Jtam-A4.dvi


JOURNAL OF THEORETICAL

AND APPLIED MECHANICS

55, 4, pp. 1205-1217, Warsaw 2017
DOI: 10.15632/jtam-pl.55.4.1205

AN EXPERIMENTAL STUDY ON THE SHEAR STRENGTH OF SFRC

BEAMS WITHOUT STIRRUPS

Guray Arslan, Riza Secer Orkun Keskin, Semih Ulusoy

Yildiz Technical University, Department of Civil Engineering, Istanbul, Turkey

e-mail: aguray@yildiz.edu.tr; okeskin@yildiz.edu.tr; smhulusoy@gmail.com

The use of steel fibers in reinforced concrete (RC) structural members aims at the impro-
vement of mechanical properties of such members. This study focuses on shear strength
characteristics of steel fiber reinforced concrete (SFRC) beamswithout stirrups. Test speci-
mens consisting of three RC and ten SFRC beams without stirrups have been tested under
three-point loading in order to investigate the effects of fiber content and shear span-to-
-effective depth ratio on the shear strength. Furthermore, an equation developed previously
for predicting the ultimate shear strength of SFRC beams without stirrups is proposed to
predict the diagonal cracking strength of SFRC beams without stirrups.

Keywords: steel fiber, reinforced concrete, shear strength, beam

1. Introduction

Concrete is a brittle material that has a relatively low tensile strength. This makes reinforced
concrete (RC) beams without any shear reinforcement vulnerable to shear failure. Such brittle
materials have been reinforced by using various types of fibers since ancient times. A substantial
amount of research has been carried out to investigate the use of steel fibers for enhancing
mechanical properties of concrete over the last half century (ACI, 1996). The focus of this study
is on shear strength characteristics of low- and normal-strength steel fiber reinforced concrete
(SFRC) beams without stirrups. It has been shown through experimental studies that the use
of steel fibers improves those characteristics significantly (Batson et al., 1972; Kadir and Saeed,
1986; Mansur et al., 1986; Uomoto et al., 1986; Lim et al., 1987; Narayanan and Darwish,
1987; Li et al., 1992; Swamy et al., 1993; Noghabai, 2000; Kwak et al., 2002; Rosenbusch and
Teutsch, 2002; Dupont and Vandewalle, 2003; Cucchiara et al., 2004; Parra-Montesinos, 2006;
Parra-Montesinos et al., 2006; Dinh et al., 2010; Ding et al., 2011; Aoude et al., 2012; Minelli
and Plizzari, 2013; Minelli et al., 2014; Sahoo and Sharma, 2014; Shoaib et al., 2014; Singh
and Jain, 2014; Sahoo et al., 2015). Besides, various studies have been conducted to develop
an accurate model for predicting the shear strength of SFRC beams without stirrups (Sharma,
1986; Narayanan andDarwish, 1987; Ashour et al., 1992, Swamy et al., 1993; Imam et al., 1997,
Khuntia et al. 1999; Kwak et al., 2002; RILEM, 2003; Yakoub, 2011; Gandomi et al., 2011;
Dinh et al., 2011; Arslan, 2014). Despite these studies, SFRChas not yet achieved awidespread
structural use. It is essential to increase the experimental database for both verifying the current
models and developing more accurate ones.
Theobjective of this study is to investigate shear strength characteristics of low- andnormal-

-strength SFRC beams without stirrups experimentally. A total of thirteen specimens, three of
whichbeingRCand theothers SFRCbeams,havebeen testedunder three-point loading in order
to examine the effects of volume fraction of steel fibers Vf and shear span-to-effective depth
ratio a/d on the shear strength of SFRC beams without stirrups. Furthermore, the ultimate
shear strengths and diagonal cracking strengths of test specimens have been predicted by using



1206 G. Arslan et al.

a number of equations available in the literature, and a comparison of those predictions is
presented. A modified version of the equation proposed by Arslan (2014) for predicting the
ultimate shear strength of SFRCbeamswithout stirrups is suggested for predicting the diagonal
cracking strength of SFRC beams without stirrups.

2. Experimental program

Test specimens consisting of threeRC and ten SFRCbeams have been divided into three groups
as A2.5, A3.5 and A4.5 series based on the shear span-to-effective depth ratio. The beams of
A2.5 series have a shear span-to-effective depth ratio of 2.5, which is usually defined as the lower
limit for slender RC beams without stirrups. The shear span-to-effective depth ratios of the
beams of A3.5 andA4.5 series have been chosen as 3.5 and 4.5, respectively, in order to observe
shear failure resulting from diagonal tension. The geometrical properties of test specimens are
shown in Fig. 1. All beams have the same cross-section of 150mm by 230mmwith an effective
depth of 200mm. The beams of A2.5 series are 1400mm long, whereas the beams of A3.5 and
A4.5 series are 2200mm long.

Fig. 1. Configuration and geometry of test specimens; (a) A2.5 series, (b) A3.5 series, (c) A4.5 series

Alongitudinal reinforcement ratioρof 1.34%hasbeenchosen toavoid anyprematureflexural
failure. Two deformed (S420 grade) steel bars of 16mm diameter were used as the longitudinal
reinforcement for all beams. Hooked-end steel fibers with a length Lf of 30mm and a nominal
diameterDf of 0.55mm, resulting in an aspect ratioLf/Df of 54.5, were used as the only shear
reinforcement. Each group of test specimens includes beams with the volume fraction of steel
fibers ranging from 0.0% to 3.0%.



An experimental study on the shear strength of SFRC beams... 1207

A specimen label consists of a combination of letters and numbers. Each label starts with
an “A” followed by 2.5, 3.5 or 4.5 to designate the shear span-to-effective depth ratio and
continues with an “F” to indicate the volume fraction of steel fibers followed by 1.0, 2.0 or 3.0
to designate the volume fraction of steel fibers. For example, a beam having a shear span-to-
-effective depth ratio of 3.5 with a volume fraction of steel fibers equal to 1.0% is labeled as
A3.5F1.0. The specimens labeled as A2.5R, A3.5R and A4.5R are the reference beams that do
not contain any steel fibers.

Table 1.Properties of test specimens

Test specimen fc [MPa] Vf [%] a/d l [mm]

A2.5R 39.00 0.0
A2.5F1.0a 33.68 1.0
A2.5F1.0b 24.53 1.0 2.5 1400
A2.5F2.0 21.43 2.0
A2.5F3.0 9.77 3.0

A3.5R 31.52 0.0

3.5 2200
A3.5F1.0 20.21 1.0
A3.5F2.0 21.43 2.0
A3.5F3.0 27.91 3.0

A4.5R 41.82 0.0

4.5 2200
A4.5F1.0 24.53 1.0
A4.5F2.0 21.43 2.0
A4.5F3.0 27.91 3.0

The properties of test specimens are summarized in Table 1, where fc is the concrete com-
pressive cylinder strength and l is the length of test specimen. All specimens have been cast
with the concretemix given inTable 2. The concrete compressive strength of each specimen has
been determined by using either 150×150×150mm cube or 100×100mm cylinder samples. The
concrete compressive strength of A2.5F3.0 is notably low compared to the others. This might
have been occurred due to poor mixing and/or compacting of concrete leading to a relatively
low concrete compressive strength.

Table 2.Concrete mix

Materials

A2.5R, A2.5F3.0, A2.5F1.0a, A2.5F1.0b,
A3.5R, A3.5F3.0, A2.5F2.0, A3.5F1.0, A3.5F2.0,
A4.5R, A4.5F3.0 A4.5F1.0, A4.5F2.0

Mixture proportions [kg/m3]

0-5mm crushed sand 1180 1150

5-12mm crushed stone 721 310

12-22mm crushed stone – 470

Fly ash (40% of binder) 80 90

Cement CEMI 42.5R 240 220

Water/binder 0.55 0.55

Superplasticizer 3.20 3.10

A load-controlled testprocedurehasbeen followed such that all specimenswere incrementally
loaded up to the failure. After each load increment, the deflections were measured by means of
linear variable differential transducers (LVDTs) placed at locations 1, 2 and 3 shown in Fig. 1,
and the crack pattern was monitored visually throughout the test.



1208 G. Arslan et al.

3. Experimental results

At the early stages of loading, fine vertical cracks were observed in the vicinity of mid-span of
each beam. With the increasing load, new flexural cracks formed away the mid-span. With a
further increase in the load, the flexural cracks started then to propagate diagonally towards the
applied load andadditional diagonal cracks began to form farther away themid-span.The failure
mechanisms of test specimens except for A4.5F2.0 and A4.5F3.0 were characterized by a wide
diagonal crack. It was observed that (i) the failure mechanisms were controlled by an increased
shear strength and the dowel effect, and reduced crack spacing and crack width resulting from
the crack-bridging ability of steel fibers, and (ii) the specimens exhibited large deflections at
failure. The crack patterns of test specimens at failure are shown in Fig. 2.

Fig. 2. Crack patterns of test specimens

It is usually assumed that the diagonal tension failure of an RC beam without stirrups
initiates when the principal tensile stresses within the shear span exceed the tensile strength of
concrete and a diagonal crack propagates through the beamweb. In the studies of Arslan (2008,
2012) andArslanandPolat (2013), adiagonal crack isdefinedasamajor inclinedcrack extending
from the level of the longitudinal reinforcement towards the applied load, and the load at the
growth of the first inclined crack is termed as the diagonal cracking load. The diagonal cracking
load Pcr, the mid-span deflection at diagonal cracking δcr, the ultimate load Pu, the ultimate
mid-span deflection δu, the diagonal cracking strength vcr and the ultimate shear strength vu for
each test specimen are given in Table 3, where the diagonal cracking strength and the ultimate



An experimental study on the shear strength of SFRC beams... 1209

shear strength are the diagonal cracking load and the ultimate load divided by the product of
beam thickness bw and effective depth, respectively. The load-deflection curves of all specimens
are plotted in Fig. 3.

Table 3.Experimental results

Test Pcr δcr Pu δu vcr vu
δu/δcr vu/vcr

specimen [kN] [mm] [kN] [mm] [MPa] [MPa]

A2.5R 65 1.23 81 1.89 1.08 1.35 1.54 1.25

A2.5F1.0a 85 4.31 130 6.69 1.42 2.17 1.55 1.53

A2.5F1.0b 70 4.41 88 5.71 1.17 1.47 1.29 1.26

A2.5F2.0 70 2.75 100 5.09 1.17 1.67 1.85 1.43

A2.5F3.0 60 4.90 78 7.79 1.00 1.30 1.59 1.30

A3.5R 60 2.81 62 2.83 1.00 1.03 1.01 1.03

A3.5F1.0 55 2.80 65 4.26 0.92 1.08 1.52 1.17

A3.5F2.0 60 3.08 85 6.36 1.00 1.42 2.06 1.42

A3.5F3.0 95 5.09 117 6.83 1.58 1.95 1.34 1.23

A4.5R 60 5.51 76 7.37 1.00 1.27 1.34 1.27

A4.5F1.0 60 4.60 85 8.70 1.00 1.42 1.89 1.42

A4.5F2.0∗ 45 8.54 70 15.35 0.75 1.17 1.80 1.56

A4.5F3.0∗∗ – – 97 18.63 – 1.62 – –
∗ Failed in shear-flexure; ∗∗ failed in flexure

3.1. Influence of volume fraction of steel fibers

Experimental results given in Table 3 and Fig. 3 clearly show that the use of steel fibers
improved the shear strength and deformation capacity considerably. In the case of A2.5 series,
the use of steel fibers in the amounts of 1.0% and 2.0% by volume increased the ultimate shear
strength by 9%and 23%, respectively, and increased the deflection capacity 3.02 and 2.69 times,
respectively. It is tobenoted that increasing thevolume fraction of steel fibers from1.0%to 2.0%
for approximately the same concrete compressive strength (A2.5F1.0b and A2.5F2.0) increased
the ultimate shear strength by 14%butdid not increase the deflection capacity. A2.5F3.0 cannot
be compared directly since its concrete compressive strength is significantly low. In the case of
A3.5 series, an increase in the ultimate shear strength due to the use of steel fibers in the
amounts of 1.0%, 2.0% and 3.0% is 5%, 37% and 89%, respectively, and the deflection capacity
is increased 1.51, 2.25 and 2.41 times, respectively.

For a better understandingof the effect of fiber content on the shear strength, the normalized
maximumshear stress against thevolume fractionof steel fibers for eachbeamisplotted inFig. 4.
It is clearly observed that the normalizedmaximum shear stress increases with the fiber content
in the case of A2.5 andA3.5 series. A similar trend cannot be observed in the case of A4.5 series
since A4.5F2.0 and A4.5F3.0 failed in flexure.

Even though the use of steel fibers enhanced the shear strengths and deformation capacities
of the beams considerably, it was still not able to change the failure mechanisms of the beams
of A2.5 and A3.5 series. On the other hand, the use of steel fibers in the amount of 3.0% in the
case of A4.5 series both increased the shear strength and the deformation capacity by 28% and
152%, respectively, and changed the failuremode from shear to flexure. It is to be noted that a
high volume fraction of steel fibers, i.e. 3.0%, was required to prevent the shear failure and use
the flexural capacity. However, it may not be practical to work with a concrete mix having such
a high volume fraction of steel fibers. Instead, steel fibers can be used together with a limited
amount of stirrups to modify the failure mode.



1210 G. Arslan et al.

Fig. 3. Load-deflection curves; (a) A2.5 series, (b) A3.5 series, (c) A4.5 series

Fig. 4. Normalizedmaximum shear stress vs. fiber content



An experimental study on the shear strength of SFRC beams... 1211

It is observed inTable 3 that the ratio of the ultimate shear strength to the diagonal cracking
strength increases with the volume fraction of steel fibers up to 2.0% for the beams of all three
series, but decreases with an increase in the volume fraction of steel fibers from 2.0% to 3.0% for
the beams ofA2.5 andA3.5 series. A4.5F3.0 exhibited flexural failure and the diagonal cracking
was not observed in this specimen.

3.2. Influence of shear span-to-effective depth ratio

It can be seen in Table 3 that the diagonal cracking strength decreases with the increasing
shear span-to-effective depth ratio as a result of the increasedflexuralmomentand theassociated
principal stresses and the diminishing arching effect. The shear span-to-effective depth ratio
eventually affects the ultimate shear strength.As expected for the reference beams, the ultimate
shear strength of A2.5R, which has the smallest shear span-to-effective depth ratio, is greater
than that of the other reference beams; however it has a smaller deflection capacity. A similar
relationship between the beams with the volume fraction of steel fibers of 2.0% is observed.
A2.5F2.0 has a greater load carrying capacity and a smaller deflection capacity than A3.5F2.0
and A4.5F2.0 do.

It is observed that increase in thedeflection capacity decreaseswith the increasing shear span-
to-effective depth ratio for agiven fiber content.Thedeflection capacities ofA2.5F1.0b,A3.5F1.0
and A4.5F1.0 are 3.02, 1.51 and 1.18 times those of A2.5R, A3.5R and A4.5R, respectively.
The use of steel fibers in the amount of 2.0% by volume resulted in deflection capacities 2.69,
2.25 and 2.08 times those of the reference specimens for A2.5F2.0, A3.5F2.0 and A4.5F2.0,
respectively. Experimental results manifest that it is essential to consider the effect of shear
span-to-effective depth ratio in predicting the shear strength of SFRCbeams, as donebySharma
(1986), Narayanan and Darwish (1987), Ashour et al. (1992), Imam et al. (1997), Kwak et al.
(2002), Gandomi et al. (2011) and Arslan (2014).

4. Predicting the shear strengths of test specimens

Anumberof equations proposed for predicting theultimate shear strengthanddiagonal cracking
strength of SFRC beams without stirrups are considered. The statistical evaluations of the
equations considered within the scope of this study are available in the work of Arslan (2014).
In this study, the equations are used only for predicting theultimate shear strength anddiagonal
cracking strength of test specimens.

4.1. The equations for ultimate shear strength

Sharma (1986) proposed a simple empirical equation for predicting the ultimate shear
strength of SFRC beams without stirrups. The equation, which is recommended byACI (1988)
(vu in MPA), is

vu = kfct
(d

a

)0.25
(4.1)

where fct is the concrete tensile strength, k=1 if fct is obtained by a direct tension test, k=2/3
if fct is obtained by an indirect tension test and k=4/9 if fct is obtained by using themodulus
of rupture or fct =0.79

√
fc.

Narayanan and Darwish (1987) proposed an empirical equation as

vu = e
(

0.24fsp+80ρ
d

a

)

+vb (4.2)



1212 G. Arslan et al.

where e=1.0 for a/d> 2.8 and e=2.8d/a for a/d¬ 2.8, fsp = fcuf/(20−
√
F)+0.7+

√
F is

the computed value of split-cylinder strength of fiber concrete, fcuf is the cube strength of fiber
reinforced concrete, F =(Lf/Df)Vfdf is the fiber factor (df is the fiber bond factor that is 0.5
for round, 0.75 for crimped and 1.0 for indented fibers), vb =0.41τF is the pull-out strength of
fibers along the inclined crack and τ is the average fibermatrix interfacial bond stress equal to
4.15MPa.
Ashour et al. (1992) revised the equations given by the ACI 318 code (ACI, 2014) and

Zsutty (1971) for predicting the ultimate shear strength of RC beams without stirrups in order
to propose two empirical equations for SFRC beams with a/d­ 2.5 as

vu =
(

0.7
√

fc+F
)d

a
+17.2ρ

d

a
vu =

(

2.11 3
√

fc+7F
)

3

√

ρ
d

a
(4.3)

respectively.
Swamy et al. (1993) proposed an equation based on the truss model as

vu =0.37τVf
Lf
Df
+0.167

√

fc (4.4)

where τ is assumed to be 4.15MPa as suggested by Narayanan and Darwish (1987).
Imam et al. (1997) modified the equation that Bazant and Sun (1987) had developed to

predict the ultimate shear strength of RC beams without stirrups to propose the relationship

vu =0.6
1+

√

5.08/da
√

1+d/25da

3

√

ρ(1+4F)

(

f0.44c +275

√

ρ(1+4F)

(a/d)5

)

(4.5)

where da is the maximum aggregate size and df is 0.5 for smooth, 0.9 for deformed and 1.0 for
hooked fibers.
Khuntia et al. (1999) proposed the following equation

vu =(0.167+0.25F)
√

fc (4.6)

where df is 2/3 for plain and round, 1.0 for hooked or crimped fibers.
Kwak et al. (2002) developed an equation by using the form of the equation proposed by

Zsutty (1971) combined with an additional term accounting for the contribution of steel fibers
and proposed two versions of the equation with different constants as

vu =2.1ef
0.7
sp

(

ρ
d

a

)0.22
+0.8v0.97b (4.7)

where e=1.0 for a/d> 3.5 and e=3.5d/a for a/d¬ 3.5, and

vu =3.7e
3

√

f2sp
3

√

ρ
d

a
+0.8vb (4.8)

where e=1.0 for a/d> 3.4 and e=3.4d/a for a/d¬ 3.4.
According to RILEM (2003), the ultimate shear strength of SFRC beams without stirrups

is calculated as

vRd,3 =0.12k
3
√

100ρfc+0.7kfk1τfd (4.9)

where k = 1+
√

200/d ¬ 2 (d is in mm), ρ¬ 0.02, kf is a factor considering the contribution
of flanges in a T-section and is equal to 1 for rectangular sections, k1 = 1+

√

200/d ¬ 2 (d is



An experimental study on the shear strength of SFRC beams... 1213

inmm), τfd =0.12fRk,4 is the design value of increase in shear strength due to steel fibers and
fRk,4 is the characteristic residual strength for the ultimate limit state.

Yakoub (2011) used an expression developed for predicting the contribution of steel fibers
to the shear strength of SFRC beams tomodify the equations given by Bazant andKim (1984)
and CSAA23.3-04 (CSA, 2004). The resulting equations for a/d­ 2.5 are

vu =0.83ξ 3
√
ρ

(

√

fc+249.28

√

ρ

(a/d)5

)

+0.162F
√

fc

vu =β
√

fc(1+0.70F)

(4.10)

respectively, where ξ = 1/
√

1+d/(25da) is the aggregate size effect factor, β = [0.4/(1 +
1500εx)][1300/(1000+sxe)] (sxe is inmm), εx =(M/dv+V )/(2EsAs) is the longitudinal strain
at the mid-depth of the beamweb,M and V are the external failure moment and shear acting
on the section, respectively, dv is the flexural lever arm equal to 0.9d or 0.72h (h is the beam
height), whichever is greater, sxe = 35sx/(16 + da) ­ 0.85sx is the equivalent crack spacing
factor that accounts for the maximum aggregate size effects on the shear strength, sx is the
crack spacing parameter that accounts for the crack spacing at the mid-depth of the beam and
df is 0.79 for sheared, 0.83 for crimped, 0.89 for duoform, 0.91 for rounded, 0.92 for indented
cut wire and 1.00 for hooked fibers.

Gandomi et al. (2011) developed a nonlinearmodel bymeans of linear genetic programming
as

vu =2
d

a
(ρfc+vb)+2

d

a

ρ

(288ρ−11)4
+2 (4.11)

Dinh et al. (2011) proposed an equation as the summation of the shear stress carried across
the compression zone and the vertical component of the diagonal tension resistance provided by
steel fibers, such that

vu =0.13ρfy +1.2
4

√

Vf
0.0075

(

1−
c

d

)

(4.12)

where fy is the yield strength of flexural reinforcement and c is depth of the compression zone,
which can be simply taken as 0.1h.

Arslan (2014) proposed an equation by considering the influences of the shear span-to-
-effective depth ratio, dowel strength of tensile reinforcement and contribution of steel fibers
to the shear strength as

vu =
(

0.2 3
√

f2c
c

d
+
√

ρ(1+4F)fc
)

3

√

3

a/d
(4.13)

where (c/d)2+(600ρ/fc)(c/d)−600ρ/fc =0.

4.2. The predictions for ultimate shear strength

Theultimate shear strengths of test specimens excluding the reference beams (A2.5R,A3.5R
andA4.5R), A4.5F2.0 andA4.5F3.0 – since they failed in shear-flexure and flexure, respectively
– have been predicted by using Eqs. (4.1)-(4.13) and the predictions were compared with the
experimental values. Themean value (MV), standard deviation (SD) and coefficient of variation
(COV) of the ratios of the experimental values to the corresponding predictions are given in
Table 4.



1214 G. Arslan et al.

Table 4. Statistics of the ratios of the experimental values to the predictions

Themodel MV SD COV

Sharma (1986) 1.241 0.186 0.150

Narayanan and Darwish (1987) 0.593 0.183 0.309

Ashour et al. (1992), Eq. (4.3)1 0.504 0.186 0.369

Ashour et al. (1992), Eq. (4.3)2 0.783 0.214 0.274

Swamy et al. (1993) 0.734 0.239 0.326

Imam et al. (1997) 0.633 0.201 0.317

Khuntia et al. (1999) 0.853 0.192 0.225

Kwak et al. (2002), Eq. (4.7) 0.543 0.128 0.235

Kwak et al. (2002), Eq. (4.8) 0.574 0.145 0.253

RILEM (2003) 1.361 0.227 0.167

Yakoub (2011), Eq. (4.10)1 0.858 0.126 0.147

Yakoub (2011), Eq. (4.10)2 1.342 0.329 0.246

Gandomi et al. (2011) 0.480 0.116 0.242

Dinh et al. (2011) 0.725 0.172 0.238

Arslan (2014) 0.833 0.098 0.118

The equations proposed by Sharma (1986), RILEM (2003) andYakoub (2011) (Eq. (4.10)2)
underestimate the ultimate shear strengths of test specimens involved in this study, whereas the
ones proposed by Narayanan and Darwish (1987), Ashour et al. (1992) (Eq. (4.3)1), Imam et
al. (1997), Kwak et al. (2002) andGandomi et al. (2011) largely overestimate the experimental
values. It is observed from the statistics given in Table 4 that the equation proposed byYakoub
(2011) (Eq. (4.10)2) andArslan (2014) provide themost accurate predictions for the specimens
involved in this study, where as the predictions of the equation of Arslan (2014) are slightly
better. The ratios of the experimental values to the corresponding predictions of the equation of
Arslan (2014) have amean value of 0.833 with the lowest coefficient of variation equal to 0.118.

4.3. The equations for diagonal cracking strength

Narayanan and Darwish (1987) proposed an empirical equation for predicting the diagonal
cracking strength as

vcr =0.24fsp+20ρ
d

a
+0.5F (4.14)

Kwak et al. (2002) proposed an equation by following a procedure similar to the one followed
for developing Eqs. (4.7) and (4.8) as

vcr =3
3

√

f2sp
3

√

ρ
d

a
(4.15)

The equation proposed by Arslan (2014) and given in Eq. (4.13) has been modified by
introducing a strength reduction factor of 0.6, whichwas obtained through a regression analysis
undertaken to identify the strength reduction factor in calculating thediagonal cracking strength
of SFRC slender beamswithout stirrups by using the results of existing experimental data. The
resulting equation is

vu =0.6
(

0.2 3
√

f2c3
c

d
+
√

ρ(1+4F)fc
)

3

√

3

a/d
(4.16)



An experimental study on the shear strength of SFRC beams... 1215

4.4. The predictions for diagonal cracking strength

The diagonal cracking strengths of test specimens containing steel fibers excludingA4.5F3.0
that failed in flexure have been predicted by using Eqs. (4.14)-(4.16). Themean value, standard
deviation and coefficient of variation of the ratios of the experimental values to the corresponding
predictions are given in Table 5. It is observed from Table 5 that Eq. (4.16) performed better
in predicting the diagonal cracking strengths of the considered test specimens than the other
equations do. The ratios of the experimental values to the corresponding predictions obtained
fromEq. (4.16) have amean value of 1.032with the lowest coefficient of variation equal to 0.079.

Table 5. Statistics of the ratios of the experimental values to the predictions

Themodel MV SD COV

Eq. (4.16) 1.032 0.082 0.079

Narayanan and Darwish (1987) 0.899 0.166 0.185

Kwak et al. (2002) 1.102 0.131 0.119

5. Conclusion

An experimental study has been conducted to investigate shear strength characteristics of low-
and normal-strength SFRC slender beamswithout stirrups. The fact that the use of steel fibers
improves the ultimate shear strength, diagonal cracking strength and ductility significantly is
justified based on the following observations.
• Theuse of steel fiberswith volume fractions of 1.0%and 2.0% increased the ultimate shear
strength by 9% and 23%, respectively, in the case of a shear span-to-effective depth ratio
of 2.5 and by 5% and 37%, respectively, in the case of a shear span-to-effective depth ratio
of 3.5.

• The use of steel fibers in an amount of 3.0% was not able to change the failure mode of
test specimens with a shear span-to-effective depth ratio of either 2.5 or 3.5, but it made
the beam with a shear span-to-effective depth ratio of 4.5 fail in flexure instead of shear.
However, it is to be noted that 3.0%may not be a practical volume fraction in the context
of workability of a concrete mix. The use of steel fibers with a limited amount of stirrups
can be amore practical way to modify the failure mode.

• The ratio of the ultimate shear strength to the diagonal cracking strength increased with
the volume fraction of steel fibers up to 2.0% for all series of beams.

• Thediagonal cracking strength decreasedwith the increasing shear span-to-effective depth
ratio, which eventually affected the ultimate shear strength.This implies that it is essential
to consider the effect of shear span-to-effective depth ratio in predicting the shear strength
of SFRC beams.

• The use of steel fibers increased the deflection capacities significantly in all cases.

Besides the experimental study, the ultimate shear strengths and diagonal cracking streng-
ths of SFRC beams involved in the experimental study were predicted by various equations
available in the literature. Among the fifteen equations considered for predicting the ultimate
shear strength of SFRCbeamswithout stirrups, the equation proposedbyArslan (2014) had the
best performance. The equation of Arslan (2014) wasmodified to predict the diagonal cracking
strengths of SFRCbeams involved in this studyby introducing a strength reduction factor equal
to 0.6. Themodified equation had a better performance than those of the other two considered
equations. Since the number of test specimens was limited, themodified version of the equation
of Arslan (2014) should be verified with more data.



1216 G. Arslan et al.

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Manuscript received January 19, 2017; accepted for print May 9, 2017