Next Article in Journal
Model-Based Roentgen Stereophotogrammetric Analysis to Monitor the Head–Taper Junction in Total Hip Arthroplasty in Vivo—And They Do Move
Next Article in Special Issue
The Impact of Interphase Precipitation on the Mechanical Behavior of Fire-Resistant Steels at an Elevated Temperature
Previous Article in Journal
Minimization of the Influence of Shear-Induced Particle Migration in Determining the Rheological Characteristics of Self-Compacting Mortars and Concretes
Previous Article in Special Issue
Effect of Elevated Temperature on Compressive Strength and Physical Properties of Neem Seed Husk Ash Concrete
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Materials
Volume 13
Issue 7
10.3390/ma13071541
materials-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Study on Low-Temperature Cracking Performance of Asphalt under Heat and Light Together Conditions

by
Limin Li
1,*,
Zhaoyang Guo
2,
Longfei Ran
3 and
Jiewen Zhang
3
1
School of Civil and Environmental Engineering, Hunan University of Science and Engineering, Yongzhou 425199, China
2
Inner Mongolia Communications Construction Engineering Quality Supervision Bureau, Hohhot 010050, China
3
School of Civil Engineering, Chongqing Jiaotong University, Chongqing 400074, China
*
Author to whom correspondence should be addressed.
Materials 2020, 13(7), 1541; https://doi.org/10.3390/ma13071541
Submission received: 24 February 2020 / Revised: 23 March 2020 / Accepted: 25 March 2020 / Published: 27 March 2020
(This article belongs to the Special Issue Sustainability in Construction and Building Materials)
Browse Figures
Versions Notes

Abstract

:
The low-temperature cracking performance of asphalt is considered one of the main deteriorations in asphalt pavements. However, there have been few studies on the low-temperature cracking performance of asphalt under heat and light together. Hence, the ductility test, bending beam rheometer (BBR) test, and asphalt composition analysis test are combined to investigate the low-temperature cracking performance under heat and light together based on the climatic conditions of China. The styrene–butadiene–styrene block copolymer (SBS)-modified asphalt binders were prepared with different modifier types and base asphalt in this research. The results show that the low-temperature cracking resistance of asphalt reduces under heat and light together. It is obviously reduced at the early stage, and it becomes worse with the increase of the aging time, temperature, and ultraviolet (UV) intensity. The asphalt composition has a significant impact on its low-temperature cracking performance, and the SBS modifier can improve the low-temperature cracking resistance of asphalt. The rational selection of base asphalt and modifier can improve the low-temperature cracking performance of asphalt. Under heat and light together, whether base asphalt or modified asphalt, the change trends of their ductility and component content are similar. Therefore, to improve the anti-cracking ability of the asphalt pavement, it is suggested to use the ductility of asphalt aged by heat and light together for 15 days as the evaluation index of the low-temperature cracking performance of asphalt, and asphalt should be selected according to the temperature and UV intensity of the asphalt pavement use area.

1. Introduction

1.1. Background

Asphalt pavement cracking will cause the surface water to run into the pavement, which will cause many issues, such as loose, potholes, and stripping. Water into the pavement will also soften the base course and the subgrade, which will cause causes different issues, such as steps, slurry pumping, and mesh cracking [1]. Cracking will accelerate the asphalt pavement damage as well as decreasing its service life [2,3]. To solve the cracking failure of asphalt pavement, the researchers conducted much work on the cracking of asphalt pavement and asphalt mixture. Mao [4] studied the crack initiation mechanism and propagation behavior of asphalt pavements, and the results showed that the mechanism for crack propagation was primarily tensile. Yan [5] investigated the cracking mechanism and prevention measures of top–down cracks on a flexible base asphalt pavement in a seasonal frozen area and found that the traffic load, environmental factors, and asphalt aging were the major reasons for top–down cracking. Research on the causes, effects, and cures of top–down cracking in asphalt pavement has been conducted by Donna et al. [6], and the results showed that the mixture with higher asphalt content would not be as prone to segregate. Wang [7] analyzed the crack problem of the asphalt pavement under UV light aging and claimed that asphalt pavement was more prone to cracks because of the effect of UV. Ramos et al. [8] reviewed the methods to measure the fatigue damage resistance of asphalt binders and put forward their suggested method. Wu et al. [9] evaluated the aging effect of UV radiation on the asphalt mixture and found that UV radiation significantly affected the asphalt semi-circular bending strength of asphalt concrete, it decreased the −10 °C bending strength of asphalt concrete, and the longer the exposure duration was, the more obvious the aging effect. Behnia et al. [10] reviewed the approach to evaluating the low-temperature cracking of asphalt and found that acoustic emission could assess the low-temperature cracking performance of asphalt. Although lots of investigations have been performed for the cracking of asphalt pavement and asphalt mixture, research rarely focuses on the effect of heat and light together.
On the other hand, lots of investigations have been conducted for the low-temperature performance of asphalt materials. The low-temperature performance and evaluation method of asphalt were implemented by several researchers [11,12,13,14,15], although they didn’t consider the influence of light and heat together. Zhou et al. [16] studied styrene–butadiene–styrene (SBS)-modified asphalts’ anti-cracking characteristics by using the rolling thin film oven (RTFO) and the Pressure Aging Vessel (PAV) residue based on Strategic Highway Research Program (SHRP) methods. It was shown that correlation was very good among the complex shear modulus, phase angle, fatigue cracking factor, creep stiffness, m value, and temperature in the range of wider temperature. The cracking characteristics of three modified and nine unmodified asphalt binders aged by different testing methodologies i.e., an UV route and a thermal route with changing exposition time by Patrícia et al. [17], and it was found that the critical block-cracking zone could be reached by the two routes, being the oxidative effect that happens in the field more evident in the UV radiation route. The carbonyl index was very sensitive to UV aging and presented in general larger values than the other aging strategies. Zhang et al. investigated the effect of long-term laboratory aging on the rheological properties and cracking resistance of polymer-modified asphalt binders at intermediate and low-temperature ranges and analyzed different evaluation indexes [18]. Glotova et al. [19] researched the effect of UV aging on an asphalt binder by testing the composition contents, structures, and the chemical properties of asphalt binder before and after aging, and the results showed that the type of light irradiation had a close relationship with the photo-oxidation aging speed, and UV radiation had obvious degeneration effects on these properties. The aging effect of three types of aging methods—namely UV radiation, pressure aging vessel (PAV), and thin film oven test (TFOT) was investigated by Zhang et al. [20], and they found that PAV aging and UV aging have more obvious effects on the degradation of styrene–butadiene–styrene (SBS) polymer. The results showed that the studied binders tended to be more viscous at relatively low loading frequencies and harder after aging, and the ability to relax internal stress declined. The UV light plays a great role in the photo-oxidation of bitumen and makes the surface layer of asphalt pavement stiffer and brittle [21,22,23]. However, the effect on the cracking resistance of asphalt heat and light together has been rarely performed to date.
In fact, the low-temperature cracking resistance of asphalt has a vital influence on the anti-cracking performance of asphalt pavement [24,25,26]. Meanwhile, due to asphalt’s temperature sensitivity, light and heat affect the crack resistance of asphalt during the asphalt pavement construction and service life [27]. The PAV test and the RTFOT (Rotary thin film oven test) are commonly used in the world to simulate the long-term aging behavior and short-term thermo-oxidative aging of bitumen [21,28]. However, due to ignoring the effect of UV radiation, the correlation between actual pavement aging and PAV simulation aging is not significant. At present, understanding of the cracking performance of asphalt under heat and light together is very limited. Hence, to solve the problem of asphalt pavement cracking, it is necessary to investigate systematically the low-temperature cracking performance of asphalt under heat and light together based on the environmental conditions of asphalt pavement.

1.2. Objectives

The main objective of the paper is to assess the effect of heat and light together on the low-temperature behavior of asphalt mixtures expressed under the climatic conditions of China in terms of the ductility curves (ductility test), the parameters of the bending beam rheometer (BBR) test, and the compositions (asphalt composition analysis test) of the asphalt aged under heat and light together.

2. Materials

The SBS modifiers used in the research are the 501s branched and the 4402 linear modifier produced by Dongguan Yuetai New Material Co., Ltd., Guangdong, China, and their characteristic properties are illustrated in Table 1. Zhonghai AH-70 (ZH-70) asphalt and South Korea AH-70 (SK-70) asphalt were employed as the base asphalt sample, and their characteristic properties are listed in Table 2. Based on the existing research results [29,30] and economy, the dosage of SBS modifiers of modified asphalt was 5%. The modified asphalts were prepared using an FM300 High Shear Dispersing Emulsifier (FLUKO, Shanghai, China). Prior to shearing with the dispersing emulsifier, the base asphalt was preheated to 170–180 °C in a small container. Then, according to the required dose, the 501s branched or 4402 linear modifier was gradually added to the base asphalt. Meanwhile, the mix was heated and maintained at 175–180 °C, and it was melted and mixed for 30 minutes. Afterward, the mix was stirred with a high-shear mixer for 40–60 min with a shearing rate of 3000–5000 r/min at 175–180 °C. At last, the mix was put into the oven for 2 h at 175 °C. The characteristic properties of four kinds of modified asphalt for the test are given in Table 3.
The aging confronting asphalt during asphalt construction was simulated by using short-term aging addressed by RTFO (85 min, 163 °C and air flow at 4 L/min) according to ASTM D2872 [31]. The long-term aging confronting asphalt during the use of asphalt pavement was simulated by using PAV aging (air pressure at 2.1 MPa). The long-term aging of asphalt under heat and light together was done using a RG-80 asphalt aging test chamber manufactured independently, as shown in Figure 1. Considering the maximum ground temperature of 65 to 75 °C in most areas of China and the strong heat absorption ability of asphalt pavement, the maximum temperature of the aging test was set to 70 °C [32]. Considering the aging of asphalt pavement of sunlight caused by the wavelength range of 260–410 nm UV radiation [23,33], the high-pressure mercury lamp with a radiation spectrum ranging from 250 to 440 nm was used as the light source of the RG-80 asphalt aging test chamber. The UV intensity was controlled by the power, quantity, and voltage of the high-pressure mercury lamp, and it was measured by the UV365 UV radiometer (Beijing Normal University Photoelectric instrument Company, Beijing, China). Based on the previous study, the results by Zhang and Ran [32,33], the maximum UV intensity of 40 W/m2 and the longest time of 15 days were adopted for the aging test. To meet the requirement of UV light aging, the melted asphalt for the aging test was put into a flat bottom disk with an inner diameter of 140 mm and a height of 9.5 mm, as shown in Figure 2, and the asphalt weight of the flat bottom disk was 30 g.

3. Low-Temperature Cracking Performance of Asphalt

3.1. Ductility Test

Ductility can affect the flexibility of asphalt, and it can evaluate the tensile deformation ability of the bituminous binder. The smaller the ductility value of asphalt is, the better its crack resistance. Firstly, the index tests of ZH-70 and SK-70 asphalt for the 15 °C ductility under different aging conditions were conducted in the research. The long-term aging of asphalt under heat and light together was conducted, and its aging temperature was set to 70 °C. Its aging time was 0 day, 5 days, 10 days, and 15 days, respectively, and its aging UV intensity was 0 W/m2, 20 W/m2, 30 W/m2, and 40 W/m2, respectively. The test results are shown in Figure 3 and Figure 4. The ductility test was carried out according to the standard testing methods of bitumen and bituminous mixtures for highway engineering (JTG E20–2011) in China.
It can be seen from Figure 3 and Figure 4 that within the 5-day aging time, the ductility value of asphalt decreased at a rapid speed, and as the extension of aging time, the reduction rate of the ductility value gradually slowed down. Compared with the ductility value of the 0-day aging time, under the aging UV intensity of 40 W/m2, the ductility values of ZH-70 and SK-70 asphalt aged for 5 days were decreased respectively by 68.6% and 77.6%. Furthermore, under the same conditions, the stronger the aging UV intensity, the bigger the ductility value of asphalt decreased. Under the aging UV intensity of 0 W/m2, compared with the ductility value of the 0-day aging time, the ductility values of ZH-70 asphalt and SK-70 asphalt aged for 15 days were decreased by 68.8% and 60.4% respectively, and under the aging UV intensity of 40 W/m2, they were decreased by 89.8% and 86.2%, respectively.
Then, the index tests of ZH-70 and SK-70 asphalt for 15 °C ductility under different aging temperatures were conducted. The long-term aging of asphalt under heat and light together was performed, and its aging UV intensity was set to 40 W/m2. Its aging time was set to 0 day, 5 days, 10 days, and 15 days, respectively, and its aging temperature was set to 50 °C, 60 °C, and 70 °C, respectively. The results are presented in Figure 5.
As observed in Figure 5, the ductility value of asphalt decreased with the increase of aging time. However, its decrease rate slowed down. Meanwhile, the ductility value of asphalt was also clearly decreased within the aging time of 5 days. At the aging temperature of 60 °C, compared with the ductility value of the aging time of 0 day, the ductility values of ZH-70 and SK-70 asphalt aged for 5 days were decreased respectively by 62.5% and 71.1%. Furthermore, under the same conditions, the higher the aging temperature, the bigger the ductility value of the asphalt that decreased. At the aging temperature of 50 °C, compared with the ductility value of the aging time of 0 day, the ductility values of ZH-70 and SK-70 asphalt for the aging time of 15 days were decreased by respectively 85% and 82.9%, and at the aging temperature of 60 °C, they were decreased by 88.3% and 84.4 %, respectively.
Lastly, under the aging UV intensity of 40 W/m2, the index tests of six kinds of asphalt for the 10 °C ductility were conducted at the aging temperature of 70 °C. The long-term aging of asphalt under a heat and light coupling condition was performed, and its aging time was 0 day, 5 days, 10 days, and 15 days, respectively. The ductility retained rates of asphalt under different aging times were calculated. The test results are given in Figure 6 and Figure 7.
It can be seen from Figure 6 and Figure 7 that whether base asphalt or modified asphalt, the change trends of the ductility of asphalt were similar. Their ductility values were decreased at a rapid speed within the aging time of 5 days, and as the extension of aging time, they were gradually decreased. For different types of asphalt, the ductility retained rate was different, and compared with the base asphalt, the ductility value of the modified asphalt was significantly higher than that of the base asphalt. For ZH-70 asphalt, ZH-70 linear-modified asphalt, ZH-70 branched-modified asphalt, SK-70 asphalt, SK-70 linear-modified asphalt, and SK-70 branched-modified asphalt, their ductility values of the aging time of 15 days were respectively 4 cm, 42 cm, 29 cm, 3 cm, 17 cm, and 11 cm, and their ductility retained rates of the 15-day aging time were 9%, 47.2%, 34.5%, 11.1%, 22.1%, and 15.1% respectively. For the same modifier, the ductility value of modified asphalt for different base asphalts was different, too. At the 15-day aging time, for ZH-70 asphalt, the ductility value of its linear-modified asphalt and branched-modified asphalt was 10.5-fold and 7.25-fold higher than that of its base asphalt, respectively, and for SK-70 asphalt, the ductility value of its linear-modified asphalt and branched-modified asphalt was 5.66-fold and 3.66-fold higher than that of its base asphalt respectively. Moreover, for the same modifier, the ductility value of different bases was also different. For the 501s branched modifier and the 4402 linear modifier, their ductility values of ZH-70-modified asphalt aged for 15 days were 2.47-fold and 2.64-fold higher than those of SK-70-modified asphalt, respectively. The different chemical composition of the base asphalt was the possible reason causing the difference.
The ductility test results indicate that heat and light have a great effect on the low-temperature cracking performance of asphalt, and they can obviously reduce the low-temperature cracking performance of asphalt at the early stage. Moreover, the higher the values of the temperature and UV intensity are, the more the low-temperature cracking performance of asphalt is reduced. The asphalt type has an important effect on the low-temperature cracking performance of asphalt under heat and light together, and the rational selection of a base asphalt and modifier can improve the low-temperature cracking performance of asphalt.

3.2. Bending Beam Rheometer (BBR) Test

Firstly, the RTFOT aging test of the asphalt was performed. Then, under a UV intensity of 40 W/m2, the long-term aging test of the asphalt aged by RTFOT was conducted at 70° C. Afterward, the aged asphalt was used in the BBR test. According to Superpave specifications, BBR tests of six kinds of asphalt were performed using a BBR 9728-V30 from the Cannon Company, at −12 °C. The creep stiffness change rate m, at 60 s, and the creep stiffness S, are the most important parameters of the BBR test, and they can evaluate the low-temperature crack resistance of asphalt binder. A smaller S-value and a bigger m-value correspond to a better deformation ability and stress relaxation ability, respectively. That is, a smaller S-value and a bigger m-value correspond to a better low-temperature crack resistance of asphalt. The change rates of the S-value and the m-value of asphalt under different aging times were calculated. The test results are given in Figure 8, Figure 9, Figure 10 and Figure 11.
As observed in Figure 8 through Figure 11, whether base asphalt or modified asphalt, the S-value was clearly elevated, and the m-value was obviously reduced with the increase of aging time, indicating that under heat and light together, the obvious embrittlement occurred in asphalt at low temperature, and the low-temperature crack resistance of asphalt was reduced. Moreover, under the same conditions, the m-value of the modified asphalt was bigger than that of the base asphalt, and the S-value of the modified asphalt was smaller than that of the base asphalt. That is, in comparison with the base asphalt, the low-temperature crack performance of modified asphalt was better. For different base asphalts and modifiers, the increase rate of the S-value and the decrease rate of the m-value were also different. Therefore, for the low-temperature crack performance, the heat and light aging have an obvious effect on the low-temperature cracking performance of asphalt; the effect on modified asphalt was smaller than that on base asphalt, and the rational selection of base asphalt and modifier can improve the low-temperature cracking resistance of asphalt.

3.3. Asphalt Composition Analysis Test

The asphalt composition has a direct effect on its low-temperature cracking performance [34]. To research the effect of heat and light together on the low-temperature cracking performance of asphalt, four constituent tests of ZH-70 asphalt and ZH-70 linear-modified asphalt were performed, according to the test method for the separation of the asphalt into four fractions (T0618-1993), based on the standard test methods for bitumen and bituminous mixtures for highway engineering (JTG E20-2011) in China [35]. Firstly, the RTFOT aging test of asphalt was conducted. Then, under the aging UV intensity of 40 W/m2, the long-term aging test of asphalt aged by RTFOT was performed at 70° C. Afterward, the aged asphalt was used in the asphalt composition analysis test. The change rate of component content (CRC) of asphalt was used for evaluating the content change of the component of asphalt before and after aging, and it can be calculated using the following Equation:
C R C = C C A C C B C C B × 100 %
where C C A is the content of the component of asphalt after aging, and C C B is the content of asphalt component before aging. The content change rates of the component of asphalt under different aging times were calculated. The results are given in Table 4 and Table 5 and Figure 12.
Table 4 and Table 5 show that in comparison with the base asphalt, before long-term aging, the content of asphaltenes of modified asphalt increased, and its contents of resins, aromatics, and saturates decreased in various degrees, indicating that the SBS modifier can increase the viscosity and surface area of asphalt, because of the high speed shear and swelling, and it can adsorb some colloids and dispersing media. Moreover, the SBS modifier is of a polyphase network structure; after it was added to the base asphalt, a good three-dimensional network structure formed, and the polystyrene chain dispersed in the matrix asphalt phase. Those can improve the elasticity and flexibility of its modified asphalt at low temperature, which may be the reason that the low-temperature cracking resistance of modifier asphalt is better than that of base asphalt.
It can be seen from Table 4 and Table 5 and Figure 12 that the content of asphaltenes increased significantly, while the content of aromatics clearly decreased with the increase of aging time. Meanwhile, the contents of saturates and resins sometimes increased and sometimes decreased, and the changes of their content were not obvious. Therefore, it can be the main reason that the transformations from aromatics to resins and then from resins to asphaltenes occurred in the aging process of asphalt. The content of resins was affected by the rates of the transformations through aromatics to resins and through resins to asphaltenes. Furthermore, the change rates of asphaltenes and aromatics of modified asphalt were smaller than those of base asphalt, indicating that after the modifier is added to the base asphalt, it can decrease the rate of the transformations through aromatics to resins and then through resins to asphaltenes. As seen in Figure 12, the change of asphaltenes content was the most obvious, and within the 5-day aging time, the four components content varied obviously: as the aging time extended, their change rates slowed down. It can be one of the main reasons that with the increase of aging time, the chain rupturing and ring-opening reactions of asphaltenes will occur and asphaltenes will transform to saturates and aromatics again.
Under heat and light together, the active bond of asphalt was activated, a polar group was produced by the oxidation reaction, there was intermolecular force enhancing due to the aggregation of the polar groups, macromolecular substances were produced; then, the content of asphaltenes of asphalt increased, which caused the decrease of ductility of the asphalt at low temperature. Moreover, the degradation of the polystyrene chain will cause the decrease of the ductility of modified asphalt at low temperature. Those may be the reason that the low-temperature cracking resistance of asphalt decreased with the increase of aging time under heat and light together.

4. Conclusions

In this research, six kinds of asphalt were exposed under heat and light together for 5, 7, and 15 days to investigate the low-temperature cracking performance, and the following conclusions can be obtained.
(1)
Under heat and light together, the ductility value of asphalt decreased with the increase of aging time, temperature, and ultraviolet intensity, and it became more obvious within 5 days; the ductility value of modified asphalt was significantly higher than that of base asphalt, and for the same modifier, the ductility value of modified asphalt for different base asphalts was also different, indicating that the asphalt cracking resistance was obviously reduced at the early stage. Moreover, it becomes worse with the increase of the aging time, temperature, and ultraviolet intensity, and the rational selection of base asphalt and modifier could improve the low-temperature cracking performance of asphalt.
(2)
Under heat and light together, the creep stiffness S value of asphalt was significantly increased, while the creep stiffness change rate m value of asphalt was obviously reduced with the increase of aging time. Meanwhile, the change rates of the S value and m value of modified asphalt were smaller than those of base asphalt. Hence, heat and light together aging could significantly weaken the low-temperature cracking resistance of asphalt, and they had less effect on the low-temperature cracking resistance of modified asphalt.
(3)
Under heat and light together, the content of asphaltenes increased significantly, while the content of aromatics clearly decreased with the increase of aging time. The change rates of asphaltenes and aromatics of modified asphalt were lower than those of base asphalt. Within 5 days of aging time, the four components content varied obviously, and as the aging time extended, their change rates slowed down.
(4)
The asphalt composition had a direct influence on its low-temperature cracking performance. Under heat and light together, whether the base asphalt or modified asphalt, the change trends of its ductility and component content were similar. Therefore, the ductility of asphalt aged by heat and light together for 15 days was suggested for use as the evaluation index of the low-temperature cracking performance of asphalt.

Author Contributions

Writing—original draft preparation, L.L.; project administration, Z.G.; analyzing test data and writing—review and editing, L.R.; performing the experiment, J.Z. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Hunan Provincial Natural Science Foundation of China (Grant No. 2015JJ2073), Hunan Provincial Department of Education of China (Grant No.16A082), and the construct program of applied characteristic discipline in Hunan University of Science and Engineering.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Rajbongshi, P.; Das, A. Estimation of temperature stress and low-temperature crack spacing in asphalt pavements. J. Transp. Eng. 2009, 135, 745–752. [Google Scholar] [CrossRef]
  2. Zhou, C.; Huang, B.; Shu, X.; Dong, Q. Validating MEDPG with tennessee pavement performance data. J. Transp. Eng. 2013, 139, 306–312. [Google Scholar] [CrossRef]
  3. Ma, H.; Wang, D.; Feng, D.; Wu, X. Verification of low temperature performance of asphalt pavement aging material in cold regions. J. Funct. Mater. 2015, 46, 24074–24077. [Google Scholar]
  4. Mao, C. Study on Crack Initiation Mechanism and Propagation Behavior of Asphalt Pavements. Ph.D. Thesis, Southwest Jiaotong University, Chengdu, China, 2004. [Google Scholar]
  5. Yan, Z. Study on the Cracking Mechanism and Prevention Measures of Top-down Crack on Flexible base Asphalt Pavement in Seasonal Frozen Area. Master’s Thesis, Chang’an University, Xi’an, China, 2013. [Google Scholar]
  6. Donna, H.; Scott, S.E.; Tim, A. Top-Down cracking in asphalt pavements: Cause, effects and cures. J. Transp. Eng. 2008, 134, 1–6. [Google Scholar]
  7. Wang, X. Analysis of Crack in Asphalt Pavement under the Ultraviolet Light Ageing. Master’s Thesis, Xi’an University of Architecture and Technology, Xi’an, China, 2014. [Google Scholar]
  8. Bagdat, T.; Boris, R. Predicting thermal cracking of asphalt pavements from bitumen and mix properties. Road Mater. Pavement Des. 2018, 19, 1832–1847. [Google Scholar]
  9. Behnia, B.; Buttlar, W.; Reis, H. Evaluation of Low-Temperature Cracking Performance of Asphalt Pavements Using Acoustic Emission: A Review. Appl. Sci. 2018, 8, 306. [Google Scholar] [CrossRef] [Green Version]
  10. Wu, S.; Ye, Y.; Li, Y.; Li, C.; Song, W.; Li, H.; Li, C.; Shu, B.; Nie, S. The Effect of UV Irradiation on the Chemical Structure, Mechanical and Self-Healing Properties of Asphalt Mixture. Materials 2019, 12, 2424. [Google Scholar] [CrossRef] [Green Version]
  11. Hesp, S.; Terlouw, T.; Vonk, W. Low temperature performance of SBS-modified asphalt mixes. Asph. Paving Technol. 2000, 69, 540–573. [Google Scholar]
  12. Kim, S.S.; Wysong, Z.D.; Kovach, J. Low-temperature thermal cracking of asphalt binder by asphalt binder cracking device. Transp. Res. Rec. 2006, 1962, 28–35. [Google Scholar] [CrossRef]
  13. Li, X.; Marasteanu, M.O.; Turos, M. Study of low temperature cracking in asphalt mixtures using mechanical testing and acoustic emission methods (With Discussion). J. Assoc. Asph. Paving Technol. 2007, 76, 427–453. [Google Scholar]
  14. Liu, T.; Hao, P. Comparison study of evaluation method for low temperature anti -cracking performance of hot mix asphalt. J. Tongji Univ. 2002, 30, 1468–1471. [Google Scholar]
  15. Pszczola, M.; Jaczewski, M.; Rys, D.; Jaskula, P.; Szydlowski, C. Evaluation of Asphalt Mixture Low-Temperature Performance in Bending Beam Creep Test. Materials 2018, 11, 100. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  16. Zhou, J.; Zhang, Z.; Rao, X. Study on SHRP SBS modified asphalts’ anti-cracking characteristics. J. Chongqing Jiaotong Univ. 2005, 24, 50–52. [Google Scholar]
  17. Patrícia, H.; Leni, F.; Francisco, T.; Margareth, C.; Luciana, N.; Thaísa, F. Cracking resistance evaluation of asphalt binders subjected to different laboratory and field aging conditions. Road Mater. Pavement Des. 2019, 20, 663–677. [Google Scholar]
  18. Zhang, H.; Xu, G.; Chen, X.; Wang, R.; Kairen, S. Effect of long-term laboratory aging on rheological properties and cracking resistance of polymer-modified asphalt binders at intermediate and low temperature range. Constr. Build. Mater. 2019, 226, 767–777. [Google Scholar] [CrossRef]
  19. Glotova, N.; Kats, B.; Gorshkov, V. Photooxidation of asphalts in thin films. Chem. Technol. Fuels Oils 1974, 10, 876–879. [Google Scholar] [CrossRef]
  20. Zhang, D.; Zhang, H.; Shi, C. Investigation of aging performance of SBS modified asphalt with various aging methods. Constr. Build. Mater 2017, 145, 445–451. [Google Scholar] [CrossRef]
  21. Durrieu, F.; Farcas, F.; Mouillet, V. The influence of UV aging of a styrene/butadiene/styrene modified bitumen: Comparison between laboratory and on site aging. Fuel 2007, 86, 1446–1451. [Google Scholar] [CrossRef]
  22. Mouillet, V.; Farcas, F.; Besson, S. Ageing by UV radiation of an elastomer modified bitumen. Fuel 2008, 87, 2408–2419. [Google Scholar] [CrossRef]
  23. Liu, X.; Wu, S.; Liu, G.; Li, L. Optical and UV-Aging Properties of LDH-Modified Bitumen. Materials 2015, 8, 4022–4033. [Google Scholar] [CrossRef] [Green Version]
  24. Zhan, X.; Zhang, X.; Tan, Y.; Lu, L. Study on the low temperature performance evaluation indexes of modified asphalt. J. Highw. Transp. Res. Dev. 2007, 24, 42–45. [Google Scholar]
  25. Li, X.; Han, S.; Li, Y.; Li, B. Experimental study on index of low-temperature crack resistance of asphalt binder. J. Wuhan Univ. Technol. 2010, 32, 81–84. [Google Scholar]
  26. Huang, X.; Ismail Bakheit, E. Experimental study to determine the most preferred additive for improving asphalt performance using polypropylene, crumb rubber, and tafpack super in medium and high-temperature range. Appl. Sci. 2019, 9, 1567–1571. [Google Scholar]
  27. Lin, J.D.; Chen, S.H.; Liu, P.; Wang, J.N. Modified toughness used to evaluate the effect of polymer modified asphalt on Sma. J. Chin. Inst. Eng. 2004, 27, 8. [Google Scholar] [CrossRef]
  28. Menapace, I.; Yiming, W.; Masad, E. Chemical analysis of surface and bulk of asphalt binders aged with accelerated weathering tester and standard aging methods. Fuel 2017, 202, 366–379. [Google Scholar] [CrossRef]
  29. Li, W.; Fan, L.; Ling, L. Influence on performance of modified asphalt by SBS doping ratio. Shandong Jiaotong Keji 2009, 7, 35–37. [Google Scholar]
  30. Ding, Y.; Tan, D. Experimental research on pavement performance of SBS polymer modified bitumen. Build. Sci. 2012, 28, 3–46. [Google Scholar]
  31. ASTM D2872. Standard Test Method for Effect of Heat and Air on a Moving Film of Asphalt (Rolling Thin-Film Oven Test); ASTM International: West Conshohocken, PA, USA, 2019. [Google Scholar]
  32. Ran, L. Research on Aging Mechanism and High Performance Regenerant of SBS Modified Asphalt under Coupling Condition of Light, Heat, Water. Ph.D. Thesis, Chongqing Jiaotong University, Chongqing, China, 2016. [Google Scholar]
  33. Zhang, J. Research of Aging Characteristic of SBS Modified Asphalt under Coupling Condition of Heat and Light. Master’s Thesis, Chongqing Jiaotong University, Chongqing, China, 2014. [Google Scholar]
  34. Wang, M.; Gao, B.; Wu, Z.; Gou, J. Test research and application of rock asphalt composite modified asphalt SMA performance. Technol. Highw. Transp. 2014, 3, 29–40. [Google Scholar]
  35. China Ministry of Transport. JTG E20-2011 Specifications and Test Methods of Bitumen and Bituminous Mixtures for Highway Engineering; China Communications Press: Beijing, China, 2011.
Materials 13 01541 g001 550
Figure 1. RG-80 asphalt aging test chamber.
Figure 1. RG-80 asphalt aging test chamber.
Materials 13 01541 g001
Materials 13 01541 g002 550
Figure 2. Asphalt sample.
Figure 2. Asphalt sample.
Materials 13 01541 g002
Materials 13 01541 g003a 550Materials 13 01541 g003b 550
Figure 3. Relationship between ductility and aging time.
Figure 3. Relationship between ductility and aging time.
Materials 13 01541 g003aMaterials 13 01541 g003b
Materials 13 01541 g004a 550Materials 13 01541 g004b 550
Figure 4. Relationship between ductility and aging time for different UV intensity.
Figure 4. Relationship between ductility and aging time for different UV intensity.
Materials 13 01541 g004aMaterials 13 01541 g004b
Materials 13 01541 g005 550
Figure 5. Relationship between ductility and aging times for different temperatures.
Figure 5. Relationship between ductility and aging times for different temperatures.
Materials 13 01541 g005
Materials 13 01541 g006 550
Figure 6. Ductility and aging times for different asphalts.
Figure 6. Ductility and aging times for different asphalts.
Materials 13 01541 g006
Materials 13 01541 g007 550
Figure 7. Ductility retained rates and aging times for different asphalts.
Figure 7. Ductility retained rates and aging times for different asphalts.
Materials 13 01541 g007
Materials 13 01541 g008 550
Figure 8. Creep stiffness change rate and aging time.
Figure 8. Creep stiffness change rate and aging time.
Materials 13 01541 g008
Materials 13 01541 g009 550
Figure 9. Decrease rate of creep stiffness change rate and aging time.
Figure 9. Decrease rate of creep stiffness change rate and aging time.
Materials 13 01541 g009
Materials 13 01541 g010 550
Figure 10. Stiffness modulus and aging time.
Figure 10. Stiffness modulus and aging time.
Materials 13 01541 g010
Materials 13 01541 g011 550
Figure 11. Increase rate of stiffness modulus and aging time.
Figure 11. Increase rate of stiffness modulus and aging time.
Materials 13 01541 g011
Materials 13 01541 g012 550
Figure 12. Change rate of component content and aging time for ZH-70 base and modified asphalt.
Figure 12. Change rate of component content and aging time for ZH-70 base and modified asphalt.
Materials 13 01541 g012
Table
Table 1. Properties of styrene–butadiene–styrene (SBS) modifier.
Table 1. Properties of styrene–butadiene–styrene (SBS) modifier.
TypeElongation at Break (%)CharacterPermanent Set (%)Tensile Strength (MPa)Modulus at 300% Elongation (MPa)Block Ratio
501s modifier≥800White floc≤42≥14.2≥2.331/69
4402 modifier≥700White strip≤40≥14.0≥2.030/70
Table
Table 2. Properties of base asphalt.
Table 2. Properties of base asphalt.
PropertiesCriteriaSK-70ZH-70Methods
Ductility at 10 °C (cm)≥204526.7T0604-2011 [22]
Viscosity at 135 °C (Pa.s)≤3.00.5540.632T0625-2011 [22]
Rutting factor (kPa)≥1.01.911.20AASHTOT315
Penetration degree at 25 °C (0.1 mm)60~807271T0605-2011 [22]
Penetration index−1.5 to +1.00.80.4T0604-2011 [22]
Softening point (°C)≥4748.448.6T0606-2011 [22]
After the thin film oven test (TFOT)
(163 °C, 5 h)		Mass loss (%)±0.8−0.3−0.14T0609-2011 [22]
Ductility at 10 °C (cm)≥6s1626T0604-2011 [22]
Penetration degree ratio at 25 °C (%)≥6180.373.6T0605-2011 [22]
Table
Table 3. Properties of SBS-modified asphalt.
Table 3. Properties of SBS-modified asphalt.
PropertiesCriteriaLinear-Modified AsphaltBranched-Modified AsphaltMethods
ZH-70SK-70ZH-70SK-70
Ductility at 10 °C (cm)≥2089847773T0604-2011 [28]
viscosity at 135 °C (Pa.s)≤3.01.6251.4001.8531.769T0625-2011 [22]
Rutting factor (kPa)≥1.02.232.351.861.97AASHTOT315
Penetration degree at 25 °C (0.1 mm)30~6042494851T0605-2011 [28]
Penetration index≥00.20.90.40.2T0604-2011 [28]
Softening point (°C)≥ 6061.563.260.562T0606-2011 [28]
After the thin film oven test (TFOT)
(163 °C, 5 h)		Mass loss (%)± 0.80.6−0.3−0.2−0.2T0609-2011 [28]
Ductility at 10 °C (cm)≥2065495450T0604-2011 [28]
Penetration degree ratio at 25 °C (%)≥6585.783.781.373.4T0605-2011 [28]
Table
Table 4. ZH-70 base asphalt composition.
Table 4. ZH-70 base asphalt composition.
Aging TimeSaturates (%)Aromatics (%)Resins (%)Asphaltenes (%)
0 day13.3549.2828.329.05
5 days13.7045.3228.3512.63
10 days13.6544.9128.6412.80
15 days13.5444.5028.9113.05
Table
Table 5. ZH-70 linear-modified asphalt composition.
Table 5. ZH-70 linear-modified asphalt composition.
Aging TimeSaturates (%)Aromatics (%)Resins (%)Asphaltenes (%)
0 day12.6745.3126.9715.05
5 days12.5843.8225.6217.98
10 days12.6143.5425.5018.35
15 days12.6743.3325.4918.51

Share and Cite

MDPI and ACS Style

Li, L.; Guo, Z.; Ran, L.; Zhang, J. Study on Low-Temperature Cracking Performance of Asphalt under Heat and Light Together Conditions. Materials 2020, 13, 1541. https://doi.org/10.3390/ma13071541

AMA Style

Li L, Guo Z, Ran L, Zhang J. Study on Low-Temperature Cracking Performance of Asphalt under Heat and Light Together Conditions. Materials. 2020; 13(7):1541. https://doi.org/10.3390/ma13071541

Chicago/Turabian Style

Li, Limin, Zhaoyang Guo, Longfei Ran, and Jiewen Zhang. 2020. "Study on Low-Temperature Cracking Performance of Asphalt under Heat and Light Together Conditions" Materials 13, no. 7: 1541. https://doi.org/10.3390/ma13071541

APA Style

Li, L., Guo, Z., Ran, L., & Zhang, J. (2020). Study on Low-Temperature Cracking Performance of Asphalt under Heat and Light Together Conditions. Materials, 13(7), 1541. https://doi.org/10.3390/ma13071541

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop