










































Microsoft Word - ETASR_V12_N3_pp8701-8706


Engineering, Technology & Applied Science Research Vol. 12, No. 3, 2022, 8701-8706 8701 
 

www.etasr.com Fahim et al.: The Behavior of RC Beams Retrofitted with Carbon Fiber Reinforced Polymers (CFRP) 

 

The Behavior of RC Beams Retrofitted with Carbon 

Fiber Reinforced Polymers (CFRP) 
 

Muhammad Fahim 

Civil Engineering Department 
University of Engineering and Technology, Peshawar 

Peshawar, Pakistan 

drmfahim@uetpeshawar.edu.pk 

Fakhere Alam 

Civil Engineering Department 
University of Engineering and Technology, Peshawar 

Peshawar, Pakistan 

falam.ms20nice@student.nust.edu.pk 

Hazrat Khan 

Civil Engineering Department 

University of Engineering and Technology, Peshawar 
Peshawar, Pakistan 

hazkhan.pg19mce@student.nust.edu.pk 

Inzimam ul Haq 

Civil Engineering Department 

University of Engineering and Technology, Peshawar 
Peshawar, Pakistan 

inzimamul.haq2@students.uettaxila.edu.pk 

Shahid Ullah 

Civil Engineering Department 

University of Engineering and Technology, Peshawar 

Peshawar, Pakistan 
shahid.ullah@uetpeshawar.edu.pk 

Saeed Zaman 

Civil Engineering Department 

University of Engineering and Technology, Peshawar 

Peshawar, Pakistan 
saeed.zaman79@gmail.com 

 

Received: 17 March 2022 | Revised: 5 April 2022 | Accepted: 7 April 2022 

 

Abstract- The need for the introduction of economical and 
quicker retrofitting techniques is increasing due to the ever-aging 

infrastructure and damages produced by major catastrophic 

events around the world. The application of Carbon Fiber 

Reinforced Polymers (CFRPs) for strengthening and retrofitting 

of reinforced concrete structures is gaining popularity due to its 
higher strength, lightweight, durability, corrosion resistance, and 

aesthetic value. This study presents the results of two 

strengthened and two retrofitted beams in comparison to control 

specimens. Two specimens were strengthened and two were 

retrofitted by attaching CFRP (Sika Carbo-Dur S812 or Sika-

Wrap 230C) to the tension side of the beams using high strength 
epoxy. The results show that one CFRP strip/wrap simply 

attached at the tension side can help the damaged beam 

regain/pass the original strength. All specimens fail due to 

debonding of CFRP from the concrete surface emphasizing the 

need for efficient anchorage systems. Among the four patterns 

adopted, CFRP strips along with u-shaped anchorages at the 
ends provided the highest strength enhancement of 17.36%. 

Keywords-CFRP; strengthening; retrofitting; reinforced concrete beams; 
debonding 

I. INTRODUCTION  

Collapse and cracking of structural elements of buildings, 
bridges, or other structures take place due to poor construction 
practices, use of low quality materials, inappropriate design of 
elements, and application of unexpected external loads that 
have not been considered during the design. Retrofitting is 

defined as the strengthening intervention that is able to restore 
an acceptable level of safety against such actions [1]. The terms 
retrofitting and strengthening are generally used 
interchangeably. However, more precisely, the term 
rehabilitation is used when a structure is strengthened before an 
earthquake or other damaging phenomena whereas 
strengthening of damaged structures is called retrofitting [2]. 
Carbon Fiber Reinforced Polymer (CFRP) is made of two 
components, carbon fiber and resin and is used extensively for 
the retrofitting of reinforced concrete structures. It has the 
desirable properties of higher strength, light weight, durability, 
electrical and corrosive resistance, and good aesthetic 
appearance. The base material (poly acrylonitrile-PAN) of 
CFRP has higher molecular orientation [3]. In 1977, because of 
its higher stiffness and high strength-to-weight ratio, CFRPs 
were used in the casing of aircrafts. In 1980, CFRPs were used 
as a reinforcement material in reinforced concrete beams. 

Ever since their first use in the construction industry, CFRP 
retrofitted members have been extensively investigated, both 
experimentally and numerically. Authors in [4] compiled a 
database of 127 beam specimens from the literature which were 
externally bonded with CFRP and GFRP sheets to increase the 
flexure capacity and were tested under 4-point loading. About 
one third of the tested specimens with external reinforcement 
demonstrated strength increase of 50% or more in combination 
with considerable deflection capacity. Authors in [5] used three 
different reinforcement ratios of CFRP and concluded that with 

Corresponding author: Muhammad Fahim



Engineering, Technology & Applied Science Research Vol. 12, No. 3, 2022, 8701-8706 8702 
 

www.etasr.com Fahim et al.: The Behavior of RC Beams Retrofitted with Carbon Fiber Reinforced Polymers (CFRP) 

 

the increase in reinforcing ratios in beams, their load carrying 
capacity increased. Authors in [6] carried out an experimental 
study of RC beams to investigate the behavior of structurally 
damaged full-scale RC beams retrofitted with CFRP laminates. 
The increase in maximum load value of the specimens was 
between 7% and 33% for retrofitting in flexure. The main 
failure mode found was plate debonding which reduced the 
efficiency of retrofitting. Authors in [7] performed 
experimental and numerical studies of CFRP retrofitted beams 
and concluded that the strength of RC beams with single layers 
of CFRP was enhanced from 18 to 20% and for double layers 
from 40 to 45%. The deflection of RC retrofitted beams was 
also decreased by about 80% that of control beams. Authors in 
[8] studied the flexure behavior of corroded reinforced concrete 
beams strengthened with CFRP and found 30 to 50% increase 
in capacity along with improvement in stiffness. CFRP has also 
been used in other RC components and under different loading 
conditions. For example, T-beams [9], columns [10], shear 
walls [11], and joints [12]. Similarly, various RC components 
retrofitted with CFRP were investigated under various loading 
conditions, e.g. under torsion [13], impact loading [14], and 
under fire exposure [15]. 

In many practical situations, adopting a comprehensive 
retrofitting scheme is not feasible due to financial, time, or 
execution constraints. Therefore, the main objective of this 
study is to investigate the effect of simple retrofitting schemes 
on the flexural behavior of reinforced beams. Two specimens 
were strengthened and two were retrofitted by attaching CFRP 
(Sika Carbo-Dur S812 or Sika-Wrap 230C) to the tension side 
of the beams using high strength epoxy. In addition, one 
strengthened and one retorfitted beam had u-shaped anchorages 
of the same Sika-Wrap 230C. The results are discussed and 
recommendations are presented in the subsequent sections.  

II. EXPERIMENTAL STUDY 

A. Materials 

Concrete with a specified compressive strength of 4,000 psi 
was used for casting the beam specimens. The average 
compressive strength of the companion cylinders tested in 
accordance with ASTM C-39 as shown in Figure 1 was found 
to be 3,940 psi.  

 

 
Fig. 1.  Concrete cylinder test setup. 

ASTM A615 Grade 60 steel (1/2in diameter bars) was used 
for tension reinforcement and Grade 40 steel (3/8in diameter 
bars) was used for transverse reinforcement as well as 
compression hangers. The average yield strength was found to 
be 59.94ksi and 52.28ksi for Grade 60 and Grade 40 steel 
respectively. Sika Carbodur S812 CFRP strips and SikaWrap 
230C wraps/sheets were used for strengthening and retrofitting 
the beam specimens. These conform to ASTM 
D7205/D7205M-06 [16]. The properties of CFRP strips and 
wraps as provided by the manufacturer are given in Table I. 

TABLE I.  CFRP PROPERTIES 

CFRP Type 
Thickness 

(in.) 

Width 

(in) 

Tensile 

strength 

(ksi) 

Modulus of 

elasticity 

(ksi) 

Sika Carbodur S812 0.047 3.15 400 23.2 × 10
3
 

SikaWrap 230C 0.0052 6 460 31.9 × 10
3
 

 

High strength epoxy Sikadur 30 [17] was used for attaching 
CFRP strips with the concrete surface. Similarly, for bonding 
the CFRP wraps to the concrete surface, Sikadur 330 [18] 
adhesive was used. Both types of epoxy are two-component 
thixotropic [17] epoxy including resin and filler designed for 
use at normal temperature. They conform to ASTM C-881 [19] 
and AASHTO M-235 [20] specifications. 

B. Test Specimens 

Five beams of 7ft length were casted and tested under 4-
point (pure bending) loading. The dimensions and 
reinforcement details of the specimens are shown in Table I. 
Two beams were strengthened with CFRP before the 
application of any load whereas two beams were first tested to 
cracking moment and then retrofitted before testing again to 
collapse load. Two patterns were used for CFRP application, 
the first pattern consisted of a 3.15in wide and 0.0394in thick 
strip with 5in wide U-shaped anchorages at the ends as shown 
in Figure 3. The second pattern consisted of a 6in wide and 
0.0052in thick wrap without any anchorage as shown in Figure 
4. In both cases the CFRP was applied on the tension side in 
the middle half of the span. Each pattern was applied to one 
strengthened and one retrofitted beam. 

 

 
Fig. 2.  Cross section details of the specimens. 



Engineering, Technology & Applied Science Research Vol. 12, No. 3, 2022, 8701-8706 8703 
 

www.etasr.com Fahim et al.: The Behavior of RC Beams Retrofitted with Carbon Fiber Reinforced Polymers (CFRP) 

 

 
Fig. 3.  First pattern of CFRP for beam specimens. 

 
Fig. 4.  Second pattern of CFRP for beam specimens. 

C. Test Setup 

The beams were tested under 4-point loading (pure 
bending) as shown in Figure 5. The deflection was recorded 
using a UCAM-70A data logger. 

 

 
Fig. 5.  Schematic of the test setup. 

III. RESULTS AND DISCUSSION 

A. Failure Pattern 

The failure patters of the four strengthened/retrofitted 
specimens are shown in Figures 6-9. The predominant failure 
was due to the debonding of CFRP from the concrete surface. 
The higher flexural stresses in the middle half of the beams 
caused tensile cracks which were widened with the increase in 
the applied load. At the location of these cracks, concentrated 
stresses weaken the bond between CFRP and concrete and 
eventually lead to the complete debonding of CFRP from the 
surface. Failure immediately follows after the debonding. The 
specimens without any anchorages (specimens B4 and B6) 
experienced even more pronounced debonding as shown in 
Figures 7 and 9. The simple u-shaped anchorages (without any 
mechanical anchors) provided in the specimens B3 and B5 has 
a significant impact in reducing the crack widths and delaying 
debonding as shown in Figures 6 and 8. 

(a) 

 

(b) 

 

Fig. 6.  Final failure pattern of specimen B3. 

B. Load vs Displacement Relationships 

Figures 10 and 11 show the load vs mid-span deflection of 
control and strengthened beams with CFRP strips and wraps. 
The strengthened beams are in fact the control beams after they 
were tested to their ultimate capacity and were strengthened 
with CFRP before being tested again. It can be seen that the 
beams strengthened with CFRP strips regain/crossed their 
original strength but the beams strengthened with CFRP wraps 
fell slightly short of their original strength. In both cases, the 
strengthened specimens had larger ultimate displacement. 
However, reduced stiffness was observed in strengthened 
beams, especially the specimen with CFRP wraps. However, 
the final displacement recorded was much higher than that of 
both control specimens. It must be noted that the CFRP strip 
used in the specimen B3 was anchored by applying U-shaped 
wraps at both ends as shown in Figure 6. The effect of this 
anchorage can be noted by comparing Figures 10 and 11 as 
both ultimate load and displacement are higher for specimen 
B3 than for specimen B4. 



Engineering, Technology & Applied Science Research Vol. 12, No. 3, 2022, 8701-8706 8704 
 

www.etasr.com Fahim et al.: The Behavior of RC Beams Retrofitted with Carbon Fiber Reinforced Polymers (CFRP) 

 

(a) 

 

(b) 

 

Fig. 7.  Final failure pattern of specimen B4. 

(a) 

 

(b) 

 

Fig. 8.  Final failure pattern of specimen B5. 

Figures 12 and 13 show the load vs mid-span deflection of 
control and retrofitted beams with CFRP strips and wraps. The 
CFRP strip in beam B5 was anchored at the end using a U-
shaped shear wrap as shown in Figure 8. This beam achieved 
the highest ultimate strength and the recorded displacement at 
failure was also the highest among all specimens. Retrofitted 

beam B6 reached the strength level of control specimen B2 but 
it was less than control specimen's B1. 

 

(a) 

 

(b) 

 

Fig. 9.  Final failure pattern of specimen B6. 

 
Fig. 10.  Load vs displacement relationships of control specimens and a 

specimen strengthened with CFRP strips. 

 
Fig. 11.  Load vs displacement relationships of control specimens and a 

specimen strengthened with CFRP strips. 



Engineering, Technology & Applied Science Research Vol. 12, No. 3, 2022, 8701-8706 8705 
 

www.etasr.com Fahim et al.: The Behavior of RC Beams Retrofitted with Carbon Fiber Reinforced Polymers (CFRP) 

 

 
Fig. 12.  Load vs displacement relationships of control specimens and a 

specimen retrofitted with CFRP strips. 

 
Fig. 13.  Load vs displacement relationships of control specimens and a 

specimen retrofitted with CFRP wraps. 

Table II shows the maximum load, the corresponding 
displacement, and the final load and displacement values for all 
specimens. The highest load and displacement capacity were 
observed for specimen B5 which was retrofitted with CFRP 
strips along with u-shaped anchorages. One of the most 
important characteristics observed for the strengthened and 
retrofitted beams was their ability to withstand inelastic 
deformations. This manifests an increased ductility of the 
beams which is highly desirable in earthquake resistant 
structures. 

TABLE II.  SUMMARY OF THE TEST RESULTS OF BEAM SPECIMENS 

Specimen 

Maximum load and 

corresponding 

displacement 

Final load 

displacement 

Debonding 

load (kN) 

 
Pmax 

(kN) 

∆max 

(mm) 

Pf 

(kN) 

∆f 

(mm) 
 

B1 121.11 13.76 118.65 14.21 -- 

B2 105.07 11.19 100.26 14.40 -- 

B3 117.61 12.03 101.09 32.71 113.74 

B4 99.33 14.65 89.60 20.68 96.08 

B5 132.71 29.10 125.21 41.09 131.36 

B6 105.54 30.86 92.18 33.69 100.97 

 

IV. CONCLUSIONS 

This study investigated the effect of CFRP retrofitted on the 
flexural behavior of reinforced concrete beams. Six specimens 
were tested, two control beams, two beams strengthened with 

CFRP after testing to ultimate capacity, and two beams were 
retrofitted with CFRP before they were exposed to any loading. 
The following conclusions can be drawn from the results 
obtained in the study: 

• A simple strip/wrap of CFRP applied at the critical 
locations can help damaged structural components regain 
their original (pre-loading) strength. All four specimens in 
this study regained/crossed the strength of control 
specimens with the application of a single CFRP strip/wrap 
in the middle half span on the tension side.  

• The study demonstrates the common failure pattern in 
CFRP retrofitted beams is the debonding of CFRP from the 
concrete surface. Effective anchorage systems can greatly 
enhance the capacity of retrofitted RC structures by 
delaying the debonding process and stressing the CFRP to 
higher levels. 

• The highest strength achieved in this study for a retrofitted 
beam is 17.36% higher the average strength of control 
specimens. This is an encouraging sign for the use of CFRP 
in retrofitting and strengthening of existing old or damaged 
RC structures. The application is quick, simple and doesn’t 
involve high skilled labor. 

REFERENCES 

[1] A. Costa, A. Arêde, and H. Varum, Eds., Strengthening and Retrofitting 
of Existing Structures, 1st ed. New York, NY, USA: Springer, 2017. 

[2] M. Ashraf, "Development of Low-cost and Efficient Retrofitting 

Technique for Unreinforced Masonry Buildings," Ph.D. dissertation, 
University of Engineering and Technology, Peshawar, Pakistan, 2010. 

[3] "Carbon Fiber Reinforced Polymer (CFRP) Uses and Properties," 

Essaycompany. https://www.essaycompany.com/essays/chemistry/ 
carbon-fiber-reinforced-polymer-cfrp-5854 (accessed Apr. 27, 2022). 

[4] J. F. Bonacci and M. Maalej, "Behavioral Trends of RC Beams 

Strengthened with Externally Bonded FRP," Journal of Composites for 
Construction, vol. 5, no. 2, pp. 102–113, May 2001, https://doi.org/ 

10.1061/(ASCE)1090-0268(2001)5:2(102). 

[5] M. R. Esfahani, M. R. Kianoush, and A. R. Tajari, "Flexural behaviour 
of reinforced concrete beams strengthened by CFRP sheets," 

Engineering Structures, vol. 29, no. 10, pp. 2428–2444, Oct. 2007, 
https://doi.org/10.1016/j.engstruct.2006.12.008. 

[6] Y. T. Obaidat, S. Heyden, and O. Dahlblom, "The effect of CFRP and 

CFRP/concrete interface models when modelling retrofitted RC beams 
with FEM," Composite Structures, vol. 92, no. 6, pp. 1391–1398, May 

2010, https://doi.org/10.1016/j.compstruct.2009.11.008. 

[7] P. Alagusundaramoorthy, I. E. Harik, and C. C. Choo, "Flexural 

Behavior of R/C Beams Strengthened with Carbon Fiber Reinforced 
Polymer Sheets or Fabric," Journal of Composites for Construction, vol. 

7, no. 4, pp. 292–301, Nov. 2003, https://doi.org/10.1061/(ASCE)1090-
0268(2003)7:4(292). 

[8] S. Linwang, C. Jian, C. Qingjun, L. Guobao, and Z. Juan, "Investigation 

on the Flexural Behavior of Corroded Concrete Beams Repaired by 
CFRP Sheet Under Different Corrosion Levels," The Open Civil 

Engineering Journal, vol. 10, no. 1, Sep. 2016, 
https://doi.org/10.2174/1874149501610010598. 

[9] A. Bennitz, J. W. Schmidt, J. Nilimaa, B. Taljsten, P. Goltermann, and 

D. L. Ravn, "Reinforced Concrete T-Beams Externally Prestressed with 
Unbonded Carbon Fiber-Reinforced Polymer Tendons," Structural 

Journal, vol. 109, no. 4, pp. 521–530, Jul. 2012, https://doi.org/ 
10.14359/51683871. 

[10] J. A. O. Barros, R. K. Varma, J. M. Sena-Cruz, and A. F. M. Azevedo, 

"Near surface mounted CFRP strips for the flexural strengthening of RC 
columns: Experimental and numerical research," Engineering Structures, 



Engineering, Technology & Applied Science Research Vol. 12, No. 3, 2022, 8701-8706 8706 
 

www.etasr.com Fahim et al.: The Behavior of RC Beams Retrofitted with Carbon Fiber Reinforced Polymers (CFRP) 

 

vol. 30, no. 12, pp. 3412–3425, Dec. 2008, https://doi.org/10.1016/ 
j.engstruct.2008.05.019. 

[11] N. Askarizadeh and M. R. Mohammadizadeh, "Numerical Analysis of 

Carbon Fiber Reinforced Plastic (CFRP) Shear Walls and Steel Strips 
under Cyclic Loads Using Finite Element Method," Engineering, 

Technology & Applied Science Research, vol. 7, no. 6, pp. 2147–2155, 
Dec. 2017, https://doi.org/10.48084/etasr.1279. 

[12] W. T. Lee, Y. J. Chiou, and M. H. Shih, "Reinforced concrete beam–

column joint strengthened with carbon fiber reinforced polymer," 
Composite Structures, vol. 92, no. 1, pp. 48–60, Jan. 2010, 

https://doi.org/10.1016/j.compstruct.2009.06.011. 

[13] G. Al-Bayati, R. Al-Mahaidi, and R. Kalfat, "Experimental investigation 

into the use of NSM FRP to increase the torsional resistance of RC 
beams using epoxy resins and cement-based adhesives," Construction 

and Building Materials, vol. 124, pp. 1153–1164, Oct. 2016, 
https://doi.org/10.1016/j.conbuildmat.2016.08.095. 

[14] J. Abd and I. K. Ahmed, "The Effect of Low Velocity Impact Loading 

on Self-Compacting Concrete Reinforced with Carbon Fiber Reinforced 
Polymers," Engineering, Technology & Applied Science Research, vol. 

11, no. 5, pp. 7689–7694, Oct. 2021, https://doi.org/10.48084/etasr.4419. 

[15] H. A. Al-Baghdadi and A. Sabah, "Behavior of RC Beams Strengthened 
with NSM-CFRP Strips Subjected to Fire Exposure: A Numerical 

Study," Engineering, Technology & Applied Science Research, vol. 11, 
no. 6, pp. 7782–7787, Dec. 2021, https://doi.org/10.48084/etasr.4493. 

[16] D. P. Abrams and N. Shah, "Cyclic Load Testing of Unreinforced 

Masonry Walls," Illinois University At Urbana Advanced Construction 
Technology Center, Urbana, IL, USA, 92-26-10, Dec. 1992. 

[17] "Sikadur®-30," Sika. https://gbr.sika.com/en/construction/structural-

strengthening/adhesives-and-bonding/structural-adhesives/sikadur-
30.html (accessed Apr. 27, 2022). 

[18] "Sikadur®-330," Sika. https://gbr.sika.com/en/construction/structural-

strengthening/adhesives-and-bonding/structural-adhesives/sikadur-
330.html (accessed Apr. 27, 2022). 

[19] G. Magenes and G. M. Calvi, "Cyclic behavior of brick masonry walls," 
in Earthquake Engineering, Tenth World Conference, Rotterdam, 

Netherlands, 1992. 

[20] AASHTO M 235M/M 235-13 (2018): Standard Specification for Epoxy 
Resin Adhesives (ASTM Designation: C 881-10). American Association 

of State and Highway Transportation Officials, 2013.