Coupling Effect of Salt Freeze-Thaw Cycles and Carbonation on the Mechanical Performance of Quick Hardening Sulphoaluminate Cement-Based Reactive Powder Concrete with Basalt Fibers

: The effect of salt freeze-thaw cycles coupled with carbonation on the mechanical performance of quick hardening sulphoaluminate cement-based reactive powder concrete combined with basalt ﬁbers was investigated. The ratios of basalt ﬁbers in sulphoaluminate cement-based reactive powder concrete (SAC-RPC) were 1%, 2%, 3% and 4% by the volume of concrete. The mechanical strengths (compressive strength, ﬂexural strength and bonding strength) of SAC-RPC were investigated after curing for 5 h, 1 d, 14 d and 28 d, respectively. Meanwhile, the mechanical strengths of resultant concrete were detected, when different NaCl freeze-thaw cycles and carbonation were adopted. Results showed that the addition of basalt ﬁbers could effectively improve the mechanical strengths, especially the ﬂexural strength of SAC-RPC. The dosage of 3.0% was the threshold value affected mechanical strengths. The ﬂexural, compressive and bonding strengths of SAC-RPC were higher than 8.53 MPa, 34 MPa and 3.21 MPa, respectively. The mass loss and mechanical strengths loss of SAC-RPC increased in the form of quadratic function with the increasing number of NaCl freeze-thaw cycles and varied in the form of quadratic decreasing function. Meanwhile, the effect of carbonation on the mechanical strengths of SAC-RPC can be ignored. Additionally, the coupling effect of salt freeze-thaw cycles and carbonation could accelerate the attenuation of concrete strength. The mechanical strengths loss demonstrated a decreased quadratic function with the increasing volume of basalt ﬁbers.


Introduction
Bridge is the pivotal part of building structures, which carries a lot of traffic load. However, damage often occurs to its deck due to the action of load on the surface. Meanwhile, the corrosive environmental action can accelerate the damage of the deck when in service. Therefore, the deck should be repaired timely.
So far, a variety of repair materials have been developed for the maintenance-repairing of the deck of bridges. The repairing materials can be divided into two categories, asphalt based repairing materials and cement-based repairing materials. Some research reports pointed out that the asphalt based repairing materials are convenient for construction and is followed by the fast open to traffic [1][2][3]. However, the resistance to aging on fatigue performance of the asphalt based repairing materials is poor. Moreover, the cost of asphalt based repairing materials is very high. Wang et al. [4][5][6] studied the effect of aging on fatigue performance of cement emulsified asphalt repairing material and found that the addition of cement could improve the fatigue life. Furthermore, the cement-based materials are often used in the repairing engineering of bridge deck [7][8][9]. Jin et al. [10][11][12], pointed out that the magnesium phosphate cement-based materials possessed impressive compressive and bending strengths higher than 13 MPa and 3.5 MPa, respectively, after curing for 1 h. Additionally, the tensile bonding strength of bricks repaired by asphalt based repairing materials after curing for 1 d was 2.466 MPa [10]. Sulphoaluminate cement is a kind of quick hardening cement which has been used for repairing the roads and bridges for several years [13,14]. As found out in Hu's paper [15], sulphoaluminate cement mortar reinforced with micro-fine steel fibers displayed a maximum compressive strength of 19 MPa and flexural strength of 5.3 MPa after cured for 3 h. Prior researches [16][17][18] pointed out that the mechanical strength of Portland cement based materials at initial curing age (3 h~3 d) was much lower than that of sulphoaluminate cement based materials, while at a long curing age, the mechanical strength of Portland cement based materials showed higher strength than sulphoaluminate cement based materials [19]. The reactive powder concrete is a kind of concrete with high compactness, which shows excellent mechanical strengths and durability [20][21][22][23]. Hong et al. [24][25][26] manufactured the rapid hardening reactive powder concrete with steel fibers and investigated its following mechanical properties and durability.
The mechanical properties and durability of cement-based repairing materials have been reported in several studies. The bonding strength of the cement-based repairing material is a key factor for repairing the construction buildings, however, little attention has been paid to this aspect [27][28][29][30]. As reported in some research, the addition of steel fibers can improve the mechanical performance of cement concrete effectively. Nevertheless, the steel fibers are prone to corrosion, leading eventually to the reduction of durability. Basalt fiber has become a research and application hotspot in the international civil engineering field due to its excellent high temperature resistance, strong anti-seepage, anti-crack effect, green and environmental protection production process, low price and thermal expansion coefficient similar to that of cement. Yet, little attention has been drawn to the sulphoaluminate cement-based materials reinforced with basalt fibers. Meanwhile, few researchers have paid attention to the durability of basalt fibers reinforced sulphoaluminate cement-based materials.
This paper was aimed to investigate the influence of curing age and the coupling effect of salt freeze-thaw cycles and carbonation on the mechanical performances of basalt fibers reinforced quick hardening sulphoaluminate cement-based reactive powder concrete (SAC-RPC), which will provide a new kind of rapid repairing for the concrete construction buildings.

Raw Materials
Type XK-DQXWY chopped basalt fibers with the length of 3 cm and the diameter of 5.5-6.5 µm produced by Shanghai Chenqi COBIT Co., Ltd., Shanghai, China, were used in this study. The density of basalt fibers used in this research was 2.635 g/cm 3 . Additionally, the average elastic modulus and the tensile strength of these fibers were 10,520 MPa and 4325 MPa, respectively. The dosages of basalt fibers applied in this study were 1%, 2%, 3% and 4% by the volume of sulphoaluminate cement-based reactive powder concrete (SAC-RPC). Binder materials used in this study were rapid hardening sulphoaluminate cement (R.SAC) produced by Tangshan Polar Bear Building Materials Co., Ltd., Tangshan, China, with a strength grade of 42.5 MPa, Silica fume (SF) possessing a specific surface area of 15 m 2 /g and more than 98% SiO 2 , and granulated blast furnace slag powder (GGBS) with density, specific surface area and loss on ignition of 2.9 g/cm 3 , 436 m 2 /g and 2.3%, respectively. The quartz sand with particle sizes of 1-0.71 mm, 0.59-0.35 mm and 0.15-0.297 mm was used as aggregate in this study. The mass ratios of quartz sand with particle sizes of 1-0.71 mm, 0.59-0.35 mm and 0.15-0.297 mm were 1:1.5:0.8. The quartz sand possessed 99.6% SiO 2 , 0.02% Fe 2 O 3 and other ingredients. In this study, the binder sand ratio was 1.25, and the mass ratios of cement: SF: GGBS were 1:0.5:0.15. In order to make sure enough fluidity of fresh basalt fibers reinforced SAC-RPC, the polycarboxylate-based water-reducing agent with the water-reducing rate of 40% provided by Shenteng Co., Ltd., Lingshou, China was applied. Li 2 SO 4 , tartaric acid, polyether defoamer produced by Yingshan, Co., Ltd., Shanghai, China were used as early strength agent, retarder and defoamer in this study. Furthermore, for all specimens, the lithium sulfate, defoamer and tartaric acid in this study are 0.15%, 0.2% and 0.6% by mass of cementitious materials, respectively. Tables 1 and 2 show the particle size distribution and chemical composition of cementitious materials.

Specimen Preparation and Measurement Methods
The SAC-RPC can be manufactured following these steps: The powder admixtures (sulphoaluminate cement, silica fume, slag powder, quartz sand, lithium sulfate, defoamer and tartaric acid) are firstly mixed in the UJZ-15 mortar mixer Hebei Daoneng Construction Engineering Co., Ltd., Cangzhou, China, for 0.5 min. Then, the basalt fibers were added and mixed for another 2 min. After this mixing, the water-reducing agent is mixed with water and stirred in the mixture for the last 5.5 min. The slump flow of fresh RPC paste is adjusted to 210-230 mm by water-reducing agent. DF-04 polyether surfactant with density of 0.4 g/cm 3 and pH of 7.0-7.5 produced by Yingshan New Material Technology Co., Ltd. is used to eliminate air bubbles in RPC. After mixing, the fresh SAC-RPC was poured into the molds to manufacture the specimens. The specimens with sizes of 40 mm × 40 mm × 160 mm, 100 mm × 100 mm × 400 mm and 100 mm × 100 mm × 100 mm were applied to the experiments of mechanical strengths, NaCl freeze-thaw cycles and the carbonation, respectively. All specimens were cured in the room environment (20 ± 2 • C and relative humidity of 40 ± 2%) for 1 h before demolding. After demolding, all specimens were cured in the standard curing room (temperature of 20 ± 2 • C and relative humidity of above 95%) for different curing ages. Figure 1 shows the manufacturing process of the specimens. The mechanical strengths (compressive strength and flexural strength) of specimens were determined by the YAW-300 microcomputer full-automatic universal tester with the maximum testing force of 300 kN provided by Henruijin Co., Ltd., Jinan, China according  The mechanical strengths (compressive strength and flexural strength) of specimens were determined by the YAW-300 microcomputer full-automatic universal tester with the maximum testing force of 300 kN provided by Henruijin Co., Ltd., Jinan, China according to GB/T 17671-1999 Chinese standard [31]. Additionally, the experimental process of the bonding strength is described as following. The cement mortars made by ordinary Portland cement and quartz sand were prepared for the measurement of bonding strength. The water-cement ratio of the cement mortar was 0.2, and the sand-cement ratio was 2.5. After the specimens were demolding and cured in standard curing room for 28 days, the specimens were cut in two halves and each half of specimens was repaired by the SAC-RPC. The specimen for the measurement of bonding strength is shown in Figure 2. The mechanical strengths (compressive strength and flexural strength) of specimens were determined by the YAW-300 microcomputer full-automatic universal tester with the maximum testing force of 300 kN provided by Henruijin Co., Ltd., Jinan, China according to GB/T 17671-1999 Chinese standard [31]. Additionally, the experimental process of the bonding strength is described as following. The cement mortars made by ordinary Portland cement and quartz sand were prepared for the measurement of bonding strength. The water-cement ratio of the cement mortar was 0.2, and the sand-cement ratio was 2.5. After the specimens were demolding and cured in standard curing room for 28 days, the specimens were cut in two halves and each half of specimens was repaired by the SAC-RPC. The specimen for the measurement of bonding strength is shown in Figure  2. The experiments of NaCl freeze-thaw cycles and carbonation test were carried out according to the Chinese Standard GB/T 50082-2009 [32]. All specimens for the experiment of NaCl freeze-thaw cycles were cured in the standard curing room for 24 days. The BWDR-I rapid freeze-thaw concrete testing machine produced by Cangzhou Zerui Test Instrument Co., Ltd., Cangzhou, China was provided for the experiment of NaCl freezethaw cycles. The temperature for NaCl freeze-cycles was −15-8 °C. Before experiment of NaCl freeze-cycles, all specimens were immersed in 3% NaCl solution for 4 days. After this process, the specimens were moved in the stainless-steel sealed casing filled with 3% NaCl solution for the experiments of NaCl freeze-cycles. The specimens cured for 28 days were applied for the experiment of carbonation. CCB-70F automatic concrete carbonation test box produced by Tianjin Deste Instrument Technology Co., Ltd. (Tianjin, China) was used for the carbonation experiment. The concentration of carbon dioxide for the carbonation experiment was 20% by the mass ratio of the total mass of gas. The specimens for the carbonation experiment were cured in the CCB-70F automatic concrete carbonation test box for 60 days before determination. The coupling effects of NaCl freezethaw cycles and carbonation can be described as the following steps. Three specimens of each group were cured in the CCB-70F automatic concrete carbonation test box for 60 days and then the specimens were moved for the experiment of NaCl freeze-thaw cycles. The experiments of NaCl freeze-thaw cycles and carbonation test were carried out according to the Chinese Standard GB/T 50082-2009 [32]. All specimens for the experiment of NaCl freeze-thaw cycles were cured in the standard curing room for 24 days. The BWDR-I rapid freeze-thaw concrete testing machine produced by Cangzhou Zerui Test Instrument Co., Ltd., Cangzhou, China was provided for the experiment of NaCl freezethaw cycles. The temperature for NaCl freeze-cycles was −15-8 • C. Before experiment of NaCl freeze-cycles, all specimens were immersed in 3% NaCl solution for 4 days. After this process, the specimens were moved in the stainless-steel sealed casing filled with 3% NaCl solution for the experiments of NaCl freeze-cycles. The specimens cured for 28 days were applied for the experiment of carbonation. CCB-70F automatic concrete carbonation test box produced by Tianjin Deste Instrument Technology Co., Ltd. (Tianjin, China) was used for the carbonation experiment. The concentration of carbon dioxide for the carbonation experiment was 20% by the mass ratio of the total mass of gas. The specimens for the carbonation experiment were cured in the CCB-70F automatic concrete carbonation test box for 60 days before determination. The coupling effects of NaCl freeze-thaw cycles and carbonation can be described as the following steps. Three specimens of each group were cured in the CCB-70F automatic concrete carbonation test box for 60 days and then the specimens were moved for the experiment of NaCl freeze-thaw cycles. Figure 3 shows the flexural and compressive strengths of basalt fibers reinforced SAC-RPC. As shown in Figure 3, the flexural and compressive strengths of basalt fibers reinforced SAC-RPC increased with the increasing dosage of basalt fibers and the curing time. When the curing age was 5 h, the flexural and compressive strengths of basalt fibers reinforced SAC-RPC was higher than 8.53 MPa and 34 MPa, respectively, which was enough to the passage of vehicles. When the dosages of basalt fibers increased from 0% to 1%, the flexural and compressive strengths of basalt fibers reinforced SAC-RPC increased slowly, due to the fact that the basalt fibers could effectively decrease crack propagation and improve the mechanical strengths of SAC-RPC [33,34]. However, the agglomeration of basalt fibers could induce the reduction in the mechanical strengths [35]. When the content of basalt fibers was 0-1%, the enhancement effect of basalt fibers is close to the weakening effect. Therefore, the mechanical strengths of basalt fibers reinforced SAC-RPC varied slowly with the increasing addition of basalt fibers. Meanwhile, when the content of basalt fibers increased from 1% to 3%, the mechanical strengths of basalt fibers reinforced SAC-RPC increased obviously. This was attributed to the reinforcement of basalt fibers [36]. Additionally, when the dosages of basalt fibers increased from 3% to 4%, the mechanical strengths of basalt fibers reinforced SAC-RPC reached a stable value. Consequently, it could be obtained from Figure 3, the basalt fibers volume of 3% was the threshold value of mechanical strengths of basalt fibers reinforced SAC-RPC in this study.

Mechanical Strength
enough to the passage of vehicles. When the dosages of basalt fibers increased from 0% to 1%, the flexural and compressive strengths of basalt fibers reinforced SAC-RPC increased slowly, due to the fact that the basalt fibers could effectively decrease crack propagation and improve the mechanical strengths of SAC-RPC [33,34]. However, the agglomeration of basalt fibers could induce the reduction in the mechanical strengths [35]. When the content of basalt fibers was 0-1%, the enhancement effect of basalt fibers is close to the weakening effect. Therefore, the mechanical strengths of basalt fibers reinforced SAC-RPC varied slowly with the increasing addition of basalt fibers. Meanwhile, when the content of basalt fibers increased from 1% to 3%, the mechanical strengths of basalt fibers reinforced SAC-RPC increased obviously. This was attributed to the reinforcement of basalt fibers [36]. Additionally, when the dosages of basalt fibers increased from 3% to 4%, the mechanical strengths of basalt fibers reinforced SAC-RPC reached a stable value. Consequently, it could be obtained from Figure 3, the basalt fibers volume of 3% was the threshold value of mechanical strengths of basalt fibers reinforced SAC-RPC in this study.    Figure 4 that the volume ratio of 3% was the threshold value of bonding strength. When the dosage of basalt fibers increased from 0% to 3%, the bonding strength of basalt fibers reinforced SAC-RPC increased sharply with the increasing dosages of basalt fibers. When the content of basalt fibers was higher than 3%, the bonding strength of basalt fibers reinforced SAC-RPC kept at a stable value. Figure 5 shows the bonding strength loss rate (η) compared to that of flexural strength (ft) which can be expressed in Equation (1).   Figure 4 that the volume ratio of 3% was the threshold value of bonding strength. When the dosage of basalt fibers increased from 0% to 3%, the bonding strength of basalt fibers reinforced SAC-RPC increased sharply with the increasing dosages of basalt fibers. When the content of basalt fibers was higher than 3%, the bonding strength of basalt fibers reinforced SAC-RPC kept at a stable value. Figure 5 shows the bonding strength loss rate (η) compared to that of flexural strength (f t ) which can be expressed in Equation (1).
As shown in Figure 5, the bonding strength loss rate ranged from 52.63% to 65.73%, indicating that the bonding strength was 34.27-47.37% of the flexural strength. It can be observed from Figures 3-5 that the error bars of mechanical strengths are relatively low (less than 0.1), indicating a low discreteness in the experimental observations. Moreover, it could be observed from Figures 3-5, the addition of basalt fibers was more favorable to the flexural and bonding strengths than that of compressive strength.
As shown in Figure 5, the bonding strength loss rate ranged from 52.63% to 65.73%, indicating that the bonding strength was 34.27-47.37% of the flexural strength. It can be observed from Figures 3-5 that the error bars of mechanical strengths are relatively low (less than 0.1), indicating a low discreteness in the experimental observations. Moreover, it could be observed from Figures 3-5, the addition of basalt fibers was more favorable to the flexural and bonding strengths than that of compressive strength.    As shown in Figure 5, the bonding strength loss rate ranged from 52.63% to 65.73%, indicating that the bonding strength was 34.27-47.37% of the flexural strength. It can be observed from Figures 3-5 that the error bars of mechanical strengths are relatively low (less than 0.1), indicating a low discreteness in the experimental observations. Moreover, it could be observed from Figures 3-5, the addition of basalt fibers was more favorable to the flexural and bonding strengths than that of compressive strength.    Figure 6 demonstrates the mass loss of basalt fibers reinforced SAC-RPC during NaCl freeze-thaw cycles. Table 3 shows the fitting results of the relationship between the number of freeze-thaw cycles and mass loss rate. As illustrated in Figure 6 and Table 3, the mass loss rate of the basalt fibers reinforced SAC-RPC increased in the form of quadratic growth function. This was attributed to the fact that the NaCl freeze-thaw cycles could make the inner frost heaving stress of basalt fibers reinforced SAC-RPC increasing, leading to the mass loss of SAC-RPC increased. [37,38]. Meanwhile, as obtained from Figure 6 that the addition of basalt fibers could effectively decrease the mass loss rate and improve the resistance of NaCl freeze-thaw cycles. the mass loss rate of the basalt fibers reinforced SAC-RPC increased in the form of quadratic growth function. This was attributed to the fact that the NaCl freeze-thaw cycles could make the inner frost heaving stress of basalt fibers reinforced SAC-RPC increasing, leading to the mass loss of SAC-RPC increased. [37,38]. Meanwhile, as obtained from Figure 6 that the addition of basalt fibers could effectively decrease the mass loss rate and improve the resistance of NaCl freeze-thaw cycles.   Figure 7 presents the mechanical strengths loss rate of basalt fibers reinforced SAC-RPC during NaCl freeze-thaw cycles. Table 4 shows the fitting results of mechanical loss rate and the number of NaCl freeze-thaw cycles (N). As illustrated in Figure 7 and Table  4, the mechanical strengths loss rate of SAC-RPC increased in the form of quadratic function with the number of NaCl freeze-thaw cycles. This was attributed to the fact that the NaCl freeze-thaw cycles could increase the inner cracks of basalt fibers reinforced SAC-RPC, meanwhile, the NaCl freeze-thaw cycles caused the freeze-thaw fatigue to the basalt fibers reinforced SAC-RPC and reduced the mechanical strengths of basalt fibers reinforced SAC-RPC. Furthermore, the addition of basalt fibers could effectively improve the attenuation of NaCl freeze-thaw cycles due to the limiting effect of freeze-thaw cracks [39,40]. Moreover, the basalt fibers possess excellent corrosion resistance of corrosion.   Figure 7 presents the mechanical strengths loss rate of basalt fibers reinforced SAC-RPC during NaCl freeze-thaw cycles. Table 4 shows the fitting results of mechanical loss rate and the number of NaCl freeze-thaw cycles (N). As illustrated in Figure 7 and Table 4, the mechanical strengths loss rate of SAC-RPC increased in the form of quadratic function with the number of NaCl freeze-thaw cycles. This was attributed to the fact that the NaCl freeze-thaw cycles could increase the inner cracks of basalt fibers reinforced SAC-RPC, meanwhile, the NaCl freeze-thaw cycles caused the freeze-thaw fatigue to the basalt fibers reinforced SAC-RPC and reduced the mechanical strengths of basalt fibers reinforced SAC-RPC. Furthermore, the addition of basalt fibers could effectively improve the attenuation of NaCl freeze-thaw cycles due to the limiting effect of freeze-thaw cracks [39,40]. Moreover, the basalt fibers possess excellent corrosion resistance of corrosion. Consequently, the addition of basalt fibers demonstrated positive effect on the resistance of NaCl freeze-thaw cycles. It can be obtained from Figure 7a-c, the compressive strength decreased the least during the NaCl freeze-thaw cycles, however, the flexural strength lost the highest. of NaCl freeze-thaw cycles. It can be obtained from Figure 7a-c, the compressive strength decreased the least during the NaCl freeze-thaw cycles, however, the flexural strength lost the highest.

Mechanical Properties of SAC-RPC during the Coupling Effect of Carbonation and NaCl Freeze-Thaw Cycles
The carbonation depth of basalt fibers reinforced SAC-RPC is shown in Figure 8. Table 5 shows the results of the fitting parameters. As depicted in Figure 8 and Table 5, the carbonation depth of basalt fibers reinforced SAC-RPC demonstrated a descending trend with the volume of basalt fibers. The fitting equation of the relationship between the volume of basalt fibers and carbonation depth conforms to the quadratic decreasing function. Meanwhile, the NaCl freeze-thaw cycles could lead to increasing the carbonation depth. This was attributed to the fact that the basalt fibers could decrease the number and size of cracks in SAC-RPC thus decreasing the contact of CO 2 and Ca(OH) 2 leading eventually to decreasing the carbonation depth of basalt fibers reinforced SAC-RPC [41,42]. However, the NaCl freeze-thaw cycles were able to accelerate the formation and propagation of cracks thus increasing the carbonation depth of basalt fibers reinforced SAC-RPC.

Mechanical Properties of SAC-RPC during the Coupling Effect of Carbonation and NaCl Freeze-Thaw Cycles
The carbonation depth of basalt fibers reinforced SAC-RPC is shown in Figure 8. Table 5 shows the results of the fitting parameters. As depicted in Figure 8 and Table 5, the carbonation depth of basalt fibers reinforced SAC-RPC demonstrated a descending trend with the volume of basalt fibers. The fitting equation of the relationship between the volume of basalt fibers and carbonation depth conforms to the quadratic decreasing function. Meanwhile, the NaCl freeze-thaw cycles could lead to increasing the carbonation depth. This was attributed to the fact that the basalt fibers could decrease the number and size of cracks in SAC-RPC thus decreasing the contact of CO2 and Ca(OH)2 leading eventually to decreasing the carbonation depth of basalt fibers reinforced SAC-RPC [41,42]. However, the NaCl freeze-thaw cycles were able to accelerate the formation and propagation of cracks thus increasing the carbonation depth of basalt fibers reinforced SAC-RPC.   Figure 9 shows the mechanical strengths loss rate of SAC-RPC under the coupling effect of carbonation and NaCl freeze-thaw cycles. Table 6 is the fitting result of mechanical loss rate and the volume of basalt fibers. It can be observed from Figure 9 and Table 6, the mechanical strengths loss rate decreased in the form of the quadratic function with the increasing dosage of basalt fibers. This was attributed to the limiting effect of basalt fibers on cracks [43]. When only carbonation was applied to the SAC-RPC the mechanical strengths rarely changed due to the fact that the substances (CaCO 3 ) produced by carbonation reaction demonstrated little influence on the mechanical strengths of SAC-RPC. However, when the coupling effect of carbonation and NaCl freeze-thaw cycles acted on the SAC-RPC, the mechanical strengths loss rate increased obviously with the increasing numbers of NaCl freeze-thaw cycles. The NaCl freeze-thaw cycles could accelerate the development of internal cracks which in turn facilitate the ingression of carbon dioxide to corrode the cement matrix. These two factors will be coupled and further accelerate the deterioration of SAC-RPC. As obtained from Figure 9a-c, the flexural strength of SAC-RPC decayed the most seriously under the environment of coupling effect of salt freeze-thaw cycles and carbonation. However, the attenuation of the compressive strength was the least. It can be obtained from this study that the addition of basalt fibers showed better enhancement effect on the flexural and bonding strengths of SAC-RPC. However, the flexural and bonding strengths descended more obviously than that of the compressive strength. Compared the basalt fibers with the steel fibers reinforced SAC-RPC [24], basalt fibers reinforced SAC-RPC showed more excellent resistance to the NaCl freeze-thaw cycles. Furthermore, the mechanical strengths of basalt fibers reinforced SAC-RPC was worse than that of steel fibers reinforced SAC-RPC. It can be obtained from this study that the addition of basalt fibers showed better enhancement effect on the flexural and bonding strengths of SAC-RPC. However, the flexural and bonding strengths descended more obviously than that of the compressive strength. Compared the basalt fibers with the steel fibers reinforced SAC-RPC [24], basalt

Conclusions
In this study, the mechanical strengths of basalt fibers reinforced SAC-RPC and the bonding strength of cement mortar repaired by this material were investigated. Moreover,