TORSIONAL VIBRATION OF AN ELASTIC SOLID CONTAINING A PENNY-SHAPED CRACK.
Abstract
The axisymmetric wave equation is solved for the problem of torsional elastic waves impinging on a penny-shaped crack the periphery of which is assumed to be infinitely sharp. Using Hankel transforms, the problem is reduced to the solution of two simultaneous integral equations of the Fredholm type. The proposed method of solution permits an examination of the complete scattered-wave field at points both near to and far from the penny-shaped plane of discontinuity. In elastodynamics, however it is the near-field stress solution that is of chief interest. To this end, the singular nature of the local dynamic stress field is determined in elementary closed form, while the magnitude of this stress field, which can be adequately described by a singularity parameter, is calculated numerically. A knowledge of this parameter is essential to a clear understanding of the propagation of cracks through structural components undergoing torsional oscillations, since its value has been known to control the stability or instability behavior of cracks. (Author)
Document Details
- Document Type
- Technical Report
- Publication Date
- Oct 01, 1969
- Accession Number
- AD0698839
Entities
People
- George C. Sih
- J. F. Loeber
Organizations
- Lehigh University