轮胎成型模型复杂性对高频模拟的影响

IF 0.9 Q4 ENGINEERING, MECHANICAL

Tire Science and Technology Pub Date : 2024-06-04 DOI:10.2346/tst-22-014

Girish Radhakrishnan, Zakariás Erősdi, Claude Rouelle

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引用次数: 0

摘要

赛车轮胎在转弯时会承受高速和高垂直负荷。当轮胎驶过高频率、低振幅的弯道时，也会承受极大的压力，往往会导致轮胎故障。D. C. Davis 和 P. W. A. Zegelaar 的研究和开发表明，当轮胎驶过高频率、低振幅和短波长的障碍物时，轮胎会表现出障碍物包围特性。轮胎在这种障碍物上的反应包括垂直力变化、纵向力变化和转速变化。此外，这种路面输入会激发包括高频模式在内的轮胎带动力学。因此，单接触点模型已不足以预测轮胎在此类障碍物上的响应。为了更好地捕捉轮胎包覆障碍物的行为，人们开发了先进的接触点模型，如 P. W. A. Zegelaar 的串联凸轮模型、J. M. Badalmenti 和 G. R. Davis Jr. 的径向-径向弹簧模型以及 S. Gong 的柔性环模型。为了捕捉高频轮胎带动力学，P. W. A. Zegelaar 开发了刚性环模型。之前的工作将刚性环模型与串联凸轮模型相结合，以捕捉障碍物包围行为和高达 60-100 Hz 的轮胎带动力学。本文对不同的轮胎与路面接触模型进行了比较研究，以模拟赛道上常见的高频路缘。本文选择了保罗-里卡尔赛道辛格弯的弯道轮廓进行模拟，因为众所周知，该弯道对轮胎的要求极高，经常导致轮胎故障。先进的四轮模型用于模拟高速行驶的赛车。创建了量化轮胎对这些高频弯道响应的指标，并进行了一项调查，以量化轮胎模型复杂性对指标的影响。

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Influence of Tire-Enveloping Model Complexity on High-Frequency Simulations

Race tires are subject to high speeds and high vertical loads during cornering. They are also subject to extreme stress when they are driven over high-frequency and low-amplitude curbs, often leading to tire failures. Research and development by D. C. Davis and P. W. A. Zegelaar has shown that when the tire moves over high-frequency, low-amplitude, and short-wavelength obstacles, it exhibits obstacle-enveloping properties. Tire response over such obstacles includes vertical force variation, longitudinal force variation, and rotational speed variation. Additionally, such road inputs excite tire belt dynamics that include high-frequency modes. Therefore, a single-contact-point model is no longer sufficient to predict tire response over such obstacles. To better capture the tire obstacle-enveloping behavior, advanced contact patch models such as the tandem-cam model by P. W. A. Zegelaar, the radial–interradial spring model by J. M. Badalmenti and G. R. Davis Jr., and the flexible ring model by S. Gong have been developed. To capture high-frequency tire belt dynamics, the rigid-ring model has been developed by P. W. A. Zegelaar. Previous work combines the rigid-ring model with the tandem-cam model to capture obstacle-enveloping behavior and tire belt dynamics up to 60–100 Hz. This paper presents a comparative study of different tire–road contact models to simulate high-frequency curbs typically found at racetracks. The curb profile of the Singes corner at the Paul Ricard racetrack is chosen for simulations as it is known to be extremely demanding on the tires, often causing failures. An advanced four-wheel model is used to simulate a race car at high speeds. Metrics to quantify the tire response over these high-frequency curbs are created and an investigation is conducted to quantify the influence of tire model complexity on the metrics.

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来源期刊

Tire Science and Technology ENGINEERING, MECHANICAL-

CiteScore

2.10

自引率

0.00%

发文量

期刊介绍： Tire Science and Technology is the world"s leading technical journal dedicated to tires. The Editor publishes original contributions that address the development and application of experimental, analytical, or computational science in which the tire figures prominently. Review papers may also be published. The journal aims to assure its readers authoritative, critically reviewed articles and the authors accessibility of their work in the permanent literature. The journal is published quarterly by the Tire Society, Inc., an Ohio not-for-profit corporation whose objective is to increase and disseminate knowledge of the science and technology of tires.