With increasing level of complexity and automation in the area of automotive engineering, the simulation of safety relevant Advanced Driver Assistance Systems (ADAS) leads to increasing accuracy demands in the description of tyre contact forces. In recent years, with improvement in tyre simulation, the needs for coping with tyre temperatures and the resulting changes in tyre characteristics are rising significantly. Therefore, experimental validation of three different temperature model approaches is carried out, discussed and compared in the scope of this article. To investigate or rather evaluate the range of application of the presented approaches in combination with respect of further implementation in semi-physical tyre models, the main focus lies on the a physical parameterisation. Aside from good modelling accuracy, focus is held on computational time and complexity of the parameterisation process. To evaluate this process and discuss the results, measurements from a Hoosier racing tyre 6.0 / 18.0 10 LCO C2000 from an industrial flat test bench are used. Finally the simulation results are compared with the measurement data.
|Titel||Proceedings of CAR2017 Int. Congress of Automobile Transport and Engineering|
|Untertitel||Mobility Engineering and Environment|
|Herausgeber (Verlag)||IOP Publishing Ltd.|
|Publikationsstatus||Veröffentlicht - 8 Nov 2017|
Hackl, A., Scherndl, C., Hirschberg, W., & Lex, C. (2017). Experimental Validation of Various Temperature Models for Semi-Physical Tyre Model Approaches. in Proceedings of CAR2017 Int. Congress of Automobile Transport and Engineering : Mobility Engineering and Environment (Band 252, S. 1-8). Pitesti: IOP Publishing Ltd..