Used to Determine Shear and Bending Moment 400
*5.5 Nonprismatic Beams 413
Review and Summary 424
6 Shearing Stresses in Beams and Thin-Walled Members 434
6.1 Horizontal Shearing Stress in Beams 437
*6.2 Distribution of Stresses in a Narrow Rectangular Beam 443
6.3 Longitudinal Shear on a Beam Element of Arbitrary Shape 454
6.4 Shearing Stresses in Thin-Walled Members 456
*6.5 Plastic Deformations 458
*6.6 Unsymmetric Loading of Thin-Walled Members and Shear Center 471
Review and Summary 484
7 Transformations of Stress and Strain 494
7.1 Transformation of Plane Stress 497
7.2 Mohr's Circle for Plane Stress 509
7.3 General State of Stress 520
7.4 Three-Dimensional Analysis of Stress 521
*7.5 Theories of Failure 524
7.6 Stresses in Thin-Walled Pressure Vessels 537
*7.7 Transformation of Plane Strain 546
*7.8 Three-Dimensional Analysis of Strain 551
*7.9 Measurements of Strain; Strain Rosette 555
Review and Summary 563
8 Principal Stresses Under a Given Loading 574
8.1 Principal Stresses in a Beam 576
8.2 Design of Transmission Shafts 579
8.3 Stresses Under Combined Loads 592
Review and Summary 608
9 Deflection of Beams 616
9.1 Deformation Under Transverse Loading 619
9.2 Statically Indeterminate Beams 628
*9.3 Singularity Functions to Determine Slope and Deflection 640
9.4 Method of Superposition 652
*9.5 Moment-Area Theorems 666
*9.6 Moment-Area Theorems Applied to Beams with Unsymmetric Loadings 681
Review and Summary 696
10 Columns 708
10.1 Stability of Structures 709
*10.2 Eccentric Loading and the Secant Formula 726
10.3 Centric Load Design 739
10.4 Eccentric Load Design 756
Review and Summary 767
11 Energy Methods 776
11.1 Strain Energy 777
11.2 Elastic Strain Energy 780
11.3 Strain Energy for a General State of Stress 787
11.4 Impact Loads 801
11.5 Single Loads 805
*11.6 Multiple Loads 819
*11.7 Castigliano's Theorem 821
*11.8 Deflections by Castigliano's Theorem 823
*11.9 Statically Indeterminate Structures 827
Review and Summary 840
Appendices 850
A: Moments of Areas 851
B: Typical Properties of Selected Materials Used in Engineering 862
C: Properties of Rolled-Steel Shapes 866
D: Beam Deflections and Slopes 878
E: Fundamentals of Engineering Examination 879
Answers to Problems 880
Photo Credits 891
Index 892
A 892
B 892
C 892
D 893
E 893
F 893
G 894
H 894
I 894
L 894
M 894
N 894
O 895
P 895
R 895
S 895
T 897
U 897
V 897
W 897
Y 897

Suitable for the teaching of solid mechanics, this book provides a precise presentation of the subject illustrated with numerous engineering examples that students both understand and relate to theory and application. It explains topics ranging from detailed examples, to the homework problems, to the carefully developed solutions manual.

Provides a presentation of the subject illustrated with numerous engineering examples that students both understand and relate to theory and application. This book includes the tried and true methodology for presenting material that gives the students an opportunity to succeed in the course.

2021-07-21