低曲折透水性混凝土路面材料:改善物理性能的新方法

IF 5.3 Q2 ENGINEERING, ENVIRONMENTAL
Goutom Barua , G.M. Sadiqul Islam
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引用次数: 0

摘要

透水路面是一种有益于环境的材料,可以缓解城市问题,减轻气候变化的影响,如洪水、城市热岛和地下水减少。然而,这种材料容易堵塞,强度有限,而且需要经常维护。为了克服这些问题,本研究对一种非传统的纤维增强透水路面进行了研究,这种路面具有低迂回度的孔隙结构,具有出色的渗透率和强度,同时还能防止堵塞。在自密实混凝土中引入了不同大小和数量的直孔隙通道,从而形成了这种透水路面。测试了孔隙率为 3.60% 至 8.30%、纤维含量为 0-0.2% 的高强度透水路面 (HSP) 样品。在所有情况下,HSP 都表现出较高的渗透率(1 厘米/秒)、较高的抗压强度(27 兆帕)和抗拉强度(1.5 兆帕)、较低的抗冲击和磨损降解质量损失(25%)。然而,尽管在含有沙子、粘土和混合 "沙子&粘土 "的水流中进行了大量的循环暴露,它也没有堵塞。PP 纤维含量为 0.1%。考虑到所有特性,3.60% 的孔隙率被认为是最佳的,而 8.30% 的孔隙率则能提供更高的渗透率,但特性会受到影响。这种透水路面可以保持足够的孔隙率和渗透性,以利于雨水渗透,而无需经常维护。添加聚丙烯纤维会略微降低抗压强度,但会提高劈裂拉伸强度、抗降解性和抗电位性。这种新型纤维增强 HSP 有可能扩大材料的适用范围。这项研究取得的成果有望为 HSP 在各种环境和举措中更广泛的应用开辟道路,而这些环境和举措以前并不被认为是合适的。这最终将加强新一代抗洪基础设施的设计和实施,并显著提高缓解城市洪灾的能力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Low tortuous permeable concrete pavement material: A new approach to improve physical properties

Permeable pavement is an environmentally beneficial material that can ease urban problems and mitigate the effects of climate change, such as flooding, urban heat islands, and groundwater decrease. However, it is susceptible to clogging, has limited strength, and demands frequent maintenance. To overcome these problems, an untraditional fiber-reinforced permeable pavement with a low tortuosity pore structure that has an excellent infiltration rate and strength while being resistant to clogging has been studied in this research. Straight pore channels of various sizes and quantities were introduced into self-compacting concrete to create this permeable pavement. High-strength pervious pavement (HSP) samples with porosity ranging from 3.60 to 8.30% and 0–0.2% fiber content were tested. In all cases, HSP showed high infiltration rate (>1 cm/s), high compressive strength (>27 MPa) and tensile strength (1.5 MPa), low mass loss in potential resistance to degradation by impact and abrasion (>25%). However, it did not clog despite extensive cyclic exposure to flow containing sand, clay, and combined ‘sand & clay’. PP fiber content of 0.1%. The 3.60% porosity was found to be optimum considering all properties, whereas 8.30% porosity gave a higher infiltration rate with compromised properties. This permeable pavement can maintain sufficient porosity and permeability for stormwater infiltration without frequent maintenance. Adding polypropylene fiber reduces compressive strength marginally but increases split tensile strength, degradation and potential resistance. This novel fiber-reinforced HSP has the potential to expand the material's applicability. The results obtained from this research are expected to lead the way for a broader application of HSP in various contexts and initiatives that were not previously considered appropriate. This will eventually enhance the design and implementation of a new generation of flood-resistant infrastructure and significantly improve the ability to mitigate urban floods.

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来源期刊
Cleaner Engineering and Technology
Cleaner Engineering and Technology Engineering-Engineering (miscellaneous)
CiteScore
9.80
自引率
0.00%
发文量
218
审稿时长
21 weeks
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