Recycling concrete not only reduces the use of virgin aggregate but also decreases the pressure on landfills. As a result, recycled coarse aggregate (RCA) is extensively recommended for new construction projects. However, the flexural behavior of corroded reinforced recycled aggregate concrete (RAC) beams is uncertain. The experimental research presented in this paper was performed to investigate the flexural behavior of corroded reinforced RAC beams compared to that of corroded reinforced natural aggregate concrete (NAC) beams and consequently explore the possibility of using RAC beams in corrosive environments. Four different percentages of RCA in total mass of coarse aggregate in concrete mixtures (0%, 33%, 66%, and 100%) and two different concrete strengths (C30, C60) were the governing parameters. The electrochemical method was adopted to accelerate steel corrosion. Full-scale tests were performed on eight simply supported beams until the failure load was reached. Comparison of load-deflection behavior, crack patterns, failure modes, ductility, and ultimate flexural capacity of corroded reinforced NAC and RAC beams was made based on the experimental results obtained. The comparison results show that the flexural behavior of corroded reinforced RAC beams with an appropriate percentage of RCA is satisfactory compared to the behavior of NAC beams.
The amount of concrete waste has increased significantly over the years owing to reconstruction and the demolition of old buildings and has become a serious global environmental concern. Recycling of waste concrete is one of the sustainable solutions for the growing waste disposal crisis and depletion of natural aggregate sources. As a result, recycled coarse aggregate (RCA) is being produced for various applications, and a number of studies have been carried out to examine its fundamental properties and mixture design. Researchers [
Various studies have also examined the mechanical properties, mixture design, and structural performance of reinforced concrete beams comprising recycled aggregate. Numerous researchers have investigated the flexural behavior of reinforced RAC beams, with their results showing that the flexural performance of beams made of RAC is comparable to that of beams made of conventional NAC [
However, it should be noted that the above studies on reinforced RAC beams were conducted in ideal environments without corrosive mediums. In fact, a corrosive environment such as seawater is very harmful to the applicability and security of structure or component. Tests have shown that different corrosion ratios of longitudinal bars have a different impact on the flexural properties of corroded reinforced concrete beams with 100% replacement of coarse aggregate [
The methodology used in this study was to compare the flexural performance of corroded reinforced concrete beams made of NAC and to that of RAC. As the antipermeability property of RAC is related to RCA replacement percentage and the performance of medium-strength concrete and high-strength concrete are different, four different percentages of RCA in total mass of coarse aggregate in concrete mixtures (0%, 33%, 66%, and 100%) and two different concrete strengths (C30, C60) were the governing parameters in this analysis. All specimens were designed to have the same structure, size, reinforcement ratio, and corrosion ratio. The electrochemical method was adopted to accelerate steel corrosion. Full-scale tests up to failure load on eight simply supported beams were conducted to investigate the flexural behavior of corroded reinforced RAC beams. The experimental results were then analyzed to obtain more general conclusions concerning the flexural behavior of RAC beams compared to that of NAC beams under corrosive circumstances.
Common Portland cement type 42.5, conforming to the Chinese standard GB 175-2007, machine-made sand with a fineness modulus of 2.6, tap water, Grade I Class F coal fly ash, and granulated blast furnace slag with strength grade S95 were used in this research. The natural coarse aggregate (NCA) was gravel with continuous grain size having diameters between 5 mm and 25 mm, conforming to the Chinese standard GB/T 14685-2011 [
The grading curves of the NCA and RCA.
Physical properties of RCA and NCA.
Coarse aggregate | Bulk density (kg/m3) | Apparent density (kg/m3) | Water absorption (%) | Crushing index (%) | Needle-like particle content (%) | Mud content (%) |
---|---|---|---|---|---|---|
Natural | 1464.27 | 2760.24 | 0.42 | 9.71 | 4.98 | 0.41 |
Recycled | 1252.98 | 2575.05 | 2.99 | 13.10 | 3.01 | 2.25 |
Mechanical properties of the steel bars.
Type | Nominal diameter (mm) | Yield strength (N/mm2) | Ultimate strength (N/mm2) | Elastic modulus (N/mm2) | Elongation (%) |
---|---|---|---|---|---|
HPB300 | 6 | 470.7 | 670.0 | 1.98 × 105 | 13.7 |
HRB400 | 12 | 487.3 | 627.3 | 1.99 × 105 | 18.6 |
HRB400 | 14 | 496.7 | 645.0 | 2.03 × 105 | 20.8 |
Because of its high water absorption rate, the used RCAs were presoaked in additional water before mixing. The water amount used to presoak the RCAs was calculated on the basis of the saturated surface-dry condition. The main differences between the eight groups were the RCA replacement percentage (0%, 33%, 66%, and 100%) and concrete strengths (C30 and C60). The ratio of the recycled to the total aggregates (by weight) is termed the RCA replacement percentage (
Mix proportions of concrete.
Specimen | Water/binder ratio | Unit weight (kg/m3) |
|
|
||||||
---|---|---|---|---|---|---|---|---|---|---|
Cement | Coal fly ash | Slag | Sand | Gravel | RCA | Water | ||||
RCB-0 | 0.52 | 227 | 75 | 75 | 910 | 910 | 0 | 195 | 36.1 | 3.18 × 104 |
RCB-33 | 0.52 | 227 | 75 | 75 | 910 | 610 | 300 | 195 | 36.4 | 3.05 × 104 |
RCB-66 | 0.52 | 227 | 75 | 75 | 910 | 310 | 600 | 195 | 37.4 | 3.05 × 104 |
RCB-100 | 0.52 | 227 | 75 | 75 | 910 | 0 | 910 | 195 | 36.6 | 2.38 × 104 |
HRCB-0 | 0.39 | 435 | 52 | 52 | 758 | 928 | 0 | 210 | 63.9 | 3.72 × 104 |
HRCB-33 | 0.39 | 435 | 52 | 52 | 758 | 623 | 305 | 210 | 57.1 | 3.30 × 104 |
HRCB-66 | 0.39 | 435 | 52 | 52 | 758 | 315 | 613 | 210 | 57.9 | 3.02 × 104 |
HRCB-100 | 0.39 | 435 | 52 | 52 | 758 | 0 | 928 | 210 | 56.6 | 2.96 × 104 |
Eight beams were tested in total. All the beams had a rectangular cross section of 200 mm width, 300 mm depth, and a total length of 3.3 m. They had the same structure, size, reinforcement, and corrosion ratio but different RCA replacement percentages (0%, 33%, 66%, and 100%) and concrete strengths (C30 and C60). All the beams were designed to fail in flexure, that is, they were reinforced with sufficient transversal reinforcement to prevent shear failure. Figure
Specimen size and reinforcement details (unit: mm).
In practical engineering, corrosion of the stirrups occurs prior to that of the longitudinal bars in the beam. The diameter and area of the stirrup is smaller than that of the longitudinal bar, and the corrosion of the stirrup is heavier than that of the longitudinal reinforcement. This affects the performance of the beam to a certain extent. In order to simulate the corrosion status of steel in beams, all the longitudinal bars, stirrups, and erection bars were bound as a reinforcing cage and all the steel cross points were welded to ensure that all the steel bars were corroded after the application of electricity, as shown in Figure
Processing of steel bar crossing points.
Under natural conditions, the corrosion of a steel bar in concrete is mainly caused by chemical reactions among the corrosive mediators, water, and oxygen, which is similar to the operating principle of a battery. As the progression of natural corrosion is very slow, using the natural corrosion method in tests is unrealistic. Therefore, in this study, the electrochemical method was adopted to obtain the corroded reinforced concrete beams in a short time. The advantage of this method is that the corrosion ratio can be calculated based on current intensity and corrosion time according to Faraday’s first law of electrolysis.
To enable the NaCl solution to fully penetrate the steel surface and damage its passivation film, the beams were soaked in 5% concentration NaCl solution in a stainless steel pool for seven days, during which time the solution was tested regularly to maintain a steady liquid level and solution concentration. Subsequently, the solution height was adjusted to one-half that of the specimens (to ensure sufficient oxygen) and then plugged into DC regulated power. The anode connected to the rebar was exposed 50 mm above the beam; the cathode was connected to the stainless steel tube in the solution, as shown in Figure
The accelerated corrosion device.
The corrosion current intensity was provided by DC-regulated power, current density was 0.01–0.02 mA/mm2 [
All beams were simply supported with a span length of 3.0 m and subjected to four-point bending test in the test frame. The shear span to depth ratio was kept constant for all beam specimens. At one end, the specimen support was fixed hinge support, whereas at the other end, a sliding hinge support was utilized. Concrete strain gauges were installed to measure the concrete’s strains, while beam deflections were measured by displacement meters. The layout of the test setup and measuring equipment is presented in Figure
(a) Layout of test setup and measuring equipment (unit: mm). (b) Loading test arrangement.
Before loading the specimens, preloading using 10 kN weight was conducted to enable measuring instruments to function and stabilize the relationship between deformation and load. Monotonic multistage loading was first applied, followed by unidirectional repetitive loading when the yield load reached 80% of the estimated value. The testing was load-controlled in the elastic stage, the increment of load was about one-tenth of the calculated ultimate load, and displacement control was used in the elastoplastic stage. The specimens were considered to have reached or exceeded the limit of their bearing capacity if any of the following phenomena occurred: (1) breaking of tensile reinforcement; (2) concrete crushing in the compressive zone; (3) the maximum deflection value of the midspan reached one-fiftieth of the calculation span (or 60 mm); or (4) the maximum vertical crack width reached a value of 2.00 mm.
The corrosion ratio of steel bars calculated using Faraday’s law had a certain error compared to the actual corrosion ratio because of influence factors such as stray current in the process of accelerating corrosion with electricity, and the final corrosion ratio was determined by weighing. In order to calculate the mass loss after rebar corrosion, the rebar specimens were weighed using an electronic scale with precision 1 mg and the measured gravity per length of the longitudinal bar was 1211 g/m.
To measure the precise mass corrosion ratio, all beams were broken apart and longitudinal bars near the specimen beams support were selected. Subsequently, in accordance with the method in Testing Code of Concrete for Port and Waterway Engineering (JTJ 270-98), the corrosion products on the surface of these rebars were cleaned using dilute hydrochloric acid and then neutralized with alkali. The specimens were then cleaned with water, weighed, and their length was measured. The ratio of the weight of the lost rebars to the initial weight is the actual corrosion ratio (precision of 0.01%), which is calculated using (
At the beginning of electricity application, a large number of small bubbles escaped from the stainless steel tube. Subsequently, a layer of bronzing bubbles existed on the solution surface. The solution gradually became dark green and later reddish brown with increased electricity application time. Several tiny cracks and rust also appeared on the corrosive rebar. By the end of the electricity application period, brown nodules very visible at the ends and bottom of the beam, with more black-brown nodules formed on those sites with relatively more corrosion. Corrosive cracks kept widening and expanding, and there was visible cracking, mainly caused by the corroded expansion at the bottom of the longitudinal rebar. Some concrete also fell off in some parts. The corrosion process is shown in Figure
(a) Rust on the specimen. (b) Rust on the stainless steel tube. (c) The specimen after accelerated corrosion.
After accelerated corrosion, the specimens were cleaned and dried, the width of the corrosive cracks measured, and their positions recorded. The corrosive cracks are plotted in Figure
Corrosive cracks on the eight specimens after electricity application. (a) RCB-0, (b) RCB-33, (c) RCB-66, (d) RCB-100, (e) HRCB-0, (f) HRCB-33, (g) HRCB-66, and (h) HRCB-100.
At the initial stage, very little visible effect occurred on the concrete surface, the load-deflection curve was linear, and the concrete’s strain and deflection were both very small. After the initial vertical crack was observed, flexural cracking propagated to the midspan close to the loading points. Subsequently, new flexural cracks appeared on the pure bending area and near the corrosion cracks, and their width was extending a certain distance along the beam height. After the midspan deflection suddenly increased with concrete cracking, the main stress crack kept widening—the load and midspan deflection curve are close to the horizontal line, that is, the reinforcement yielded and deformation increased rapidly, followed by the maximum vertical crack width reaching 2.00 mm. Overall results indicate that the crack propagation, and failure mode of corroded reinforced RAC beams are similar, regardless of the replacement percentage with RCA and concrete strengths. Similar failure behavior was observed for all the specimens in this research. They underwent four stress process steps: elastic stage with corrosive cracks and without stress cracks, elastic-plastic stage with both corrosive cracks and stress cracks, yield stage of longitudinal bar, and failure stage after yield of reinforcement.
The summarized beam testing results are shown in Table
Results of the loading test.
Specimen |
|
|
|
|
|
|
---|---|---|---|---|---|---|
RCB-0 | 29.7 | 132.2 | 138.2 | 14.94 | 51.24 | 3.43 |
RCB-33 | 30.2 | 125.6 | 140.2 | 14.04 | 49.55 | 3.53 |
RCB-66 | 30.3 | 126.3 | 138.2 | 13.29 | 51.13 | 3.85 |
RCB-100 | 20.5 | 131.4 | 131.3 | 14.32 | 30.03 | 2.10 |
HRCB-0 | 30.2 | 123.9 | 137.4 | 13.89 | 50.23 | 3.62 |
HRCB-33 | 30.3 | 123.6 | 135.1 | 13.95 | 50.91 | 3.65 |
HRCB-66 | 20.7 | 126.6 | 133.4 | 15.50 | 40.19 | 2.60 |
HRCB-100 | 21.0 | 123.9 | 128.3 | 15.26 | 30.18 | 1.98 |
When the concrete is middle strength, the cracking load of RCB-33 and RCB-66 are comparable with RCB-0, whereas the cracking load of RCB-100 decreases. When the concrete is high strength, the cracking load for HRCB-33 and HRCB-0 is virtually the same, and HRCB-66 and HRCB-100 decrease but are relatively close. The ultimate loads of RCB-33 and RCB-66 are comparable with RCB-0, whereas the ultimate load of RCB-100 is 4.99% lower than that of RCB-0. The decrease in the ultimate load of middle-strength RAC declines by 1.18% on average compared with RCB-0. The ultimate loads of HRCB-33, HRCB-66, and HRCB-100 are 1.67%, 2.91%, and 6.62% lower than that of HRCB-0, respectively. The decrease in the ultimate load of high-strength RAC declines by 3.74% on average compared with HRCB-0. This shows that RCA replacement percentage and concrete strength grade have little effect on ultimate load.
When the specimens failed, the midspan ultimate deflection of RCB-33 and RCB-66 was close to that of RCB-0, and the deflection of RCB-100 abruptly decreased. The deflection between HRCB-33 and HRCB-0 was consistent. However, the deflection of HRCB-66 and HRCB-100 decreased with increased RCA replacement percentage.
The displacement ductility ratio
After electric corrosion, the specimens became more likely to transform from appropriate reinforcement beam failure to rare-reinforced beam failure, as all specimen failures were only embodied in the yield of reinforcement without crushing of compressive concrete. All specimens were believed to be failed as soon as the maximum vertical crack width reached 2.00 mm. The crack patterns of beams at failure are shown in Figure
Crack patterns of beams at failure. (a) RCB-0, (b) RCB-33, (c) RCB-66, (d) RCB-100, (e) HRCB-0, (f) HRCB-33, (g) HRCB-66, and (h) HRCB-100.
From the figure, it can be seen that when the concrete was middle strength, and many stress cracks with small spacing appeared on the pure bending section of the specimens. In contrast, when the concrete was high strength, fewer stress cracks with large spacing appeared on the pure bending section, and a few cracks also occurred on the bending shear section. This signifies that the higher the concrete strength is, the greater the brittleness. Thus, the concrete ductility was suppressed, and the quantity of the main cracks reduced. In addition, the crack width increased with load increase, and some concrete was damaged because of wide cracks before exerting their energy dissipation capacity.
Flat section assumption is the precondition of the bending component’s theoretical calculation in Chinese Code for Design of Concrete Structures (GB 50010—2010), which is an important assumption in the calculation of concrete theory. Thus, it is essential in the calculation of the bending bearing capacity of corroded reinforced RCA beams. The midspan concrete’s average strain distribution along the section height is shown in Figure
Concrete strain distribution of the eight specimens. (a) RCB-0, (b) RCB-33, (c) RCB-66, (d) RCB-100, (e) HRCB-0, (f) HRCB-33, (g) HRCB-66, and (h) HRCB-100.
The load-deflection curves of each beam, whose support displacements at both ends were modified, are shown in Figure
Load-deflection curves of the eight specimens. (a) RCB-0, (b) RCB-33, (c) RCB-66, (d) RCB-100, (e) HRCB-0, (f) HRCB-33, (g) HRCB-66, and (h) HRCB-100.
The load-deflection skeleton curves are shown in Figure
Skeleton curves of load deflection: (a) middle-strength concrete specimens, (b) high-strength concrete specimens, and (c) all specimens.
Unidirectional repetitive loading is similar to low-cycle reverse loading in terms of energy dissipation detection. According to the load-deflection skeleton curves shown in Figure
Experimental results of energy dissipation.
Specimen | Energy dissipation (kN·mm) | Relative energy dissipation |
---|---|---|
RCB-0 | 6008.03 | 1.00 |
RCB-33 | 5877.43 | 0.98 |
RCB-66 | 6044.27 | 1.01 |
RCB-100 | 3090.23 | 0.51 |
HRCB-0 | 5813.11 | 1.00 |
HRCB-33 | 5799.32 | 0.99 |
HRCB-66 | 4309.04 | 0.74 |
HRCB-100 | 2995.92 | 0.52 |
When the concrete is middle strength, the energy dissipation capacity among RCB-33, RCB-66, and RCB-0 is close, but RCB-100 obviously decreases, with a value of 49%. When the concrete is high strength, HRCB-33 and HRCB-0 have close energy dissipation capacity, and that of HRCB-66 and HRCB-100 decreases with the increase of RCA replacement percentage, with a value of 26% and 48%, respectively. The value of energy dissipation is associated with ultimate bearing capacity and ultimate deflection. In short, the effects of RCA replacement percentage on energy dissipation capacity vary with concrete strength. However, the energy dissipation capacity decreases significantly with a RCA replacement percentage of 100%, regardless of the concrete strengths.
The corrosion crack width, position, and length of each specimen were measured before loading, and the actual corrosion ratio and mechanical properties of the corroded longitudinal reinforcement were tested after loading. The results are shown in Table
Corrosion ratios and mechanical properties of tensile corroded steel bar.
Specimen | Maximum crack width (mm) | Actual corrosion ratio (%) | Theoretical corrosion ratio (%) |
|
|
Elongation (%) |
---|---|---|---|---|---|---|
RCB-0 | 1.00 | 5.23 | 5.00 | 493 | 598 | 10.41 |
RCB-33 | 1.12 | 5.26 | 5.00 | 488 | 590 | 10.12 |
RCB-66 | 1.36 | 5.33 | 5.00 | 463 | 579 | 7.63 |
RCB-100 | 1.56 | 5.45 | 5.00 | 452 | 584 | 9.44 |
HRCB-0 | 0.94 | 5.15 | 5.00 | 489 | 594 | 10.97 |
HRCB-33 | 1.08 | 5.27 | 5.00 | 495 | 595 | 11.05 |
HRCB-66 | 1.28 | 5.36 | 5.00 | 484 | 600 | 11.10 |
HRCB-100 | 1.52 | 5.40 | 5.00 | 475 | 590 | 11.13 |
From the table, we can make the following conclusions. (1) The maximum corrosion crack width increases with increased RCA replacement percentage and declines with increased concrete strength under constant RCA replacement percentage. This is because the porosity and water absorption of the RCAs are larger than those of NCA, which makes chlorine salt easily reach the rebar surface, causing the rebar to corrode faster. Further, the antipermeability of the RCAs decreases with increase in the replacement percentage and causes rebar corrosion in the concrete to form corrosion cracks. (2) The actual corrosion ratio of the longitudinal reinforcement is higher than that of the theoretical corrosion ratio and increases with the RCA replacement percentage as the dense high-strength concrete has greater resistance to chloride penetration. (3) The yield strength of longitudinal reinforcement declines slightly with increase in the RCA replacement percentage. This because RCA and NCA have inherent differences mainly on density and water absorbability, RCA is more vulnerable to chloride ion erosion and its resistance to chloride ion decreases with the increase of RCA replacement percentage [
The broken beams show that all the concrete touching the corrosion bars were dip-dyed by rust; the corrosion of the bars close to the protective layer was more serious than those far from the protective layer; stirrup corrosion was more serious than corrosion of the longitudinal bars; bottom rebar corrosion was more serious than corrosion of the bars in the middle; the corrosion of the longitudinal bars at the bottom was more serious than the corrosion of the erection bars, as shown in Figure
(a) The concrete touching the corrosion bars were dip-dyed by rust. (b, c) The corroded steel bars.
The ultimate bearing capacity of the test beams serves as the measured values of ultimate bearing capacity (
The effect of the low corrosion ratio on the ultimate bearing capacity of the beam is mainly manifested in the following three aspects: (1) the cross section of the longitudinal bar decreases; (2) the mechanical properties of the longitudinal bar are reduced; and (3) the bonding behavior of the steel bars and concrete is degraded. Therefore, from the above three points on the existing Chinese standard, in the calculation of the formula, the following amendments are needed: (1) according to the actual corrosion ratio of the longitudinal bar, calculate the area of the corroded reinforcement; (2) replace the measured yield strength of the reinforcement with that of the corroded reinforcement; and (3) according to the literature [
The characteristic value of the ultimate bearing capacity of each beam is shown in Table
Characteristic values of bearing capacity.
Specimen |
|
|
|
|
|
---|---|---|---|---|---|
RCB-0 | 69.1 | 64.6 | 1.07 | 64.6 | 1.07 |
RCB-33 | 70.1 | 64.1 | 1.09 | 59.8 | 1.17 |
RCB-66 | 69.1 | 61.2 | 1.13 | 53.1 | 1.30 |
RCB-100 | 65.7 | 59.6 | 1.10 | 47.7 | 1.37 |
HRCB-0 | 68.7 | 67.4 | 1.02 | 67.4 | 1.02 |
HRCB-33 | 67.6 | 67.5 | 1.00 | 63.1 | 1.07 |
HRCB-66 | 66.7 | 66.0 | 1.01 | 57.3 | 1.16 |
HRCB-100 | 64.2 | 64.7 | 0.99 | 51.8 | 1.24 |
From Table
It can be seen that the values of
Based on tests performed on material properties and on comparisons made in terms of flexural behavior of corroded reinforced RAC beams, the following conclusions have been drawn: During the corroded reinforced RAC beam cross-sectional loading process, they undergo four stages, elasticity, cracking, yield, and failure, regardless of RCA replacement percentage and concrete strengths. The concrete’s strain is in good agreement with the flat section assumption, and the influence of RCA replacement percentage and concrete strengths on it is negligible. The ultimate bearing capacity of middle-strength RAC and high-strength RAC declines by 1.18% and 3.74% on average compared with reference concrete, respectively. This shows that RCA replacement percentage and concrete strengths have little influence on ultimate bearing capacity. The computed value considering the influence of steel bar corrosion ratio and RCA replacement percentage on the ultimate bearing capacity of the corroded reinforced RAC beam is in good agreement with the measured value. The value of displacement ductility ratio for middle-strength RAC and high-strength RAC declines by 7.87% and 24.22% on average compared with reference concrete, respectively. This shows that RCA replacement percentage has little influence on the properties of medium-strength concrete but affects the properties of high-strength concrete significantly. According to the results of ductility and energy dissipation capacity, we can conclude that RCA replacement percentage of 100% should not be adopted in chlorine salt and other corrosive environments; the RCA replacement percentage of high-strength concrete should be lower than 30% and that of low and medium-strength concrete should be no more than 60%.
The authors declare that there are no conflicts of interest regarding the publication of this paper.
The authors would like to appreciate the funding from National Natural Science Foundation of China (no. 51438007).