Solution of the Contact Problem of a Rigid Conical Frustum Indenting a Transversely Isotropic Elastic Half Space

Abstract

The contact problem of a rigid conical frustum indenting a transversely isotropic elastic halfspace is analytically solved using a displacement method and a stress method, respectively. The displacement method makes use of two potential functions, while the stress method employs one potential function. In both the methods, Hankel's transforms are applied to construct potential functions, and the associated dual integral equations of Titchmarsh's type are analytically solved. The solution obtained using each method gives analytical expressions of the stress and displacement components on the surface of the halfspace. These two sets of expressions are seen to be equivalent, thereby confirming the uniqueness of the elasticity solution. The newly derived solution is reduced to the closedform solution for the contact problem of a conical punch indenting a transversely isotropic elastic halfspace. In addition, the closedform solution for the problem of a flatend cylindrical indenter punching a transversely isotropic elastic halfspace is obtained as a special case. To illustrate the new solution, numerical results are provided for different halfspace materials and punch parameters and are compared to those based on the two specific solutions for the conical and cylindrical indentation problems. It is found that the indentation deformation increases with the decrease of the cone angle of the frustum indenter. Moreover, the largest deformation in the halfspace is seen to be induced by a conical indenter, followed by a cylindrical indenter and then by a frustum indenter. In addition, the axial force–indentation depth relation is shown to be linear for the frustum indentation, which is similar to that exhibited by both the conical and cylindrical indentations—two limiting cases of the former.