Influence of Filler Type and Rheological Properties of Asphalt Mastic on the Asphalt Mastic–Aggregate Interaction
Abstract
:1. Introduction
2. Materials and Experimental
2.1. Materials
2.1.1. Bitumen
2.1.2. Filler
2.1.3. Aggregates
2.2. Preparation of the Specimens
2.2.1. Design of Asphalt Mastics
2.2.2. Design of the Asphalt Mastic–Aggregate Interface Specimens
2.3. Experimental Tests
2.3.1. Rheological Testing of Asphalt Mastics
- A dynamic shear rheometer (DSR) was employed in this study to evaluate the rheological properties of the asphalt mastics, focusing on the influence of fillers. In this test, mastic specimens with a 2 mm thickness were prepared and sandwiched between two flat plates with a diameter of 8 mm. One of the two plates was fixed and the other one was oscillated back and forth around the central axis at a certain angular velocity. The mastic specimens were tested at a temperature interval of 10 °C in the range of 30–60 °C and the scanning rate was 10 rad/s. According to the curves, the complex shear modulus G*, phase angle δ, and rutting factor (G*/sin δ) of the asphalt mastics at different temperatures were obtained. The results were employed to evaluate high-temperature performance of the asphalt mastics at moderate temperatures;
- The bending-beam rheometer (BBR) test was employed to characterize the low-temperature cracking resistance of the asphalt mastics. In this research, the BBR test was performed at −6 °C, −12 °C, and −18 °C. During testing, a constant load of 980 ± 50 mN was added in the middle of the mastic beam for 240 s. The deflection was automatically recorded in order to calculate the creep stiffness (S) and m-value (m). In order to resist thermal cracking at low temperatures, the creep stiffness (S) and the m-value must meet certain requirements.
2.3.2. Bond Strength Testing of the Asphalt Mastic–Aggregate Interface
2.3.3. Water Absorption of Asphalt Mastics
2.3.4. Water Attack Testing of the Asphalt Mastic–Aggregate Interface
3. Results and Discussion
3.1. Physical Features of Three Types of Filler
3.2. Rheological Properties of Asphalt Mastics at High Temperature
3.3. Rheological Properties of Asphalt Mastics at Low Temperature
3.4. Water Diffusion of Asphalt Mastics
3.5. Bond Strength of the Asphalt Mastic–Aggregate Interface
3.5.1. Influence of Temperature
3.5.2. Influence of Water Immersion without Pressure
3.5.3. Influence of Water Pressure
4. Conclusions
- The mineral filler type influenced the complex modulus and low-temperature performance index of the asphalt mastic, and the difference in pore volume and specific surface area changed the content of the structural asphalt components in the asphalt mastics, thereby affecting the phase angle. The specific surface area of the basalt filler was the largest, resulting in a high content of structural asphalt components, and its mastic had a relatively higher stiffness modulus at −18 °C and −12 °C. The chemical composition of the filler was the primary factor in determining rheological behavior and the morphology was the secondary factor in influencing the properties of asphalt mastics;
- When exposed to the water immersion, the moisture absorption rate of the basalt mastic was the highest, followed by the limestone and granite mastics, and the granite mastic had the lowest diffusion coefficient. This may be related to the pore features of the basalt filler, which had a high pore volume and surface area;
- The alkaline limestone aggregate exhibited strong initial adhesion with bitumen and the acid granite aggregate exhibited weak adhesion. When the complex modulus of asphalt mastic was high and its phase angle was low, it resulted in a good initial bonding behavior with aggregate in the dry state. However, this does not indicate that such an interface between alkaline limestone aggregate and asphalt mastic exhibits good durability, e.g., against water attack;
- Static and pressured water immersion conditions can accelerate the deterioration process of asphalt mastic–aggregate interfaces. For the three asphalt mastics, when the complex modulus of the asphalt mastic was low and its phase angle was high, the durability of asphalt mixtures subjected to static and pressured water immersion conditions improved. The asphalt mastic with the acid granite filler initially exhibited relatively weak adhesion in the asphalt mastic, but it showed good water attack resistance between the asphalt mastic and coarse aggregate;
- The deterioration mechanism of the interfacial bond strength of the asphalt mastic–aggregate interface under static water immersion was different from pressured water immersion. It was found that the water stability of the asphalt mastic–aggregate interface was strongly related to the properties of the aggregates and fillers and the diffusion behavior of the asphalt mastics, which influenced the rheological properties of the asphalt mastics.
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Items | Results | Unit | Requirement |
---|---|---|---|
Needle penetration (25 °C) | 68.3 | 0.1 mm | 60–80 |
Ductility (10 °C) | 40.1 | cm | no less than 25 |
Ductility (15 °C) | >150 | cm | no less than 100 |
Softening point | 48.2 | °C | no less than 45 |
Viscosity (135 °C) | 0.450 | Pa·s | - |
Density (15 °C) | 1.035 | g/cm3 | - |
Solubility | 99.6 | % | no less than 99.5 |
Property | LP | BP | GP |
Density/g/cm3 | 2.67 | 2.87 | 2.69 |
Items | LP | BP | GP |
---|---|---|---|
D10 | 2.75 | 3.27 | 3.89 |
D50 | 13.08 | 26.17 | 26.16 |
D90 | 52.33 | 62.33 | 62.23 |
Oxide | Filler Type | ||
---|---|---|---|
LP | BP | GP | |
CaO | 82.828 | 9.879 | 2.877 |
SiO2 | 5.843 | 45.812 | 63.87 |
Al2O3 | 4.15 | 18.552 | 16.854 |
Fe2O3 | 0.573 | 11.656 | 3.116 |
MgO | 4.786 | 5.954 | 0.692 |
K2O | 0.351 | 1.893 | 5.252 |
Na2O | / | 2.581 | 6.023 |
Other | 1.469 | 3.673 | 1.316 |
Properties | Limestone | Basalt | Granite | Requirement |
---|---|---|---|---|
Density/g/cm3 | 2.816 | 3.111 | 3.070 | no less than 2.6 |
Crushing value/% | 23.1 | 10.2 | 19.8 | no less than 26 |
Abrasion value/% | 20.2 | 16.6 | 14.3 | no less than 28 |
Adhesion grade | 5 | 5 | 3 | - |
Type of Interface | Name |
---|---|
Limestone mastic–Limestone | LM–L |
Limestone mastic–Basalt | LM–B |
Limestone mastic–Granite | LM–G |
Basalt mastic–Limestone | BM–L |
Basalt mastic–Basalt | BM–B |
Basalt mastic–Granite | BM–G |
Granite mastic–Limestone | GM–L |
Granite mastic–Basalt | GM–B |
Granite mastic–Granite | GM–G |
Pore Features | LP | BP | GP |
---|---|---|---|
Pore volume/cm3/g | 0.007 | 0.034 | 0.009 |
Average pore size/nm | 3.059 | 3.810 | 3.819 |
Surface area/m2/g | 1.899 | 9.008 | 3.42 |
Type of Mastic | Condition | D/(cm2/s) | R2 |
---|---|---|---|
LP mastic | Water Immersion | 1.054 × 10−10 | 0.8396 |
BP mastic | 1.078 × 10−10 | 0.8912 | |
GP mastic | 0.938 × 10−10 | 0.8725 |
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E, G.; Zhang, J.; Shen, Q.; Ji, P.; Wang, J.; Xiao, Y. Influence of Filler Type and Rheological Properties of Asphalt Mastic on the Asphalt Mastic–Aggregate Interaction. Materials 2023, 16, 574. https://doi.org/10.3390/ma16020574
E G, Zhang J, Shen Q, Ji P, Wang J, Xiao Y. Influence of Filler Type and Rheological Properties of Asphalt Mastic on the Asphalt Mastic–Aggregate Interaction. Materials. 2023; 16(2):574. https://doi.org/10.3390/ma16020574
Chicago/Turabian StyleE, Guangxun, Jizhe Zhang, Quanjun Shen, Ping Ji, Jing Wang, and Yushuai Xiao. 2023. "Influence of Filler Type and Rheological Properties of Asphalt Mastic on the Asphalt Mastic–Aggregate Interaction" Materials 16, no. 2: 574. https://doi.org/10.3390/ma16020574
APA StyleE, G., Zhang, J., Shen, Q., Ji, P., Wang, J., & Xiao, Y. (2023). Influence of Filler Type and Rheological Properties of Asphalt Mastic on the Asphalt Mastic–Aggregate Interaction. Materials, 16(2), 574. https://doi.org/10.3390/ma16020574