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    Mechanics of materials / Ferdinand P. Beer [and others].

    • Title:Mechanics of materials / Ferdinand P. Beer [and others].
    •    
    • Other Contributors/Collections:Beer, Ferdinand P. (Ferdinand Pierre), 1915-2003, author.
    • Published/Created:New York : McGraw-Hill, ©2012.
    • Holdings

       
    • Library of Congress Subjects:Strength of materials--Textbooks.
    • Edition:6th ed.
    • Description:xix, 758, [52] pages : color illustrations ; 26 cm
    • Notes:Previous edition: 2009.
      Includes bibliographical references and index.
    • ISBN:9780073380285 (alk. paper)
      0073380288 (alk. paper)
    • Contents:Machine generated contents note: 1. Introduction
      Concept of Stress
      1.1. Introduction
      1.2.A Short Review of the Methods of Statics
      1.3. Stresses in the Members of a Structure
      1.4. Analysis and Design
      1.5. Axial Loading; Normal Stress
      1.6. Shearing Stress
      1.7. Bearing Stress in Connections
      1.8. Application to the Analysis and Design of Simple Structures
      1.9. Method of Problem Solution
      1.10. Numerical Accuracy
      1.11. Stress on an Oblique Plane under Axial Loading
      1.12. Stress under General Loading Conditions; Components of Stress
      1.13. Design Considerations
      Review and Summary for Chapter 1
      2. Stress and Strain
      Axial Loading
      2.1. Introduction
      2.2. Normal Strain under Axial Loading
      2.3. Stress-Strain Diagram
      2.4. True Stress and True Strain
      2.5. Hooke's Law; Modulus of Elasticity
      2.6. Elastic versus Plastic Behavior of a Material
      2.7. Repeated Loadings; Fatigue
      2.8. Deformations of Members under Axial Loading
      2.9. Statically Indeterminate Problems
      2.10. Problems Involving Temperature Changes
      2.11. Poisson's Ratio
      2.12. Multiaxial Loading; Generalized Hooke's Law
      2.13. Dilatation; Bulk Modulus
      2.14. Shearing Strain
      2.15. Further Discussion of Deformations under Axial Loading; Relation among E, v, and G
      2.16. Stress-Strain Relationships for Fiber-Reinforced Composite Materials
      2.17. Stress and Strain Distribution under Axial Loading; Saint-Venant's Principle
      2.18. Stress Concentrations
      2.19. Plastic Deformations
      2.20. Residual Stresses
      Review and Summary for Chapter 2
      3. Torsion
      3.1. Introduction
      3.2. Preliminary Discussion of the Stresses in a Shaft
      3.3. Deformations in a Circular Shaft
      3.4. Stresses in the Elastic Range
      3.5. Angle of Twist in the Elastic Range
      3.6. Statically Indeterminate Shafts
      3.7. Design of Transmission Shafts
      3.8. Stress Concentrations in Circular Shafts
      3.9. Plastic Deformations in Circular Shafts
      3.10. Circular Shafts Made of an Elastoplastic Material
      3.11. Residual Stresses in Circular Shafts
      3.12. Torsion of Noncircular Members
      3.13. Thin-Walled Hollow Shafts
      Review and Summary for Chapter 3
      4. Pyre Bending
      4.1. Introduction
      4.2. Symmetric Member in Pure Bending
      4.3. Deformations in a Symmetric Member in Pure Bending
      4.4. Stresses and Deformations in the Elastic Range
      4.5. Deformations in a Transverse Cross Section
      4.6. Bending of Members Made of Several Materials
      4.7. Stress Concentrations
      4.8. Plastic Deformations
      4.9. Members Made of an Elastoplastic Material
      4.10. Plastic Deformations of Members with a Single Plane of Symmetry
      4.11. Residual Stresses
      4.12. Eccentric Axial Loading in a Plane of Symmetry
      4.13. Unsymmetric Bending
      4.14. General Case of Eccentric Axial Loading
      4.15. Bending of Curved Members
      Review and Summary for Chapter 4
      5. Analysis and Design of Beams for Bending
      5.1. Introduction
      5.2. Shear and Bending-Moment Diagrams
      5.3. Relations among Load, Shear, and Bending Moment
      5.4. Design of Prismatic Beams for Bending
      5.5. Using Singularity Functions to Determine Shear and Bending Moment in a Beam
      5.6. Nonprismatic Beams
      Review and Summary for Chapter 5
      6. Shearing Stresses In Beams and Thin-Walled Members
      6.1. Introduction
      6.2. Shear on the Horizontal Face of a Beam Element
      6.3. Determination of the Shearing Stresses in a Beam
      6.4. Shearing Stresses & tau;xy in Common Types of Beams
      6.5. Further Discussion of the Distribution of Stresses in a Narrow Rectangular Beam
      6.6. Longitudinal Shear on a Beam Element of Arbitrary Shape
      6.7. Shearing Stresses in Thin-Walled Members
      6.8. Plastic Deformations
      6.9. Unsymmetric Loading of Thin-Walled Members; Shear Center
      Review and Summary For Chapter 6
      7. Transformations of Stress and Strain
      7.1. Introduction
      7.2. Transformation of Plane Stress
      7.3. Principal Stresses'. Maximum Shearing Stress
      7.4. Mohr's Circle for Plane Stress
      7.5. General State of Stress
      7.6. Application of Mohr's Circle to the Three-Dimensional Analysis of Stress
      7.7. Yield Criteria for Ductile Materials under Plane Stress
      7.8. Fracture Criteria for Brittle Materials under Plane Stress
      7.9. Stresses in Thin-Walled Pressure Vessels
      7.10. Transformation of Plane Strain
      7.11. Mohr's Circle for Plane Strain
      7.12. Three-Dimensional Analysis of Strain
      7.13. Measurements of Strain; Strain Rosette
      Review and Summary for Chapter 7
      8. Principal Stresses under a Given Loading
      8.1. Introduction
      8.2. Principal Stresses in a Beam
      8.3. Design of Transmission Shafts
      8.4. Stresses under Combined Loadings
      Review and Summary for Chapter 8
      9. Deflection of Beams
      9.1. Introduction
      9.2. Deformation of a Beam under Transverse Loading
      9.3. Equation of the Elastic Curve
      9.4. Direct Determination of the Elastic Curve from the Load Distribution
      9.5. Statically Indeterminate Beams
      9.6. Using Singularity Functions to Determine the Slope and Deflection of a Beam
      9.7. Method of Superposition
      9.8. Application of Superposition to Statically Indeterminate Beams
      9.9. Moment-Area Theorems
      9.10. Application to Cantilever Beams and Beams with Symmetric Loadings
      9.11. Bending-Moment Diagrams by Parts
      9.12. Application of Moment-Area Theorems to Beams with Unsymmetric Loadings
      9.13. Maximum Deflection
      9.14. Use of Moment-Area Theorems with Statically Indeterminate Beams
      Review and Summary for Chapter 9
      10. Columns
      10.1. Introduction
      10.2. Stability of Structures
      10.3. Euler's Formula for Pin-Ended Columns
      10.4. Extension of Euler's Formula to Columns with Other End Conditions
      10.5. Eccentric Loading; the Secant Formula
      10.6. Design of Columns under a Centric Load
      10.7. Design of Columns under an Eccentric Load
      Review and Summary for Chapter 10
      11. Energy Methods
      11.1. Introduction
      11.2. Strain Energy
      11.3. Strain-Energy Density
      11.4. Elastic Strain Energy for Normal Stresses
      11.5. Elastic Strain Energy for Shearing Stresses
      11.6. Strain Energy for a General State of Stress
      11.7. Impact Loading
      11.8. Design for Impact Loads
      11.9. Work and Energy under a Single Load
      11.10. Deflection under a Single Load by the Work-Energy Method
      11.11. Work and Energy under Several Loads
      11.12. Castigliano's Theorem
      11.13. Deflections by Castigliano's Theorem
      11.14. Statically Indeterminate Structures
      Review and Summary for Chapter 11
      Appendices
      A. Moments of Areas
      B. Typical Properties of Selected Materials Used in Engineering
      C. Properties of Rolled-Steel Shapes
      D. Beam Deflections and Slopes
      E. Fundamentals of Engineering Examination.
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