A review of developments and understanding of transverse cracking and delamination in cross-ply laminates is presented. First, experimental investigations reported in the literature for analyzing the development of transverse cracking are considered. Next, characteristics of different models for evaluating the stress distribution in the damaged laminates are developed. It is shown how these models associated with the statistical description of strength or energy released in the 90° plies make it possible to describe the development of transverse cracking in monotonic or fatigue loading. According to the nature of cross-ply laminates, transverse cracking is not, however, sufficient for describing the development of transverse cracks in 90° plies in the case of monotonic loading. In this case, the delamination process induced at transverse crack tips is to be considered for describing the experimental results. There are 108 references in this review article.

Issue Section:
Review Articles
Keywords:
glass fibre reinforced composites, carbon fibre reinforced composites, laminates, cracks, delamination, reviews
Topics:
Cracking (Materials), Fracture (Materials), Fracture (Process), Laminates, Stress, Delamination, Fatigue, Glass fibers, Shear (Mechanics), Stress concentration
1.
Birman
V
and
Byrd
LW
(
2000
),
Review of fracture and fatigue in ceramic matrix composites
,
Appl. Mech. Rev.
53
(
6
),
147
174
.
2.
Garrett
KW
and
Bailey
JE
(
1977
),
Multiple transverse fracture in 90° cross-ply laminates of a glass fiber reinforced polyester
,
J. Mater. Sci.
12
,
157
168
.
3.
Parvizi
A
,
Garrett
KW
, and
Bailey
JE
(
1978
),
Constrained cracking in glass fiber-reinforced epoxy cross-ply laminates
,
J. Mater. Sci.
13
,
195
201
.
4.
Bailey
JE
and
Parvizi
A
(
1981
),
On fibre debonding effects and the mechanisms of transverse-ply failure in cross-ply laminates of glass fiber/thermoset composites
,
J. Mater. Sci.
16
,
649
659
.
5.
Highsmith AL and Reifsnider KL (1982), Stiffness reduction mechanisms in composite laminates, Damage in Composite Materials, ASTM STP 775, KL Reifsnider (ed), 103–117.
6.
Manders
PW
,
Chou
T-W
,
Jones
FR
, and
Rock
JW
(
1983
),
Statistical analysis of multiple fracture in 0°/90°/0° glass fibre/epoxy resin laminates
,
J. Mater. Sci.
18
,
2876
2889
.
7.
Aveston
J
and
Kelly
A
(
1973
),
Theory of multiple fracture of fibrous composites
,
J. Mater. Sci.
8
,
352
362
.
8.
Tong
J
,
Guild
FJ
,
Ogin
SL
, and
Smith
PA
(
1997
),
On matrix crack growth in quasi-isotropic laminates-I. Experimental investigations
,
Compos. Sci. Technol.
57
,
1527
1535
.
9.
Bader MG, Bailey JE, Curtis PT, and Parvizi A (1979), The mechanisms of initiation and development of damage in multiaxial fiber-reinforced plastic laminates, Proc of 3rd Int Conf on Mechanical Behavior of Materials, Cambridge, UK, 227–239.
10.
Wang
ASD
and
Crossman
FW
(
1980
),
Initiation and growth of transverse cracks and edge delamination in composite laminates, Part 1: An energy method
,
J. Compos. Mater.
14
,
71
87
.
11.
Crossman
FW
,
Warren
WJ
,
Wang
ASD
, and
Law
GE
(
1980
),
Initiation and growth of transverse cracks and edge delamination in composite laminates, Part 2: Experimental correlation
,
J. Compos. Mater.
14
,
88
108
.
12.
Crossman FW and Wang ASD (1982), The dependence of transverse cracking and delamination on ply thickness in graphite/epoxy laminates, Damage in Composite Materials, ASTM STP 775, 118–139.
13.
Wang
ASD
,
Chou
PC
, and
Lei
SC
(
1984
),
A stochastic model for the growth of matrix cracks in composite materials
,
J. Compos. Mater.
18
,
239
254
.
14.
Wang
ASD
(
1984
),
Fracture mechanics of sublaminates cracks in composite materials
,
Composites Technology Review
6
,
45
62
.
15.
Charewicz A and Daniel IM. (1986), Damage mechanisms and accumulation in graphite/epoxy laminates, Composites Materials: Fatigue and Fracture, ASTM STP 907, HT Hahn (ed), 274–297.
16.
Groves
SE
,
Harris
CE
,
Highsmith
AL
,
Allen
DH
, and
Norvell
RG
(
1987
),
An experimental and analytical treatment of matrix cracking in cross-ply laminates
,
Exp. Mech.
27
,
73
79
.
17.
Nairn
JA
and
Mendels
DA
(
2001
),
On the use of planar shear-lag methods for stress-transfer analysis of multilayered composites
,
Mech. Mater.
33
,
335
362
.
18.
Fukunaga
H
,
Chou
T-W
,
Peters
PWM
, and
Schulte
K
(
1984
),
Probabilistic failure strength analyses of graphite/epoxy cross-ply laminates
,
J. Compos. Mater.
18
,
339
356
.
19.
Laws
N
and
Dvorak
GJ
(
1988
),
Progressive transverse cracking in composite laminates
,
J. Compos. Mater.
22
,
900
916
.
20.
Han
YM
,
Hahn
HT
, and
Croman
RB
(
1988
),
A simplified analysis of transverse ply cracking in cross-ply laminates
,
Compos. Sci. Technol.
31
,
165
177
.
21.
Han
YM
and
Hahn
HT
(
1989
),
Ply cracking and property degradation of symmetric balanced laminates under general in-plane loading
,
Compos. Sci. Technol.
35
,
377
397
.
22.
Lee
J-W
and
Daniel
IM
(
1990
),
Progressive transverse cracking of cross-ply composite laminates
,
J. Compos. Mater.
24
,
1225
1243
.
23.
Zhang
J
,
Fan
J
, and
Soutis
C
(
1992
),
Analysis of multiple matrix cracking in [±0m/90n] composite laminates
,
Composites
23
,
291
298
.
24.
Fan
J
and
Zhang
J
(
1993
),
In-situ damage evolution and micro/macro transition for laminated composites
,
Compos. Sci. Technol.
47
,
107
118
.
25.
Hashin
Z
(
1985
),
Analysis of cracked laminates: a variational approach
,
Mech. Mater.
4
,
121
136
.
26.
Hashin
Z
(
1986
),
Analysis of stiffness reduction of cracked cross-ply laminates
,
Eng. Fract. Mech.
25
,
771
778
.
27.
Nairn
JA
(
1989
),
The strain energy release rate of composite microcracking: a variational approach
,
J. Compos. Mater.
23
,
1106
1129
.
28.
Berthelot
J-M
,
Leblond
P
,
El Mahi
A
, and
Le Corre
J-F
(
1996
),
Transverse cracking of cross-ply laminates: Part 1. Analysis
,
Composites, Part A
27A
,
989
1001
.
29.
Berthelot
J-M
(
1997
),
Analysis of the transverse cracking of cross-ply laminates: a generalized approach
,
J. Compos. Mater.
31
,
1780
1805
.
30.
McCartney
LN
(
1992
),
Theory of stress transfer in a 0°-90°-0° cross-ply laminate containing a parallel array of transverse cracks
,
J. Mech. Phys. Solids
40
,
27
68
.
31.
McCartney
LN
(
1998
),
Predicting transverse cracks formation in cross-ply laminates
,
Compos. Sci. Technol.
58
,
1069
1081
.
32.
Cox
HL
(
1952
),
The elasticity and strength of paper and other fibrous materials
,
Br. J. Appl. Phys.
22
,
72
79
.
33.
Peters
PWM
and
Chou
T-W
(
1987
),
On cross-ply cracking in glass and carbon-fiber reinforced epoxy laminates
,
Composites
18
,
40
46
.
34.
Lee
JH
and
Hong
CS
(
1993
),
Refined two-dimensional analysis of cross-ply laminates with transverse cracks based on the assumed crack opening deformation
,
Compos. Sci. Technol.
46
,
157
166
.
35.
Whitney JM (1987), Structural Analysis of Laminated Anisotropic Plates, Technomic Publ, Lancaster.
36.
Berthelot J-M (1999), Composite Materials. Mechanical Behavior and Structural Analysis, Springer, New York.
37.
Steif PS (1984), Parabolic shear lag analysis of a [0/90]s laminate, Transverse ply crack growth and associated stiffness reduction during the fatigue of a simple cross-ply laminate, by SL Ogin et al., Report CUED/C/MATS/TR 105, Cambridge Univ.
38.
Ogin
SL
,
Smith
PA
, and
Beaumont
PWR
(
1985
),
Matrix cracking and stiffness reduction during the fatigue of a (0/90)s GFRP laminate
,
Compos. Sci. Technol.
22
,
23
31
.
39.
Ogin
SL
,
Smith
PA
, and
Beaumont
PWR
(
1985
),
A stress intensity factor approach to the fatigue growth of transverse ply cracks
,
Compos. Sci. Technol.
24
,
47
59
.
40.
Nuismer
RJ
and
Tan
SC
(
1988
),
Constitutive relations of a cracked composite lamina
,
J. Compos. Mater.
22
,
306
321
.
41.
Tan
SC
and
Nuismer
RJ
(
1989
),
A theory for progressive matrix cracking in composite laminates
,
J. Compos. Mater.
23
,
1029
1047
.
42.
Hashin
Z
(
1985
),
Analysis of orthogonally cracked laminates under tension
,
ASME J. Appl. Mech.
4
,
121
136
.
43.
Nairn
JA
and
Hu
S
(
1992
),
The formation and effect of outer-ply microcracks in cross-ply laminates: a variational approach
,
Eng. Fract. Mech.
41
,
203
221
.
44.
McCartney
LN
,
Schoeppner
GA
, and
Becker
W
(
2000
),
Comparison of models for transverse ply cracks in composite laminates
,
Compos. Sci. Technol.
60
,
2347
2359
.
45.
McCartney LN and Pierse C (1997), Stress transfer mechanics for multiple ply laminates for axial loading and bending, Proc of 11th Int Conf on Composite Materials, Gold Coast, Australia.
46.
Schoeppner
GA
and
Pagano
NJ
(
1998
),
Stress fields and energy release rates in cross-ply laminates
,
Int. J. Solids Struct.
35
,
1025
1055
.
47.
Lee SW and Aboudi J (1988), Analysis of composite laminates with matrix cracks, Report CCMS-88-03, Col of Eng, Virginia Polytechnic Inst and State Univ, Blacksburg VA.
48.
Aboudi
L
,
Lee
SW
, and
Herakowich
CT
(
1988
),
Three dimensional analysis of laminates with cross cracks
,
ASME J. Appl. Mech.
55
,
389
397
.
49.
Gamby
D
and
Rebie`re
J-L
(
1993
),
A two-dimensional analysis of multiple matrix cracking in a laminated composite close to its characteristic damage state
,
Comput. Struct.
25
,
325
337
.
50.
Yuan
FG
and
Selek
MC
(
1993
),
Transverse cracking and stiffness reduction in composite laminates
,
J. Reinf. Plast. Compos.
12
,
987
1015
.
51.
Peters
PWM
(
1984
),
The strength distribution of 90° plies in 0/90/0 graphite-epoxy laminates
,
J. Compos. Mater.
18
,
545
556
.
52.
Wang
ASD
,
Kishore
NN
, and
Li
CA
(
1985
),
Crack development in graphite-epoxy cross-ply laminates under uniaxial tension
,
Compos. Sci. Technol.
24
,
1
31
.
53.
Guild
FJ
,
Ogin
SL
, and
Smith
PA
(
1993
),
Modelling of 90° ply cracking in cross ply laminates, including three-dimensional effects
,
J. Comp. Mater.
27
,
646
667
.
54.
Weibull
W
(
1951
),
A statistical distribution function of wide applicability
,
ASME J. Appl. Mech.
18
,
293
297
.
55.
Berthelot
J-M
and
Le Corre
J-F
(
1999
),
Modelling the transverse cracking in cross-ply laminates: application to fatigue
,
Composites, Part B
30B
,
569
577
.
56.
Dvorak
GJ
and
Laws
N
(
1987
),
Analysis of progressive matrix cracking in composite laminates. II: First ply failure
,
J. Compos. Mater.
21
,
309
329
.
57.
Varna
J
and
Berglund
LA
(
1992
),
A model for prediction of the transverse cracking strain in cross-ply laminates
,
J. Reinf. Plast. Compos.
11
,
708
728
.
58.
Nairn JA and Hu S (1994), Micromechanics of damage: A case study of matrix cracking, Damage Mechanics of Composite Materials, R Talreja (ed), Elsevier, Amsterdam, 187–243.
59.
McCartney
LN
(
1998
),
Predicting transverse crack formation in cross-ply laminates
,
Compos. Sci. Technol.
58
,
1069
1081
.
60.
McCartney
LN
(
2002
),
Prediction of ply crack formation and failure in laminates
,
Compos. Sci. Technol.
62
,
1619
1631
.
61.
Griffith AA (1921), The phenomena of rupture and flow in solids, Philosophical Transaction, Royal Society of London, Series A-221, London, 163–198.
62.
Griffith AA (1924), The theory of rupture, Proc of 1st Int Congress of Applied Mechanics, Delft, 55–93.
63.
Irvin GR (1948), Fracture Dynamic, Fracture of Metals, Am Soc of Metals, Cleveland, 147.
64.
Orowan E (1952), Fundamentals of brittle behavior of metals, Fatigue and Fracture of Metals, WM Murray (ed), J Wiley and Sons, New York, 139–167.
65.
Rubinstein RY (1981), Simulation and the Monte-Carlo Method, J Wiley and Sons, New York.
66.
Wang ASD, Chou PC, Lei CS, and Bucinell R (1983), Cumulative damage model for advanced composite materials, final report, Contract F 33615-80-C-5039, US Air Force Wright Aeronautical Laboratory, Dayton OH.
67.
Chou PC, Wang ASD, and Miller HR (1982), Cumulative damage model for advanced composite materials, AFWAL-TR-82-4083, US Air Force Wright Aeronautical Laboratory, Dayton OH.
68.
Le Corre J-F (1999), Fissuration transverse et de´laminage dans les stratifie´s croise´s. Analyse statistique de la progression. Application a` la fatigue, PhD Thesis, Univ du Maine, Le Mans, France.
69.
Berthelot
J-M
and
Le Corre
J-F
(
2000
),
Statistical analysis of the progression of transverse cracking and delamination in cross-ply laminates
,
Compos. Sci. Technol.
60
,
2659
2669
.
70.
Janson
J
and
Hult
J
(
1977
),
Fracture mechanics and damage mechanics. A combined approach
,
Journal de Me´canique Applique´e
1
,
69
84
.
71.
Løland
KE
(
1980
),
Continuous damage models for load-response estimation of concrete
,
Cem. Concr. Res.
10
,
395
402
.
72.
Mazars J (1981), Mechanical damage and fracture of concrete structures, Proc of 5th Int Conf of Fracture, D Franc¸ois (ed), Cannes, France, 4, 1499–1506.
73.
Bazant ZP (1985), Mechanics of fracture and progressive cracking in concrete structures, Fracture Mechanics in Concrete, GC Sih and A Ditommaso (eds), 1–94.
74.
Talreja
R
(
1985
),
Transverse cracking and stiffness reduction in composite laminates
,
J. Compos. Mater.
19
,
355
375
.
75.
McCartney
LN
(
2000
),
Model to predict effects of triaxial loading on ply cracking in general symmetric laminates
,
Compos. Sci. Technol.
60
,
2255
2279
.
76.
Ladeve`ze
P
and
Lubineau
G
(
2001
),
On a damage mesomodel for laminates: micro-meso relations. Possibilities and limits
,
Compos. Sci. Technol.
61
,
2149
2158
.
77.
Ladeve`ze
P
and
Lubineau
G
(
2002
),
An enhanced mesomodel for laminates based on micromechanics
,
Compos. Sci. Technol.
62
,
533
541
.
78.
Ladeve`ze P (1989), About a damage mechanics approach, Mechanics and Mechanics of Damage in Composite and Multimaterials, D Baptiste (ed), 119–142.
79.
Ladeve`ze
P
and
Le Dantec
E
(
1992
),
Damage modeling of the elementary ply for laminated composites
,
Compos. Sci. Technol.
43
,
257
267
.
80.
O’Brien TK (1985), Analysis of local delaminations and their influence on composite behavior, Delamination and Debonding of Materials, ASTM STP 876, WS Johnson (ed), 282–297.
81.
Crossman FW and Wang ASD (1982), The dependence of transverse cracking and delamination on ply thickness in graphite/epoxy laminates, Damage in Composite Materials, ASTM STP 775 118–139.
82.
Dharani
LR
and
Tang
H
(
1990
),
Micromechanics characterization of sublaminate damage
,
Int. J. Fract.
46
,
123
140
.
83.
Nairn
JA
and
Hu
S
(
1992
),
The initiation and growth of delaminations induced by matrix microcracks in laminated composites
,
Int. J. Fract.
57
,
1
24
.
84.
Takeda
N
and
Ogihara
S
(
1994
),
Initiation and growth of delamination from the tips of transverse cracks in CFRP cross-ply laminates
,
Compos. Sci. Technol.
52
,
309
318
.
85.
Berthelot
J-M
and
Le Corre
J-F
(
2000
),
A model for transverse cracking and delamination in cross-ply laminates
,
Compos. Sci. Technol.
60
,
1055
1066
.
86.
Reifsnider
KL
and
Talug
A
(
1980
),
Analysis of fatigue damage in composite laminates
,
Int. J. Fatigue
2
,
3
11
.
87.
O’Brien
TK
and
Reifsnider
KL
(
1981
),
Fatigue damage evaluation through stiffness measurements in boron-epoxy laminates
,
J. Compos. Mater.
15
,
55
70
.
88.
Masters JE and Reifsnider KL (1982), An investigation of cumulative damage development in quasi-isotropic graphite/epoxy laminates, ASTM STP 77, 40–62.
89.
Reifsnider
KL
and
Jamison
R
(1982), Fracture of fatigue-loaded composite laminates, Int. J. Fract. Oct, 187–197.
90.
Jamison RD, Schulte K, Kenneth L, Reifsnider KL, and Stinchcomb WW (1984), Characterization and analysis of damage mechanisms in tension-tension fatigue of graphite/epoxy laminates, Effects of Defects in Composite Materials, ASTM STP 836, J Wilkins (ed), 21–55.
91.
Daniel IM, Lee JW, and Yaniv G (1987), Damage mechanisms and stiffness degradation in graphite/epoxy composite, Proc of 6th Int Conf on Composite Materials, FL Matthews et al. (eds), 4, 129–4.138.
92.
Charewicz A and Daniel IM (1986), Damage mechanisms and accumulation in graphite/epoxy laminates, Composite Materials: Fatigue and Fracture, ASTM STP 907, HT Hahn (ed), 274–297.
93.
Boniface
L
and
Ogin
SL
(
1989
),
Application of the Paris equation to the fatigue growth of transverse ply cracks
,
J. Compos. Mater.
23
,
735
754
.
94.
Lafarie-Frenot
M-C
and
He´naff-Gardin
C
(
1991
),
Formation and growth of 90° ply fatigue cracks in carbon/epoxy laminates
,
Compos. Sci. Technol.
40
,
307
324
.
95.
He´naff-Gardin C, Lafarie-Frenot M-C, Brillaud J, and El Mahi A (1992), Influence of the stacking sequence on the fatigue transverse ply cracking in cross-ply laminates, Damage Detection in Composite materials, ASTM STP 1128, JE Masters (ed), 236–255.
96.
Paris PC, Gomez MP, and Anderson WE (1961), The Trend in Engineering, Washington Univ, Seattle WA.
97.
Ogin
SL
and
Smith
PA
(
1987
),
A model for matrix cracking in cross-ply laminates
,
ESA Journal
11
,
45
60
.
98.
Sih
GC
,
Paris
PC
, and
Erdogan
F
(
1962
),
Crack tip stress intensity factor for plane extension and plate bending problems
,
ASME J. Appl. Mech.
29
,
306
312
.
99.
Hertzberg RW (1976), Deformation and Fracture Mechanics of Engineering Materials, J Wiley and Sons, New York.
100.
Lee JW, Daniel IM, and Yaniv G (1989), Fatigue life prediction of cross-ply composite laminates, Composite Materials: Fatigue and Fracture, ASTM, STP 1012, PA Lagace (ed), 2, 19–28.
101.
Gao
Z
(
1994
),
A cumulative damage model for fatigue life in composite laminates
,
J. Reinf. Plast. Compos.
13
,
128
141
.
102.
Diao
X
,
Ye
L
, and
Mai
Y-W
(
1995
),
A statistical model for residual strength and fatigue life of composite laminates
,
Compos. Sci. Technol.
54
,
329
336
.
103.
Diao
X
,
Ye
L
, and
Mai
Y-W
(
1996
),
Fatigue life prediction of composite laminates using a stress redistribution function
,
J. Reinf. Plast. Compos.
3
,
329
326
.
104.
Diao
X
,
Ye
L
, and
Mai
Y-W
(
1997
),
Statistical fatigue life prediction of cross-ply composite laminates
,
J. Compos. Mater.
31
,
1442
1460
.
105.
Reifsnider KL and Stinchcomb WN (1986), A critical-element model of the residual strength and life of fatigue-loaded composite coupons, Composite Materials: Fatigue and Fracture, ASTM STP 907, KL Reifsnider (ed), 298–313.
106.
Halpin JC, Jerina KL, and Johnson TS (1973), Characterization of composites for the purpose of reliability evaluation, Analysis of the Test Methods for High Modulus Fibers and Composites, ASTM STP 521, JM Whitney (ed), 5–64.
107.
Berthelot
J-M
,
EL Mahi
A
, and
Leblond
P
(
1996
),
Transverse cracking of cross-ply laminates, Part 2: Progressive widthwise cracking
,
Composites, Part A
27A
,
1003
1010
.
108.
Berthelot
J-M
,
El Mahi
A
, and
Le Corre
J-F
(
2001
),
Development of transverse cracking in cross-ply laminates during fatigue tests
,
Compos. Sci. Technol.
61
,
1711
1721
.
Copyright © 2003
 by ASME
You do not currently have access to this content.