Peterson’s Stress Concentration Factors

Walter D. Pilkey is the Frederick Morse Professor in the Department of Mechanical and Aerospace Engineering at the University of Virginia and a leading authority in the areas of stress and strain in mechanical and civil engineering. He is the author of Formulas for Stress, Strain, and Structural Matrices, Second Edition and Analysis and Design of Elastic Beams, also available from Wiley.Deborah F. Pilkey is an Engineer/Scientist in the Loads & Environments Department at ATK Launch Systems in Utah. She has been involved with structures technology, loads, dynamics, and production stress analysis of the Space Shuttle's main engines and their solid rocket motors.

Die zweite Auflage dieses Referenzwerkes liefert eine erweiterte computergrafische Darstellung der Thematik sowie eine Diskette, die anpaßbare Formeln und Faktoren enthält. Die Anwendungen sind vielfältig: Kernreaktoren, U-Boote, Luft- und Raumfahrzeuge, Tunnel und Turbinen. Ein aktueller Klassiker seiner Disziplin.

Peterson s Stress Concentration Factors establishes and maintains a system of data classification for all of the applications of stress and strain analysis and expedites their synthesis into CAD applications. Substantially revised and completely updated, this book presents stress concentration factors both graphically and with formulas.

Index to the Stress Concentration Factors.

Preface for the Third Edition.

Preface for the Second Edition.

1. Definitions and Design Relations.

1.1 Notation.

1.2 Stress Concentration.

1.3 Stress Concentration as a Two-Dimensional Problem.

1.4 Stress Concentration as a Three-Dimensional Problem.

1.5 Plane and Axisymmetric Problems.

1.6 Local and Nonlocal Stress Concentration.

1.7 Multiple Stress Concentration.

1.8 Theories of Strength and Failure.

1.9 Notch Sensitivity.

1.10 Design Relations For Static Stress.

1.11 Design Relations for Alternating Stress.

1.12 Design Relations for Combined Alternating and Static Stresses.

1.13 Limited Number of Cycles of Alternating Stress.

1.14 Stress Concentration Factors and Stress Intensity Factors.

References

2. Notches and Grooves.

2.1 Notation.

2.2 Stress Concentration Factors.

2.3 Notches in Tension.

2.4 Depressions in Tension.

2.5 Grooves in Tension.

2.6 Bending of Thin Beams with Notches.

2.7 Bending of Plates with Notches.

2.8 Bending of Solids with Grooves.

2.9 Direct Shear and Torsion.

2.10 Test Specimen Design for Maximum Kt for a Given r D or r H 76.

References.

Charts.

3. Shoulder Fillets.

3.1 Notation.

3.2 Stress Concentration Factors.

3.3 Tension (Axial Loading).

3.4 Bending.

3.5 Torsion.

3.6 Methods of Reducing Stress Concentration at a Shoulder.

References.

Charts.

4. Holes.

4.1 Notation.

4.2 Stress Concentration Factors.

4.3 Circular Holes with In-Plane Stresses.

4.4 Elliptical Holes in Tension.

4.5 Various Configurations with In-Plane Stresses.

4.6 Holes in Thick Elements.

4.7 Orthotropic Thin Members.

4.8 Bending.

4.9 Shear and Torsion.

5. Miscellaneous Design Elements.

5.1 Notation.

5.2 Shaft with Keyseat.

5.3 Splined Shaft in Torsion.

5.4 Gear Teeth.

5.5 Press- or Shrink-Fitted Members.

5.6 Bolt and Nut.

5.7 Bolt Head,Turbine-Blade, orCompressor-Blade Fastening (T-Head).

5.8 Lug Joint.

5.8.1 Lugs with h d 0.5.

5.8.2 Lugs with h d 0.5.

5.9 Curved Bar.

5.10 Helical Spring.

5.10.1 Round or Square Wire Compression or Tension Spring.

5.10.2 Rectangular Wire Compression or Tension Spring.

5.10.3 Helical Torsion Spring.

5.11 Crankshaft.

5.12 Crane Hook.

5.13 U-Shaped Member.

5.14 Angle and Box Sections.

5.15 Cylindrical Pressure Vessel with Torispherical Ends.

5.16 Tubular Joints.

References.

Charts.

6. Stress Concentration Analysis and Design.

6.1 Computational Methods.

6.2 Finite Element Analysis.

6.3 Design Sensitivity Analysis.
6.4 Design Modification.

Index.

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