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基于部分轮胎水滑状况的沥青路面抗滑特性

Anti-Skid Characteristics of Asphalt Pavement Based on Partial Tire Aquaplane Conditions.

作者信息

Yu Miao, Kong Yao, You Zhanping, Li Jue, Yang Liming, Kong Lingyun

机构信息

Key Laboratory of Road Structure and Material of Transport Ministry, Chang'an University, Xi'an 710064, China.

School of Civil Engineering, Chongqing Jiaotong University, 66 Xuefu Blvd, Chongqing 400074, China.

出版信息

Materials (Basel). 2022 Jul 17;15(14):4976. doi: 10.3390/ma15144976.

DOI:10.3390/ma15144976
PMID:35888443
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9321324/
Abstract

This study presented a finite element model of radial tire-asphalt pavement interaction using ABAQUS 6.14 software to investigate the skid resistance properties of asphalt pavement under partial tire aquaplane conditions. Firstly, the pavement profile datum acquired by laser scanning were imported to Finite Element Analysis (FEA) software to conduct the pavement modeling. Secondly, a steady state rolling analysis of a tire on three types of asphalt pavements under drying conditions was carried out. Variation laws of the friction coefficient of the radial tire on different pavements with different pavement textures, tire pressures, and loads on the tire were examined. Subsequently, calculation results of the steady state rolling analysis were transmitted to dynamic explicit analysis, and an aquaplane model of a radial tire on asphalt pavements was built by inputting the flow Euler grids. The tire-pavement adhesive characteristics under partial aquaplane conditions are discussed regarding the aquaplane model. Influences of the thickness of water film, the texture of asphalt pavement, and the rolling speed of the tire on the vertical pavement-tire contact force are analyzed. It is found that the vertical contact force between open graded friction course (OGFC) pavement and tire is the highest, followed by stone mastic asphalt (SMA) pavement and dense graded asphalt concrete (AC) pavement surface. The vertical contact force between tire and pavement will be greatly reduced, even with increasing speed or water film thickness. As tire speed increases from 70 km/h to 130 km/h, the tire-pavement contact force is reduced by about 25%. Moreover, when the thickness of water film increases from 0 (dry condition) to 4 mm and then to 12 mm, the vertical contact force reduced 50% and 15%, respectively, compared with under the dry contact condition. This study provided a key theoretical reference for safe driving on wet pavements.

摘要

本研究使用ABAQUS 6.14软件建立了子午线轮胎-沥青路面相互作用的有限元模型,以研究部分轮胎水滑条件下沥青路面的抗滑性能。首先,将通过激光扫描获取的路面轮廓数据导入有限元分析(FEA)软件进行路面建模。其次,对三种类型的沥青路面在干燥条件下的轮胎稳态滚动进行了分析。研究了子午线轮胎在不同路面纹理、轮胎压力和轮胎载荷条件下,在不同路面上摩擦系数的变化规律。随后,将稳态滚动分析的计算结果传输到动态显式分析中,并通过输入流动欧拉网格建立了子午线轮胎在沥青路面上的水滑模型。针对该水滑模型,讨论了部分水滑条件下轮胎-路面的黏附特性。分析了水膜厚度、沥青路面纹理和轮胎滚动速度对路面-轮胎垂直接触力的影响。结果发现,开级配磨耗层(OGFC)路面与轮胎之间的垂直接触力最高,其次是沥青玛蹄脂碎石(SMA)路面和密级配沥青混凝土(AC)路面表面。即使速度或水膜厚度增加,轮胎与路面之间的垂直接触力也会大幅降低。当轮胎速度从70 km/h增加到130 km/h时,轮胎-路面接触力降低约25%。此外,当水膜厚度从0(干燥条件)增加到4 mm,再增加到12 mm时,与干燥接触条件相比,垂直接触力分别降低了50%和15%。本研究为湿滑路面上的安全驾驶提供了关键的理论参考。

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