Abstract
The steady-state solution for an elastic half-plane under a moving frictionless smooth indenter of arbitrary shape is derived based on the corresponding transient problem and on a condition concerning energy fluxes. Resulting stresses and displacements are found explicitly starting from their expressions in terms of a single analytical function. This solution incorporates all speed ranges, including the super-Rayleigh subsonic and intersonic speed regimes, which received no final description to date. Next, under a similar formulation the wedging of an elastic plane is considered for a finite wedge moving at a distance from the crack tip. Finally, we solve the problem for such a wedge moving along the interface of two elastic half-planes compressed together. Considering these problems we determine the driving forces caused by the main underlying factors: the stress field singular points on the contact area (super-Rayleigh subsonic speed regime), the wave radiation (intersonic and supersonic regimes) and the fracture resistance (wedging problem). In addition to the sub-Rayleigh speed regime, where the sliding contact itself gives no contribution to the driving forces, there exists a sharp decrease in the resistance in the vicinity of the longitudinal wave speed with zero limit at this speed. (C) 2012 Elsevier Ltd. All rights reserved.
Original language | English |
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Pages (from-to) | 1883-1906 |
Number of pages | 24 |
Journal | Journal of the Mechanics and Physics of Solids |
Volume | 60 |
Issue number | 11 |
Early online date | 09 Jul 2012 |
DOIs | |
Publication status | Published - Nov 2012 |
Keywords
- Moving indentation
- MEDIA
- GROWTH
- INTERSONIC CRACK-PROPAGATION
- Contact mechanics
- Analytic functions
- Wedging
- Dynamics