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Tire ABS-Braking Prediction with Lab Tests and Friction Simulations

Ignatyev, Pavel A. ; Ripka, Stefan ; Mueller, Norbert ; [et al.]

The Tire Society ; 2015

In: Tire Science and Technology Vol. 43, No. 4 ( 2015-10-01), p. 260-275

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In: Tire Science and Technology, The Tire Society, Vol. 43, No. 4 ( 2015-10-01), p. 260-275

Abstract: The invention and application of antilock braking systems (ABS) has resulted in a significant improvement of traffic safety and a reduction of stopping distance, especially on wet roads [1]. The reason for this success is rather clear: ABS is designed to steer the braking process in the most efficient way by keeping an optimal level of tire slip. At the same time, it must be clear that ABS uses braking forces generated in the tire footprint, and really good braking is possible only with high-performance tires. The best way to probe tire performance is to build tires and test them. This is, however, a long and an expensive procedure, so prediction of ABS performance based on results of some simple experiments is a very attractive supplement to the development process. Tire-braking performance is related to the friction of rubber on a surface. Relevant friction mechanisms can include adhesion, rubber hysteresis, and various kinds of viscous friction. All of these phenomena depend on the local sliding velocity, load, and temperature of tread rubber. Tire blocks pass the footprint area of a braking tire very rapidly, but their dynamics are indeed influenced by ABS. All of these aspects make the problem of ABS-braking prediction very intricate. In this publication, we present an approach for prediction of the ABS-braking performance. The approach links friction measurements conducted in laboratory to tire tests results. The friction of six specially designed compounds was measured on dry and wet surfaces using a high-speed linear friction test rig. Obtained experimental results are analyzed with the aid of rubber friction theory [2,3] involving both surface and rubber as input parameters. It is demonstrated that lab friction test procedures can be used for prediction of ABS wet braking performance.

Type of Medium: Online Resource

ISSN: 1945-5852 , 0090-8657

URL: Article

DOI: 10.2346/tire.15.430401

Language: English

Publisher: The Tire Society

Publication Date: 2015

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Beam model for tyre tread block dynamics

Zimmermann, Martin ; Ripka, Stefan ; Kühbach, Nico ; [et al.]

Inderscience Publishers ; 2013

In: International Journal of Vehicle Noise and Vibration Vol. 9, No. 3/4 ( 2013), p. 312-

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In: International Journal of Vehicle Noise and Vibration, Inderscience Publishers, Vol. 9, No. 3/4 ( 2013), p. 312-

Type of Medium: Online Resource

ISSN: 1479-1471 , 1479-148X

URL: Article

DOI: 10.1504/IJVNV.2013.055812

Language: English

Publisher: Inderscience Publishers

Publication Date: 2013

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Simulation of a siped tire tread block by an Euler‐Bernoulli beam

Ripka, Stefan ; Wangenheim, Matthias

Wiley ; 2009

In: PAMM Vol. 9, No. 1 ( 2009-12), p. 531-532

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In: PAMM, Wiley, Vol. 9, No. 1 ( 2009-12), p. 531-532

Abstract: Winter tires earn more and more attention due to the increasing awareness of safety aspects also in emerging markets like Russia and China. Besides the rubber compound the siped geometry of the tread blocks is essential. The mechanical behaviour of sliding lamellas is modeled with the beam theory of Euler–Bernoulli. In this contribution the siped tread block model will be experimentally verified and first simulation results will be presented. (© 2009 Wiley‐VCH Verlag GmbH & Co. KGaA, Weinheim)

Type of Medium: Online Resource

ISSN: 1617-7061 , 1617-7061

URL: Issue

URL: Article

DOI: 10.1002/pamm.v9:1

DOI: 10.1002/pamm.200910238

Language: English

Publisher: Wiley

Publication Date: 2009

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Experimental Friction and Temperature Investigation on Aircraft Tires

Linke, Tim ; Wangenheim, Matthias ; Lind, Hagen ; [et al.]

The Tire Society ; 2014

In: Tire Science and Technology Vol. 42, No. 3 ( 2014-07-01), p. 116-144

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In: Tire Science and Technology, The Tire Society, Vol. 42, No. 3 ( 2014-07-01), p. 116-144

Abstract: For modeling an aircraft tire using the brush model method, the friction coefficient μ between rubber and asphalt should not only be described in terms of the applied pressure and sliding velocity/slip ratio, but also by local temperature inside the contact area. Its influence cannot be neglected, since it leads to significant material property changes. Therefore, investigations on different test rigs are analyzed using thermal recordings of an infrared camera. First measurements are done on a high speed linear tester (HiLiTe), a test rig at the Institute of Dynamics and Vibration Research (IDS) at Leibniz University Hanover, Germany. It allows testing single tread block samples with a constant slip ratio of 100%, that is, pure sliding, on a variety of surfaces such as dry and wet asphalt or concrete, as well as on snow and ice. Results in this paper show that the convection has a smaller impact on tread block cooling than the actual contact between runway surface and sample. Since colder surface temperatures lead to higher friction, this effect antagonizes the excitation frequency, which heats up the rubber sample at high velocities. On long-lasting test sequences a quasi–steady-state friction coefficient might be achieved once these effects start to converge. Still, owing to permanent slip, the abrasion leads to cooling as the hot top layer of the rubber is removed occasionally. In addition to these quasi–steady-state measurements on HiLiTe, the thermal behavior of an aircraft tire is investigated with an autonomously running test rig. It allows realistic testing on an airfield runway by altering load, speed, and slip angle of the tire within and beyond the regions of a passenger aircraft. During the measurements, new and partially unknown effects could be observed. The temperature is mostly influenced by the slip angle followed by speed and load. Furthermore, the contact between tire and runway leads to cooling of the tread but does not affect the temperature inside the grooves. They heat up separately and tend to transfer heat to the tread if the cooling by the runway becomes too low.

Type of Medium: Online Resource

ISSN: 1945-5852 , 0090-8657

URL: Article

DOI: 10.2346/tire.14.420301

Language: English

Publisher: The Tire Society

Publication Date: 2014

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