Coupled transient thermoelastic contact problems for axial cracks in hollow cylinders
Abstract
A coupled transient thermoelastic behavior of an axial-cracked hollow circular cylinder subjected to a sudden heating is investigated. It is shown that surface heating may induce the compressive thermal stress near the inner surface of the cylinder which in turn may force the cracked surfaces to close together. Assuming that the existence of the crack does not alter the temperature distribution, we can divide this problem into two parts and solve it by the principle of superposition. First, the temperature and transient thermal stress distributions along the axisymmetric surface of the imaginary cylinder without crack are obtained by finite element implicit time integration method. Secondly, the opposite sense of the stress distributions along the cracked surfaces, which is obtained previously, is treated as the traction boundary conditions; the contact length and contact pressure of the real cracked cylinder are obtained by modified elimination finite element scheme. Finally, we also obtained the normalized stress intensity factor for the crack tip of the cylinder. It is concluded that the effect due to thermoelastic coupling term on stress intensity factor becomes more important for higher coupling coefficient, and this coupling term also results in a small time lag in temperature, thermal stress, and stress intensity factor.
- Publication:
-
International Journal for Numerical Methods in Engineering
- Pub Date:
- June 1994
- DOI:
- 10.1002/nme.1620371207
- Bibcode:
- 1994IJNME..37.2109C
- Keywords:
-
- Circular Cylinders;
- Contact Loads;
- Coupling Coefficients;
- Cracks;
- Cylindrical Shells;
- Stress Intensity Factors;
- Thermal Stresses;
- Thermoelasticity;
- Compression Loads;
- Finite Element Method;
- Heating;
- Stress Distribution;
- Temperature Distribution;
- Traction;
- Structural Mechanics