Applied Electromagnetics Using QuickField and MATLAB

Chapter 12 - Stress Analysis: Stress and Strain

In This Chapter

  • Stress and Strain
  • Beams
  • Stress Analysis in QuickField
  • Coupled Thermal and Stress Analysis
  • Stress Analysis with Electric Forces
  • Stress Analysis with Magnetic Forces
  • Coupled Electric Current, Thermal and Stress Analysis

In 1807 Thomas Young developed a theory for characterizing material bodies deformed by external forces. Two decades later, C. Navier established a mathematical form of Young’s theory in 1826. In one dimension, the stress σ is the force applied to a body divided by its area σ = F/A. Strain ε, a dimensionless factor, is the change in length ΔL divided by the original length L0 or
ε
= ΔL/L0. Young’s modulus, often referred to as the elastic modulus, is defined as the ratio of the stress divided by the strain

for a body in tension or compression. Young's modulus is an intrinsic property of a given material that is independent of its shape. The units of E are force divided by area N/m2or Pa. The relation between Young's modulus and Hooke's law F = kΔL relating the linear stretch of a body with force constant k under a given load for sufficiently small ΔL may be obtained considering

Solving for F gives

so that the familiar spring constant is Young's modulus times the cross-sectional area divided by the initial length.

Shear Modulus

The shear modulus S is defined by the shear stress σ = F/A divided by the shear strain ε= γ in radians

The sheer modulus is roughly two to three times smaller than Young's modulus in most materials.

Young's modulus is given for various engineering materials in Appendix 4 and for biological tissues in Appendix 5.

Poisson's Ratio

Material bodies pulled in one direction generally tend to contract in the orthogonal direction as shown in Figure 12.1. The negative transverse contraction strain perpendicular to the load divided by the axial, or extension strain in the direction of the load gives Poisson's ratio

Most materials have v values between 0 - 0.5 with many metals v = 0.27 - 0.35.

FIGURE 12.1 Transverse and axial strains of a bar stretched in the vertical direction illustrating Poisson's ratio.

 

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