Determination of Stress Intensity Factors in a Thick-walled Cylinder with Multiple Axial Cracks using the Energy Based Finite Element Method

Kiragu, Kenneth Karanja (2011) Determination of Stress Intensity Factors in a Thick-walled Cylinder with Multiple Axial Cracks using the Energy Based Finite Element Method. Masters thesis, Jomo Kenyatta University of Agriculture & Technology.

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Abstract

The stress intensity factors at the crack tip in an internally pressurized pressure vessel with multiple axial cracks were determined using the energy based modifed virtual crack closure technique. This technique was selected because it had been shown to give accurate results in determining stress intensity factors in at plates despite the fact that only one finite element analysis is required unlike in the virtual crack closure technique which requires two finite element analyses. Furthermore, the literature sources that were consulted did not show evidence of the use of this method in determining stress intensity factors in cylinders with multiple cracks. The Ansys10 Finite Element Analysis software was used to obtain the nodal forces at the crack tip and the nodal displacements in the vicinity of the crack tip. The finite element hoop, radial and axial stresses along the crack face were found to be very close to those obtained using the Lame's equations for an un-cracked cylinder except at the crack tip where a region of stress concentration exist. The stress intensity factors obtained using the modifed virtual crack closure technique for cylinders with a single crack were found to be very close to those in literature. However this was after assuming that the crack extends by 37.5% of the length of the finite element behind the crack tip. The same assumption was also found to be valid for cylinders with multiple cracks. The cylinders that were considered in this analysis were those with 1< n<100,0.1< a/t<0.7 and 1.5< Y<2.5. Most of the stress intensity factor values obtained for both single crack and multiple crack cases were in good agreement with those found in literature with the error being less than 5% in most cases. It is anticipated that this work will form a useful reference material for owners of such cylinders, manufacturers, designers, and developers of design codes. A lot of light has also been shed on how effectively this technique can be applied to obtain stress intensity factor values in both single and multiply cracked cylinders.

Item Type:	Thesis (Masters)
Subjects:	Q Science > QC Physics T Technology > T Technology (General) T Technology > TJ Mechanical engineering and machinery
Divisions:	Africana
Depositing User:	Geoffrey Obatsa
Date Deposited:	15 Jun 2017 10:29
Last Modified:	15 Jun 2017 10:29
URI:	http://thesisbank.jhia.ac.ke/id/eprint/1817

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