Fracture and Damage Behaviors of Concrete in the Fractal Space

doi:10.4236/jmp.2010.11006

J. Mod. Phys., 2010, 1, 48-58

doi:10.4236/jmp.2010.11006 Published Online April 2010 (http://www.scirp.org/journal/jmp)

Fracture and Damage Behaviors of Concrete in the

Fractal Space

Heng Zhang1, Demin Wei1,2

1Department of Civil Engineering, South China University of Technology, Guangzhou, China

2State Key Laboratory of Subtropical Building Science, South China University of Technology, Guangzhou, China

E-mail: heng.zh@mail.scut.edu.cn

Received January 22, 2010; revised March 17, 2010; accepted March 20, 2010

Abstract

The fracture toughness, the driving force and the fracture energy for an infinite plate with a fractal crack are

investigated in the fractal space in this work. The perimeter-area relation is adopted to derive the transforma-

tion rule between damage variables in the fractal space and Euclidean space. A plasticity yield criterion is

introduced and a damage variable tensor is decomposed into tensile and compressive components to describe

the distinct behaviors in tension and compression. A plastic damage constitutive model for concrete in the

Euclidean space is developed and generalized to fractal case according to the transformation rule of damage

variables. Numerical calculations of the present model with and without fractal are conducted and compared

with experimental data to verify the efficiency of this model and show the necessity of considering the fractal

effect in the constitutive model of concrete. The structural response and mesh sensitivity of a notched unre-

inforced concrete beam under 3-point bending test are theoretical studied and show good agreement with the

experimental data.

Keywords: Fracture Mechanics, Damage Variable, Fractal Space, Constitutive Model

1. Introduction

Concrete has been widely used in civil engineering for its

good in-situ casting and molding abilities. As a quasi-

brittle material, the fracture behavior of concrete receives

much of researchers’ concerns. Though classic fracture

mechanics which is based on the assumption of smooth

cracking in materials can analyze concrete properties and

meet the need of structure design in a certain extent, no

advance is made to explain the failure mechanism from

the change of the concrete internal structure. The difficulty

mentioned above has a hindering effect for researchers to

improve the mechanical property of concrete.

Fractal geometry is established by Mandelbrot in

1970s [1], which plays an important role in the develop-

ment of fracture mechanics theory. Researches show that

the fracture zone of metal, rock and concrete has fractal

characteristics [2-4]. This leads a widely use of fractal

geometry in many fields of material science, for in-

stances, the Sierpinski carpet was adopted by Carpinteri

et al. [5] to simulate the composition of concrete cross

section, and the fractal effect was also introduced into

the cohesive crack model. Another remarkable applica-

tion of fractal geometry is to describe the roughness of

cracks quantitatively. Saouma et al. [6] and Issa et al. [7]

investigated the crack profiles of concrete through tests

and pointed out that cracks in concrete have an average

fractal dimension of 1.1. Meanwhile, Issa et al. [7] ana-

lyzed the fracture surface of concrete and found its frac-

tal dimension is about 2.1 to 2.3.

Studies on the damage of concrete point out that the

propagation micro defects, i.e. microvoids and micro-

cracks, etc, is the mainly cause of the macro fracture of

materials. Based on this fact, a new kind of constitutive

model for concrete, called the damage constitutive model,

is developed within the framework of continuum damage

mechanics. In this model, the choice of damage variable

is a key to control the effectiveness and performance.

Because of the heterogeneity of concrete, definition of

the damage variable still remains at the state that the

change of material macro property, such as elastic

modulus and stress, are used to reflect the development

of damage indirectly, and no direct relation is set with

the intrinsic deflects. As the progress in studying fractal

phenomena, some researchers try to explore the damage

growth by means of fractal geometry. Zhao [8] defined a

damage variable as a function of the area of fracture sur-

face, and proposed a new damage constitutive model for

H. ZHANG ET AL.

49

rock in which the fractal effect was taken into account;

Guarracino [9] gave out a damage variable as the ratio of

the porous and REV (or the representative elementary

volume) volume fraction of materials and presented a

fractal constitutive model for rock.

In this work, the fracture behaviors of a material with

fractal cracks are investigated by using fractal geometry.

Theoretical expressions of the fracture toughness, the

driving force and the fracture energy is derived conse-

quently. The transformation rule of a fractal damage va-

riable in the fractal space and a apparent damage variable

in the Euclidean space is obtained by adopting the pe-

rimeter-area relation. This rule is introduced into a new

plastic damage constitutive model of concrete presented

in this research. A notched plain concrete beam under

3-point bending test is simulated to verify the efficiency

of the model.

2. Fracture Parameters in the Fractal Space

2.1. Simplification of Fracture Zone

Figure 1 illustrates an infinite plate with a fractal cut in

uniaxial tension. The cut releases the stress in a fracture

domain, whose shape can be approximated as an ellipse

[10]. A standard Koch fractal curve is employed to con-

struct the boundary of the crack, see Figure 2. n denotes

the construction step. Keep the area of frac

ture zone as a constant of 2

0

a



, then the fractal dimen-

sion D of the crack is independent on the yardstick

0

3na





, where η is a shape parameter and η=2π

when smooth cracking.

2.2. Critical Cracking Stress

According to the fractal theory [1], the real length 2a and

the apparent length (projected to the axial) 2a0 of the

crack has the following relation:

1

0

D

aa





 (1)

The surface energy of the fracture surface is:

Figure 1. A fractal crack in the infinite plate.

Figure 2. Construction of the crack boundary with a stan-

dard Koch fractal curve.

1

0

() 44

D

atata







  (2)

where t is the plate thickness. The perimeter C of the

fracture zone is:

1

0

44

D

Caa





 (3)

Thus, one gets the zone area A as follows by adopting

the perimeter-area relation

 

22 4

2

22

00

2

D

DD

D

A

amCm a

 





  (4)

where the proportional coefficient m is:

4

2

D

m





 (5)

Therefore, the strain energy released during the crack-

ing process can be written as:

22

2

0

00

()

22

tt

UA a

EE







  (6)

where σ denotes the tensile stress of the plate; E0 is the

elastic modulus. For a plate strain state, one needs to

replace E0 in Equation (6) with



2

00

1E



, where ν0 is

the Poisson’s ratio.

The Griffith fracture criterion state that: materials

cracks when the released elastic energy ΔU equals to the

surface energy Π concentrated in the fracture zone for an

infinitesimally small increment of the crack length da0,

i.e.,





0

dU

da

  (7)

Substituting Equations (2) and (6) into Equation (7),

one obtains the critical cracking stress σc for materials as:

121

00

4

D

cEDa

 



 (8)

For a smooth cut case, D=1.0, η=2π, and we have:

0

2

c

E

a





 (9)

H. ZHANG ET AL.

50

2.3. Fracture Toughness

Wunk and Yavari [11] studied the stress field at the frac-

tal crack tip, and presented the component σy in y direc-

tion as shown in Figure 1.

 



cos()sinsin1

2

f

I

y

K

r





 









(10)

where f

I

K

is the fractal stress intensity factor; α repre-

sents the singularity order of the stress field, and can be

expressed as:

2

D





, 12D

(11)

in terms of D for a self-similar fractal crack.

For D=1.0, we have α=1/2 and f

I

KK, and Equa-

tion (10) degenerates to the smooth cracking case as:



13

cossin sin

22 2

2

I

y

K

r





















(12)

When σy=σc, ff

I

IC

K

K, the crack begins to grow. Re-

ferring to Equations (8) and (10), one obtains the fractal

fracture toughness for materials:



121

00

24

cos()sinsin1

D

f

IC

rEDa

K



 

 



 







(13)

Figure 3 illustrates the relation among

f

I

C

K

, D and a0.

It can be noted from Figure 3 that

f

I

C

K decreases with

the increasing of the crack length; If a0=0,

f

I

C

K tends to be infinite, and no crack exists in materials,

which verifies the concept that the growth of initial de-

flects leads to the final failure of materials. The greater

the D value, the more bifurcated the cracks are, and the

larger

f

I

C

K is, which indicates that roughness has a hin-

Figure 3. Influences of D and a0 on

f

I

C

K

.

dering effect on the cracking of materials.

2.4. Driving Force

Classic driving force is defined as the strain energy dis-

sipated to form a unit fracture area [11], and can be ex-

pressed as:



2

0

1

2

I

UK

Gta E



 

 (14)

Submitting Equations (1) and (6) into Equation (14),

one gets:

2

21

0

2

fDD

Ga

ED







 (15)

For the mode I cracking case, G f reaches its maximum

value max

f

G when σ increases to the tensile strength σt of

materials:

2

21

max 0

0

2

fDD

t

Ga

ED









(16)

We also have the cracking resistance GIC of materials

as:

12

2

IC

Gta





 

 (17)

If max

f

I

C

GG, cracking occurs, and cracks does not

grow when max

f

I

C

GG. This is the G-fracture criterion

for fractal cracks.

2.5. Fracture Energy

The fracture energy GF of materials is defined as the area

under the stress vs. the crack open displacement curve in

the cohesive law, and represents the energy dissipated on

the unitary crack surface [12]. GF is usually determined

by tests. For a large size specimen, the fracture energy

*

F

G equals to the max driving force max

f

G expressed in

Equation (16), approximately. Therefore, fracture energy

GF for a normal size specimen has relation with max

f

G as:

** *

max

f

FN F

GAGA GA



  (18)

where AN and A* are the real areas of the fracture surfaces

corresponding to the normal size and large size speci-

mens, respectively, with a transformation as:

22

*

,

D

ch

N

ch N

l

A

l













(19)

where *

ch

l and ,ch N

l are the characteristic lengthes cor-

responding to A* and AN, respectively. Usually, *

ch

l is

taken to be the minimum threshold of characteristic

lengths. For concrete, *

ch

l= 0.15 mm when0

f

 = 100 MPa

H. ZHANG ET AL.

51

and *

ch

l= 0.15 mm when 0

f



= 200 MPa [13], and *

ch

l

can be obtained by linear interpolation for other strengths.

,ch N

l is given by [14]:

,0

2

ch N

lab (20)

where the constant b < 1 represents the initially cracked

portion of the interface prior to load application, 2a0 is

the initial crack diameter and is assumed to be equal to

the maximum aggregate size in concrete.

Substituting Equations (16) and (19) into Equation

(18), one obtains

22 2

,21

0

*

0

2

D

ch NDD

t

F

ch

l

Ga

ED

l















 (21)

Here 2a0 needs is considered to be the final length of

the main crack for concrete, and represents a specimen

size. Figure 4 shows the behaviors of GF as the changes

of a0 and D. We can find that GF increases with the in-

creasing of these two factors.

3. Damage Variable

An apparent damage variable is defined as the ratio of

the effective bearing area Ak and the cross section area Ac

of materials, and has the following form:

k

c

A



 (22)

For a Euclidean shape, the area A0 and the perimeter

C0 have the following relation:

2

000

A

mC (23)

where m0 is a shape constant. Substituting Equation (23)

into Equation (22), one obtains the expression for the

apparent damage variable



as follows:

and

2

k

c

C









(24)

where Ck and Cc are the perimeters corresponding to Ak

and Ac, respectively. It is reasonable for us to take Ck

Figure 4. Influences of D and a0 on GF.

Cc as the crack length in one direction and the total

length of all cracks in all directions in a unit cell at fail-

ure, respectively.

By referring to Equation (1), the perimeter C of a

fractal damaged surface and the counterpart C0 in the

Euclidean space has the following relation:

1

0

D

ch

CCl



 (25)

Substituting Equation (4) into Equation (22), concern-

ing Equation (25), and based on the fact that cracks in

concrete is statistically self-similar fractal when the

yardstick δ ranges from 0.263 to 1 [15], one obtains the

following expression for a fractal damage variable in the

fractal space:

11

ˆ16 ck

DD













 (26)

where Dk = 1.0 ~ 2.0. From Equation (29), we find that

only the fractal dimension is different between the fractal

and apparent damage variables, and δ has no influence

on this relation. Since Ac is the cross section area of ma-

terials, which indicates Dc = 1.0, thus Equation (26) can

be rewritten as:

1

ˆ16 k

D

ij ij













 (27)

For a smooth crack, Dk = 1.0, and no fractal effect ex-

ists, and we have:

ˆij ij





(28)

From the above discussion, we notice that the apparent

damage variable in the Euclidean space is a special case

of the fractal damage variable in the fractal space, and

the fractal damage variable is the generalization of the

apparent damage variable. Figure 5 illustrates the dif-

ferences between the two kind damage variables in uni-

axial compression with an assumption that Dk takes the

average value of 1.1, and the original evolution data for

apparent damage variables is referred from reference

[16].

Figure 5. Evolutions of damage variables for concrete in

uniaxial compression cases.

H. ZHANG ET AL.

52

4. Plastic Damage Constitutive Model for

Concrete

Among the various existed constitutive models for con-

crete, the plastic damage model has a better effect to

characterize the stiffness degeneration, the strain soften-

ing and the unilateral effect of concrete under various

loading conditions.

4.1. Decomposition of Effective Stress Tensor

In view of the fact that the typical failure modes of con-

crete are cracking in tension and crushing in compression,

we decompose the effective stress tensor into tensile and

compressive parts (denoted by 

σ and 

σ, respec-

tively) by utilizing spectral decomposition technique

[17,18]:

:



σPσ (29)

:



 

+

σσσPσ (30)

where P+ and P- are the fourth-order projection tensors

expressed as [19]:



iii ii

i

H







Ppp (31)



PIP (32)

where I is the fourth-order identity tensor;





i

H



represents the Heaviside function calculated for the ith

eigenvalue i



of σ; Pij is the second-order tensor and

is defined as:



1

2

ijjiij ji

 pp nnnn (33)

where ni is the ith normalized eigenvector corresponding

to i



.

4.2. Plasticity

We adopt a plasticity yield function f and a plastic poten-

tial function Fp as:

 



12 max

ˆ

,3

fIJ



 σκκ







10c





 κ (34)

21

3

pp

F

JI





(35)

where



2xxx denotes the Macaulay bracket

function, max

ˆ



is the algebraically maximum effective

principal stress. α, β and c are parameters with the fol-

lowing forms [20]:

00

2

b

f







;





11

c











κ





cf



κκ;







cf



κκ (36)

where 0b

f



and 0

f



are the initial equibiaxial and uni-

axial compressive yield stresses, respectively. 00b

f



lies between 1.10 and 1.20 from experiments, therefore,

α varies from 0.08 to 0.12.



cκ represent the inner

cohesion, and





fκ are the evolution stresses (posi-

tive values are used here in compression) in the effective

stress space due to plastic hardening or softening under

uniaxial tension and compression, respectively. 1

I

is

the first invariant of the effective stress tensor, 2

J

is

the second invariant of the effective deviatoric stress

tensor. αp ≥ 0 is a dilation parameter with 0.2 ≤ αp ≤ 0.3

for concrete.

According to the flow rule, the rate of the effective

plastic strain

p



 can be written as:

2

3

23

p

ij

pp pp

ij ij

ij

s

F

J



 







 







 (37)

where

p



 is a plastic consistency factor, and can be

determined by the consistency condition for the yield

surface f, which can be expressed in the Kuhn-Tucker

form as:

0f



, 0

p





, 0

pf





, 0

pf







 (38)

In this study, the linear isotropic hardening rules are

introduced to describe the change of the yield surfaces in

the effective stress space, and can be expressed in simple

forms as [21]:





p

y

ffE







κ (39)

where y

f



are the effective yield strengths in uniaxial

tension and compression, and have approximate values

as 0y

f



 and0y

f



, respectively. 0

f



are the

uniaxial yield strengths of concrete corresponding to

tension and compression, respectively. p

E



are the

effective plastic hardening modulus in uniaxial case, and

have relation with the elastoplastic tangent modulus

ep

E



as [22]:

0

ep

p

ep

EE

EEE



 (40)

According to the plasticity consistency condition, we

have:

0

ff

f







σκ

 (41)

and obtain the rate form of the constitutive equation as

follows:

0,

p

ijijkl kl

kl

F

C



















 (42)

where C0,ijkl is the fourth-order undamaged elastic stiff-

H. ZHANG ET AL.

53

ness tensor.

Accounting for the coupling of tension and compres-

sion, κ

 can be written as [22]:



max min

,(1)T

pp

ww



κ

 

(43)

where max

p



 and min

p



 are the maximum and minimum

values of the equivalent plastic strains

p

ij



; w is the

weight factor and has the following form:

33

11

ˆˆ

ii

w







(44)

where ˆi



are the principle stresses.

Substituting Equations (42) and (43) into Equation

(41), we obtain:

0,

1

p

ijkl kl

p

ij

fC

h













 (45)

where

p

h can be expressed in the following forms:

0,

max

ˆ

p

ijkl

ij kl

f

FfF

hC w







 





 (46)



0,

min

1ˆ

p

ijkl

ij kl

f

FfF

hC w

 



 



  (47)

where max

ˆ



and min

ˆ



are the maximum and minimum

effective principle stresses, respectively. Therefore, we

can rewrite the rate form of the relation Equation (42) for

the effective stress and the strain as:

ijijkl kl

C







 (48)

where Cijkl is the elasto-plastic tangent stiffness tensor

and has the following form:

0, 0,0,

1p

ijkl ijklijrsmnkl

p

rs mn

Ff

CC CC

h





  (49)

4.3. Helmholtz Free Energy

A damage constitutive model of a material is based on

the second law of thermodynamics which states that all

the selected internal variables must satisfy the Clau-

sius-Duhem inequality for any irreversible process under

an isothermal condition, and has a simple form as:

:0



σε 

 (50)

where σ and ε are the stress and strain tensors,



is the

total Helmholtz free energy (HFE) which can be consid-

ered as the sum of the elastic part e



and the plastic

part

p



, that is:





,,, ,

eeep



εκΦεΦ κΦ

(51)

where Φ is the damage variable tensor.

We decompose e



into tensile and compressive

parts as:

 

,,,

eee ee e





εΦεε (52)

where



0

1

,11:

2

eee eee

 

 

 εεσε (53)



0

1

,11 :

2

ee eee

 

 

εεσε (54)

where









0:2

ee e





εσε represent the initial elastic

strain energy of materials;



 are the tensile and com-

pressive components of Φ. Therefore, we derive:







00

11

ee ee

ee









 



εε

σ

εε





11







 σσ (55)

The incremental form of Equation (55) can be ex-

pressed as:









11 dd







 

+

σσ σσσ



 (56)

Equations (56) and (48) form the final plastic damage

constitutive equations for the plain concrete.

Similarly, we can rewrite

p



as:









,, ,

pp p







κκ κ (57)

Referring to the fact that the contribution to the plastic

HFE from plastic strains of concrete in tension is much

smaller comparing to the one in compression, we assume

that 0

p







. Thus, we have:











0

,1

ppp





κκ κ (58)

Substituting Equations (51), (52) and (58) into Equa-

tion (50), we get:

:0

ep

e



 





 

 



 

σεσεκΦ

κΦε



 (59)

Since the above inequality must be satisfied for any

elastic strain εe, we have:

e









σ

ε (60)

0YΦ

 (61)

:0

p











σε κ

κ



 (62)

where Y is the damage energy release rate and can be

expressed as:









YΦ (63)

According to the above discussions about the total

HFE, we can rewrite Y as:

0

Y





 (64)

H. ZHANG ET AL.

54

We define the damage criteria in tension and compres-

sion for concrete, respectively, as:



,0gYrY r

 



(65)

where r are the current damage thresholds whose ini-

tial values is denoted by 0

r. Equation (65) indicates that

damage is initiated when Y exceed the corresponding

damage thresholds r.

Initial strain energy of materials can be written as:



00 0

1::0

2

eee ee





 εεεCε (66)



00 0

ee p



 

εκ （67)

where 0

e



 is the initial strain energy of materials in

compression, and can be expressed as:



2

0

0021011

0

12

121 0

23

eJIII

E



 







 





(68)



021211

1

62

23

p

pp

J

IJ II

















κ

s



212 11

0

1

62

26

p

J

IJ II

E



 









(69)

where 2

:2

J

sss is the norm of s;

2

1:

2

J

ss is the second invariant of the compres-

sive effective deviatoric stress tensor 

s; 1

I and 1

I



are the first invariant of



σ and 

σ, respectively.

0

2p

E





 s

 is a material parameter.

Therefore, 0



 has the following form in compres-

sion case:



2

00211 221311

32

J

IJ III



 



 





(70)

where parameters Ω0, Ω1, Ω2, Ω3 are



0

621

6E



 

 ;



1

0

3

621

p







  



0

2

0

12

621





  ;



0

3

0

0.5 3

621





   (71)

Assume that concrete is in biaxial compression, which

indicates σ3≡0, and we have:



22 0

012 12

00

22

121212

0

66

63

66

6

p

YEE

E





 

 

 



 





(72)

For an uniaxial compression case, we denote the uni-

axial compressive ultimate strength as 0

f, and have

σ1=0

f



,σ2=0. We can derive the initial damage threshold

0

r



as:





0

361

6

p

f

rE













 (73)

And for an equibiaxial compression case, we use 0b

f



to denote the biaxial compressive ultimate strength. One

gets σ1=σ2=0b

f



, and derives 0

r as:







0

00

0

6161 2

6

bp

f

rE













 (74)

Noticing that the initial damage threshold is unique for

a material, we obtain the expression for Ω from Equa-

tions (73) and (74):





2

000

2

00

61 3

6161 2

b

p

b

ff







  (75)

For concrete, one has 00b

f



 = 1.10~1.16 and

p



=

0.2~0.3. Assuming ν0=0.2, and substituting the above

three parameters into Equation (74), we find that Ω ≥ 0 is

always hold. Thus we have 0

p



≥0 (see Equation (69)),

and 000

ep

Y









 ≥0, and finally have Y



≥0.

Accounting for the fact that damage is irreversible, we

get





,





≥ 0. Therefore, the total HFE defined in

Equation (51) satisfies the thermodynamic consistency,

or satisfies the inequality of Equation (61).

Equation (75) reaches the limit state Ω→+∞ when







2

00

2

00

1

21

b

p

b

ff











, and the undamaged area of a ma-

terial in compression can be characterized by the follow-

ing inequality:



22 22

121212 1212

p



 

 





0

1pf





 (76)

Figure 6 illustrates the changes of the undamaged ar-

eas with αp. We find that the increase of αp will lead an

expansion of the undamaged area.

4.4. Evolution Laws

The evolution laws proposed by Faria et al. [18] are

adopted in this research. Damage variables (in the Euc-

lidean space) and their rate forms are expressed as:

0

1exp 1

rr

B

rr









 











(77)

H. ZHANG ET AL.

55

Figure 6. Influences of αp on undamaged domain.



0

11 exp1

rr

AA B

rr

















 

















(78)

0

d

rh







 (79)

where



0

2

0

exp 1

dGr Brrr

hB

rr

r

  











 











(80)





0

2

1

dGr r

hA

rr

 









00

exp 1

AB r

B

rr

 





















(81)

where A- is a material parameter, and can be determined

by the uniaxial compression test; B± can be expressed as:



1

0

2

0

10

2

F

ch

GE

B

lf















(82)

where

F

G is the fracture energy of a material and can

be determined by tests or from Equation (21).

Replacing



 in the above model by ˆ



 in Equa-

tion (27), we can generalize the Euclidean constitutive

model for concrete to the fractal space.

5. Example Analysis

5.1 Comparison of Constitutive Models

In this section, numerical simulations of the present

model considering fractal effect are performed for con-

crete under different loading conditions, and compari-

sons of the results are done with some experimental data,

i.e. the unaxial loading test by Karsan and Jirsa [23] and

the biaxial loading one by Kupfer et al. [24]. Material

parameters for concrete are listed in Table 1. The values

of E0, ν0, αp and α are obtained from the study of Lee and

Fenves [18]; Average values of lch,N, *

ch

l, η, a0, b and Dk

are used here because of their narrow range intervals.

Therefore, we can obtain the fracture energy for con-

crete from Equation (21) as:

F

G=45.3N/m in tension

and

F

G



=1497N/m in compression.

5.1.1. Uniaxial Tension

Both the predictions of the present model with and

without the fractal effect and the test data obtained by

Karsan and Jirsa [23] for concrete under uniaxial tension

are illustrated in Figure 7(a). We can find that the two

kind results of the present model agree well with the test

data in the stress hardening stage. Comparing with the

case of no fractal, the prediction considering the fractal is

more coincident with the test. In the last large deforma-

tion stage, the three behaviors are close with each other.

5.1.2. Uniaxial Compression

Figure 7(b) shows the comparison of the calculation

results of the present model and the test data for concrete

under uniaxial compression obtained by Karsan and Jirsa

(a)

(b)

Figure 7. Comparison of the constitutive curves of the pre-

sent model with test results (Karsan and Jirsa 1969) in the

uniaxial loading conditions. (a) Uniaxial tension; (b) Uniax-

ial compression.

H. ZHANG ET AL.

56

[23]. Comparing with the uniaxial tension case, both of

the two kind results of the model are more efficient to

simulate the concrete compressive behaviors. The pre-

dictions considering fractal is slightly lower than the two

other data.

5.1.3. Biaxial Tension

In this simulation, equibiaxial tensile condition is

adopted, and material parameters are taken as the same

as those listed in Table 1. Figure 8(a) gives the behav-

iors obtained from the present model and the test in bi-

axial tension [24]. We find that the two kind theoretical

results are coincident with the test data; in the initial

strain softening stage, the result concerning no fractal

agrees with the test better, but there is obviously a dif-

ference between them comparing with the data consider-

ing the fractal effect. All these show the superiority of

the proposed model.

Table 1. Material parameters for concrete.

E0=31.7GPa ν0=0.2 0

f



=3.48MPa 0

f



=20MPa

α=0.12 αp=0.2

δ

=0.286 *

ch

l=0.156mm

η=2π a0=6.0mm b=0.79 Dk=1.16

(a)

(b)

Figure 8. Comparisons of the constitutive curves of the

present model with test results (Kupfer et al. 1969) in the

biaxial loading conditions. (a) Biaxial tension (σ1: σ2=1:1);

(b). Biaxial compression (σ1: σ2=-1:-1).

5.1.4. Biaxial Compression

In equibiaxial compression, concrete shows a good plas-

tic deformation ability which can be found both in the

proposed model and the test [24]; see Figure 8(b). The

three curves are well close with each other. Comparing

with the three other loading cases discussed above, the

peak stress increases obviously, accompanied by the

slowest decreasing softening stage in biaxial compres-

sion, which indicates a good compressive capacity of

concrete under the confining pressure condition. Spe-

cially, model with fractal damage variables is more ac-

curately than the one with apparent damage variables.

5.2. Structural Analysis

An unreinforced notched concrete beam under 3-point

bending is simulated to verify the efficiency of the pre-

sent concrete damaged plasticity model. This problem

has been studied extensively both experimentally by Pe-

tersson [25] and analytically by Meyer et al. [26], among

others. This beam is simply supported at both ends with

concentrated force acting at the center. Its sketch is illus-

trated in Figure 9 (unit: m).

The measured parameters of concrete are: elastic mo-

dulus E0=30GPa, Poisson’s ratio ν0=0.2, density ρ0 =

2400 kg/m3 and uniaxial tensile strength ft = 3.33 MPa.

The present constitutive model considering the fractal

effect of concrete is adopted for the theoretical analysis.

The model parameters are taken as:

F

G = 138 N/m, 0

f



= ft = 3.33 MPa, 0

f



= 30 MPa, and other properties are

same as that listed in Table 1. The beam is under the

plane stress condition. Accounting for the symmetry of

both the structure and the load, only one half of the beam

is modeled. The model is meshed with 280 4-node bilin-

ear, reduced integration plane elements. The beam is

loaded by prescribing the vertical displacement at the

center of the beam until it reaches a value of 0.0015 m.

The Riks method is used to solve this problem.

Figure 10 illustrates the variation curves of the con-

centrated force and the center displacement of the beam

calculated from the theoretical analysis and the Peters-

son’s test [25]. We can note that the theoretical result is

coincidence with the test at the loading stage and slightly

higher then the test at the unloading branch. Figure 11

shows the distribution of the principal tensile stress of

Figure 9. Notched beam: geometry and dimensions (unit: m).

H. ZHANG ET AL.

57

the structure as well.

Mesh sensitivity is investigated in this study by mesh-

ing the structure into coarse and fine grids, respectively,

with 70 and 1120 same type elements with the medium

mesh case. Resolving the above problem at the same

condition, we get the relation between the load and dis-

placement in center. Figure 12 represents the relation

curves corresponding to the three kind meshes. We find

that: comparing with the coarse mesh case, the structural

responses agree well for the other two meshes. The

structure is not sensitive to the mesh size in general.

6. Conclusions

In this research, the fracture toughness, the driving force

and the fracture energy of a material with fractal cracks

are investigated and their theoretical expresses in the

fractal space are derived based on fracture mechanics and

fractal geometry. The surface energy and the strain en-

ergy in the fractal fracture zone are theoretical expressed

in the fractal space. The transformation rule of damage

variables in the fractal space and the Euclidean space is

obtained which indicates that the apparent damage vari-

able in the Euclidean space is a special case of the fractal

one in the fractal space with the fractal dimension of

cracks equals to 1. We introduce a plastic yield function

and decompose the damage variable tensor into tensile

and compressive parts to establish a plastic damage con-

stitutive model for concrete in the Euclidean space. Gen-

eralization of this model to the fractal space is done by

utilizing the damage variable transformation rule.

Figure 10. Comparison of the theoretical and experimental data for the load vs. displacement curve.

Figure 11. Distribution of the principle tensile stress.

Figure 12. Influences of mesh size on structural response.

H. ZHANG ET AL.

58

Comparisons of the results obtained from the present

model and tests for concrete under different loading con-

ditions are done to verify the efficiency of this model and

show the necessity of considering the fractal effect in the

constitutive model of concrete. The present model con-

sidering the fractal effect is used to analyze a notched

plain concrete beam under 3-point bending. Mesh sensi-

tivity is also concerned. The numerical results show the

efficiency and validation of the present model for struc-

tural analysis.

7. Acknowledgements

The present research is partly supported by the National

Natural Science Foundation of China (No. 90815012),

which is gratefully acknowledged.

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