An alternating method, in conjunction with the finite element method and a newly developed analytical solution for an elliptical crack in an infinite solid, is used to determine stress intensity factors for semi-elliptical surface flaws in cylindrical pressure vessels. The present finite element alternating method leads to a very inexpensive procedure for routine evaluation of accurate stress intensity factors for flawed pressure vessels. The problems considered in the present paper are: (i) an outer semi-elliptical surface crack in a thick cylinder, and (ii) inner semi-elliptical surface cracks in a thin cylinder which were recommended for analysis by the ASME Boiler and Pressure Vessel Code (Section III, App. G, 1977). For each crack geometry of an inner surface crack, seven independent loadings, such as internal pressure loading on the cylinder surface and polynomial pressure loadings from constant to fifth order on the crack surface, are considered. From the analyses of these loadings, the magnification factors for the internal pressure loading and the polynomial influence functions for the polynomial crack surface loadings are determined. By the method of superposition, the magnification factors for internally pressurized cylinders are rederived by using the polynomial influence functions to check the internal consistency of the present analysis. These values agree excellently with the magnification factors obtained directly. The present results are also compared with the results available in literature.
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November 1982
Research Papers
Analysis of Surface Flaw in Pressure Vessels by a New 3-Dimensional Alternating Method
T. Nishioka,
T. Nishioka
Center for the Advancement of Computational Mechanics, Georgia Institute of Technology, School of Civil Engineering, Atlanta, Ga. 30332
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S. N. Atluri
S. N. Atluri
Center for the Advancement of Computational Mechanics, Georgia Institute of Technology, School of Civil Engineering, Atlanta, Ga. 30332
Search for other works by this author on:
T. Nishioka
Center for the Advancement of Computational Mechanics, Georgia Institute of Technology, School of Civil Engineering, Atlanta, Ga. 30332
S. N. Atluri
Center for the Advancement of Computational Mechanics, Georgia Institute of Technology, School of Civil Engineering, Atlanta, Ga. 30332
J. Pressure Vessel Technol. Nov 1982, 104(4): 299-307 (9 pages)
Published Online: November 1, 1982
Article history
Received:
August 10, 1982
Online:
November 5, 2009
Citation
Nishioka, T., and Atluri, S. N. (November 1, 1982). "Analysis of Surface Flaw in Pressure Vessels by a New 3-Dimensional Alternating Method." ASME. J. Pressure Vessel Technol. November 1982; 104(4): 299–307. https://doi.org/10.1115/1.3264221
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