Analysis of Factors Influencing the Modulus of Hot-Recycled Asphalt Mixture with High RAP
Abstract
:1. Introduction
2. Materials and Methods
2.1. Regenerant
2.2. RAP
2.2.1. Grading of RAP
2.2.2. Performance Evaluation of RAP
2.3. Mix Design of Hot-Recycled Asphalt Mixture
2.4. Experimental Groups
2.5. Laboratory Experiments
2.5.1. Dynamic Modulus
2.5.2. Three-Point Bending of the Small Beams
3. Results and Discussion
3.1. Effect of Regenerant Dosage on Modulus
3.1.1. Dynamic Modulus
- (1)
- The dynamic moduli of hot-recycled asphalt mixture with three dosages of regenerant followed the same trend, and the trend of the values was 0%, 10%, and 5% successively. Thus, increasing the amount of regenerant increased the viscosity of the recycled asphalt, but the dynamic modulus of the hot-recycled asphalt mixture first decreased and then increased with increasing proportions in the mixture.
- (2)
- The regenerant had little effect on the phase angle of the hot-recycled asphalt mixture, and there was some scatter in the curves of the phase angle. However, within the frequency range of the test (0.1–25 Hz), the phase angle of the hot-recycled asphalt mixture was slightly less for 5% than 10% regenerant, and the trend of the dynamic modulus was similar.
3.1.2. Bending Strength Modulus
3.2. The Effect of Curing Temperature on Modulus
3.2.1. Dynamic Modulus
- (1)
- With a regeneration time of four hours, the dynamic modulus of hot-recycled asphalt mixtures with 5% and 10% rejuvenator dosage was similar under different regeneration temperatures. The dynamic modulus was lower at 60 °C compared with 100 °C. At a regeneration temperature of 135 °C, the dynamic modulus of hot-recycled asphalt mixtures was the highest, approaching the value of asphalt mixture with no added rejuvenator. For hot-recycled asphalt mixtures with 10% rejuvenator dosage, the dynamic modulus at a regeneration temperature of 100 °C was slightly higher than at 135 °C.
- (2)
- When the dosage of the rejuvenator was 5%, the dynamic modulus value of the hot-recycled asphalt mixture at 135 °C for three hours was almost the same as the dynamic modulus value of the hot-recycled asphalt mixture at 100 °C for four hours. When the dosage of the rejuvenator was 10%, the dynamic modulus value of the hot-recycled asphalt mixture at 135 °C for three hours was similar to the dynamic modulus value of the hot-recycled asphalt mixture at 60 °C for four hours. Therefore, when the regeneration temperature varies, adjusting the regeneration time can achieve a similar modulus for the hot-recycled asphalt mixture.
- (3)
- The results of the dynamic modulus under the two rejuvenator dosages indicate that the larger the dosage of the rejuvenator, the more significant was the effect of the regeneration temperature on the dynamic modulus of the hot-recycled asphalt mixture.
3.2.2. Bending Strength Modulus
3.3. The Effect of Curing Time on Modulus
3.3.1. Dynamic Modulus
- (1)
- When the curing temperature was 135 °C, the dynamic modulus of the hot-recycled asphalt mixture with a 10% regenerant dosage decreased with curing for 4 h, 1 h, 3 h, and 2 h.
- (2)
- The recovery of the dynamic modulus recovery was generally consistent for hot-recycled asphalt mixture with 5% and 10% regenerant, but the dynamic modulus was higher for specimens cured for 2 h than other lengths of time.
- (3)
- According to the values of the dynamic modulus for two types of regenerant dosages, the larger the regenerant dosage, the more significant was the effect of curing time on the dynamic modulus of the hot-recycled asphalt mixture.
3.3.2. Bending Strength Modulus
3.4. Analysis of Factors Influencing the Modulus
3.4.1. Qualitative Analysis of Modulus Changes
- (1)
- The dynamic modulus and bending stiffness modulus data of the hot-recycled asphalt mixture showed that the dynamic modulus was indeed slightly lower for the 10% than the 5% dosage. Although there was no peak, it satisfied the trend of the modulus curve.
- (2)
- The dynamic modulus of the hot-recycled asphalt mixture with 10% regenerant was slightly larger than that of the control group without the addition of recycled agent, for a curing temperature of 100 °C. However, the dynamic modulus of the hot-recycled asphalt mixture with both types of regenerant dosages reached its minimum at a curing temperature of 60 °C and then increased with increasing curing temperature, which was basically consistent with the overall trend.
- (3)
- Although the dynamic modulus of the hot-recycled asphalt mixture with the 5% regenerant dosage reached its maximum value after 2 h of curing, its overall trend of change followed the basic trend. The dynamic modulus of the hot-recycled asphalt mixture with 10% regenerant first decreased and then increased, with a minimum value after 2 h of curing, which was consistent with the basic trend.
- (4)
- Comparing the minimum bending stiffness modulus of hot-recycled asphalt mixture with different regenerant dosages showed that for the recovery degree of low-temperature performance, the performance was slightly better for hot-recycled asphalt mixture with 5% than 10% regenerant, which was consistent with the changes in basic behavior.
- (5)
- When the curing time was 4 h, as the curing temperature increased, the bending stiffness modulus of the hot-recycled asphalt mixture showed an upwards trend. Although it deviated from the basic trend of first decreasing and then increasing, it also satisfied the latter half of the trend.
- (6)
- When the curing temperature was 135 °C for the hot-recycled asphalt mixture with 10% regenerant, the bending stiffness modulus was lower for the asphalt cured for 4 h than 3 h. However, when the curing time was within 3 h, the bending stiffness modulus of the hot-recycled asphalt mixture with two types of regenerant dosages first decreased and then increased, and the curing temperature was the lowest at 2 h. Therefore, the trend in the bending stiffness modulus within 3 h of curing was consistent with the basic trend, which first decreased and then increased.
3.4.2. Quantitative Analysis of Modulus Changes
4. Conclusions
- (1)
- In the design of hot-recycled asphalt mixture, mixtures with similar responses can be obtained by changing the dosage of regenerant, curing time, curing temperature, and other parameters.
- (2)
- For the dynamic modulus of the hot-recycled asphalt mixture, the influence of the curing time was the largest, followed by the regenerant dosage, and finally the curing temperature. For the bending stiffness modulus, the regenerant dosage had the greatest influence, followed by the curing time, and then the curing temperature.
- (3)
- The influence of each factor was greater for the bending stiffness modulus than the dynamic modulus of the hot-recycled asphalt mixture, and the modulus change rate of the former was approximately 1.5 times that of the latter.
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Testing Items | Indicators | Technical Requirement |
---|---|---|
Flash point (°C) | 228 | ≥220 |
Saturates content (%) | 14.6 | ≤30 |
Viscosity ratio before and after thin-film oven test (%) | 1.41 | ≤3 |
Mass change after thin-film oven test (%) | 1.4 | ≤4, ≥-4 |
Density 15 °C (g/cm3) | 0.935 | Measured Value |
Asphalt Type | Penetration (0.1 mm) | Softening Point (°C) | 15 °C Ductility (mm) | 60 °C Dynamic Viscosity (Pa·s) |
---|---|---|---|---|
Asphalt in RAP | 57.1 | 64.9 | 14.6 | 6014.5 |
90#Base asphalt | 80–100 | >45 | >100 | ≥140 |
Testing Items | Indicators | Technical Requirement |
---|---|---|
Moisture content (%) | 0.17 | ≤3 |
Maximum particle size (mm) | 26.50 | ≤26.5 |
Density (g/m3) | 2.74 | ≥2.45 |
Crushing value (%) | 17.30 | ≤30 |
Needle and flake particle content (%) | 8.90 | ≤15 |
Bulk-Specific Gravity (g/cm3) | Marshall Stability (kN) | Air Voids (%) | Flow Value (0.1 mm) | VMA (%) | VFA (%) |
---|---|---|---|---|---|
2.472 | 13.59 | 3.53 | 34.10 | 13.45 | 73.75 |
Number | Dosage of Regenerant (%) | Curing Condition | Number | Dosage of Regenerant (%) | Curing Condition |
---|---|---|---|---|---|
1-1 | 10 | Room temperature storage | 2-1 | 5 | Room temperature storage |
1-2 | 10 | 60 °C, 4 h | 2-2 | 5 | 60 °C, 4 h |
1-3 | 10 | 100 °C, 4 h | 2-3 | 5 | 100 °C, 4 h |
1-4 | 10 | 135 °C, 1 h | 2-4 | 5 | 135 °C, 1 h |
1-5 | 10 | 135 °C, 2 h | 2-5 | 5 | 135 °C, 2 h |
1-6 | 10 | 135 °C, 3 h | 2-6 | 5 | 135 °C, 3 h |
1-7 | 10 | 135 °C, 4 h | 2-7 | 5 | 135 °C, 4 h |
Curing Condition | 60 °C 4 h | 100 °C 4 h | 135 °C 4 h | 135 °C 3 h | 135 °C 2 h | 135 °C 1 h | |
---|---|---|---|---|---|---|---|
Regenerant Dosage | |||||||
5% | 0.31940 | 0.24357 | 0.01269 | 0.27069 | 0.37109 | 0.18280 | |
10% | 0.68369 | 0.24881 | 0.01346 | 0.51502 | 0.60846 | 0.44191 |
Curing Condition | 60 °C 4 h | 100 °C 4 h | 135 °C 4 h | 135 °C 3 h | 135 °C 2 h | 135 °C 1 h | |
---|---|---|---|---|---|---|---|
Regenerant Dosage | |||||||
5% | 0.44643 | 0.35714 | 0.16071 | 0.25029 | 0.41071 | 0.23214 | |
10% | 0.39286 | 0.28571 | 0.17857 | 0.12586 | 0.30357 | 0.33929 |
Modulus | Grey Correlation Coefficient | ||
---|---|---|---|
Regenerant Dosage | Curing Temperature | Curing Time | |
Dynamic modulus | 0.6898 | 0.5747 | 0.7213 |
Bending stiffness modulus | 0.6767 | 0.5927 | 0.6525 |
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Chen, Z.; Liu, B.; Feng, D.; Li, G. Analysis of Factors Influencing the Modulus of Hot-Recycled Asphalt Mixture with High RAP. Materials 2023, 16, 5280. https://doi.org/10.3390/ma16155280
Chen Z, Liu B, Feng D, Li G. Analysis of Factors Influencing the Modulus of Hot-Recycled Asphalt Mixture with High RAP. Materials. 2023; 16(15):5280. https://doi.org/10.3390/ma16155280
Chicago/Turabian StyleChen, Zining, Boying Liu, Decheng Feng, and Gang Li. 2023. "Analysis of Factors Influencing the Modulus of Hot-Recycled Asphalt Mixture with High RAP" Materials 16, no. 15: 5280. https://doi.org/10.3390/ma16155280
APA StyleChen, Z., Liu, B., Feng, D., & Li, G. (2023). Analysis of Factors Influencing the Modulus of Hot-Recycled Asphalt Mixture with High RAP. Materials, 16(15), 5280. https://doi.org/10.3390/ma16155280