The Mathematical Theory of Elasticity and The Mathematical Theory of Plasticity
J. N. Goodier, P. G. Hodge, Jr.
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Elasticity and Plasticity
The Mathematical Theory of Elasticity and The Mathematical Theory of Plasticity
J. N. Goodier, P. G. Hodge, Jr.
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This volume comprises two classic essays on the mathematical theories of elasticity and plasticity by authorities in this area of engineering science. Undergraduate and graduate students in engineering as well as professional engineers will find these works excellent texts and references. The Mathematical Theory of Elasticity covers plane stress and plane strain in the isotropic medium, holes and fillets of assignable shapes, approximate conformal mapping, reinforcement of holes, mixed boundary value problems, the third fundamental problem in two dimensions, eigensolutions for plane and axisymmetric states, anisotropic elasticity, thermal stress, elastic waves induced by thermal shock, three-dimensional contact problems, wave propagation, traveling loads and sources of disturbance, diffraction, and pulse propagation. The Mathematical Theory of Plasticity explores the theory of perfectly plastic solids, the theory of strain-hardening plastic solids, piecewise linear plasticity, minimum principles of plasticity, bending of a circular plate, and other problems.
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If more than one component of stress is acting simultaneously, the description of material behavior becomes much more complex. In order to keep the ensuing discussion as general as possible, we shall follow Prager [1.1] and introduce generalized stress and strain variables. The stress variables will be denoted by Q1, Q2, …, Qn, where n is the number of variables needed to specify the stress state. For example, in a beam subjected to bending, the only variable would be Q1 = M. In the torsion of a cylindrical rod we could set Q1 = τxz, Q2 = τyz. Alternatively, it might be convenient to use dimensionless variables Q1 = τxz/k, Q2 = τyz/k, where k is the yield stress in pure shear. The general three-dimensional stress state is included as a special case by setting Q1 = σx, Q2 = σy, Q3 = σz, Q4 = τyz, Q5 = τzx, Q6 = τxy.
The choice of stress variables above is, to some extent, arbitrary. Thus in the torsion problem one might prefer to set Q1 = τrz, Q2 = τθz. Or, more profoundly, one might wish a more exact solution to the beam problem and set Q1 = σx, Q2 = σy, Q3 = τxy. However, once the stress variables have been chosen, the strain variables qi are determined to within a single multiplicative constant by a requirement that the internal energy be of the form *
Thus, in the bending problem if Q1 = M, then q1 = κ. In the bending of circular plates which will be considered in more detail in Chapter 5, it is convenient to define
where Y is the tensile yield stress, 2h the plate thickness, and a the radius. In this case all stresses and strains are dimensionless and the internal energy per unit area is
in agreement with (1.1).
A second example is provided by the radially symmetric deformation of axially symmetric shells. Let Mθ and Μϕ be the moments per unit length, and Nθ and Νϕ the corresponding direct stresses. We then define
as the stress variables, and
Here again it is readily verified that
In view of the defining relationship between stresses and strains, only quantities which contribute to the internal energy can be taken as generalized variables. Thus, in the usual beam theory the shear force S must be treated as a reaction, not as a stress, since shear deformations are neglected.
For linear elasticity, the generalized stresses and strains will be linear functions of the component stresses and strains respectively. It follows that they will be linearly related to each other, so that
The values of Bij can always be computed in terms of Young’s modulus and Poisson’s ratio (or more generally in terms of the anisotropic elastic constants). Thus, for example, in the symmetric bending of circular plates, the elastic moments and curvatures are related by *
Solution of these equations for the curvatures, and substitution of the values from (1.2) leads to
Therefore, in this case
In this example it is obvious that Bij is symmetric. Also, since
, it is positive definite. It can be shown that these two properties are generally true, and use will be made of this fact in Chapter 4.
A basic assumption of plasticity theory is that the total strain rate can always be decomposed into an elastic part and a plastic part. Thus, if
denotes the plastic strain rate, it follows from (1.4) that
where dots indicate differentiation with respect to time. In much of the theory to follow we shall consider only the effect of the plastic strains pi. If this is done, the results will be immediately meaningful only for a rigid-plastic material (Fig. 1e and f). However, by means of (1.8), any such results can be generalized to include elastic-plastic materials.
2.Yield condition and flow law
In the Introduction we showed that two current yield stress values were necessary to specify the elastic range of a one-dimensional stress system at any instant. This was because we had a choice of two directions of loa...
