Assume that stresses vanish at and that is the radius of an undeformed cylindrical hole. Also stresses vanish at
. Relative displacement is prescribed on each face of the cut.
The edge dislocation problem is a plane strain problem. However, it is not axisymmetric.
It is probable that and are
symmetric about the plane. Similarly, it is probable that is symmetric about the plane.
These probable symmetries suggest that we can use a stress function
of the form
In cylindrical co-ordinates, the gudir beta Airy stress function leads to
and
Proceeding as usual, after plugging the value of in to
the biharmonic equation, we get
Applying the stress boundary conditions and neglecting terms containing
, we get
Next we compute the displacements, in a manner similar to that shown
for the cantilever beam problem. The displacement BCs are at
and at . We can use these
to determine and hence the stresses.
Rigid body motions are eliminated next by enforcing zero displacements
and rotations at and . The final expressions for the displacements can then be obtained.
Show that this stress function provides an approximate solution for a cantilevered triangular beam with a uniform traction applied to the upper surface. The angle is the angle subtended by the free edges of the triangle.
Using a cylindrical co-ordinate system, the stresses are
At , , , .
Therefore, and .
Hence, the shear traction BC is satisfied and the normal traction BC is satisfied if
At , , , .
Therefore, and . Both
these BCs are identically satisfied by the stresses (after substituting for ).
Hence, equilibrium is satisfied.
To satisfy compatibility, . Use Maple to verify that this is indeed true.
The remaining BC is the fixed displacement BC at the wall. We replace this BC with weak BCs at . The traction distribution on the surface
are and .
The statically equivalent forces and moments are
You can verify these using Maple.
Hence, the given stress function provides an approximate solution for the cantilevered beam (in the St. Venant sense).