Effect of Recycled Asphalt Pavement Binder on Rheology of Crumb Rubber–Modified Binder—An Experimental, Analytical, and Analogical Study

IF 1.4 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY
Dharamveer Singh, Burhan Showkat, Shashibhushan Girimath
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引用次数: 0

Abstract

The popularity of recycled asphalt pavement (RAP) is on the rise because of the benefits of sustainability. In an unavoidable scenario wherein crumb rubber–modified binder (CRMB) is adopted as a base binder in RAP mixes, the binder from RAP will blend with CRMB, thereby influencing its rheology and performance at high, intermediate, and low temperature. Hence, in this study, binder extracted from two RAP sources (RAP X and RAP Y) was blended with CRMB at varying proportions of 15, 25, and 40 % by weight. Isochronal temperature sweeps, isothermal frequency sweeps, and bending beam rheometer tests were conducted on the prepared blends. Thereafter, analytical and analogical studies were performed using master curve construction, 2S2P1D, and Huet modelling. The results indicated that RAP from different sources affects the high-, intermediate-, and low-temperature performance of CRMB. Different RAPs were observed to have contrasting effects on high-temperature performance grading. Intermediate-temperature performance based on cross-over temperature (TCROSS-OVER) indicated a compromise because of the inclusion of RAPs. An evaluation of the differences among critical temperatures at low temperature (ΔTc) indicated the degradation of low-temperature performance. Such changes in high-, intermediate-, and low-temperature performances were validated by complex modulus (G*), stiffness (S(t)), and stress relaxation (E(t)) master curves. Finally, the 2S2P1D and Huet model were observed to depict reasonably good fits for the prepared blends. This study concludes that RAPs from different sources have contrasting impact on CRMB and may adversely impact the intermediate- and low-temperature performance.
再生沥青路面粘结剂对碎橡胶改性粘结剂流变学的影响——实验、分析和类比研究
由于可持续性的好处,再生沥青路面(RAP)的受欢迎程度正在上升。在RAP混合料中不可避免地采用碎屑橡胶改性粘结剂(CRMB)作为基础粘结剂时,RAP中的粘结剂会与CRMB共混,从而影响CRMB在高、中、低温下的流变学和性能。因此,在本研究中,从两种RAP源(RAP X和RAP Y)中提取的粘合剂以15%、25%和40%的不同重量比例与CRMB混合。对制备的共混物进行了等时温度扫描、等温频率扫描和弯曲梁流变仪试验。随后,使用主曲线构建、2S2P1D和Huet建模进行了分析和类比研究。结果表明,不同来源的RAP对CRMB的高、中、低温性能均有影响。不同的RAPs对高温性能分级有不同的影响。基于交叉温度(TCROSS-OVER)的中温性能表明,由于包含RAPs而有所妥协。低温临界温度之间的差异评估(ΔTc)表明低温性能的退化。复合模量(G*)、刚度(S(t))和应力松弛(E(t))主曲线验证了高温、中低温性能的变化。最后,观察到2S2P1D和Huet模型对所制备的共混物具有较好的拟合性。本研究认为,不同来源的RAPs对CRMB有不同的影响,并可能对中低温性能产生不利影响。
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来源期刊
Advances in Civil Engineering Materials
Advances in Civil Engineering Materials MATERIALS SCIENCE, MULTIDISCIPLINARY-
CiteScore
2.70
自引率
7.10%
发文量
40
期刊介绍: The journal is published continuously in one annual issue online. Papers are published online as they are approved and edited. Special Issues may also be published on specific topics of interest to our readers. Advances in Civil Engineering Materials provides high-quality, papers on a broad range of topics relating to the properties and performance of civil engineering materials. Materials Covered: (but not limited to) Concrete, Asphalt, Steel, Polymers and polymeric composites, Wood, Other materials used in civil engineering applications (for example, pavements, bridges, and buildings, including nonstructural building elements such as insulation and roofing), and environmental systems (including water treatment). Core Topics Covered: Characterization, such as chemical composition, nanostructure, and microstructure, Physical properties, such as strength, stiffness, and fracture behavior, Constructability, such as construction methods, quality control/assurance, life cycle analysis, and sustainability, Durability. Papers may present experimental or modeling studies based on laboratory or field observations. Papers relating to sustainability of engineering materials or to the impact of materials on sustainability of engineering structures are especially encouraged.
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