Article


 

  AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   15 (2022) 018–022 
 

   

       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: inm.khld@atu.edu.iq (Khalid M. Breesem) 

 

https://doi.org/10.30772/qjes.v15i1.808 

2411-7773/© 2022 University of Al-Qadisiyah. All rights reserved.                                This work is licensed under a Creative Commons Attribution 4.0 International License. 

    

Improvement behavior of RC beams with continuous spiral stirrups 

under shear 

Thaer Jasim Mohammed a and  Khalid M. Breesemb* 

aDepartment of Civil Techniques, Institute of Technology/ Baghdad, Middle Technical University, Baghdad, Iraq 
bMussaib Technical Institute, Al-furat Al-Awsat Technical University, Babylon, Iraq 

 

A R T I C L E  I N F O 

Article history:  

Received 6 April 2022 

Received in revised form 5 June 2022 

Accepted 3 July 2022 

 

Keywords: 

Spiral stirrups 

RC beam 

Finite element analysis 

Shear strength Each  

 

A B S T R A C T 

Reinforced concrete, RC beams subjected to shear failure which is the most unwanted failure mode due to 

speed progress is studied numerically. Therefore, the effective design of beams is necessary because of the 

sudden failure types of these beams in shear. The minimum shear reinforcement ratio of RC beams must be 

provided around the longitudinal rebars. Thus, the stirrups with different patterns have a significant benefit 

for improving the RC beam. In this paper, the performance of specimens with different spiral stirrups using 

ANSYS programs is investigated by comparing them with conventional stirrups of RC beams. One 

statement on the experimental results has been obtained from previous research Karayannis et al. [17]. The 

behaviors of these experimental beams are compared with finite element analysis of the identical beams. It 

is found that the behaviors of the experimental beam in comparison with the behaviors of the numerical 

beam are slightly different. Based on the FE analysis, the shear strength results demonstrated the mean 

accuracy and standard deviation of about 0.994 and 0.028, respectively, compared with the experimental 

test. Furthermore, the curve determined from FE analysis is consistent with the experiment data. The results 

give knowledge about the importance of spiral stirrups of the beam, and the most effective method among 

the investigated cases. 

 

© 2022 University of Al-Qadisiyah. All rights reserved.     

1. Introduction 

Shear failure behavior is brittle due to the rapid breakdown of 

reinforced concrete beams [1]. It makes predicting the occurrence of shear 

failure is difficult due to low deformations. The use of stirrup correctly is 

necessary for buildings construction to ensure bending failure occurs before 

sudden shear failure. Therefore, it is necessary to discover more effective 

stirrup reinforcement methods for shear beams. Thus, stirrups with different 

patterns are a significant benefit [2]. The spiral reinforcement of seven 

small-sized RC beams enhances the ductility of the beam before shear 

failure occurs. mixed shear reinforcement of RC beam-column joints 

improved failure mechanisms and increased bearing compared to 

specimens with traditional stirrups [3]. 

Moreover, beams with spiral stirrups increased shear resistance and 

improved ductility and peak deformation compared to beams with 

commonly used stirrups [4]. Meanwhile, it is found that the use of spiral 

stirrups in place of conventional rectangular stirrups with the same amount 

in beams improves the beams' torsional ability and performance response 

[5]. So, to enhance constructability and cost, the structural performance of 

reinforced concrete columns was developed by using continuous hoops 

subjected to repeated loads [6].  Joshy and Faisal [7] have improved the 

shear capacity and ductility of 12 self-compacting concrete beams, and 

Corte and Boel [8] stated that the use of spiral stirrups instead of 

conventionally stirrups under the bending test. Also, Shataratet et al. 

recommended using spiral shear stirrups with an angle of about 80° to 

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THAER J. MOHAMMED AND KHALID M. BREESEM /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   15 (2022) 018–022                                                                                     19 

 

improve the ductility and shear behavior of the beams and reduce labor 

costs [9]. In addition, continuous spiral stirrups are recommended in the 

SCC beam at an angle of 85° regardless of the spacing between them. It 

enhances the shear capacity and reduces the construction cost [10]. Thus, it 

is found that few researchers use spiral stirrups rather than traditional 

vertical stirrups [11]. Since the shear failure mechanism is complex, the 

experimental test of beams underestimated the contribution of the stirrups 

but increased the contribution of the concrete component. In contrast to 

analytical methods, stirrups do not reach yield upon failure [12]. 

In general, structural analysis is very complex. Therefore, finite element 

analysis (FE) is used to simulate realistic problems of structures and obtain 

approximate solutions. Finite element analysis has been used widely by 

practicing engineers [13-16]. The finite element method can analyze the 

non-linearity of the behavior of the RC beams. 

2. Research significance 

ANSYS is commercial software for 1D, 2D, and 3D structure behavior 

analysis by geometric model properties, meshing the different shapes and 

post-processing. Thus, numerous engineering and scientific research use 

ANSYS interactive software to evaluate experimental results. In this paper, 

ANSYS software is used to study the performance of beams with different 

continuous spiral stirrups based on the experimental beam that has been 

obtained from previous research Karayannis et al. [17]. 

3. Numerical Analysis 

The numerical analysis employed is finite element analysis of various 

engineering applications of ANSYS software. 

3.1.  Modeling 

The modeling was performed by using ANSYS software for beams with 

various forms of conventional and continuous stirrups and then analyzing 

these models. Then, it was defined as geometric of concrete with both 

longitudinal and stirrups reinforcement details for the beam. Thus, 

analyzing results reveals the importance of spiral stirrups and the most 

effective ones for beams to support the literature survey.  

 

3.2. Details of beams 

A numerical study includes three RC beams with a length of 1.84 m, a width 

of 200 mm, and a height of 300 mm (rectangular section). According to 

experimental research, the shear reinforcement of concrete beams has been 

represented by Karayannis et al. [17]. The beam B1 is with traditional 

closed stirrups (see Fig. 1) and beam B2 is reinforced with continuous spiral 

stirrups. The type of reinforcement of beam B3 is continuous spiral stirrups 

with inclined legs. The diameter of the stirrups is constant at 5.5 mm for all 

beams. The distance between the stirrups is 120 mm with a different pattern 

to obtain almost the same reinforcement ratio of the stirrups, approximately 

p=0.002. A new study is added to the numerical analysis by reducing 

distances between the stirrups to increase the percentage of shear stirrups. 

Therefore, the effect of the ratio of stirrups with different patterns has been 

studied to enhance the shear behavior of the specimens. Also, the effect of 

the grade of concrete strength on the shear strength has been studied. 

3.3. Material properties 

The steel reinforcement and concrete material properties by Karayannis et 

al. [17] have been used in Ansys software in accordance with the 

experimental results as listed in Table 1. 

 

Figure 1. Traditional closed and spiral stirrups of beam B1 and B2 

 

Table 1.  Material properties of specimens 

               Concrete Steel 

Tensile strength, (MPa) 02.85 Stirrup steel (MPa) 220 

Compressive strength (MPa) 28.50 Longitudinal steel (MPa) 500 

Young’s modulus (GPa) 25.00 Young’s modulus (GPa) 200 

Poisson’s ratio 00.20 Poisson’s Ratio  0.3 

3.4. Meshing and loading 

The concrete and steel reinforcement were modeled in the Ansys program 

[18]. A quadrilateral mesh of concrete was used to obtain good results, as 

shown in Fig.2. The number of mesh elements and nodes are 9854 and 

12728, respectively. The location of two-point loading with pinned 

supports on both ends of the model is represented. The applied loading was 

at two points with the distance between it 200 mm in the midspan apart of 

the beams. Meanwhile, the distance between two supports of the beam was 

1.64 m apart. 3D spar elements represent the longitudinal and transverse 

steel reinforcement as link elements (see Fig. 3). Thus, the compatibility 

between practical and numerical data is achieved.  



20                     THAER J. MOHAMMED AND KHALID M. BREESEM /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   15 (2022) 018–022 

 

 

 

 

 

Figure 2. Quadrilateral mesh of concrete 

 

Figure 3. Link elements of different steel reinforcement 

 

3.5. Linear analysis of specimens 

This work uses the ANSYS program to perform a linear analysis of beams. 

The shear failure occurred after several attempts with maximum and 

minimum loading steps, leading to convergence failure at small loading 

increments. 

 

3.6. Effect of stirrup ratio on shear behavior 

In this paper, the numerical results have been verified by comparing them 

with experimental results in the literature reviews. Table 2 presents a 

numerical and experimental comparison of the shear strength of specimens 

with different types of spiral and closed stirrups. The numerical data 

analysis indicated shear failure for all beams consistent with the 

experimental data analysis. In addition, the results revealed that the shear 

strength of spiral reinforcement beams is higher than a conventional beam. 

Fig. 4 shows the  

 

 

4. Results and discussions 

In this section, load-deflection curve of the beam has been obtained by 

numerical analysis. In started, the high-resolution FE analysis is compared 

to the experimental beams. Then, the load-deflection curves defined from 

the FE analysis are less inconsistent with experimental curves after the 

cracks of the beam occurred because the perfect bond between beam 

components (steel reinforcement and concrete material) led to FE results 

having more stiffness. In general, the diagonal shear stress appeared in 

beams. According to the behavior of the curves of specimens, the results 

reveal that the spiral stirrups have higher shear strength than closed stirrups. 

This information agrees with Karayannis C. G. et al. [17]. In general, the 

behavior all curves of the beams B2 and B3 with continuous shear 

reinforcement showed that the shear strength is higher than the specimen 

B1 with stirrups closed. Moreover, the performance of specimen B3 

showed more ductility improvement than the other beams on shear failure 

as compatible with experimental results Chalioris CEand Karayannis CG. 

[19]. 

Table 2.  Comparison between numerical load and experimental load 

of beams [17] 

Bea

m  

Crackin

g load 

(EXP) 

Crackin

g load 

(ANS) 

Ultima

te load 

(EXP) 

Ultima

te load 

(ANS) 

Differen

ce 

Crackin

g load 

Differen

ce 

Ultimate 

load 

B1 148 135 215 210 1.096 1.024 

B2 150 135 247 250 1.111 0.988 

B3 150 135 252 260 1.111 0.969 

             Mean 1.106 0.994 

          Standard deviation 0.009 0.028 

 

Figure 4. The load-defection of the beam with different pattern 

stirrups 

 

 



THAER J. MOHAMMED AND KHALID M. BREESEM /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   15 (2022) 018–022                                                                                     21 

 

4.1. Shear patterns 

The finite element analysis was performed to predict crack development in 

concrete beams. ANSYS records a shear stress during the loading phases. 

The result of all beams appeared failure shear. In the beginning, no cracks 

of all beams were observed, and the behavior was essentially linear until 

the first crack was obtained. Thus, propagation of diagonal shear stress was 

observed in these beams. New diagonal cracks appeared with increasing 

loads, as the number of cracks increased parallel to the primary cracks until 

the final load. Thus, one crack developed significantly from the other cracks 

resulting in sample failure. For beams with different stirrup patterns, FE 

showed that the diagonal shear stress appear in concrete under the point 

loading toward the supports of the beam. So, beams with spiral stirrups have 

shear failure because enough longitudinal steel in the flexure area led to 

incline cracks appearing in concrete faster. For Example, Fig. 5 shows crack 

patterns deformation in concrete and steel on beam B2 at failure. Diagonal 

shear stress appeared within the shear test. As a result, the beam 

reinforcement pattern led to the typical shear patterns Shatarat et al. [10]. 

 

 
 

Figure 5. Shear patterns in concrete and steel of beams  

B1, B2 and B3 at failure.  

 

In this section, some numerical parametric study is included, like 

compressive strength of concrete and ratio of spiral reinforcement on shear 

strength. For getting more information, the impact of concrete strength on  

the shear strength has been studied. Therefore, the compressive strength of 

concrete is increased from f'c to 1.5 f'c and 2f'c MPa for beams B1, B2 and 

B3, respectively. For beam B3, the numerical result indicates the 

appreciable increase in shear strength of beams of about 21 % and 39% with 

an increased grade of concrete from 1.5 f'c and 2 f'c, respectively. Also, it 

is noticing the shear strength response of all beams is better, as indicated in 

Fig. 6.  

Figure 7 presents the shear strength of specimens with spiral stirrups 

reinforcement distances equal 120, 100, and 80 mm. The effect of the 

increased ratio of spiral stirrups on the shear capacity of specimens is about 

5%, while the change distance between spiral stirrups is from 120 mm to 

80 mm. The shear behavior of the RC beams depends on the shape of 

reinforcement of the stirrups. It also depends on the concrete strength by 

comparing different shapes of spiral stirrups in RC beams with 

conventional stirrups. 

Figure 6. Effect compressive concrete on different pattern 

 stirrups of beams 

 

Figure 7. Effect ratio of stirrups on different pattern 

 stirrups of beams 

 

5. Conclusions 

In this paper, the shear performance of traditional and continuous spiral 

reinforced concrete beams is investigated. These beams are analyzed using 

the ANSYS program and compared with the practical results from previous 

research.  Numerical analysis indicted that the increasing in the grade of 

concrete to 1.5fc and 2fc led to increase the shear strength of the beam by 

about 21% and 39% respectively. The effective ratio of spiral stirrups by 

the less distance between stirrups from 120 to 80 mm is increased the shear 

strength of the beam by approximately 5%. The spiral stirrups 

configurations improved failure mechanisms and shear response compering 

with the same beam with conventional stirrups. The beam with spiral 

 

 



22                     THAER J. MOHAMMED AND KHALID M. BREESEM /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   15 (2022) 018–022 

 

transverse reinforcement is enhanced performance and ductility response. 

Meanwhile, the beam with conventional stirrups showed the failure of the 

brittle shear. The numerical result is indicated the appreciable increase in 

shear capacity of all specimens with a high grade of concrete. The effect of 

the decreased distance between spiral stirrups on the shear capacity of 

specimens is low. 

 

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