Investigation of Steel Fiber-Reinforced Mortar Overlay for Strengthening Masonry Walls by Prism Tests

: A strengthening method using steel ﬁber-reinforced mortar (SFRM), proposed for the seismic retroﬁt of masonry buildings, is veriﬁed experimentally in this study. The SFRM is overlaid on masonry walls directly, which is possible to implement while the building is occupied for residence. First, tests of workability and material strengths were conducted for SFRM itself in order to ﬁnd SFRM mixing ratios appropriate for overlay construction and strengthening. Then, masonry prisms were produced using two types of bricks and strengthened with SFRM for the chosen mixing ratios and test variables such as the number of overlaid sides and the ﬁber volume fraction. Compressive strength tests and diagonal tension tests for those specimens were conducted. Both compressive and shear strengths were improved the most highly by overlaying the SFRM with a ﬁber volume fraction of 1.3%, which is the highest among the test variables, on both sides. Overlaid SFRM tends to be detached without cracking almost at the maximum strength in both compression and diagonal tension tests. For red clay brick prisms, the compressive and shear strengths increased by up to 61% and 138%, respectively. For concrete brick prisms, the compressive and shear strengths increased by up to 26% and 67%. Finally, a design formula for the shear strength of strengthened masonry prisms is compared with the experimental results, and it is observed that the design formula gives slightly higher results.


Introduction
Unreinforced masonry is one of representative structural systems for buildings that have been damaged severely in most major earthquakes worldwide. Recently, two major earthquakes occurred in Gyeongju and Pohang, respectively, located in South Korea caused significant damage to many buildings although those earthquakes have a moderate level of local magnitude, 5.8 and 5.4, respectively. Unexceptionally, bearing walls in unreinforced masonry buildings and external masonry veneers were reported as building components damaged the most significantly in the two earthquakes.
The mechanical property of masonry is difficult to predict because masonry is composed of different materials, i.e., masonry units and type or material of joint, and strongly influenced by workmanship strongly [1]. In particular, masonry units have different dimensions and shapes and are made of diverse materials, such as adobe and concrete. Masonry walls also fail in diverse modes such as diagonal cracking, horizontal sliding, rocking, and corner crushing. The mechanical characteristics of masonry have been investigated through experimental works by many researchers. One of the representative reasons for this is that the mechanical characteristics of masonry are considerably influenced by local materials. Narrowing down the scope of the literature to the Korean masonry materials, the following research works are available in the literature. Yu and Kwon (2011) [2] compared mechanical characteristics of masonry prisms produced using either cement or lime for joint mortar based on compression and diagonal tension tests. Kim et al. (2001) [3] performed compression and diagonal tension tests for the masonry prisms produced using joint mortar with various mixing ratios, and proposed empirical equations for the compressive strength of joint mortar and elastic modulus of masonry prisms. Yang et al. (2019) [4] proposed a shear stress-strain relationship through diagonal tension tests of masonry prisms for numerical analysis of masonry walls.
Most Korean masonry buildings are low-rise buildings and have not been designed seismically, even though those were constructed after the Korean Building Acts introduced seismic design provisions in 1988. The structural system of Korean masonry buildings is usually unreinforced masonry, of which vulnerability to earthquakes is well-known, as mentioned above. As a result, social demand for strengthening methods that can be installed easily with low cost is increasing in Korea after the two recent earthquakes. Choi et al. (2010) [5] studied seismic retrofit of unreinforced masonry walls using shotcrete overlay, which was made of Engineered Cementitious Composite (ECC) containing Polyvinyl Alcohol (PVA) fibers. They validated the effect of shotcrete overlay to enhance both strength and deformability experimentally. Taghdi et al. (2000) [6] showed that the shear strength and ductility of masonry walls and reinforced concrete walls were increased by attaching steel strips with concrete anchors. Ghiassi et al. (2012) investigated bond-slip behavior for masonry strengthened with different FRP materials both numerically and experimentally [7]. In addition, Ismail et al. (2011) [8] proposed a method to stitch masonry units with twisted steel bars that are placed in the groove made on the surface of the masonry and filled with mortar. Darbhanzi et al. (2014) [9] conducted a seismic retrofit of unreinforced masonry walls, which comprises the addition of two vertical steel ties on both edges of the walls, and anchored to the top and bottom of the walls. Silva et al. (2014) [10] strengthened unreinforced masonry by injecting lime grout, confirming that the strength and deformation capacity of the masonry increase two times and three times, respectively. In addition, as with this study, several researchers have conducted experimental studies to strengthen unreinforced masonry using overlay methods. Almeida et al. (2015) [11] strengthened unreinforced masonry by overlaying polypropylene fiber reinforced mortar (PFRM) and carbon fiber mesh (CFM). D' Ambrisi et al. (2013) [12] strengthened unreinforced masonry walls with three types of polymeric mesh attached with mortar plastered on the walls. Benedetti (2019) [13] strengthened masonry walls using glass fiber mesh-reinforced mortar (G-FRM) so that the shear strength of the masonry walls increased by more than 100%, even with a 15 mm or smaller thickness of strengthening layers on the two wall faces. In most preceding studies, fiber mesh or wire mesh is usually used in the overlaying method for strengthening masonry walls.
In this study, an efficient method to strengthen unreinforced masonry walls using a steel fiber-reinforced mortar (SFRM) overlay. The proposed overlaying method has the advantage of constructability during residence of occupants. In addition, plastering work does not require high workmanship and can be applied to the vicinity of openings without cutting or splicing. Above all, mortar can be integrated with masonry, considering that it has been used for the joint and finishing of masonry. However, the brittle behavior of plain mortar is similar to masonry. It is necessary to add reinforcement appropriate for plastering material to improve mechanical behavior of masonry walls after retrofit. SFRM is a cement composite incorporating steel fibers which improves brittle behavior of mortar as well as mechanical properties such as tensile strength and toughness. Generally, steel fibers are known to have better strength and stiffness than organic fibers such as Polyethylene (PE), Polypropylene (PP), Nylon, etc., but relatively long and thick dimensions make those difficult to apply steel fibers to thin mortar overlay. On the other hand straight or hook-type steel fibers commonly used in construction fields are relatively stiff and difficult to plaster in a thin layer without balls and protrusion, of which the latter may cause human injury. As a result, this study adopted Amorphous Steel Fibers (ASF), which reinforces mortar effectively in spite of its relatively short length due to better bonding characteristics owing to the thin shape and surface roughness.
In this study, the effect of SFRM for strengthening masonry walls was assessed based on the compressive and diagonal tension strength for masonry prisms. Those strength parameters are used to define the lateral force-resisting capacity of masonry walls in a major failure mode such as toe-crushing or diagonal tension failure, as stipulated in ASCE 41-17 [14]. In order to build strengthened prism specimens, a recommended SFRM mixing ratio with both strengthening efficiency and overlay constructability is derived based on constructability tests for fresh mortar, compression and tension tests for hardened mortar specimens for various mixing ratios, since the characteristics of SFRM strongly depend on the type of fiber, fiber volume fraction, and mixing ratio of mortar. Then, the performance of the strengthening method is evaluated by compressive and diagonal tension tests of masonry prisms with and without SFRM overlay to which the recommended mixing ratio of the mortar. This study concentrates on two representative types of unreinforced masonry. One is made of red bricks and usually used as an exterior veneer. The other is concrete bricks, usually used for bearing walls. For easy construction, only SFRM was used, without additional glass fiber or wire mesh. Finally, the applicability of existing design equations is investigated based on the measured strengths of prism specimens.

Derivation of Appropriate Mixing Ratio for SFRM
The main objective of developing an appropriate mixing ratio for SFRM is to obtain higher compressive and tensile strengths as well as a workability suitable for overlay construction. Flow tests and cohesion tests of fresh SFRM were conducted for diverse mixing ratios in order to select the candidate mixing ratios that are the most appropriate for overlay construction on masonry. Then, compressive and tensile tests were conducted for hardened SFRM specimens produced with the candidate mixing ratios, and the most appropriate mixing ratio is determined.

Mixing Design
Regarding a mixing ratio appropriate for overlay construction, the Korean Construction Standard (KCS) 41 16 02 [15] set forth two standard mixing ratios for plastering mortar, of which cement-to-sand ratios are 1:2 for exterior walls and 1:3 for interior walls, respectively. However, in case of mortar with steel fibers, various cement-to-sand ratios are investigated from preceding studies and summarized in Table 1. The volume of sand is relatively small, so that the highest equals two times the volume of cement in Table 1 in order to enhance binding action for fibers. In light of the preceding studies given in Table 1, three trial cement-to-sand ratios between 1:1 to 1:2 in combination with different water-to-cement ratios were chosen and summarized in Table 2. In addition, a mixing ratio utilizing superplasticizer was introduced to prevent the development of fiber balls and improve fluidity, referring to Park et al. (2016) and Shabdin et al. (2017) [19,20]. Additional tests using fiber volume fractions 1.0% and 1.3% were performed for the last two mixing ratios in Table 2 that showed superior workability and cohesion compared to others. In the designation of mixing ratios for SFRM defined in Table 2, S/C means the volume ratio of sand over cement, and W/C means the weight ratio of water to cement as noted in the foot note.

Materials
Mortar in this study was comprised of ordinary Portland cement for binder and standard river sand with a specific gravity of 2.6 for fine aggregate. The superplasticizer included in mixing variables is a polycarbonate type. The steel fibers used for SFRM are amorphous steel fibers, which proved effective in improving the flexural performance of beam type structural components by Lee and Choi (2014) [21]. The appearance of the amorphous steel fibers is shown in Figure 1.
Appl. Sci. 2020, 10, x FOR PEER REVIEW 4 of 21 means the volume ratio of sand over cement, and W/C means the weight ratio of water to cement as noted in the foot note.

Materials
Mortar in this study was comprised of ordinary Portland cement for binder and standard river sand with a specific gravity of 2.6 for fine aggregate. The superplasticizer included in mixing variables is a polycarbonate type. The steel fibers used for SFRM are amorphous steel fibers, which proved effective in improving the flexural performance of beam type structural components by Lee and Choi (2014) [21]. The appearance of the amorphous steel fibers is shown in Figure 1.  [22]. (b) Amorphous steel fiber [23].
The physical properties of the amorphous steel fibers are summarized in Table 3. According to Ku et al. (2014) [22], the amorphous steel fiber not only has excellent tensile and flexural strength compared to ordinary steel fibers, but also increases adhesion to concrete with rough surface. In addition, it shows good flexibility and dispersibility in mixing. Consequently, the above characteristics for the amorphous steel fibers were supposed to help the uniform distribution of fibers in SFRM in spite of relatively small thickness of overlay on existing walls.
The same procedure of mixing was applied to all mixing ratios to ensure uniform quality. Firstly, cement and fine aggregate were dry-mixed at low speed for 1 min. Secondly, water and admixture, if specified, were added and mixed for 1 min at low speed and then for 3 min at high speed. Finally, mixing was finished by adding fibers and mixing for 2 min 30 s. The physical properties of the amorphous steel fibers are summarized in Table 3. According to Ku et al. (2014) [22], the amorphous steel fiber not only has excellent tensile and flexural strength compared to ordinary steel fibers, but also increases adhesion to concrete with rough surface. In addition, it shows good flexibility and dispersibility in mixing. Consequently, the above characteristics for the amorphous steel fibers were supposed to help the uniform distribution of fibers in SFRM in spite of relatively small thickness of overlay on existing walls.
The same procedure of mixing was applied to all mixing ratios to ensure uniform quality. Firstly, cement and fine aggregate were dry-mixed at low speed for 1 min. Secondly, water and admixture, if specified, were added and mixed for 1 min at low speed and then for 3 min at high speed. Finally, mixing was finished by adding fibers and mixing for 2 min 30 s.

Workabiliy Tests
Plastering work requires fresh mortar to have adhesion enough to prevent flowing down on the vertical face of masonry walls. However, workability represented in the form of a specific slump or flow appropriate for plastering work of fresh mortar is not clearly prescribed in Korean Industrial Standards (KS) and Korean Construction Specifications (KCS) such as KS F 4716 [24], KS F 2262 [25], KCS 41 16 01 [26] and KCS 41 16 02 [15], which only provide testing methods for hardened mortar or specifications for plastering work. Instead, recommended values of flow were found from the literature survey. Lee (2009) [27] suggested an appropriate flow range of lightweight mortar mixed with gypsum, of which fire resistance performance was tested, from 170 to 210 mm. Park (2010) [28] suggested a flow of 180 mm suitable for constructability in a study of diverse mortar for interior finishing plaster. In this study, the target flow of SFRM was determined to be 180 mm in light of preceding research. Flow table tests for various mixing ratios of SFRM were carried out in accordance with KS L 5111 [29].
Measured flow values are plotted with respect to the fiber volume fraction in Figure 2. The flow value obtained for S/C20-W/C25-AD01 containing superplasticizer, and S/C20-W/C50 and S/C20-W/C50 with a relatively high water-cement ratio exceeded the target, 180 mm, by 20 mm or higher. The fiber volume fraction does not have clear influence on the flow for those specimens. However, flow values for other specimens are lower than 200 mm and tend to decrease slowly as the fiber volume fraction increases. The three groups of specimens corresponding to S/C20-W/C40, S/C15-W/C35, and S/C10-W/C32 had flow values that were adequately close to the target, 180 mm.

Workabiliy Tests
Plastering work requires fresh mortar to have adhesion enough to prevent flowing down on the vertical face of masonry walls. However, workability represented in the form of a specific slump or flow appropriate for plastering work of fresh mortar is not clearly prescribed in Korean Industrial Standards (KS) and Korean Construction Specifications (KCS) such as KS F 4716 [24], KS F 2262 [25], KCS 41 16 01 [26] and KCS 41 16 02 [15], which only provide testing methods for hardened mortar or specifications for plastering work. Instead, recommended values of flow were found from the literature survey. Lee (2009) [27] suggested an appropriate flow range of lightweight mortar mixed with gypsum, of which fire resistance performance was tested, from 170 to 210 mm. Park (2010) [28] suggested a flow of 180 mm suitable for constructability in a study of diverse mortar for interior finishing plaster. In this study, the target flow of SFRM was determined to be 180 mm in light of preceding research. Flow table tests for various mixing ratios of SFRM were carried out in accordance with KS L 5111 [29].
Measured flow values are plotted with respect to the fiber volume fraction in Figure 2. The flow value obtained for S/C20-W/C25-AD01 containing superplasticizer, and S/C20-W/C50 and S/C20-W/C50 with a relatively high water-cement ratio exceeded the target, 180 mm, by 20 mm or higher. The fiber volume fraction does not have clear influence on the flow for those specimens. However, flow values for other specimens are lower than 200 mm and tend to decrease slowly as the fiber volume fraction increases. The three groups of specimens corresponding to S/C20-W/C40, S/C15-W/C35, and S/C10-W/C32 had flow values that were adequately close to the target, 180 mm.  The adhesion of SFRM to bricks was tested using a procedure proposed by the authors, since test methods and acceptance criteria for the adhesion of fresh mortar are not specified in the Korean or international standards investigated by authors, as mentioned above. The test method is to check the deflection of the plastered SFRM in 1 min after a trial plastering of SFRM with a thickness of 2.5 mm as shown in Figure 3, and the measured flow values and overlayable thickness are summarized in Table 4. The trial plastering and measurement of the deflection was conducted repeatedly and recorded. The adhesion of SFRM for each trial plastering was evaluated as good, normal, and poor for a deflection of 0, 2, and 5 mm, respectively. The maximum plastered thickness for which accumulated total deflection was restrained under 2 mm are summarized as the overlayable thickness in Table 4. The overlayable thickness for SFRM tends to decrease gradually as the fiber volume ratio increases. The S/C20-W/C25-AD01 specimen containing superplasticizer and the S/C20-W/C50 with a relatively high water-cement ratio show relatively low overlayable thickness that does not exceed 7.5 mm. The low overlayable thickness may lengthen the construction periods because subsequent plastering shall be conducted on previous overlay, which hardened sufficiently. On the other hand, the two mixing ratios of S/C20-W/C45 and S/C10-W/C32 showed good adhesion performance with all the overlayable thickness higher than or equal to 10 mm in Table 4. Based on the adhesion test result, the thickness of the SFRM for a single trial of plastering was decided to be 10 mm for the production of strengthened masonry prism specimens Appl. Sci. 2020, 10, x FOR PEER REVIEW 6 of 21 The adhesion of SFRM to bricks was tested using a procedure proposed by the authors, since test methods and acceptance criteria for the adhesion of fresh mortar are not specified in the Korean or international standards investigated by authors, as mentioned above. The test method is to check the deflection of the plastered SFRM in 1 min after a trial plastering of SFRM with a thickness of 2.5 mm as shown in Figure 3, and the measured flow values and overlayable thickness are summarized in Table 4. The trial plastering and measurement of the deflection was conducted repeatedly and recorded. The adhesion of SFRM for each trial plastering was evaluated as good, normal, and poor for a deflection of 0, 2, and 5 mm, respectively. The maximum plastered thickness for which accumulated total deflection was restrained under 2 mm are summarized as the overlayable thickness in Table 4. The overlayable thickness for SFRM tends to decrease gradually as the fiber volume ratio increases. The S/C20-W/C25-AD01 specimen containing superplasticizer and the S/C20-W/C50 with a relatively high water-cement ratio show relatively low overlayable thickness that does not exceed 7.5 mm. The low overlayable thickness may lengthen the construction periods because subsequent plastering shall be conducted on previous overlay, which hardened sufficiently. On the other hand, the two mixing ratios of S/C20-W/C45 and S/C10-W/C32 showed good adhesion performance with all the overlayable thickness higher than or equal to 10 mm in Table 4. Based on the adhesion test result, the thickness of the SFRM for a single trial of plastering was decided to be 10 mm for the production of strengthened masonry prism specimens

Compressive and Tensile Tests
The compressive and tensile strength for SFRM with diverse mixing ratios given in Table 2 were tested in accordance with KS L 5105 [30] and KS L5104 [31], as shown in Figure 4. The specimens for compressive tests were made in cubes with a 50 × 50 × 50 mm dimension in accordance with KS L 5105 [30]. The specimens for tensile tests were made in briquettes shown in Figure 4b, in accordance with KS L 5104 [31]. All the specimens were cured in water at room temperature for 28 days. For each mixing ratio, both compressive and tensile strengths were measured and averaged for three specimens, respectively. A universal testing machine (UTM) was used for compression tests, and a hydraulic oil pump was used for tension tests. The compressive strengths for different SFRM mixing ratios are plotted with respect to the volume fraction of amorphous steel fiber in Figure 5. It is observed that the fiber volume fraction does not affect the compressive strength of the SFRM significantly. The highest compressive strength 67 MPa was obtained for S/C10-W/C32, followed by S/C15-W/C35, and S/C20-W/C40 in a descending order. Based on the test result, the compressive strength of SFRM is more influenced by increased cement volume and reduced water cement ratio rather than the fiber volume fraction.
The tensile test results are plotted in Figure 6. The five mixing ratios except S/C20-W/C25-AD01 show an increasing trend with respect to the fiber volume fraction. In more detail, it is observed that the tensile strength of SFRM increases little with 0.7% or less steel fiber volume fraction. However, the tensile strength of SFRM with 1.0% or higher steel fiber volume fraction increases compared to mortar without fibers by about 30%. S/C10-W/C32 with a relatively low sand-cement ratio and low water-cement ratio achieves a tensile strength of 6.6 MPa at with 1.3% steel fiber volume fraction resulting in a strength enhancement of 50%. From this observation, it is supposed that the increased amount of cement in paste enhances bond of steel fibers and makes a corresponding contribution to tensile strength.
Appl. Sci. 2020, 10, x FOR PEER REVIEW 8 of 21 amount of cement in paste enhances bond of steel fibers and makes a corresponding contribution to tensile strength.              Table 5 summarizes the mixing ratios that achieved target performance for each test category. In Table 4, S/C20-W/C40, S/C15-W/C35, and S/C10-W/C32 have flow characteristics corresponding to the target flow, 180 mm. In the adhesion test, only two specimens S/C20-W/C45 and S/C10-W/C32 achieved the overlayable thickness of 10 mm or higher for fiber entire fiber volume fractions. Therefore, Appl. Sci. 2020, 10, 6395 9 of 21 only S/C10-W/C32 is a common candidate for recommendation from both workability tests. In addition, S/C10-W/C32 with the fiber volume ratio of 1.3% shows the highest tensile strength among all the tested mixing ratios while compressive strength did not show a meaningful increase in strength with respect to the fiber volume fraction. As a result, the mixing ratio S/C10-W/C32, which showed adequate characteristics for all four evaluation categories including flow, adhesion, compression, and tensile strength, was adopted for subsequent tests of masonry prisms strengthened with SFRM overlay. Table 5. Determination of SFRM mixing ratio.

Experiment SFRM Mixing Ratio
Workability Flow

Test Program
Tests for the compressive strength and diagonal tension of masonry prisms strengthened with SFRM overlay were performed. The tests were conducted in accordance with ASTM C 1314 [32] and ASTM E 519 [33], since the Korean Building Code does not clearly stipulate methodology and procedure for such tests of masonry prisms. The mixing ratio S/C10-W/C32 was chosen for SFRM as described in the previous section based on the result of tests for workability and strength tests. In this study, the compressive strength, shear strength, elastic modulus and shear modulus of each prism specimen were measured.

Specimens
The type of bricks, the number of strengthened faces, and the fiber volume ratios adopted for test variables are summarized in Table 6 with specimen names. Concrete and red clay bricks usually used for construction of bearing walls and external masonry veneers, respectively, were adopted to comprise masonry prisms and designated by C and R in the specimen names. In the specimen names, P designates the specimen without strengthening, S designates the specimen strengthened on a single surface, and B designates the specimen strengthened on both sides. The number that follows the characters in a specimen name represents the fiber volume fraction in percent in mortar overlay for strengthening. Due to lack of amorphous steel fibers, only two specimens were produced per RS1.0 and CS1.0 in Table 6.  The shapes and dimensions of test specimens for compression and diagonal tension tests, illustrated in Figure 7, comply with ASTM C 1314 [32] and ASTM E 519 [33], respectively. The dimension of both concrete bricks and red clay bricks is 190 × 90 × 57 mm. Concrete bricks are hollow but red clay bricks are solid, as is usual in Korea. The shapes and dimensions of test specimens for compression and diagonal tension tests, illustrated in Figure 7, comply with ASTM C 1314 [32] and ASTM E 519 [33], respectively. The dimension of both concrete bricks and red clay bricks is 190 × 90 × 57 mm. Concrete bricks are hollow but red clay bricks are solid, as is usual in Korea.  [36] proposed an empirical equation to predict the compressive strength of the joint mortar with respect to the sand-to-cement weight ratio. The test result for the compressive strength of the joint mortar used in this study that were cured in water was 33 MPa, which was almost similar to the 32.5 MPa predicted in accordance with Yi et al. (2004) [36].
The prism specimen for compression strength test has a total of three layers laid-up in a stack bond pattern, while the diagonal tension prism has a total of six layers laid-up in a running bond pattern as illustrated in Figure 7. Both vertical and horizontal joints between bricks were filled with  [36] proposed an empirical equation to predict the compressive strength of the joint mortar with respect to the sand-to-cement weight ratio. The test result for the compressive strength of the joint mortar used in this study that were cured in water was 33 MPa, which was almost similar to the 32.5 MPa predicted in accordance with Yi et al. (2004) [36].
The prism specimen for compression strength test has a total of three layers laid-up in a stack bond pattern, while the diagonal tension prism has a total of six layers laid-up in a running bond pattern as illustrated in Figure 7. Both vertical and horizontal joints between bricks were filled with mortar without a visual gap. As shown in Figure 8, strengthened prisms were produced by plastering SFRM repetitively on bare masonry prisms 28 days after lay-up. A total thickness of 30 mm were plastered in three times with an interval of 24 h, according to the adhesion test result described previously. Water was sprayed on the bare masonry before plastering SFRM. All of the SFRM-overlaid prisms were cured in air dry conditions and room temperature. mortar without a visual gap. As shown in Figure 8, strengthened prisms were produced by plastering SFRM repetitively on bare masonry prisms 28 days after lay-up. A total thickness of 30 mm were plastered in three times with an interval of 24 h, according to the adhesion test result described previously. Water was sprayed on the bare masonry before plastering SFRM. All of the SFRMoverlaid prisms were cured in air dry conditions and room temperature.

Test Setup and Loading Protocol
Both compression and diagonal tension tests were conducted using 200-ton universal testing machines (UTMs). Monotonic loading in compression test was applied at a rate of 1.0 mm/min and diagonal tension test, which was expected to have relatively low loading capacity, was applied at a rate of 0.6 mm/min. Both types of tests were terminated when the resistance of the specimens decreased to 70% of the peak. For the compression test of masonry prisms, the vertical deformation of a masonry prism specimen was measured by setting linear variable displacement transducers (LVDTs) at the front and rear of a specimen, as shown in Figure 9. The average of the two measurements is used as the compressive deformation of the specimen. In case of the diagonal tension test of masonry prisms, the diagonal deformation in the vertical direction of the specimen rotated by 45° was measured in the same way as for the compression test. Additionally, the diagonal deformation in the horizontal direction of the 45°-rotated specimen was measured using two LVDTs set in the plane of the specimen at the right-and left-hand side corners, as shown in Figure 10. The horizontal deformation was calculated as the sum of the displacements from the two horizontal LVDTs.

Test Setup and Loading Protocol
Both compression and diagonal tension tests were conducted using 200-ton universal testing machines (UTMs). Monotonic loading in compression test was applied at a rate of 1.0 mm/min and diagonal tension test, which was expected to have relatively low loading capacity, was applied at a rate of 0.6 mm/min. Both types of tests were terminated when the resistance of the specimens decreased to 70% of the peak. For the compression test of masonry prisms, the vertical deformation of a masonry prism specimen was measured by setting linear variable displacement transducers (LVDTs) at the front and rear of a specimen, as shown in Figure 9. The average of the two measurements is used as the compressive deformation of the specimen. In case of the diagonal tension test of masonry prisms, the diagonal deformation in the vertical direction of the specimen rotated by 45 • was measured in the same way as for the compression test. Additionally, the diagonal deformation in the horizontal direction of the 45 • -rotated specimen was measured using two LVDTs set in the plane of the specimen at the right-and left-hand side corners, as shown in Figure 10. The horizontal deformation was calculated as the sum of the displacements from the two horizontal LVDTs. mortar without a visual gap. As shown in Figure 8, strengthened prisms were produced by plastering SFRM repetitively on bare masonry prisms 28 days after lay-up. A total thickness of 30 mm were plastered in three times with an interval of 24 h, according to the adhesion test result described previously. Water was sprayed on the bare masonry before plastering SFRM. All of the SFRMoverlaid prisms were cured in air dry conditions and room temperature.

Test Setup and Loading Protocol
Both compression and diagonal tension tests were conducted using 200-ton universal testing machines (UTMs). Monotonic loading in compression test was applied at a rate of 1.0 mm/min and diagonal tension test, which was expected to have relatively low loading capacity, was applied at a rate of 0.6 mm/min. Both types of tests were terminated when the resistance of the specimens decreased to 70% of the peak. For the compression test of masonry prisms, the vertical deformation of a masonry prism specimen was measured by setting linear variable displacement transducers (LVDTs) at the front and rear of a specimen, as shown in Figure 9. The average of the two measurements is used as the compressive deformation of the specimen. In case of the diagonal tension test of masonry prisms, the diagonal deformation in the vertical direction of the specimen rotated by 45° was measured in the same way as for the compression test. Additionally, the diagonal deformation in the horizontal direction of the 45°-rotated specimen was measured using two LVDTs set in the plane of the specimen at the right-and left-hand side corners, as shown in Figure 10. The horizontal deformation was calculated as the sum of the displacements from the two horizontal LVDTs.

Strength and Modulus of Elasticity
The compressive strength of the masonry prism was calculated in accordance with ASTM C-1314 [32] considering the correction factors for the height-to-thickness ratio. In accordance with ASTM C-1314, the net cross-sectional area for red clay bricks with a hollow cross section was deemed to be the gross cross-sectional area because the net cross-sectional area is higher than or equal to 75% of the gross cross-sectional area. The elastic modulus was calculated using Equation (1) where is the elastic modulus for the masonry prism (MPa), is the compressive strength of the masonry prism (MPa), and and are strains at 5% and 33% of the maximum stress, respectively. However, in the actual calculation of and , only the stress-strain curve higher than the horizontal broken line in Figure 11, at which the slope begins to be almost constant, was taken into account, because the initial growth of stress is too slow. The shear strength and shear modulus from diagonal tension tests for masonry prisms were calculated in accordance with ASTM E-519 [33], in which the net area of the masonry unit is used for

Strength and Modulus of Elasticity
The compressive strength of the masonry prism was calculated in accordance with ASTM C-1314 [32] considering the correction factors for the height-to-thickness ratio. In accordance with ASTM C-1314, the net cross-sectional area for red clay bricks with a hollow cross section was deemed to be the gross cross-sectional area because the net cross-sectional area is higher than or equal to 75% of the gross cross-sectional area. The elastic modulus was calculated using Equation (1) where E m is the elastic modulus for the masonry prism (MPa), σ is the compressive strength of the masonry prism (MPa), and 1 and 2 are strains at 5% and 33% of the maximum stress, respectively. However, in the actual calculation of 1 and 2 , only the stress-strain curve higher than the horizontal broken line in Figure 11, at which the slope begins to be almost constant, was taken into account, because the initial growth of stress is too slow.

Strength and Modulus of Elasticity
The compressive strength of the masonry prism was calculated in accordance with ASTM C-1314 [32] considering the correction factors for the height-to-thickness ratio. In accordance with ASTM C-1314, the net cross-sectional area for red clay bricks with a hollow cross section was deemed to be the gross cross-sectional area because the net cross-sectional area is higher than or equal to 75% of the gross cross-sectional area. The elastic modulus was calculated using Equation (1) where is the elastic modulus for the masonry prism (MPa), is the compressive strength of the masonry prism (MPa), and and are strains at 5% and 33% of the maximum stress, respectively. However, in the actual calculation of and , only the stress-strain curve higher than the horizontal broken line in Figure 11, at which the slope begins to be almost constant, was taken into account, because the initial growth of stress is too slow. The shear strength and shear modulus from diagonal tension tests for masonry prisms were calculated in accordance with ASTM E-519 [33], in which the net area of the masonry unit is used for The shear strength and shear modulus from diagonal tension tests for masonry prisms were calculated in accordance with ASTM E-519 [33], in which the net area of the masonry unit is used for Appl. Sci. 2020, 10, 6395 13 of 21 the calculation of shear stress. The shear strain for the calculation of shear modulus was calculated based on the vertical and horizontal displacement measured, as described in Figure 10.

Compression Test Result
The result of the compression tests for masonry prisms made of red clay bricks and concrete bricks is summarized in Tables 7 and 8, respectively. The average compressive strengths for red clay brick prisms and concrete brick prisms without strengthening designated with RP and CP in Tables 7 and 8 are 14.5 and 16.3 MPa, respectively, which are not significantly different. However, the elastic moduli for RP and CP are 1382.7 and 3951.1 MPa, respectively, which shows significantly higher stiffness for concrete brick prisms than for red clay brick prisms. Mechanical properties such as compressive strength and elastic modulus for red clay brick prisms were enhanced effectively by overlaying mortar. Comparing RB0 and RB1.3 in Table 7, the SFRM with a sufficiently high fiber volume fraction, at 1.3%, is significantly more effective than the mortar without fibers. The highest compressive strength among red clay brick prisms was obtained for RB1.3 among strengthened red clay brick prisms and the amount of increase was 61%. In a similar manner, CB1.3 showed the highest compressive strength among concrete brick prisms in Table 8 due to the largest amount of the strengthening overlay and steel fibers. However, the increase in the compressive strength reaches only 26% of the strength for bare prisms denoted by CP and the elastic modulus decreased by 6%.  Figures 12 and 13 plot compressive stress-strain relation for prisms made of red clay bricks and concrete bricks, respectively. In these figures, it is observed that RB1.3 specimens show the most prominent enhancement in both strength and deformability. In case of CB1.3, the strength increase is significant only in one specimen, but deformability is enhanced for all three specimens. Consequently, the strengthening effect of SFRM for masonry prisms in compression is more remarkable for red clay brick prisms than for concrete brick prisms. From the above observation, it is supposed that the weaker and softer characteristics of red clay bricks make the strengthening effect of SFRM more prominent in comparison with application on concrete bricks. The pictures of masonry prisms for compression tests after the termination of tests are presented in Figure 14. The specimen RP without strengthening failed with vertical cracks, as shown in Figure  14a. The strengthened specimens RB0 and RB1.3 failed accompanying separation between mortar overlay and masonry, as shown in Figure 14b,c. In case of RB0, the mortar overlay without fibers plastered on masonry was split in addition to separation from masonry, as shown in Figure 14b. The mortar overlay without fibers were completely detached from the surface of the masonry and the masonry between the two strengthening overlays was crushed almost at the same time as the separation of the mortar overlay occurred. On the other hand, for RB 1.3, the SFRM overlay was not damaged, but only cracks formed at the interface between the overlay and prisms around boundary edges slowly after the load reaches the peak. The crushing of masonry in RB1.3 progressed in a relatively slow manner. Based on the observed behavior of strengthened masonry prisms, the strengthening effects of SFRM overlay are expected to be improved by developing mechanical connection details between the SFRM overlay and masonry.  The pictures of masonry prisms for compression tests after the termination of tests are presented in Figure 14. The specimen RP without strengthening failed with vertical cracks, as shown in Figure  14a. The strengthened specimens RB0 and RB1.3 failed accompanying separation between mortar overlay and masonry, as shown in Figure 14b,c. In case of RB0, the mortar overlay without fibers plastered on masonry was split in addition to separation from masonry, as shown in Figure 14b. The mortar overlay without fibers were completely detached from the surface of the masonry and the masonry between the two strengthening overlays was crushed almost at the same time as the separation of the mortar overlay occurred. On the other hand, for RB 1.3, the SFRM overlay was not damaged, but only cracks formed at the interface between the overlay and prisms around boundary edges slowly after the load reaches the peak. The crushing of masonry in RB1.3 progressed in a relatively slow manner. Based on the observed behavior of strengthened masonry prisms, the strengthening effects of SFRM overlay are expected to be improved by developing mechanical connection details between the SFRM overlay and masonry.  The pictures of masonry prisms for compression tests after the termination of tests are presented in Figure 14. The specimen RP without strengthening failed with vertical cracks, as shown in Figure 14a. The strengthened specimens RB0 and RB1.3 failed accompanying separation between mortar overlay and masonry, as shown in Figure 14b,c. In case of RB0, the mortar overlay without fibers plastered on masonry was split in addition to separation from masonry, as shown in Figure 14b. The mortar overlay without fibers were completely detached from the surface of the masonry and the masonry between the two strengthening overlays was crushed almost at the same time as the separation of the mortar overlay occurred. On the other hand, for RB 1.3, the SFRM overlay was not damaged, but only cracks formed at the interface between the overlay and prisms around boundary edges slowly after the load reaches the peak. The crushing of masonry in RB1.3 progressed in a relatively slow manner. Based on the observed behavior of strengthened masonry prisms, the strengthening effects of SFRM overlay are expected to be improved by developing mechanical connection details between the SFRM overlay and masonry. The pictures of masonry prisms for compression tests after the termination of tests are presented in Figure 14. The specimen RP without strengthening failed with vertical cracks, as shown in Figure  14a. The strengthened specimens RB0 and RB1.3 failed accompanying separation between mortar overlay and masonry, as shown in Figure 14b,c. In case of RB0, the mortar overlay without fibers plastered on masonry was split in addition to separation from masonry, as shown in Figure 14b. The mortar overlay without fibers were completely detached from the surface of the masonry and the masonry between the two strengthening overlays was crushed almost at the same time as the separation of the mortar overlay occurred. On the other hand, for RB 1.3, the SFRM overlay was not damaged, but only cracks formed at the interface between the overlay and prisms around boundary edges slowly after the load reaches the peak. The crushing of masonry in RB1.3 progressed in a relatively slow manner. Based on the observed behavior of strengthened masonry prisms, the strengthening effects of SFRM overlay are expected to be improved by developing mechanical connection details between the SFRM overlay and masonry.

Diagonal Tension Test Result
The result of the diagonal tension test for masonry prisms made of red clay and concrete bricks are summarized in Tables 9 and 10, respectively. The average shear strength of unreinforced concrete brick prism CP is about 1.6 times higher than that of unreinforced red clay brick prisms RP, but the average shear modulus for CP is only 1.2 times higher than that of RP. The increase rate of shear strength by mortar overlay for RS1.3, RB0 and RB1.0 is from 51 to 69%, and those for CS1.3, CB0 and CB1.0 are between 39 and 56%. The strengthening efficiency for red clay brick masonry is slightly higher than for concrete brick masonry. The maximum enhancements of shear strength are 138% and 67% for RB1.3 and CB1.3, respectively, to which the highest fiber volume fraction is applied. One of the reasons for the higher strengthening efficiency in red clay brick masonry is supposed to be the lower strength of the masonry itself, considering that SFRM with the same mixing ratios and fiber volume fractions was applied to both types of masonry materials. A similar tendency was observed by Borri et al. (2011) [38], in which masonry walls strengthened using high-strength steel wires and mortar were tested and the unreinforced test specimens with higher strength and stiffness obtained less strengthening effects. Therefore, the efficiency of the strengthening method proposed by this study is expected to be more prominent when applied to masonry in poor condition. Regarding the shear modulus, red clay brick masonry and concrete brick masonry obtained an increase of 32% for RB1.3 and 20% for CB1.3, respectively, using SFRM with a fiber volume fraction of 1.3% on both sides. However, the increase rates of the shear modulus are relatively small compared to the increase in shear strength and the shear modulus even decreases for a number of specimen types. The increase rate of shear modulus for red clay brick masonry is slightly better than for concrete brick masonry regarding the shear strength.
The stress-strain curves obtained from the unreinforced masonry without strengthening and masonry strengthened on both sides are plotted in Figures 15 and 16 for red clay brick masonry and concrete brick masonry, respectively. In the initial loading stage, difference between unreinforced and strengthened masonry is not significant, but the strengthening effects become more obvious as the strain increases. Above all, masonry prisms strengthened with SFRM exhibit much more deformation capacity compared to those strengthened with plain mortar commonly for both masonry materials.
Appl. Sci. 2020, 10, x FOR PEER REVIEW 16 of 21 deformation capacity compared to those strengthened with plain mortar commonly for both masonry materials.
(a) (b) (c) Representative damage states of specimens after the termination of diagonal tension tests are represented in Figure 17. Failure in diagonal tension tests of masonry prisms is generally classified into three types: diagonal tension failure along the force direction, sliding failure along the horizontal mortar joint, and composite failure in which both diagonal tension failure and sliding failure occur in combination. According to Yu and Kwon (2011) [1], the compressive strength of the joint mortar higher than the compressive strength of the brick tends to result in diagonal tension failure or composite failure, while low compressive strengths of the joint mortar lead to sliding failure. In this study, the compressive strengths for joint mortar, concrete bricks and red clay bricks are 33, 29.1 and 23.2 MPa, respectively, from which diagonal tension failure or composite failure are anticipated, as observed in Figure 17a.
In case of the specimen CB0 strengthened with mortar overlay without steel fibers, brittle failure occurred in both mortar overlay and the masonry, as shown in Figure 17b. On the other hand, for the specimen CB1.3 strengthened with SFRM, the overlay detached as the load reached the peak in a similar way to the compression tests, and the condition of the SFRM at the termination of the test was good with few cracks, as shown in Figure 17c.
The damage state of the masonry beneath the mortar overlay was difficult to identify visually, so the mortar overlay was taken off after the termination of the test. From the investigation, it was observed that diagonal tension failure had occurred in the masonry prism between the two mortar overlays, as shown in Figure 18. From the above observations, it is supposed that masonry prisms strengthened with SFRM overlay failed in diagonal tension after the detachment of the overlay. Therefore, strengthening effects are expected to be improved, as in the compression test, if the integrity between the masonry and SFRM is improved. Representative damage states of specimens after the termination of diagonal tension tests are represented in Figure 17. Failure in diagonal tension tests of masonry prisms is generally classified into three types: diagonal tension failure along the force direction, sliding failure along the horizontal mortar joint, and composite failure in which both diagonal tension failure and sliding failure occur in combination. According to Yu and Kwon (2011) [1], the compressive strength of the joint mortar higher than the compressive strength of the brick tends to result in diagonal tension failure or composite failure, while low compressive strengths of the joint mortar lead to sliding failure. In this study, the compressive strengths for joint mortar, concrete bricks and red clay bricks are 33, 29.1 and 23.2 MPa, respectively, from which diagonal tension failure or composite failure are anticipated, as observed in Figure 17a.
In case of the specimen CB0 strengthened with mortar overlay without steel fibers, brittle failure occurred in both mortar overlay and the masonry, as shown in Figure 17b. On the other hand, for the specimen CB1.3 strengthened with SFRM, the overlay detached as the load reached the peak in a similar way to the compression tests, and the condition of the SFRM at the termination of the test was good with few cracks, as shown in Figure 17c.
The damage state of the masonry beneath the mortar overlay was difficult to identify visually, so the mortar overlay was taken off after the termination of the test. From the investigation, it was observed that diagonal tension failure had occurred in the masonry prism between the two mortar overlays, as shown in Figure 18. From the above observations, it is supposed that masonry prisms strengthened with SFRM overlay failed in diagonal tension after the detachment of the overlay. Therefore, strengthening effects are expected to be improved, as in the compression test, if the integrity between the masonry and SFRM is improved. Representative damage states of specimens after the termination of diagonal tension tests are represented in Figure 17. Failure in diagonal tension tests of masonry prisms is generally classified into three types: diagonal tension failure along the force direction, sliding failure along the horizontal mortar joint, and composite failure in which both diagonal tension failure and sliding failure occur in combination. According to Yu and Kwon (2011) [1], the compressive strength of the joint mortar higher than the compressive strength of the brick tends to result in diagonal tension failure or composite failure, while low compressive strengths of the joint mortar lead to sliding failure. In this study, the compressive strengths for joint mortar, concrete bricks and red clay bricks are 33, 29.1 and 23.2 MPa, respectively, from which diagonal tension failure or composite failure are anticipated, as observed in Figure 17a.
In case of the specimen CB0 strengthened with mortar overlay without steel fibers, brittle failure occurred in both mortar overlay and the masonry, as shown in Figure 17b. On the other hand, for the specimen CB1.3 strengthened with SFRM, the overlay detached as the load reached the peak in a similar way to the compression tests, and the condition of the SFRM at the termination of the test was good with few cracks, as shown in Figure 17c.
The damage state of the masonry beneath the mortar overlay was difficult to identify visually, so the mortar overlay was taken off after the termination of the test. From the investigation, it was observed that diagonal tension failure had occurred in the masonry prism between the two mortar overlays, as shown in Figure 18. From the above observations, it is supposed that masonry prisms strengthened with SFRM overlay failed in diagonal tension after the detachment of the overlay. Therefore, strengthening effects are expected to be improved, as in the compression test, if the integrity between the masonry and SFRM is improved.

Estimation of Enhanced Shear Strength
The shear strength observed in the tests are compared with those predicted using design equations. ACI 549.4R-13 [39] provides that shear strength of masonry walls strengthened with Fabric Reinforced Cement Matrix (FRCM) is calculated by combining the contribution of the masonry and the FRCM composite material, respectively, as follows where , and are the nominal shear strength, the contribution of the masonry, and the contribution of the FRCM composite material. The FRCM is a kind of mortar reinforced with grid type mesh, while SFRM is mortar reinforced with steel fibers. In spite of difference between the two types of reinforcement, the shear strength of masonry walls strengthened by SFRM is supposed to be calculated using Equation (2) considering that both FRCM and SFRM are essentially the same material for strengthening masonry walls.
The masonry prisms failed in the diagonal tension failure mode as shown in Figures 17 and 18 where is the angle between horizontal and main diagonal of the wall, is the net area of the cross section of the masonry wall (mm ), and ′ is the tensile strength of the masonry calculated as

Estimation of Enhanced Shear Strength
The shear strength observed in the tests are compared with those predicted using design equations. ACI 549.4R-13 [39] provides that shear strength of masonry walls strengthened with Fabric Reinforced Cement Matrix (FRCM) is calculated by combining the contribution of the masonry and the FRCM composite material, respectively, as follows where , and are the nominal shear strength, the contribution of the masonry, and the contribution of the FRCM composite material. The FRCM is a kind of mortar reinforced with grid type mesh, while SFRM is mortar reinforced with steel fibers. In spite of difference between the two types of reinforcement, the shear strength of masonry walls strengthened by SFRM is supposed to be calculated using Equation (2) considering that both FRCM and SFRM are essentially the same material for strengthening masonry walls.
The masonry prisms failed in the diagonal tension failure mode as shown in Figures 17 and 18 where is the angle between horizontal and main diagonal of the wall, is the net area of the

Estimation of Enhanced Shear Strength
The shear strength observed in the tests are compared with those predicted using design equations. ACI 549.4R-13 [39] provides that shear strength of masonry walls strengthened with Fabric Reinforced Cement Matrix (FRCM) is calculated by combining the contribution of the masonry and the FRCM composite material, respectively, as follows where V n , V m and V f are the nominal shear strength, the contribution of the masonry, and the contribution of the FRCM composite material. The FRCM is a kind of mortar reinforced with grid type mesh, while SFRM is mortar reinforced with steel fibers. In spite of difference between the two types of reinforcement, the shear strength of masonry walls strengthened by SFRM is supposed to be calculated using Equation (2) considering that both FRCM and SFRM are essentially the same material for strengthening masonry walls.
The masonry prisms failed in the diagonal tension failure mode as shown in Figures 17 and 18. For such a case, the shear strength of the masonry wall, V m , can be calculated using Equation (3) proposed by Li et al. (2005) [40] for the diagonal tension failure where θ is the angle between horizontal and main diagonal of the wall, A n is the net area of the cross section of the masonry wall (mm 2 ), and f t is the tensile strength of the masonry calculated as 0.67 × f m and 0.5 × f m , in which f m is the compressive strength of the masonry (MPa), for red clay bricks and concrete bricks, respectively (MPa), in accordance with Silva et al. (2008) [41]. However, diagonal tension test result for masonry prisms without strengthening was used for V m instead of calculation by Equation (3), considering the tensile strength of bricks has much uncertainty. From the peak load in the diagonal tension test, only the component parallel to the horizontal joints in the masonry prism was decomposed and assigned to V m . On the other hand, Equation (3) was used to calculate the contribution of the SFRM overlay to the shear strength, denoted by V f . In Almeida et al. (2015) [11], masonry prisms were strengthened with mortar overlay reinforced by mesh, and the contribution of mortar overlay except mesh was calculated using Equation (3). This is a reasonable approximation when the mortar joints between bricks are relatively strong and the failure is governed by masonry units such as bricks. The tensile strength of SFRM in Figure 6 was used for f t in Equation (3). In addition, Sagar et al. (2017) [42] conducted experiments on the diagonal tension strength and out-of-plane flexural strength for masonry walls strengthened with FRCM, and proposed Equation (4) to calculate the contribution to the shear strength by FRCM where V ECC is the shear strength of the engineered cementitious composite (ECC) section (kN) and was used as shear strength of the SFRM in this study, t ECC is the thickness of the overlay (mm), z is the lever arm assumed as 0.87 times the length of the specimen (mm), f yECC and f ECC are the tensile and compressive strengths of the overlay, respectively (MPa), and L is the length of the wall (mm). The shear strengths of masonry prisms strengthened with SFRM overlays obtained from the tests and calculations using Equations (2)-(4) are summarized for comparison in Table 11, in which the contribution of the masonry and that of the SFRM are given separately. It is noted that all the calculated shear strengths for strengthened masonry prisms are consistently higher than the corresponding experimental strengths and Equation (4) tends to overestimate the shear strengths more significantly than Equation (3).
Equation (2) assumes that both masonry and mortar overlay for strengthening fail simultaneously. However, SFRM overlay detached from the interface without damage, as shown in Figure 17c. The premature detachment of the SFRM overlay causes Equation (2) to overestimate the strength of the strengthened masonry prisms. To improve the accuracy in predicted shear strength, it is necessary to take into account the bond strength between SFRM and masonry, which requires an additional test program. Otherwise, it can be anticipated that error in strength estimation using Equations (2) and (3) will be reduced if any technique to improve the bond strength or shear connectors between masonry and SFRM overlay are applied.
In case of RB0 and CB0, the strengthened masonry prism fail with the mortar overlay cracked, as shown in Figure 17b. Therefore, the error in strength estimation given in Table 11 does not result from the premature detachment of the mortar overlay. In this case, the error may be caused by the use of Equation (3) or (4), in which material strength is for the masonry unit and mortar joint stronger than the masonry unit is assumed to exist.

Conclusions
In this study, material specifications of steel fiber-reinforced mortar to strengthen masonry prisms were investigated based on extensive test programs regarding both workability and strength. In addition, the strengthening effect of SFRM overlay for masonry prisms was investigated through tests for various strengthening schemes. Finally, applicability of existing design equations to predict enhanced strength is evaluated. The key findings from the experimental study are summarized as follows.

1.
The mixing ratios of SFRM appropriate for plastering work on masonry walls and effective in strengthening were identified. Plastering the SFRM was more effective for the shear strength than the compressive strength and achieved 67% and 138% increases for red clay brick prisms and concrete brick prisms; 2.
The higher volume fraction of amorphous steel fibers in SFRM e.g., 1.3% achieved considerably ductile behavior in the diagonal tension test in contrast to the brittle behavior observed for the plain mortar overlay; 3.
The SFRM overlay was separated without damage from the masonry prisms at the failure in diagonal tension tests. For accurate estimation of enhanced shear strength, it is necessary to take into account the bond strength between the SFRM overlay and the masonry, instead of the shear strength of SFRM overlay itself. Additionally, enhancement of the bond strength is expected to improve the strengthening effects by fully exploiting the capacity of the SFRM overlay; 4.
The masonry prisms used in this study have relatively good condition. In order to apply the proposed strengthening technique to existing masonry buildings in relatively poor conditions, additional verification for masonry in such a condition is necessary.