Recycling of Macro-Synthetic Fiber-Reinforced Concrete and Properties of New Concretes with Recycled Aggregate and Recovered Fibers
Abstract
:1. Introduction
1.1. Background
1.2. Objective and Significance of the Research
2. Materials and Methods
2.1. Concept of the Study
2.2. Materials
2.3. Mix Design
2.4. Methods
- is the residual flexural tensile, MPa;
- Fj is the load corresponding to CMOD = CMODj, N;
- is the span length, mm;
- is the width of the specimen, mm;
- hsp is the distance between the tip of the notch and the top of the specimen, mm.
3. Results and Discussion
3.1. Distribution of RA and Fiber Recovery
3.2. Basic Concrete Properties
3.3. Axial Stress–Strain Behavior
3.4. The Residual Flexural Tensile Strength
4. Conclusions
- In terms of PPFRC recycling, the fiber content in the concrete being crushed does not affect the particle size distribution of the RA and the shape of the RF, only the fiber recovery rate. The percentage of recovered fiber increases with the fiber content of the original concrete.
- Concretes with 100% coarse RA can achieve the same compressive strength as the parent concrete, but with a lower modulus of elasticity by increasing the cement content and lowering the water–cement ratio. When the mixture design is the same, concrete with 100% recycled fiber has little effect on the compressive strength and modulus of elasticity when the fiber content is low compared to concrete with virgin fiber, while both properties are slightly reduced when the fiber content is high.
- The residual flexural tensile strength of concrete is decreased by approximately 50% when 100% of virgin fibers are replaced by RF. This is explained by the smaller average length of RF. However, concrete with 100% coarse RA has improved the residual flexural tensile strength compared to natural aggregate due to the recycled aggregate embedded fiber. The residual (flexural and compression) strength of concrete can increase when RA obtained from PPFRC recycling is used, due to the contribution of the fibers that remain embedded in the RA. This means that the RA obtained from PPFRC recycling can bring a higher added value to new concrete and should, therefore, be treated and stockpiled differently in CDW plants. Both RA and RF as recycled materials can be used in structural applications, such as buildings, by adjusting the mixture design. However, there are still knowledge gaps, such as the porosity of the RA and the influence of the distribution of the RF on the interfacial transition zone (ITZ) of the concrete, which are still worth investigating.
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
References
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Type | Fraction | Fines Content (%) | 24 h Water Absorption (%) | Oven-Dry Density (kg/m3) |
---|---|---|---|---|
Natural Aggregate | 0/4 mm | 8.1 | 1.56 | 2590 |
4/12 mm | 0.5 | 0.57 | 2690 | |
12/20 mm | 2.4 | 0.61 | 2680 | |
Recycled Aggregate (R3) | 4/12 mm | 6.1 | 6.64 | 2270 |
12/20 mm | 2.6 | 3.63 | 2440 | |
Recycled Aggregate (R9) | 4/12 mm | 5.2 | 7.04 | 2250 |
12/20 mm | 4.9 | 6.68 | 2260 |
Concrete | Cement (kg/m3) | weff1 (kg/m3) | wadd2 (kg/m3) | Plast. (%cem.) | NA (kg/m3) | RCA (kg/m3) | Fiber (kg/m3) | ||||
---|---|---|---|---|---|---|---|---|---|---|---|
0/4 mm | 4/12 mm | 12/20 mm | 4/12 mm | 12/20 mm | Virgin | Recovered | |||||
N-3 | 350 | 192.5 | 0.00 | 0.80 | 782.6 | 265.9 | 706.4 | 0.0 | 3.00 | ||
N-9 | 2.73 | 770.5 | 261.8 | 695.5 | 9.00 | ||||||
RF-3 | 0.80 | 782.6 | 265.9 | 706.4 | 3.00 | ||||||
RF-9 | 2.73 | 770.5 | 261.8 | 695.5 | 9.00 | ||||||
R3-3 | 385 | 36.48 | 1.26 | 638.6 | 0.0 | 478.9 | 478.9 | 3.00 | |||
R3-9 | 2.53 | 632.1 | 474.1 | 474.1 | 9.00 | ||||||
R9-3 | 29.27 | 1.49 | 638.6 | 478.9 | 478.9 | 3.00 | |||||
R9-9 | 3.00 | 632.1 | 474.1 | 474.1 | 9.00 |
Parent Concrete | RA Distribution (%) | RF Distribution (%) | Fiber Recovery Ratio (%) | ||||
---|---|---|---|---|---|---|---|
4/12 mm | 12/20 mm | Others | Long | Short | Bent | ||
N-3 | 33.9 | 23.3 | 42.8 | 37.9 | 19.0 | 43.1 | 39.8 |
N-9 | 34.1 | 28.1 | 37.8 | 32.9 | 29.6 | 37.5 | 53.1 |
Concrete | Slump (mm) | fc (MPa) | Ec (MPa) |
---|---|---|---|
N-3 | 134 | 31.2 (1.8%) | 28,449 (2.4%) |
N-9 | 107 | 34.4 (0.3%) | 31,253 (5.7%) |
RF-3 | 135 | 29.2 (1.2%) | 28,983 (5.0%) |
RF-9 | 115 | 28.2 (11.7%) | 27,479 (2.1%) |
R3-3 | 143 | 30.9 (4.8%) | 19,627 (11.5%) |
R3-9 | 120 | 28.3 (0.7%) | 18,147 (5.0%) |
R9-3 | 102 | 27.1 (2.7%) | 21,772 (8.4%) |
R9-9 | 114 | 30.4 (5.5%) | 21,270 (12.6%) |
Concrete | fLOP | fR1 | fR2 | fR3 | fR4 |
---|---|---|---|---|---|
N-3 | 4.00 (5.1%) | 0.97 (19.0%) | 1.06 (24.3%) | 1.12 (24.4%) | 1.13 (24.1%) |
N-9 | 3.78 (1.6%) | 2.89 (13.7%) | 3.54 (16.2%) | 3.75 (15.0%) | 3.80 (14.0%) |
RF-3 | 3.54 (4.9%) | 0.53 (34.2%) | 0.45 (44.5%) | 0.44 (40.0%) | 0.43 (35.1%) |
RF-9 | 3.15 (3.6%) | 1.56 (20.5%) | 1.81 (23.8%) | 1.87 (23.0%) | 1.93 (24.4%) |
R3-3 | 3.34 (14.0%) | 1.48 (53.3%) | 1.62 (53.1%) | 1.64 (47.3%) | 1.09 (70.4%) |
R3-9 | 3.23 (2.2%) | 2.89 (11.3%) | 3.62 (10.3%) | 3.87 (10.6%) | 3.79 (10.8%) |
R9-3 | 3.36 (–) | 1.18 (–) | 1.29 (–) | 1.31 (–) | 1.28 (–) |
R9-9 | 3.43 (–) | 3.20 (–) | 3.99 (–) | 4.03 (–) | 3.90 (–) |
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Liu, G.; Tošić, N.; de la Fuente, A. Recycling of Macro-Synthetic Fiber-Reinforced Concrete and Properties of New Concretes with Recycled Aggregate and Recovered Fibers. Appl. Sci. 2023, 13, 2029. https://doi.org/10.3390/app13042029
Liu G, Tošić N, de la Fuente A. Recycling of Macro-Synthetic Fiber-Reinforced Concrete and Properties of New Concretes with Recycled Aggregate and Recovered Fibers. Applied Sciences. 2023; 13(4):2029. https://doi.org/10.3390/app13042029
Chicago/Turabian StyleLiu, Guanzhi, Nikola Tošić, and Albert de la Fuente. 2023. "Recycling of Macro-Synthetic Fiber-Reinforced Concrete and Properties of New Concretes with Recycled Aggregate and Recovered Fibers" Applied Sciences 13, no. 4: 2029. https://doi.org/10.3390/app13042029
APA StyleLiu, G., Tošić, N., & de la Fuente, A. (2023). Recycling of Macro-Synthetic Fiber-Reinforced Concrete and Properties of New Concretes with Recycled Aggregate and Recovered Fibers. Applied Sciences, 13(4), 2029. https://doi.org/10.3390/app13042029