Review on NSM CFRP Strengthened RC Concrete Beams in Shear

Kadhim, Majid M. A.; Altaee, Mohammed J.; Adheem, Ali Hadi; Chabuk, Ali; Al-Ansari, Nadhir

doi:https://doi.org/10.1155/2021/1074010

Advances in Civil Engineering

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Review Article | Open Access

Volume 2021 | Article ID 1074010 | https://doi.org/10.1155/2021/1074010

Review on NSM CFRP Strengthened RC Concrete Beams in Shear

Majid M. A. Kadhim,¹Mohammed J. Altaee,²Ali Hadi Adheem,³Ali Chabuk,⁴and Nadhir Al-Ansari⁵

Academic Editor: Tan-Trung Bui

Received18 Aug 2021

Revised06 Oct 2021

Accepted11 Oct 2021

Published27 Oct 2021

Abstract

The use of NSM FRP strengthening of concrete structures has become an attractive option to retrofit the existing structures against shear and flexure. This paper reviews only the utilization of NSM for shear in previous review articles. A database of tests of NSM strengthened beams in shear is presented to evaluate the existing design formulations of calculating the NSM contribution in shear. These formulations were in agreement with the experimental results in the database. Further research topics are also identified such as the shape of NSM FRP bars, combined effects of existing steel stirrups, and NSM FRP reinforcement and analytical formulations.

1. Introduction

Sudden failure because of low resistance to shear is something required to be avoided. Thus, one of the priorities of researchers is to find an appropriate strengthening technique that can be employed to enhance RC beams when they are deficiently reinforced in shear, when they fall under higher loads, or when the shear capacity of beam is below the flexural capacity due to flexural strengthening for example. Employment of composite materials in strengthening/retrofitting concrete elements is one of these techniques. Externally bonded (EB) Carbon Fiber Reinforced Polymer (CFRP) is one of the earlier systems used in strengthening concrete elements in the case of using composite materials [1–7]. However, recently, using near surface mounted (NSM) with CFRP becomes one of the most investigated techniques in flexural [8–14] and shear strengthening [15–21] (see Figure 1) because of its advantages over externally bonded EB-CFRP reinforcement [18, 22]:(1)The previous experimental studies have demonstrated that the NSM strengthening technique can provide higher strengthening effectiveness compared to EBR due to higher bonded area-to-cross-sectional area of the CFRP element ratio. For this reason, the NSM technique is less prone to debonding failure.(2)The amount of site installation work needed in the case of the NSM technique is less than that required in EBR technique.(3)In the case of intending of use prestressed CFRP reinforcements, NSM bars can easily be used.(4)The NSM strengthening technique reduces the probability of harm resulting from accidental impact, mechanical damage, vandalism, and fire because the NSM bars are protected by the concrete cover.(5)The appearance of structural member is uninfluenced with using the NSM strengthening technique.

There is a growing body of literature that recognizes the importance of using the NSM strengthening technique because of the above listed advantages. Several review studies had been found in the literature [18,23–25]. However, to the best of the authors’ knowledge, there is no one that has reviewed the research of shear contribution of NSM CFRP strengthening technique. This paper focuses on research studies that investigated the shear strengthening of RC beams with CFRP NSM technique. In addition, some aspects regarding the bond strength and the factors affecting the bond performance are also discussed. Finally, the design rules for prediction of the CFRP contribution of the NSM shear strengthening systems are evaluated.

2. NSM Strengthening Technique

In order to install the CFRP laminates using NSM system, grooves with a desired depth, width, inclination, and spacing were opened on the concrete cover by using saw-cutting [16, 26–28] or diamond cutter [29]. These grooves were then cleaned by compressed air [16, 26–29] and compressed water in some cases [30]. Then, the grooves were filled with the adhesive material. Finally, the CFRP laminates were inserted into the slits of the beam, and the excess adhesive material was removed.

2.1. FRP Reinforcement

FRP bars can be produced in a variety of shapes. Two different cross-sectional shapes were used in the previous research studies that conducted the strengthening of RC beam in shear, which are round bars and thin narrow strips (simply referred as “strips” hereafter). The selection of the cross-sectional shape depends on many factors such as the depth of the concrete cover, the cost of a particular type of bar, and the availability of this type. For instance, strips need a thicker concrete cover for a specific cross-sectional area, but they have better performance compared with round bars of equivalent cross-sectional area due to maximizing bond surface and hence reduce the risk of debonding failures in beams strengthened with NSM FRP strips [11].

The surface texture of FRP bars reinforcement was also varied to improve bond properties. In some cases, these bars were coated with epoxy paste and then sprinkled with 0.2/0.3 mm of surface sanding materials [31]. In other cases, the surface of the round bars was spirally wounded with a fiber tow and coated with sand [26].

2.2. Groove Geometry

It mainly depends on the FRP cross section and bars surface treatment. The choice of groove dimensions can influence the bond performance, and hence, it can cause premature debonding failure. The rectangular, square, or round bars are commonly used.

The square and rectangular bars have several merits over round bars, such that they provide a uniform adhesive thickness in their vertical and parallel sides. Moreover, the ratio of surface to cross section area of square and rectangular bars is higher than that of round bars. This can minimize the bond stresses for the same tensile force in the FRP, which may split the groove filling cover. Another advantage of using rectangular bars is related to the simplicity of opening the grooves. The main disadvantage of rectangular bars is the need for a deeper groove to provide the same reinforcement area [18, 32].

Several studies [33–36] showed that FRP rectangular bars, which have a large height-to-thickness ratio, are superior to NSM FRP bars of other shapes. This is due to a larger embedment depth and a higher perimeter/cross-sectional area ratio than those FRP bars of other shapes, which consequently leads to a higher utilization capacity of FRP. The deeper FRP in the web provided higher shear strengthening, and the inclined FRP gave a more ductile behavior after peak load for the beams that were shear strengthened with NSM [37–39].

2.3. Groove Filler

The role of groove filler adhesive is to transfer the stresses between the FRP reinforcement and concrete. Two types of adhesive can be epoxy or cement based. The most relevant mechanical properties of groove filler are tensile and shear strengths. The tensile strength is especially important in case of round bars, which induce high circumferential tensile stresses in the epoxy [40]. The shear strength is especially important when the bond is controlled by cohesive shear failure of the epoxy. The cement based adhesive has some advantages vs. epoxy as follows: it is cheaper, presents reduced hazard to workers and environment, allows bonding to wet surfaces, has a better behavior at elevated temperatures, and is compatible with the concrete substrate. The main disadvantage is the low tensile strength compared to epoxy, and during hardening of the mortar, adequate wetting should be assured. Bond and flexural tests identified some limitations of cement mortar as grove filler [41]. The performance of the specimens with epoxy-filled grooves was almost similar and provided higher pull-out loads compared to the specimens with cement mortar adhesives [42]. The cementitious matrix with NSM strengthening system has generally improved the deformational characteristics of the strengthened specimens [39]. The NSM CFRP bar repair resulted in only a slight increase in stiffness and a slight decrease in strength due to the debonding of the vertical FRP in the web at the epoxy/mortar interface [43].

3. Bond Behavior

A key issue of the structural performance of the NSM technique is the bond behavior as for the EBR one, since the debonding of the FRP reinforcement can be a very common failure mode. Failure modes of the beams strengthened by the NSM technique were not brittle as those observed in the beams strengthened by the EBR technique [29].

Direct pull-out tests (DPT) including single or double-lap shear tests and beam pull-out tests (BPT) are commonly used to investigate the bond between NSM CFRP and concrete [18], which are described in more details elsewhere [24]. The above test methods have been used to investigate a wide range of parameters affecting the bond mechanism including: FRP fiber type and external surface [32, 33, 44–50], FRP axial stiffness [44, 47–53], FRP cross section geometry [32, 33, 46, 49, 51, 54–58], groove surface [44, 47, 59, 60], groove’s geometry [48, 50, 51, 54, 58, 61, 62], concrete strength [33, 45, 46, 50, 52], and adhesive material type and bonded length [32, 45, 46, 52, 53, 57, 63].

Different types of failure have been recorded in pull-out tests. However, in some cases, the authors of experimental works analysis tend to report more than one failure mode for the same specimen. Either this was a combination of several failure mechanisms or two failures may occur in sequence. It is thought by others [18] that any specimen should have one governing failure model and reporting more than one failure mode for a specific specimen may be caused by: (a) the occurrence of a sudden failure during the tests, hiding the possibility of observing the real failure mode, (b) in the case of BPT specimens, the test configuration itself could lead to erroneous identification of failure modes (the BPT are performed with test region (face where the FRP is applied) downwards, being more difficult to observe the development of the failure mechanism).

In this section, the locations of main failure modes that occurred in bond between NSM FRP-concrete substrate are summarized, as follows (see Figure 2).

3.1. Failure in FRP Material (FRP Rupture)

It is simpler than other failure modes to recognize, and it occurs in NSM specimens with adequate bond length [32, 45, 64].

3.2. Failure at Interface FRP/Adhesive

This failure occurred when a clean FRP bar/strip without adhesive attached detached from adhesive layer. In fact, mechanical interlock between FRP and the surrounding adhesive, in addition to chemical adhesion and friction between FRP and adhesive, is responsible to have an efficient bond. This kind of failure is observed in NSM specimens with inadequate bonded length or bad FRP surface cleaning, and some cases may occur as a result of low tensile strength of the used adhesive [25, 32, 65–67].

3.3. Cohesive Failure

This kind of failure occurs mainly as a result of the normal stresses developing together with longitudinal stresses during the test. When the normal stress reaches adhesive tensile strength, the cohesive failure then happens. The low tensile strength of adhesive material and the small NSM groove depth are of the common reasons that cause this failure [25, 40, 67, 68].

3.4. Failure at Interface Adhesive/Concrete

The failure between adhesive and concrete substrate is similar to that occurring between FRP bar and adhesive, and the reason of this failure may also be caused by the low tensile strength of adhesive material and inadequate bonded lengths [40, 41, 45, 50, 64, 69, 70].

3.5. Concrete Fracture

The failure in concrete substrate is mainly caused by the low strength of concrete, so the failure is shifted to the weakest material in joints. This type of failure is commonly observed when adequate bonded lengths and the grooves geometry are well designed [32, 58, 64].

In addition, when NSM FRP strengthening technique used in flexure a side-groove may be the choice to improve the bond strength, in this case, the system can be called (side NSM) SNSM FRP strengthening technique. Several studies showed that the SNSM FRP technique can prove the same contribution when compared to the one used in the bottom of beams [71]. It also showed that SNSM can overcome the issue of concrete fracture since a wider area of concrete can prevent such king of failure.

It seems that the bond between NSM FRP reinforcement and concrete substrate is well covered. However, as an accurate method is needed to define and describe the failure modes observed, in addition, the prediction of pull-out strength of NSM FRP strips/rods, which are bonded to concrete block, was investigated using fuzzy logic approach [72]. The results of the proposed model showed good accuracy against the experimental data and outperform the published models. For this reason, this kind of approach can also be utilized to propose methods of determining contribution of NSM FRP technique in flexure or shear as will be discussed later [72, 73].

4. Factors Affecting NSM Strengthening

The reported research studies that carried out the behavior of NSM CFRP strengthened RC beams in shear have investigated many parameters that can change the contribution of the NSM CFRP strengthening system in different levels. In the following sections, these parameters are listed and discussed.

4.1. Concrete Strength

The compressive strength of concrete was investigated in [16, 29, 74, 75] in three different series of experimental tests. The values of compressive strength were 18.6, 39.7, and 59.4 MPa at the age of beam tests. In each compressive strength of concrete, different NSM CFRP laminate inclinations (45°, 60°, and 90°), levels of CFRP percentage (0.06%, 0.09%–0.1%, and 0.13%–0.16%) and levels of steel stirrups percentage (0.1%, 0.16%, and 0.17%) were investigated. The experimental results demonstrated that the higher the concrete compressive strength, the higher the NSM CFRP effectiveness. This is related to the fact that the effective bond length is decreased with the higher concrete strength due to the decreasing of the fracture failure of concrete in the groove surface for the RC beams made by higher concrete strength class. Because of that, the contribution of the NSM CFRP laminates for shear resistance of beams is increased with the higher tensile strength of the concrete. It was also found that the NSM CFRP technique is still effective in beams produced by the lowest structural compressive strength of concrete.

4.2. Existing Steel Stirrups

The ratio of the presence tension steel reinforcement was found to be very effective when NSM FRP strengthening technique was applied in flexure [76–78]. In a similar way, the presence of steel stirrups has also a clear effect on the contribution of NSM FRP strengthening technique when it is used in shear. Several studies have tried to investigate the effectiveness of NSM FRP strengthening technique with different percentages of steel shear reinforcements [29, 30, 74, 75, 79–81]. Lorenzis and Nanni [79] tested series of RC beams with absence and with steel stirrups. It is not possible to make a comparison between the tested beams because of the differences in the percentage of CFRP applied for the beams. However, it is only possible to conclude that the contribution of the NSM CFRP strengthening technique is still significant in the presence of steel stirrups. Another set of experimental studies [29, 74, 75, 80] revealed that the effectiveness of NSM CFRP rods is more pronounced in the beams with the lower internal steel stirrups ratio. This conclusion was made by investigating different percentages of steel stirrups (0.1, 0.16–0.17). In contrast, Mofidi et al. [30] claimed that the internal steel stirrups and strengthening NSM CFRP did not diminish each other’s influence. Furthermore, a database of more than 69 RC beams strengthened with NSM CFRP laminates or rods was analyzed by the same authors [30]. It was found that the shear contribution of the NSM CFRP bars or laminates slightly increased with the increase in the internal shear steel reinforcement. Based on the aforementioned discussions, this discipline may need more research.

The effectiveness of NSM CFRP bars in improving the shear capacity of concrete beams with corroded steel stirrups was also studied [82]. Two corrosion levels were investigated comprising 8% and 15%. It was found that the contribution of the NSM CFRP strengthening technique was more pronounced with the lower stirrups corrosion of 8%. This is thought to be caused by the heavily corroded steel stirrups that minimized the friction resistance at the steel stirrups-concrete interface. This caused premature separation of the lateral concrete cover after onset of diagonal shear cracks. This process may reduce the effectiveness of NSM CFRP strengthening in shear.

The steel fibers would be used also to increase the shear resistance of concrete substrates. Therefore, NSM CFRP efficiency can be improved by using the steel fibers in concrete mix due to its ability to control the shear failure [83–86].

4.3. Shape of NSM CFRP Reinforcement

In the case of using NSM CFRP strengthening technique in enhancing RC beams in flexural capacity, it was found that using strips instead of round bars (having the same cross-sectional area) can improve the performance of NSM technique [11]. This was believed to be caused by maximizing the bond area and, therefore, reducing the debonding risk. Even with shear strengthening, the above conclusion can also be drawn [81]. However, this mechanism seems to be not identical with the test results reported by Rizzo and Lorenzis [26] who tested a series of RC concrete beams strengthened using NSM CFRP strengthening technique in shear. This finding cannot be normalized for many reasons, among which are the following:(i)The cross-sectional areas of the round bar and the strip are different (50 mm² for the round bars and 32 mm² for the strips).(ii)In the test reported in this section, all samples failed in concrete cover splitting in the region of the internal steel stirrups regardless of the strengthening configurations. Thus, the efficiency of CFRP strengthening cannot be obtained from this sample design.

More studies are needed to make the right selection of the NSM reinforcement shape.

4.4. Length of NSM Reinforcement

The length of FRP bars also plays an important role in controlling the contribution of this kind of strengthening technique [87]. Due to the limited depth of RC beams, the length of CFRP reinforcements was equal to the beam depth for the rectangular cross section beams in the most experimental tests [17, 31, 88]. However, using NSM strips with the length of 1/2D or 2/3D (D is the depth of beam) caused a noticeable improvement in the ultimate load of beam compared to using the length of NSM strips covering the full depth of beam [89]. The ultimate load of beams strengthened with full-length NSM strip was capable of sustaining a 144% higher load than that having length of NSM strips 1/2D. The propagation crack passed directly into the end of the NSM strip in beams strengthened with NSM strips having the length of 1/2D or 2/3D causing a high stress concentration at the end, which accelerates the debonding. This did not occur in the case of using NSM CFRP strips with length equal to beam depth since the length contributes more of a bonding area than the other lengths.

In the case of T-beam strengthened with CFRP bars using NSM strengthening technique, extending the CFRP bars into the flange of the beam can increase the contribution of the CFRP bars [79, 90] as shown in Figure 3(a), whereas generally the CFRP bars or strips are installed on the side of the beam web as shown in Figure 3(b). This was partly caused by the extra CFRP material added to the beam. For example, 33% more material as reported by Lorenzis and Nanni [79] caused 45.5% increasing in the beam capacity. Another reason is the extra length of CFRP bars that caused an increase in the bonded length, and hence, it maximized the failure load.

(a)

(b)

These findings were also confirmed by other researchers [17, 28, 88] who investigated the influence of CFRP length on rectangular cross section beams. This was conducted by increasing the beam depth to examine its impact on the CFRP contribution.

4.5. Mechanical Properties of Groove Filling’s Material

The influence of mechanical properties of groove filling material has widely been investigated [36, 47] to find its effect on the bond strength. It has been found that the change in the properties of groove filling material has a significant effect on the bond strength and lesser extends on the failure mode. In particular, when a stiffer adhesive material was used as a groove filling material, the bond strength was increased [36, 47]. However, these results are not in agreement with those obtained by Rizzo and Lorenzis [26] who studied the shear contribution of the NSM strengthening technique. They found that, by using an epoxy having lower elastic modulus as a groove filling material, the NSM CFRP contribution to the shear capacity was more than twice in comparison with that used an epoxy with higher elastic modulus. It was believed that the epoxy with lower modulus of elasticity leads to more ductile bond-slip response, which can then delay the onset of debonding. This contrast may be related to the points listed in Section 4.3. This factor needs more research to be clearer.

4.6. Percentage of NSM Reinforcement

Generally, the increase in the percentage of the CFRP leads to an increase in the shear resistance of the strengthened beams [16, 28, 29, 74, 75, 81, 88, 91]. It can be seen in Figure 4 that the increase of the beam’s capacity as a result of increasing the percentage of the NSM CFRP reinforcement ()—which can be calculated as in equation (1)—is sensitive to the value of concrete compressive strength [75]. In other words, the efficiency of NSM strengthening technique for the shear strengthening is maximized with the higher concrete strength. This is related to the fact that, in the case of lower concrete strength, the failure mode in the strengthened beams is concrete fracture, in which the concrete adhered to the detached laminates, while in the case of higher concrete strength, the failure mode is either the sliding of CFRP laminate (between the CFRP and the epoxy) or the rupture of the CFRP [75]. Thus, it is expected for the lower concrete strength that the increase in the percentage of CFRP does not have a significant change in the efficacy of NSM technique for the shear resistance.where is the area of the CFRP reinforcement (strip or bar) cross section, is the width of beam web, is spacing of the CFRP reinforcement, and is the orientation angle of the CFRP reinforcement with respect to the beam axis.

These findings seem to be incompatible with those presented in Rizzo and Lorenzis [26], where the increase in the percentage of the CFRP caused a decrease in the shear capacity of the beam. It was thought that increasing the percentage of CFRP accelerated the formation of debonding between CFRP bar and adhered layer.

4.7. Inclination of NSM Reinforcement

It is well known that inclined steel stirrups are more effective in shear resistance than the vertical stirrups because of diagonal cracking pattern of shear failure in RC beams. This phenomenon is identical with that found in the case of NSM CFRP strengthening technique [27, 29, 74, 75, 79, 81, 88, 90, 92] (see Figure 4). This is partly caused by the orientation of the shear cracks that tend to be almost orthogonal to the inclined CFRP reinforcement [75]. In addition, the inclined CFRP reinforcement has better total resisting bond length than the vertical CFRP reinforcement because the inclined laminates are longer than vertical laminates. Thus, it is expected to delay the debonding failure and hence have higher shear resistance. It can be seen in Figure 4 that the orientation of CFRP reinforcement at 45° was the most effective in some cases, while the orientation of CFRP laminate at 60° was the most effective than other orientations in the other cases [75]. Thus, more investigations about this point are needed.

4.8. Distance between Existing Steel Stirrups and NSM Reinforcement

The relative position between internal steel stirrups and applied CFRP reinforcement has a specific contribution on the effectiveness of CFRP shear strengthening configuration [27]. It was found that when the applied NSM reinforcement intercepted the existing steel stirrups, this may cause a debonding for the NSM bars/strips. This reflects the importance of applying the CFRP NSM reinforcement with a homogenous distance with the existing steel stirrups. Further studies are important here to find the minimum distance (between laminates and existing steel stirrups), in which the influence of this factor can be neglected.

4.9. End Conditions of FRP Bars

This kind of treatment is very important when the governing failure mode is the debonding of FRP bars or concrete cover separation. In these cases, this kind of treatment can play an important role to avoid these kinds of failures. One of the effective methods to improve end conditions of FRP bars is bending the ends of FRP bars with angles ranging between 45° and 90° as reported by others [93]. As a result, it was found that this kind of end condition can increase the load carrying capacity of RC beams in flexure by 201% and 185% compared to the reference beam. Based on that, bent ends can be also investigated in the case of shear strengthening to eliminate the problem of premature debonding in the case of shallow beams for instance.

4.10. Concrete Cover Depth

The effect of the side cover depth was investigated by [89]. Generally, it was found that, by increasing side concrete cover depth, the side concrete cover separation can be delayed or even prevented [89, 94, 95]. However, increasing the side cover could have a negative effect on the flexural response of beams since it may limit the space provided to position the longitudinal reinforcement. In addition, in many cases, NSM FRP strengthening technique is used for repairing or strengthening existing structures; thus, increasing the side concrete cover may not be an option to improve the entire contribution of this technique.

5. Failure Modes

In the cases of evaluating the shear strengthening contribution, the RC beams were designed to assure shear failure mode. The failure modes occurring in the case of using CFRP NSM in shear strengthening are as follows:(a)The first failure mode happened when the normal or low strength concrete is used. In this failure mode, the laminates/bars failed by debonding (see Figure 5). However, along the bond length, a thin layer of concrete adhered to the laminate/bar; hence, this can be classified as a concrete fracture. In the case of high percentage of CFRP used, a concrete layer with a group of CFRP reinforcements detaches to create a “concrete lateral wall” that has separated from the overall volume of concrete [75, 88]. In this bullet-point, two failure modes are presented, which are failure at interface between adhesive and concrete (debonding) and cohesion failure on concrete (concrete fracture), because, in many cases, these failure modes are difficult to be experimentally separated.(b)The failure of interface between the NSM FRP reinforcement and the adhesive “debonding” shown in Figure 5 can be classified as the most common failure mode. This failure mode occurred when a normal to high concrete strength is used [75]. The interface CFRP/adhesive is the weakest point in the CFRP NSM strengthening technique. Thus, by using a high strength adhesive material, longer CFRP reinforcements, anchoring the CFRP in the flange of T-beam, etc., this weak point can be overcome.(c)The rupture of CFRP can occur when a normal to high concrete strength is used as shown in Figure 5.(d)In some cases, when the CFRP NSM reinforcement is applied to T-beams, shear splitting failure occurred along the web-flange interface region [90]. Extending CFRP NSM reinforcement can control this failure mode.(e)Regarding the beams tested without internal shear reinforcements, splitting of concrete cover of the flexural reinforcement occurred as a result of growing cracks along the flexural reinforcement. This was thought to be caused by designing the tested beams without steel stirrups, which are responsible for maintaining the dowel force and hence restraining the splitting cracks.

It should be noted that there is no cohesive failure on the adhesive observed in the experimental studies that conducted the shear contribution of CFRP NSM strengthening technique. This is because of the higher tensile strength of adhesive material compared to the concrete tensile strength in all tests.

6. Analytical Formulations

The prediction of the shear capacity of RC beams is a challenging task because shear mobilizes several complex resisting mechanisms such as (1) shear resistance assured by the uncracked concrete in the compression zone; (2) interface shear transfer by aggregate interlocking in the cracked concrete; and (3) the dowel action of the longitudinal reinforcement [96]. Several analytical formulations were proposed in order to predict the contribution of the NSM CFRP laminates for the shear capacity of RC beams [74, 75, 79, 97–108]. Some of these models were only set to predict a certain failure mode such as Rizzo and Lorenzis [107]. Two main analytical formulations are detailed in the later sections. From these analytical formulations, the FRP contribution can be calculated. However, the nominal shear strength of RC beams strengthened with NSM FRP technique can be computed as suggested by Lorenzis and Nanni [79] using the equation by adding a third term to the basic equation provided by ACI code [109], as inwhere is the strength reduction factor for shear strengthening of RC elements, which has a value of 0.85 as reported by ACI [109]. is an additional reduction factor for the case of externally bonded CFRP. The value of this reduction factor is 0.85 as recommended by ACI 440 committee [110]. The values of and are the contributions of concrete and steel stirrups, respectively, which may be computed according to standard concrete design codes. represents the contribution of NSM FRP reinforcement to shear. The main output is the value of NSM FRP contribution () which can be calculated as per Table 1.

7. Evaluation of the Existing Formulations

In the previous section, a brief review is presented for the formations proposed in the literature that aimed at predicting the contribution of NSM FRP laminates in shear. In order to evaluate these formulations, the results obtained from them compared with the experimental results extracted from previous experimental research studies are listed in Tables 2 to 6. In these tables, and represent the values of shear contribution of the NSM FRP strengthening technique as predicted by Dias and Barros [75] and Nanni et al. [98] equations (equations 9 and 3), respectively.

The values of mean of and in Tables 2–6 have been calculated to evaluate these formations against the experiment’s results. Since the mean values were 1.09 and 0.87 for the results using Dias and Barros [75] and Nanni et al. [98] formulations, respectively, the strength prediction using Dias and Barros [75] formula is closer than that obtained by using Nanni et al. [98] formula to the experimental strength. This may be attributed to the fact that the latter formula does not include the modulus of elasticity and effective strain of CFRP. However, these closed predictions do not mean that this formulation could capture the behavior in most cases. For instance, both formulations did not account for the effect of epoxy type into the contribution of NSM FRP technique as shown in Figure 6. It can be noticed from this figure that the use of a stiffer and stronger groove filling epoxy resulted in a lower FRP contribution to the shear capacity. The reason for this is related to the fact that the stiffer bond-slip response of the joints induced larger peak bond stresses and then accelerated the initiation of debonding cracks in the concrete [26].

In addition, it can be seen from Figure 7 that the predictions of Dias and Barros [75] for the contribution of NSM FRP strengthening technique in shear () are less than the corresponding experimental values () in most points. However, in others, the predictions of Dias and Barros [75] are not conservative since their predictions () are more than the corresponding experimental values. Furthermore, considering the formulation suggested by Nanni et al. [98], it seems that although this formulation provides quite conservative predictions, their conservatism is relatively high in some points.

(a)

(b)

(c)

Regarding the effect of existing steel stirrups shown in Figure 8, it seems that the later formulation did not account for the percentage of existing steel reinforcement in their formulations. Although the predictions of Dias and Barros [75] include the influence of steel stirrups, their predictions are still overestimated compared to the corresponding experimental values. Thus, further modifications regarding this point may be needed.

Generally, the accuracy of the predictions of the theoretical formulations discussed in this section is accepted in many cases. However, further improvement is required to include the effect of some parameters such as epoxy properties, while further modifications are required to improve the predictions for some parameters such as the percentage of existing steel stirrups.

8. Numerical Modelling

It is well known that the numerical modelling is a powerful tool that is widely used in order to provide a comprehensive understanding to many phenomena in structural engineering applications. However, the number of numerical studies conducting the response of NSM CFRP strengthened concrete beams in shear is still limited. Some of these studies were only presented a simple numerical model without a deep discussion about the materials modelling and other numerical model characteristics [19]. Others tried to use these models to investigate more parameters [113–115]. Some of these parameters were already experimentally covered such as concrete compressive strength [113–115], while some of these were not investigated elsewhere such as the distance between existing shear reinforcement and SNM rods [113]. Generally, this powerful tool can more widely be used to investigate more parameters such as the percentage of steel stirrups against the percentage of NSM FRP rods and optimum distribution of FRP reinforcement along the beam. Numerical simulation is also needed to extend the parameter ranges outside those used in the experimental works.

9. Conclusions

This paper has provided a review of the current research on CFRP strengthened concrete beams with NSM technique in shear. Significant amounts of information and explanations of the existing researches on the NSM FRP strengthening of concrete beams have been provided. The important conclusions drawn from the reviewed studies can be summarized as follows:(i)Although the bond between NSM FRP reinforcement and concrete substrate is well investigated, some debate is still ongoing on the selection of the real failure mode. Some researchers tend to present several failure modes because they look essential to the final appearance of the specimens, while others preferred to indicate only the conditioning failure mode.(ii)Regarding the parameters that can influence the shear contribution of NSM FRP strengthening technique, it seems that most of these parameters are well covered. However, some of those still need deep investigation to remove the debate about that, such as the shape of NSM FRP reinforcement, inclination of NSM reinforcement, and percentage of the existing steel stirrups.(iii)The most common failure mode of NSM FRP strengthened RC beams is the failure at the interface between NSM FRP reinforcement and adhesive layer, whereas the fracture of the concrete substrate surrounding groove is also commonly observed when normal or low concrete is used.(iv)The study also considered a large number of experimental works to evaluate the contribution of NSM strengthening in shear using formulations found in the literature. It appealed that the formula suggested by Dias and Barros [75] reasonably agrees with the experimental results with 9% of conservation.

Conflicts of Interest

The authors declare that they have no conflicts of interest.

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Copyright © 2021 Majid M. A. Kadhim et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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