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一种使用钢材和塑料以提高性能、耐久性及施工效率的新型道路路面设计。

Design of a Novel Road Pavement Using Steel and Plastics to Enhance Performance, Durability and Construction Efficiency.

作者信息

Jiang Wei, Yuan Dongdong, Sha Aimin, Huang Yue, Shan Jinhuan, Li Pengfei

机构信息

Key Laboratory for Special Area Highway Engineering of Ministry of Education, Chang'an University, Xi'an 710064, China.

School of Highway, Chang'an University, Xi'an 710064, China.

出版信息

Materials (Basel). 2021 Jan 20;14(3):482. doi: 10.3390/ma14030482.

DOI:10.3390/ma14030482
PMID:33498490
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7864207/
Abstract

Durability is one important problem that pavement engineers need to address in pavement's long service life. Furthermore, easily recycled pavement materials, and safe and efficient pavement construction are also important areas for development in road engineering. For these reasons, a new asphalt steel plastic (ASP) pavement structure was proposed with an asphalt mixture forming the surface layer, and steel plate and plastic materials functioning as the main load-bearing layers. Based on a comprehensive performance review and cost-benefit analysis, stone mastic asphalt (SMA) is recommended to be used as the surface layer; and A656 steel plate and acrylonitrile butadiene styrene (ABS) plastic materials should be the main load-bearing layer, on top of a foundation layer made with graded crushed stones. A glass fiber reinforced polymer (GFRP) insulation layer is recommended for use between the steel plate and ABS. Mechanical properties of the ASP pavement were analyzed using the finite element method. Laboratory tests were conducted to verify the thermal insulation performance of GFRP, the high-temperature stability and the fatigue resistance of ASP pavement. Results show that some of the mechanical properties of ASP pavement (with a structure of 80 mm SMA asphalt mixture, 8 mm steel plate, 140 mm ABS and 200 mm crushed stones) are comparable with conventional long-life pavement (with 350 mm asphalt layer overlaying 400 mm graded crushed stones). Dynamic stability of the ASP slab specimens can reach 10,000 times/mm, and the fatigue life is about twice that of SMA. Besides, the ASP pavement can be prefabricated and assembled on-site, and thus can greatly improve construction efficiency. From the lifecycle perspective, ASP pavement has many advantages over traditional pavements, such as durability, lower environmental footprint and recyclability, making it is worth further research.

摘要

耐久性是路面工程师在路面长使用寿命中需要解决的一个重要问题。此外,易于回收的路面材料以及安全高效的路面施工也是道路工程中重要的发展领域。基于这些原因,提出了一种新的沥青钢塑(ASP)路面结构,其表面层由沥青混合料构成,钢板和塑料材料作为主要承重层。基于综合性能评估和成本效益分析,建议使用沥青玛蹄脂碎石混合料(SMA)作为表面层;A656钢板和丙烯腈-丁二烯-苯乙烯(ABS)塑料材料应作为主要承重层,铺设在由级配碎石制成的基层之上。建议在钢板和ABS之间使用玻璃纤维增强聚合物(GFRP)隔热层。采用有限元方法分析了ASP路面的力学性能。进行了实验室测试,以验证GFRP的隔热性能、ASP路面的高温稳定性和抗疲劳性能。结果表明,ASP路面(结构为80毫米SMA沥青混合料、8毫米钢板、140毫米ABS和200毫米碎石)的一些力学性能与传统长寿命路面(350毫米沥青层覆盖400毫米级配碎石)相当。ASP板试件的动稳定度可达10000次/毫米,疲劳寿命约为SMA的两倍。此外,ASP路面可以预制并在现场组装,从而可大大提高施工效率。从生命周期的角度来看,ASP路面相对于传统路面具有许多优势,如耐久性、更低的环境足迹和可回收性,因此值得进一步研究。

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