AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   13 (2020) 031–036 
 

   
       Contents lists available at http://qu.edu.iq 

 

Al-Qadisiyah Journal for Engineering Sciences 

  
Journal homepage: http://qu.edu.iq/journaleng/index.php/JQES  

  

 

* Corresponding author.  

E-mail address: Adnan.alsibahy@qu.edu.iq  (Adnan Al-Sibahy ) 

 

https://doi.org/10.30772/qjes.v13i1.647  

2411-7773/© 2019 University of Al-Qadisiyah. All rights reserved.    

 

  

Structural Behavior of Novel ECC Short Columns Subjected to Eccentric 

Loading  

Safaa mashshay a, Adnan Al-Sibahya a* 

a Civil Engineering Department, College of Engineering, The University of Al-Qadisiyah, Iraq.  

 

A R T I C L E  I N F O 

 

Article history:  

Received 05 October 2019 

Received in revised form 16 January 2020 

Accepted 28 January 2020 

 

Keywords: 

ECC columns  

hybrid ECC  

eccentric columns  

 

 
A B S T R A C T 

This study was undertaken in order to investigate the structural behaviour of novel Engineering Cementitious 

Composites (ECC) columns subjected to eccentric loading. These columns were experimentally formulated using a 

hybridization of steel and polypropylene fibres. Two ratios were adopted for the steel fibres of 0.5% and 1%, whilst 

the polypropylene fibre was kept to be constant at a ratio of 0.5% for all of the ECC columns. The eccentric loads 

were applied at two eccentricities: small (h/6) and large (5h/12). A comparison was also made with the behaviour of 

self-compacting concrete and traditional ECC columns containing either steel or polypropylene fibres. The vertical 

and lateral deformations as well as the maximum load at failure were noted. The results obtained showed that the 

hybrid ECC columns exhibited higher load carrying capacities when compared with those of both self-compacting 

concrete and traditional ECC columns. The percentage increase was 30%.  The hybrid ECC column samples 

containing 1% steel fibre did not show a signification difference in the load-deformation behaviour when it compared 

with that containing 0.5% steel fibre. The values of eccentricity governed the global behaviour of the tested columns. 

The predicated load carrying capacity of the ECC columns needs a magnification factor in case of concentric test, and 

to take into account the existence of fibres ratio when calculating the area of steel reinforcement for eccentric loading. 

  © 2020 University of Al-Qadisiyah. All rights reserved. 

1. Introduction

Developing the behaviour of structural members is the main concern for the 

most of the published research works in the construction field nowadays. In 

general, such developing can be obtained either through improving the 

composition of these members or by updating the implementation techniques 

used. Reinforced columns are part of these structural members which generally 

referred to as compression members [1]. In some cases, columns may carry 

bending moments about one or both axes of the cross section. The general 

behaviour of columns is governed by the amount of steel. Reinforcement 

available for both longitudinal and transverse directions, the strength of the 

concrete used, conditions of the supports and the slenderness ratio [2]. 

Depending on the nature of the imposed load, the failure modes of the 

reinforced concrete columns are in the forms of crushing, shearing and bending 

for the loading cases of concentric, transverse and eccentric, respectively [3-5]. 

A combined failure modes may also be found for the same case. 

Several previous studies were carried out for enhancing the integrity of the 

reinforced concrete columns under various conditions of loading. In the last 

decade, there was a tendency for replacing the conventional concrete with 

Engineering Cementitious Composites (ECC) [6-15]. However, it’s used in 

column elements is less than that for flexural structural members [11]. Except 

for the absent of coarse aggregate, this material has a similar constituents as for 

the fiber reinforced concrete (FRC). Nevertheless, ECC usually exhibits strain-

hardening after the propagation of the first crack rather than of the usual tension-

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https://doi.org/10.30772/qjes.v13i


 
32 SAFAA MASHSHAY A, ADNAN AL-SIBAHYA  / AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES 13 (2020) 031–036

 
 

 
 

softening [6]. Although the desired advantages of ECC mentioned above, 

improving its properties still needs for investigation. Since there is no published 

research work about using hybrid fibers in ECC, so it is necessary to undertake 

such trend into consideration. In this paper, using hybrid steel and 

polypropylene fibers at different ratios in the formulation of reinforced column 

members has been experimentally investigated. These columns were tested 

under the actions of eccentric loading. A comparison was also made with the 

traditional ECC containing either steel or polypropylene fibers as well as with 

the behaviour of reinforced self-compacting concrete columns. Some 

expressions were suggested to identify the general behaviour under the test 

conditions. 

2. Experimental Work 

2.1. Materials used 

An ordinary Portland cement by Lafarge Company was used in this study. 

It was compliant with EN BS 197-1 [16]. Locally available natural sand from 

Al-Najaf quarries was used as a fine aggregate to produce both of the ECC and 

self-compacting concrete specimens. It has a maximum particle size of 4.75 

mm. On the other hand, crushed gravel with a maximum size of 10 mm was 

used as a coarse aggregate to produce the self-compacting concrete specimens 

only. It was provided from Al-Nibaei quarry. Both types of aggregate are 

consistent with the grading limits of EN BS 882.1992 [17] and they have 

sulphate contents of 0.216% and 0.082%, respectively. A limestone powder was 

used as a filler in preparing of the self-compacting concrete columns, while 

silica fume was used in producing of ECC columns. For all of the column 

samples, the Daracem SP6 superplasticizer admixture of the sulphonated 

naphthalene formaldehyde condensate SNF [18] was used, its maximum 

chloride and alkali contents were < 0.1% and 0.5% by mass, respectively. Two 

types of fibres were used, namely steel and polypropylene fibres. They were 

incorporated in the ECC column samples in different ratios as a percentage from 

the total volume of the mixture. The aspect ratios of the steel and polypropylene 

fibres were 65 and 375, respectively. Two different sizes of deformed steel bars 

of Ø10 and Ø12 were used in all of the column samples as the transverse and 

main reinforcements, respectively. The values of the yield and ultimate strength 

of the former steel bars were 480 MPa and 700 MPa, respectively.   

2.2.  Selection of the concrete mix 

For the purpose of comparison, a self-compacting concrete was selected as 

a reference mix. The reason for that is the ECC usually has high flowability and 

its need for compaction effort is usually minimal [15]. On this basis, the 

composition of the reference mix was selected to be in the strength level of 50 

MPa at 28 days. This in turn gives a mix proportion of 1:1.5:1.6 with cement 

content and w/c ratio of 430 kg /m3 and 0.42, respectively. Both of limestone 

and superplasticizer were used in this mix with ratios of 0.2% and 1.5%, 

respectively. On the other hand, the suggested mix proportion of cement: 1, 

silica fume: 0.22, sand: 2, w/c : 38% by volume was selected for ECC. This 

employ 570 kg /m3 cement, 1140 kg /m3 sand and 124 kg /m3 silica fume. Two 

groups of the hybrid fibres were used in the ECC ; the first incorporated 0.5% 

steel and 0.5% polypropylene fibres, and the second incorporated 1% steel and 

0.5% polypropylene fibres. The former fibre percentages were recommended 

by previous studies [1, 5]. 

 

 

 

2.3. Description of the tested samples 

 The experimental programme comprised of testing eight column samples. 

All of the tested columns were square in shape. The height of columns was 

selected to be 1200 mm. The column samples with a square cross section of  

200*200 mm. This in turn gives a slenderness ratio of 20.  A minimum steel 

area  (AS ≥ 1%) was used for reinforcing the longitudinal direction, namely 

4Ø12mm. Whereas, 12 stirrups were adopted using Ø10@100mm c/c as a 

reinforcement for the transverse direction. The calculations for both of the 

former reinforcements was based upon the requirement of ACI 318M-11 Code 

[19]. In order to avoid the concentration of stresses near the loading plate, the 

upper and lower parts of the columns were expanded to be in a tapered shape. 

Same technique was also used by [15]. Figure 1 shows the details of the tested 

columns.  

Figure 1. Details of the tested columns 

2.4. Mixing, casting, curing operations and the tested parameters 

As shown in Figure 2, for all of the column samples, the mixing, casting and 

curing operations were carried out based upon the procedure suggested by BS 

EN 12390-2 (BSI, 2009c) [20]. Before running the test, all of the column 

samples were capped using rapid cement mortar, then they were painted in a 

white colour. During the lifting process, the location of columns was centrally 

adjusted with the centre line of the testing machine. In order to achieve the 

objective of this study, the nature of the applied load was in two categories; 

namely small (1/6 h) and large (5/12 h). The tested columns were designated 

based on the type of column, nature of loading and type and ratio of the fibre 

used, as illustrated in Table 1. The applied load was manually controlled and a 

loading rate of 0.5 MPa/Sec was adopted. During running of the test, both 

vertical and lateral deformations were measured using LVDT at the top and 

mid-height of the column. For each column, the test was performed until failure 

and the load-crack history was recorded. In addition, the failure mode and 

critical zones were monitored for each case. 



 
33 SAFAA MASHSHAY A, ADNAN AL-SIBAHYA  / AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES 13 (2020) 031–036

 
 

 
 

Table 1. The designation of the tested columns with their parameters    

3. Results and discussions 

The results obtained for the load-deformation relationships for various 

column samples are shown in Figures 3 to 8. A superior behaviour was noted 

for the hybrid ECC columns in terms of deformation and load carrying capacity 

aspects compared with those containing self-compacting concrete and those of 

the traditional ECC. For the concrete and hybrid ECC columns subjected to 

eccentric load of h/6, the results obtained are presented in Figures 3and 4. Both 

of hybrid ECC columns reached the level of 1400 kN load carrying capacity 

with a notable increase for the sample containing 1% steel fibre. On the other 

hand, the concrete column (CBe1) exhibited a lower failure load at 1070 kN. 

This in turn gives percentage increase of 30% for the hybrid ECC columns 

.Identical shape for the load-deformation curve in both directions was observed. 

The end values of vertical deformations for the columns samples of concrete, 

hybrid ECC with 0.5% steel fibre and that of 1% steel fibre were 5mm, 9mm 

and 13mm, respectively. The corresponding values for the lateral deformations 

were 5mm, 12mm and 17mm, respectively. Figures 5 to 8 show a detail 

comparison for all of the tested columns subjected to eccentric load of 5h/12 in 

terms of load-vertical and lateral deformations, respectively. The role of steel 

fibre was clear regarding improving the load carrying capacity feature. The 

traditional ECC column with 1% steel fibre exhibited the highest strength 

capacity at failure load at 925 kN. If the polypropylene fibre is used the 

aforementioned strength capacity will be reduced. This could be explained by 

two issues: the first is related to the lower strength capacity of the polypropylene 

fibre itself in both compression and tension aspects when compared with those 

for steel fibre; and the second, is related to the present of such kind of fibre 

leads to the formation of entrapped voids within the ECC composition which 

represents a weakness point that results in reducing the final strength of the 

column sample. This behaviour was clearly shown for the column containing 

polypropylene fibre alone, in which the load-bearing capacity reached 750 kN, 

meaning 20% percentage reduction compared with that of steel fibre. If 

combination of both fibres is used as in the EBe2-1 S-0.5 P and EBe2-0.5 S-0.5 

P columns, the load carrying capacity will increase with a percentage equivalent 

to the added ratio of steel fibre. In general, all of the column samples 

incorporating fibres showed vertical deformation of 11mm with a parentage 

increase of 50% compared with that of concrete column. Similar attitude was 

also noted for the lateral deformation recorded at the mid height of the column. 

However, the column formulated with polypropylene fibre alone revealed the 

highest lateral deformation due to its capability to reduce the width of cracks. 

Consequently, higher lateral buckling can be achieved prior to the column 

failure. The hybrid columns have more lateral ductile behaviour than that 

containing steel fibre alone. The percentages increase in the value of lateral 

deformation for the EBe2-0 S-0.5 P, EBe2-0.5 S-0.5 P, EBe2-1 S-0.5 P and 

EBe2-1 S-0 P compared with that of concrete sample were 127%, 171%, 180% 

and 116%, respectively. 

 

Figure 2:  Preparation of moulds, mixing and curing 

operations 

 

 

 

 

 

 

 

Figure 3: Load-lateral deformation of columns subjected to 

eccentric load of h/6 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Figure 4: Load-vertical deformation of columns subjected to 

eccentric load of h/6 

 

No. Sample 
Type of  

column 

Cross 

section mm 
e/r 

Steel fibre 

Ratio% 

Polypropylene 

fibre % 

1 EBe1-0.5S-0.5P 

ECC 

200*200 0.4 0.5 0.5 

2 EBe2-0.5S-0.5P 200*200 0.93 0.5 0.5 

3 EBe1-1S-0.5P 200*200 0.4 1 0.5 

4 EBe2-1S-0.5P 200*200 0.93 1 0.5 

5 EBe2-0S-0.5P 200*200 0.93 0 0.5 

6 EBe2-1S-0P 200*200 0.93 1 0 

7 CBe1 
CC 

200*200 0.4 0 0 
8 CBe2 200*200 0.93 0 0 

● CBe2    

   EBe2-0.5S-0.5P             

   EBe2-1S-0.5P 

 

● CBe1    

   EBe1-1S-0.5P             

  EBe1-0.5S-0.5P 

● CBe1    

   EBe1-1S-0.5P             

  EBe1-0.5S-0.5P 



 
34 SAFAA MASHSHAY A, ADNAN AL-SIBAHYA  / AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES 13 (2020) 031–036

 
 

 
 

 

 

 

 

 

 

 

Figure 5: Load-vertical deformation of columns subjected to 

eccentric load of 5h/12 

 

 

 

 

 

 

 

Figure 6: Load-lateral deformation of columns subjected to 

eccentric load of 5h/12 
 

 

 

 

 

 

 

 

 

Figure 7: Load-vertical deformation for various types of 

columns subjected to eccentric load of 5h/12 

 

 

 

 

 

 

 

 

 

Figure 8: Load-lateral deformation for various types of 

columns subjected to eccentric load of 5h/12 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Figure 9: Failure modes for the columns under eccentric 

loading 5h/12; (a) front view, (b) back view 

 

 

 

 

● CBe2    

   EBe2-1S-0.5P             

   EBe2-0.5S-0.5P 
 

● CBe2    

   EBe2-0.5S-0.5P             

   EBe2-1S-0.5P 
 

● CBe2      EBe2-0.5S-0.5P   △  EBe2-1S-0P             

   EBe2-0S-0.5P           ◊ EBe2-1S-0.5P    
 

● CBe2      EBe2-0.5S-0.5P   △  EBe2-1S-0P             

   EBe2-0S-0.5P           ◊ EBe2-1S-0.5P    
 

b 

a 



 
35 SAFAA MASHSHAY A, ADNAN AL-SIBAHYA  / AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES 13 (2020) 031–036

 
 

 
 

For the eccentric loading, composite failure modes of compression and 

bending were noted for both of hybrid ECC columns , as shown in Figure 9a 

and b. Multi cracks were located underneath the tapered part and at the mid 

height of the column which explain the role of the fibres in controlling the 

global failure. More cracks along the column height were noted for all of the 

ECC samples compared with that of concrete sample (CBe2). This is indicative 

for less spacing of cracks which can be achieved when the steel and/or 

polypropylene fibres are used. Spalling behaviour was also observed for the 

concrete column sample. 

Based upon the preliminary mechanical strength testes performed on the 

concrete, traditional ECC and hybrid ECC cube samples, the results of the 

compressive strength values are shown in Table 2. 

Table 2. The values of compressive strengths for different 

composition of columns at 28 days age 

 

 For the case of biaxial bending, Bresler [2] suggested reciprocal method to 

predict the load carrying capacity for the eccentric loading, as in Eq. 1    

  

Table 3. The calculated and measured results of load carrying capacity 

for the eccentric loaded columns 

 

             (1)                                  

 

Where 𝑃𝑛  is the approximate value of ultimate load in biaxial bending with 

eccentricities 𝑒𝑥   and 𝑒𝑦  ; 𝑃𝑛𝑥0 is the ultimate load when only eccentricity 𝑒𝑦  

is present; 𝑃𝑛𝑦0 is the ultimate load when only eccentricity 𝑒𝑥  is present; and 

𝑃0  is the ultimate load for concentrically loaded column. In this study, uniaxial 

loads were adopted, so 𝑃𝑛𝑦0 was only available for estimation. Based upon the 

column strength interaction diagram for the rectangular section with bars on end 

faces and 𝛾 = 0.45 and 0.6, the predicted values of load carrying capacities for 

the eccentric loading columns against their experimentally measured results are 

presented in Table 3. It can be seen that the predicted values of load carrying 

capacities for both of concrete columns (i.e. CBe1 and CBe2) were close to 

those measured values. On the other hand, none of the predicated values of ECC 

columns was in agreement with their corresponding experimental result. In 

order to improve the accurate of calculations, a modified technique was 

suggested to calculate the load carrying capacity from the reciprocal method. 

This was throughout incorporating the fibre ratio in the term of A_st⁄bh. The 

latter is one of the main components of the interaction diagram. This in turn 

means increasing the area of steel reinforcement in an equivalent percentage to 

that of the fibre used. Such modification was only applied in calculation of the 

load carrying capacity of the ECC columns and the results obtained are shown 

in Table 3. Close agreement has been achieved with respect to the experimental 

measurements. 

4. Conclusions 

This study is an attempt to produce a new formulation of ECC columns 

throughout hybridization process using both steel and polypropylene fibers 

followed by a structural evaluation for their behaviour under eccentric loading. 

The main significant findings of this study can be summarized as follows:  

1- Higher load carrying capacities were observed for the hybrid ECC 

columns compared with those of self-compacting concrete under eccentric 

loading scenarios.   

2- Both of the hybrid ECC columns behaved in a similar manner in terms of 

load-deformation criteria with slight increase in the value of lateral 

deformation noted when 1% of steel fibre is used.      

3- The role of steel fibre was demonstrated in preventing the propagation of 

cracks, whilst polypropylene fibre works on minimizing the crack width. 

4- The maximum load at failure was clearly reduced with an increase in the 

value of eccentricity. The percentage of decrease reached about 45%.  

5- In case of eccentric loading, the predicted values of load carrying 

capacities for ECC columns the fiber ratio should be taken in 

consideration in order to compute the maximum load at failure.     

6- Generally, composite compression and flexural failure modes were 

observed for the hybrid ECC columns with eccentric loading incorporated 

multi cracks localized approximately at mid-height of the column.   

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(MPa) 

1 CC 59.6 70.1 
2 ECC-0.5 S-0.5 P 53.9 63.4 
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4 EBe2-0.5 S-0.5 P 813 552 -32 827 +2 
5 EBe2-1 S-0.5 P 850 552 -35 827 -3 
6 EBe2-0 S-0.5 P 795 552 -31 827 +4 
7 EBe2-1 S-0 P 941 552 -41 827 -12 
8 CBe2 624 552 -12 552 -12 



 
36 SAFAA MASHSHAY A, ADNAN AL-SIBAHYA  / AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES 13 (2020) 031–036

 
 

 
 

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