Elastic, elastic-plastic and experimental stress analyses, and fatigue lifetime predictions are presented for thick cylinders containing multiple, axial holes within the wall. The holes are generally semi-elliptical (including semi-circular), and the cylinders are autofrettaged after introduction of the holes and are subsequently subjected to cyclic pressurization of the bore. Two potentially critical failure locations are identified; a fracture-mechanics based design methodology is proposed; elastic and elastic-plastic finite element (FE) analyses are undertaken. The elastic FE analysis predicts hoop stresses at the bore resulting from internal pressurization which are some 7 percent higher than those for the equivalent plain tube. For a given hole size and location and for nominal overstrains of 40 percent or greater, the residual compressive stress at the bore is reduced by approximately 15 percent below the value for a plain tube of the same radius ratio. Two experimental investigations are reported, one based upon X-ray diffraction, to measure residual stresses and stress gradients, and the other based upon radial tube slitting, to measure opening angle. They confirm most features of the residual stress profiles predicted from FE analysis with the exception of high compressive residual stresses and stress gradients immediately adjacent to the hole boundaries. Appropriate use of the residual stress information permits prediction of tube lifetimes for cracks emanating from the bore and from the hole. For the geometry and loading under consideration, the more critical location is predicted to be the hole boundary, the lifetime for failures originating from this point being some 60 percent of the lifetime for cracks originating at the bore.

1.
Endersby, S. N., Bond, T. J., and Parker A. P., 1997, “Stress Concentration, Stress Intensity and Fatigue Crack Growth Along Angled Evacuators of Pressurized, Autofrettaged Tubes,” in preparation for publication.
2.
Endersby, S. N., 1997, “Numerical Analysis of a Thick Cylinder in he Presence of Cracked Crossbore and Axial Holes,” Ph.D. thesis, University of Northumbria at Newcastle, Newcastle, England.
3.
Hill, R., 1950, The Mathematical Theory of Plasticity, Clarendon Press, Oxford, U.K.
4.
Lee, S. N., Neese, J., and Hyland, E., 1996, “Residual Stress in Swage Autofrettaged Cylinders with Semi-Circular Mid-Wall Coolant Channels,” US Army Armament Research, Development and Engineering Center Report, Watervliet, NY, in press.
5.
Milligan
R. V.
,
Koo
W. H.
, and
Davidson
T. E.
,
1966
, “
The Bauschinger Effect in a High-Strength Steel
,”
Journal of Basic Engineering
, Vol.
88
, pp.
480
488
.
6.
Nisitani
H.
,
1968
, “
Method of Approximate Calculation for Interference of Notch Effect and its Application
,”
Bulletin Japan Society of Mechanical Engineers
, Vol.
11
, p.
725
725
.
7.
Parker, A. P., Underwood, J. H., Throop, J. F., and Andrasic, C. P., 1983, “Stress Intensity and Fatigue Crack Growth in a Pressurized, Autofrettaged Thick Cylinder,” ASTM STP 791, American Society for Testing and Materials, pp. 1216–1237.
8.
Parker
A. P.
, and
Underwood
J. H.
,
1996
, “
Stress Intensity, Stress Concentration, and Fatigue Crack Growth Along Evacuator Holes of Pressurized, Autofrettaged Tubes
,”
ASME JOURNAL OF PRESSURE VESSEL TECHNOLOGY
, Vol.
118
, Aug., pp.
336
343
.
9.
Parker, A. P., and Underwood, J. H., 1996, “A Rapid Method for Determining Stress Concentrations for Autofrettaged Tubes Containing Multiple Axial Perforations Within the Wall,” US Army Armament Research, Development and Engineering Center Report, Watervliet, NY.
10.
Parker, A. P., and Underwood, J. H., 1997, “Some Methods of Representing Fatigue Lifetime as a Function of Stress Range and Initial Crack Length,” presented at 28th National Symposium on Fatigue and Fracture Mechanics, Saratoga Springs, NY, June 1996; to be published in Fatigue and Fracture Mechanics: 28th Vol. ASTM STP 1321, J. H. Underwood, B. D. MacDonald, and M. R. Mitchell, eds, American Society for Tersting and Materials
11.
Peterson, R. E., 1974, Stress Concentration Factors, Wiley, New York, NY.
12.
Schulz, K. J., 1942, “On the State of Stress in Perforated Strips and Plates,” Proc. Koninklyke Nederlandsche Akadamie van Wetenschappen (Netherlands Royal Academy of Science), Amsterdam, 6 papers; Vol. 45, pp. 233, 341, 457, 524; 1943–1945, Vols. 46–48, pp. 282, 292.
13.
Underwood
J. H.
, and
Parker
A. P.
,
1995
, “
Fatigue Life Analysis and Tests for Thick-Wall Cylinders Including Effects of Overstrain and Axial Grooves
,”
ASME JOURNAL OF PRESSURE VESSEL TECHNOLOGY
, Vol.
117
, pp.
222
226
.
This content is only available via PDF.
You do not currently have access to this content.