Useful Links
Engineering
Mechanical Engineering
Machine Design and Mechanisms
1. Introduction to Machine Design
2. Fundamentals of Kinematics
3. Kinematic Analysis of Mechanisms
4. Design and Analysis of Specific Mechanisms
5. Dynamics of Machinery
6. Vibrations in Machinery
7. Stress, Strain, and Deflection Analysis
8. Failure Prevention
9. Design of Mechanical Elements
Stress, Strain, and Deflection Analysis
Review of Mechanics of Materials
Stress and Strain
Normal Stress and Strain
Shear Stress and Strain
Stress-Strain Diagrams
Elastic and Plastic Behavior
Axial Loading
Uniform Stress Distribution
Stress Concentrations
Thermal Stresses
Torsion
Torsional Stress in Circular Shafts
Angle of Twist
Power Transmission
Torsion of Non-circular Sections
Bending in Beams
Bending Stress Distribution
Neutral Axis
Section Modulus
Moment of Inertia
Shear Stresses in Beams
Shear Stress Distribution
Shear Flow
Shear Center
Combined Stresses
Biaxial Stress States
Principal Stresses
Calculation Methods
Maximum Shear Stress
Mohr's Circle
Construction and Interpretation
Triaxial Stress States
Three-dimensional Mohr's Circles
Stress Concentration
Geometric Discontinuities
Holes
Notches
Grooves
Fillets
Stress Concentration Factors
Theoretical Factors
Charts and Empirical Data
Fatigue Considerations
Methods to Reduce Stress Concentration
Design Modifications
Material Selection
Deflection and Stiffness
Beam Deflection
Double Integration Method
Macaulay's Method
Moment-Area Method
Superposition Principle
Conjugate Beam Method
Torsional Deflection
Circular Shafts
Thin-walled Sections
Energy Methods
Castigliano's Theorem
Virtual Work Method
Unit Load Method
Statically Indeterminate Systems
Method of Consistent Deformations
Three-moment Equation
Previous
6. Vibrations in Machinery
Go to top
Next
8. Failure Prevention