胎面单元对轮胎薄膜湿牵引性能的影响

在潮湿的天气或雨后，轮胎胎面或路面上存在一层很薄的水膜，该水膜使车辆行驶的牵引力降低。建立了轮胎胎面单元挤压膜问题的数学模型，并进行了数值求解，分析了胎面单元的几何参数，液膜厚度和柔性对轮胎薄膜湿牵引性能的影响，为轮胎胎面花纹的合理设计提供了理论依据。     

宏观形貌对沥青路面黏性滑水的影响分析

为研究宏观构造对潮湿沥青路面抗滑性能的影响,引入宏观形貌概率正态分布模型,构建潮湿路面-车轮相互作用下的动水压力解析方程及数值解算方法;并将分布模型与现行的路面抗滑指标MTD相联系。在此基础上,以黏性动水压力为基本指标,分析潮湿工况下, AC-13、SMA-13及OGFC-13这3类路型的路面抗滑性能。计算表明,潮湿路面薄层水膜条件下的黏性滑水不完全等同于积水路面条件下的惯性滑水,其胎下动水压分布沿行驶方向显现出非线性变化的特征,且在胎面临近完全接触区边界附近达到峰值后迅速衰减;同时,黏性滑水产生的承载力随行驶速度呈线性增长。另一方面,黏性滑水产生的动水压力与水膜厚度和路面构造深度的比值相关:当路面水膜厚度h在0～3σ之间,动水压力明显随水膜增厚而减小、随构造深度的增加而减小;当路面水膜厚度大于3σ或构造深度足够大时,水膜厚度和构造深度的影响将随之减弱。     

论轮胎与路面间的摩擦

对轮胎与路面间摩擦产生的机理和影响因素进行了分析。其中产生的机理可归纳为轮胎与路面间分子引力的作用、轮胎与路面间的粘着作用、胎面橡胶的弹性变形及路面上小尺寸微凸体的微切削作用四种；影响轮胎与路面间摩擦的主要因素有滑移率，轮胎类型，胎面花纹的类型、密度系数、深度，路面粗糙度，路面污染情况，路面水膜，气候及充气压力等。     

带复杂花纹的轮胎滑水显式动力学分析

以205/55R16型半钢子午线轮胎为参考轮胎,利用组合类保角映射簇建模法构建了3种不同胎面花纹的轮胎有限元分析模型.利用该模型进行载荷一下沉量及流体压力一行驶速度分析结果表明.轮胎有限元模型和骨架材料的等效简化方法以及滑水求解策略有效.在此基础上,考察了胎面花纹形态对轮胎滑水性能的影响.结果表明.S型轮胎和V型轮胎由于横向花纹沟的存在,滑水性能优于纵沟胎.     

胎面花纹对轮胎性能的影响

分析了胎面花纹对轮胎行驶性能、滚阻、磨耗、滑水和噪声特性的影响，介绍了通过胎面花纹设计提高轮胎性能的基本途经和方法。     

湿滑路面车辆防滑预警

湿滑路面是一种常见的行车环境,由于这种行车环境的特殊性,导致交通事故的发生率大为提高。针对湿滑路面轮胎临界滑水车速的研究,是一种帮助驾驶员降低发生交通事故的有效行径。影响湿滑路面临界滑水车速的条件有水膜厚度、行驶车速、轮胎状况等。为了更好保证驾驶员的生命和财产安全,通过对车辆进行防滑预警研究可以更为高效明了的为驾驶员安全驾驶提供保障。     

表面粗糙度对冰路面上滑动轮胎摩擦牵引力影响的研究

依据能量守恒定律和冰的摩擦熔化理论，考虑冰面和轮胎胎面的表面粗糙度，建立了摩擦界面冰完全熔化条件下轮胎的牵引力预测模型。给出了预测模型中接地胎面温度的选择原则。研究表明，该模型可较好地预测不同条件下轮胎在冰路面上的摩擦牵引力，表面粗糙度的影响随车辆行驶速度的提高而增大。     

抗滑水轮胎技术的新发展

轮胎在湿路面上的行驶性能关系到汽车的安全性。阐述了国外开发的三种新型抗滑水轿车轮胎的设计思想，结构特点以及主要性能，介绍了提高轮胎在潮湿带水路面上行驶性能的新技术及其新发展，对开发国产高性能轿车轮肥具有现实的参考借鉴意义。     

路面附着性能影响因素分析及其改善对策的研究

路面附着性能是决定汽车安全行驶的必要条件。影响轮胎与路面间附着性能的因素很多,主要包括轮胎、路面及汽车行驶状态等等。针对上述影响因素,分别对路面类型、路面状况、轮胎结构、胎面花纹及花纹深度、轮胎气压和车速等主要影响因素进行了深入分析,研究了各因素之间的内在联系和变化特点,揭示了各因素对路面附着性能的影响规律,并从路面和轮胎两个方面提出了改善轮胎与路面间附着性能的对策,从而提高汽车行驶的安全性。     

爱车穿“冬靴”行车稳

与一般夏季轮胎相比,冬季轮胎为了提高在冰雪路面上的抓地力,轮胎花纹和胎面橡胶有很大的不同。为了保证轮胎花纹能够抓住雪,冬季用轮胎比夏季胎花纹沟的宽度宽,且深度深,胎面橡胶采用了较为柔软的材质,进一步提高了在冰雪路面的抓地力,胎面柔软才能让轮胎在冰天雪地中拥有更好的抓地性能和较大的摩擦系数。与夏季轮胎或四季轮胎相比,冬季轮胎有更大的接地面积,特殊的技术处     

接地面全熔化条件下冰面轮胎摩擦力的预测

依据流体动力润滑理论和热平衡原理，提出了接地面全熔化条件下冰面轮胎摩擦力的预测模型。结果表明，受不同因素的影响，摩擦系数变化趋势的模型预测同实验结果极为相似，文中分析讨论了影响摩擦力的主要因素，认杰表面模型，滑移率和界面温升等的影响应作为今后相关领域的研究重点。     

轮胎／路面附着系数估算方法

为提高汽车主动安全系统自适应控制性能,需要对轮胎／路面附着系数进行精确的识别或估算。鉴于附着系数估计的复杂性,文章综述了目前路面附着系数估算中的汽车动力学建模和轮胎／路面摩擦模型建模,重点讨论了轮胎／路面附着系数识别算法中传感器的直接检测估计法,以及基于车辆动力学、回正力矩和状态观测器等动力学模型的估计算法,并对各估算方法存在的问题与发展趋势等进行了分析。对开发汽车主动安全电控系统和提高汽车产业核心竞争力具有重要意义。     

湿滑条件下基于真实纹理道面的机轮着陆滑水行为解析

湿滑条件下的着陆滑跑是航空事故的高发区。为较为真实地反映湿滑条件下机轮的滑跑行为，需要建立包含真实道面纹理特征的滑跑模型。在提取真实道面形貌特征的基础上，通过解析湿滑条件下的机轮滑跑行为进一步反算其遵循的摩擦关系，以获得更加接近真实条件的摩擦模型；然后运用欧拉-拉格朗日（CEL）算法建立基于真实纹理形貌特征的道面-水膜-轮组的流固耦合模型，以摩擦因数、动水压力为分析指标来探讨速度、滑移率、水膜厚度以及道面类型对机轮滑水行为的作用规律，进而为提高飞机着陆的安全性提供理论参考。研究结果表明：A320型飞机着陆可能滑漂的危险区段为刚刚着陆阶段，随着速度的降低，道面支撑力会逐渐增大，而动水压力将逐渐减小；随着滑移率的增加，动水压力呈现出先减小后增大的趋势，当滑移率为0.15时，动水压力达到最小；关于水膜厚度的影响，水膜厚度小于3 mm时不会发生滑漂，而水膜厚度大于10 mm时极可能发生滑漂；当水膜厚度为7 mm时动水压力与飞机滑行速度、滑移率的相关性较大，可视为机轮发生滑漂的临界状态；最后，在其他条件一致的情况下，各道面类型的抗滑性排序为SMA > OGFC > AC > 平滑道面。因此，湿滑条件下，控制飞机着陆的初始速度和滑移率是减小航空事故、提高机场安全运行的有力保障。     

用于不平路面车辆动力学仿真的轮胎模型综述

介绍了轮胎在不平路面的动力学特性。在回顾不平路面轮胎动力学模型发展的基础上，以近期的研究工作为重点，对用于不平路面车辆动力学仿真的轮胎模型进行了较为系统的介绍。概要地阐述了各种轮胎模型的建模理论、方法，并进行了分析和评述。最后，总结了不平路面轮胎力学建模的核心问题及发展方向，对不平路面车辆动力学仿真选择合适的轮胎模型给出了建议。     

轮胎位移包容性研究及有效路面谱计算方法

本文提出一种有效路形测量的新方法,研究轮胎的位移包容性。提出以轮胎包容参数为变量把真实路面功率谱变换为有效路面功率谱的新方法。该研究是道路激励模拟的基础研究。     

Vehicle Energy Dissipation Due to Road Roughness

Road roughness and surface texture are known to affect tire rolling resistance; however, little emphasis has been placed on the consequent changes in total vehicle energy dissipation due to road roughness. Thus, tire rolling resistance, in isolation from vehicle contributed losses such as dissipation in the suspension, appears to be a weakness in present evaluation procedures as they relate to fuel economy and pollution level testing: Recent work by Funfsinn and Korst has shown that substantial and measurable increases in energy losses occur for vehicles traveling on rough roads. The present investigation uses vehicle axle accelerations as a means of examining various road surfaces. Correlation with computer simulations has allowed the development of a deterministic road roughness model which permits the prediction of energy dissipation in both the tire and suspension as functions of road roughness, tire pressure, and vehicle speed. Comparison to the experiments of Korst and Funfsinn results in good agreement and shows that total rolling loss increases of up to 20 percent compared to ideal smooth roads are possible. The aerodynamic drag coefficient is also found to increase while driving on rough roads.     

Vehicle Energy Dissipation Due to Road Roughness

SUMMARY

Road roughness and surface texture are known to affect tire rolling resistance; however, little emphasis has been placed on the consequent changes in total vehicle energy dissipation due to road roughness. Thus, tire rolling resistance, in isolation from vehicle contributed losses such as dissipation in the suspension, appears to be a weakness in present evaluation procedures as they relate to fuel economy and pollution level testing: Recent work by Funfsinn and Korst has shown that substantial and measurable increases in energy losses occur for vehicles traveling on rough roads. The present investigation uses vehicle axle accelerations as a means of examining various road surfaces. Correlation with computer simulations has allowed the development of a deterministic road roughness model which permits the prediction of energy dissipation in both the tire and suspension as functions of road roughness, tire pressure, and vehicle speed. Comparison to the experiments of Korst and Funfsinn results in good agreement and shows that total rolling loss increases of up to 20 percent compared to ideal smooth roads are possible. The aerodynamic drag coefficient is also found to increase while driving on rough roads.     

汽车轮胎气压电子实时监测系统

轮胎气压不足,将增大轮胎的弯曲变形,加快轮胎的磨损,增大车轮的滚动摩擦阻力,从而导致油耗显著增加,特别是当汽车高速行驶时,更会削弱轮胎的承载能力,导致轮胎破裂漏气。以北美市场及德国BERU公司的产品为例,介绍了轮胎压力电子实时监测系统的技术和市场方面的最新发展趋势。     

The mechanisms involved during the wet braking of new and worn tires

ABSTRACT

Tires are used by the customers during several tens of thousands of kilometres, and before their replacement, the driver will encounter a continuous variation of tread depth due to the tire wearing. Although the wet braking labelling demonstrates the performance of the tire in the new stage, it is known that the wet traction evolves with tire wear. In this paper, an in-depth comparison of the wet grip performance of new and worn tires will be conducted, based on the regulatory wet braking test. For this purpose, we propose an original approach to analyse braking test results, which allows breaking down and quantifying the relative importance of the mechanisms involved during this test. This study demonstrates that two main mechanisms are taking place during the entire test: rubber friction and hydroplaning mechanisms. The µ value obtained at low speeds reflects the friction potential of the tested tires while the decline of performance at higher speeds is attributed to hydroplaning mechanisms. This analysis is conducted on numerous tires and demonstrates that current regulatory test applied on new tires is focussing mainly on the rubber friction mechanism. The same test applied on worn tires exhibits both rubber friction and hydroplaning mechanisms. The mechanisms decomposition shows that the source of the performance decline from new to worn status varies greatly, some tires having most of their performance loss due to hydroplaning, some others due to rubber friction drop.