An attempt was made to define a new crack interaction criterion for pressurized cylinders with two co-planar surface cracks. Elastic-plastic finite element method with line spring concept (line spring element method) was used to verify the validity of the new interaction criterion and to establish the relative conservatism built into various codes/standards. The crack interaction criteria of two co-planar surface cracks as defined by ASME Section XI and BS PD6493 were studied and a new interaction criterion which accounts for crack shape and load factor was introduced. The basic idea behind the crack interaction criteria for co-planar surface cracks was the plastic zone and stress interaction near crack tips. To verify the new crack interaction criterion, comparisons of J-integral values were made for various crack sizes with different distances between cracks and loading conditions. Based upon these comparisons, the new crack interaction criteria, comparing a physical distance, s, to a characteristic distance d=(σ/σy)2(c1Q1 + c2Q2), proved to be a reasonable parameter for indication of the crack driving force interaction for co-planar cracks. The characteristic distance also represents a rigorous measure of an equivalent crack driving force for interacting cracks.

Issue Section:
Research Papers
Topics:
Fracture (Materials), Pipes, Pressure vessels, Surface cracks, Springs, Stress, Cylinders, Finite element methods, Shapes
1.
ASME Boiler and Pressure Vessel Code, 1983, Section XI, IWA-3000.
2.
British Standard PD6493, 1991, ”Guidance on Some Methods for the Derivation of Acceptable Levels for Defects in Fusion Welded Joints.“
3.
Murakami
Y.
, and
Nemat-Nasser
S.
,
1982
, “
Interacting Dissimilar Semielliptical Surface Flaws Under Tension and Bending
,”
Engineering Fracture Mechanics
, Vol.
16
, pp.
373
386
.
4.
O’Donoghue
,
Nishioka
T.
, and
Atluri
S. N.
,
1986
, “
Analysis of Interaction Behavior of Surface Flaws in Pressure Vessels
,”
ASME Journal of Pressure Vessel Technology
, Vol.
108
, pp.
24
32
.
5.
O’Donoghue
P. E.
,
Nishioka
T.
, and
Atluri
S. N.
,
1984
, “
Multiple Surface Cracks in Pressure Vessels
,”
Engineering Fracture Mechanics
, Vol.
20
, pp.
545
560
.
6.
Nishioka, T., Atluri, S. N., and Rhee, C. H., 1986, Alternating Method for Elliptical Cracks in Pressure Vessels and Pipes, Proceedings, OMAE.
7.
Rubinstein
A. A.
,
1985
, “
Macrocrack Interaction with Semi-Infinite Microcrack Array
,”
International Journal of Fracture
, Vol.
27
, pp.
113
119
.
8.
Soboyejo
W. O.
, and
Knott
J. F.
,
1991
, “
The Propagation of Non-Coplanar Semi-Elliptical Fatigue Cracks
,”
Fatigue Fracture Engineering Material Structures
, Vol.
14
, pp.
37
49
.
9.
Liu
X.
, and
Erdogan
F.
,
1986
, “
The Crack-Inclusion Interaction Problem
,”
Engineering Fracture Mechanics
, Vol.
23
, pp.
821
832
.
10.
Grandt, A. F., Thakker, A. B., and Tritsch, D. E., 1986, “An Experimental and Numerical Investigation of the Growth and Coalescene of Multiple Fatigue Cracks at Notches,” ASTM STP 905, pp. 239–252.
11.
Rice
J. R.
, and
Levy
N.
,
1972
, “
The Part-through Surface Crack in an Elastic Plate
,”
ASME Journal of Applied Mechanics
, Vol.
39
, pp.
185
194
.
12.
Parks
D. M.
, and
White
C. S.
, “
Elastic-Plastic Line Spring Finite Element for Surface Cracked Plates and Shells
,”
ASME Journal of Pressure Vessel Technology
, Vol.
104
, pp.
287
292
,
1982
.
13.
Yukawa, S., 1981, “ASME XI Flow Evaluation Basis and Methodology,” TWI Fitness For Service Symposium, London, U. K.
14.
Hibbit, Karlson and Sorensen, Inc., 1992, ABAQUS User’s Maual.
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