Issue 49
G. Meneghetti et alii, Frattura ed Integrità Strutturale, 49 (2019) 53-64; DOI: 10.3221/IGF-ESIS.49.06
I NTRODUCTION
D
ealing with cracks under in-plane mixed mode I+II loading conditions, according to Williams [1], the local stress fields expressed in terms of Cartesian stress components as functions of the polar coordinates ( r , θ ), with origin at the crack tip (Fig. 1a), can be written in the following form:
θ 1 2 2 θ 1 2 2
3 2
θ 1 2 2
3 2
- sin θ sin θ
cos
-2sin - sin θ cos θ
3 2
1/2 1 +T 0 +O(r ) 0
xx σ yy xy τ
K
K
1 2
3 2
sin θ cos θ
I
II
(1)
σ = cos + sin θ sin θ +
2πr
2πr
1 2
3 2
θ 1 2 2
3 2
sin θ cos θ
sin θ sin
θ
cos
With reference to cracks under mode III loading conditions, the asymptotic, singular stress distributions have been determined by Qian and Hasebe [2], following Williams’ procedure [1]. The local stress field in terms of Cartesian stress components as functions of the polar coordinates ( r , θ ), with origin at the crack tip (Fig. 1b), is the following:
θ -sin
2
xz yz τ τ
III K=
1/2 +O(r )
(2)
θ 2πr cos 2
σ nom
(a)
(b)
F
M t
τ nom
σ yy
σ yy
τ yz
y
τ xy
τ xy
y
σ xx
σ xx
σ zz
x
r
x
τ xz
θ
τ nom
z
r
θ
L = W
2α=0°
L = D
2a
a
a
crack bisector
crack bisector
D = 10 ·a
M t
W = 10 ·2a
F
Figure 1 : Cartesian stress components and polar coordinates with origin at the crack tip for (a) in-plane mixed mode I+II crack problem and (b) out-of-plane mixed mode I+III crack problem. The mode I and mode II Stress Intensity Factors (SIFs) can be defined according to Gross and Mendelson [3] by means of Eqns. (3) and (4), respectively. 0.5 0 0 2 lim I yy r K r (3) 0.5 0 0 2 lim II xy r K r (4)
54
Made with FlippingBook - Online catalogs