Analytical and Experimental Behaviour of GFRP-Reinforced Concrete Columns under Fire Loading
Abstract
:1. Introduction
2. Fire Resistance
Determination of Fire Resistance
3. Description of the Structural Model
3.1. Theoretical Model
3.2. Experimental Model
3.2.1. Full-Sided Exposed Elements (Columns)
3.2.2. Test Equipment
3.2.3. Test Procedure
4. Results and Discussion
4.1. Results
4.1.1. Oven
4.1.2. Columns
4.1.3. Theoretical Model
4.2. Discussion
- A temperature of 160 °C (close to the glassy temperature of the resin in the columns);
- A temperature of 120 °C (the temperature at which the composite begins to lose its intrinsic properties under load, as indicated in the technical specifications of the resins);
5. Conclusions
- The experimental data from column 1 suggest that fibres of GFRP rebars experience a critical temperature of around 350 °C. Although glass fibres can resist high temperatures, they do not do their job perfectly in concrete elements without a binding material (resin), which begins to degrade upon reaching the glass transition temperature, dissolving and leaving only the fibres, devoid of resistance.
- For the other columns, the experiments were carefully and successfully conducted to determine the variations of tensile strength. A minimal loss of resistance appears in the rebars after a fire, which is within the range accepted by the safety factors of materials, and in no case has it reached more than a 5% loss of the characteristic value. Because of this, GFRP rebars are valid as internal reinforcement for reinforced concrete for load-bearing construction.
- The effect of the cover thickness is much more significant at temperatures below 300 °C.
- It can be seen that the concrete cover’s thickening has a significant effect on the fire resistance of the columns. Higher concrete cover thickness delays the temperature transmission to the reinforcement, enhancing fire resistance. It is possible to recommend the following coatings to achieve a specific fire resistance:
- For 90 min of exposure (FR 90), 80 mm is recommended as the optimum concrete cover.
- For 60 min of exposure (FR 60), we advise a 50 mm overlap.
- For 30 min of exposure (FR 30), the recommended coating is 30 mm.
- Based on these limited studies, for 120 min (FR 120), which is the exposure time considered valid for load-bearing structural elements such as columns, the GFRP rebar coating should be 120 mm.
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Material | fc (MPa) | Ec (GPa) | ffk (MPa) | Ef (GPa) |
---|---|---|---|---|
Concrete | 35 | 29 | ||
GFRP | 620.9 | 42.9 |
Column No | External Dimensions (mm) | Concrete Coating (mm) |
---|---|---|
1 | 350 × 350 | 20 |
2 | 390 × 390 | 40 |
3 | 410 × 410 | 60 |
4 | 450 × 450 | 80 |
Level | Column 2 σmax (MPa) | Column 3 σmax (MPa) | Column 4 σmax (MPa) |
---|---|---|---|
A | 539 | 545 | 598 |
B | 565 | 583 | 611 |
Column | External Face Concrete (°C) | Internal Reinforcement (°C) |
---|---|---|
Steel-RC | 325 | 152 |
GFRP-RC | 265 | 92 |
Concrete Cover (mm) | Level | 120 °C (min) | 160 °C (min) | |
---|---|---|---|---|
Column 1 | 20 | A | 25 | 40 |
B | 27 | 40 | ||
Column 2 | 40 | A | 44 | 80 |
B | 58 | 90 | ||
Column 3 | 60 | A | 48 | 83 |
B | 56 | 95 | ||
Column 4 | 80 | A | 95 | Not reached after 95 min |
B | 95 | Not reached after 95 min |
Concrete Cover (mm) | Level | At 90 min (°C) | At 60 min (°C) | At 30 min (°C) | |
---|---|---|---|---|---|
Column 1 | 20 | A | 330 | 225 | 124 |
B | 328 | 239 | 128 | ||
Column 2 | 40 | A | 180 | 149 | 91 |
B | 163 | 122 | 81 | ||
Column 3 | 60 | A | 172 | 127 | 90 |
B | 133 | 121 | 53 | ||
Column 4 | 80 | A | 106 | 95 | 51 |
B | 109 | 91 | 33 |
Concrete Cover (mm) | Material | At 60 min (°C) | |
---|---|---|---|
Column 2 | 40 | GFRP | 135 |
Concrete | 230 | ||
Theoretical model | 50 | GFRP | 125 |
Concrete | 235 | ||
Column 3 | 60 | GFRP | 120 |
Concrete | 240 |
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Almerich-Chulia, A.; Martin-Concepcion, P.; Moreno-Puchalt, J.; Molines-Cano, J.M. Analytical and Experimental Behaviour of GFRP-Reinforced Concrete Columns under Fire Loading. J. Compos. Sci. 2024, 8, 187. https://doi.org/10.3390/jcs8050187
Almerich-Chulia A, Martin-Concepcion P, Moreno-Puchalt J, Molines-Cano JM. Analytical and Experimental Behaviour of GFRP-Reinforced Concrete Columns under Fire Loading. Journal of Composites Science. 2024; 8(5):187. https://doi.org/10.3390/jcs8050187
Chicago/Turabian StyleAlmerich-Chulia, Ana, Pedro Martin-Concepcion, Jesica Moreno-Puchalt, and Jose Miguel Molines-Cano. 2024. "Analytical and Experimental Behaviour of GFRP-Reinforced Concrete Columns under Fire Loading" Journal of Composites Science 8, no. 5: 187. https://doi.org/10.3390/jcs8050187
APA StyleAlmerich-Chulia, A., Martin-Concepcion, P., Moreno-Puchalt, J., & Molines-Cano, J. M. (2024). Analytical and Experimental Behaviour of GFRP-Reinforced Concrete Columns under Fire Loading. Journal of Composites Science, 8(5), 187. https://doi.org/10.3390/jcs8050187