Abstract
Friction between tire and pavement surface—also referred to as skid resistance in pavement engineering—is a complex phenomenon depending on many influencing parameters like speed, load or wetness of the surface as well as different effects like hysteresis and adhesion. Two different friction model approaches are used in this chapter, a microscale analytical model with special focus on microtexture influence and a multi-scale FE model considering both micro- and macrotexture wavelengths. Both approaches employ a generalized Maxwell model as material formulation for the tire rubber. Real and virtual textures of asphalt surfaces are replicated by 3D SLM printing on stainless steel plates. The virtual texture samples—which are still based on real asphalt surfaces—comprise pure microtextures (without macrotexture elements after filtering) and artificial combinations of sinusoidal waves with two different wavelengths. The printed surfaces are investigated by texture measurements for printing discrepancies with respect to the templates. Friction is measured with a linear friction test rig on these printed samples as well as on a real asphalt surface in dry and wet conditions. The measurements are used for calibration and validation issues by comparing them to the model calculations in wet and dry surface conditions.
Funded by the German Research Foundation (DFG) under grants KA 1163/30, RE 1620/4 and EC 412/1.
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References
https://tu-dresden.de/bu/bauingenieurwesen/sdt/forschung/for2089/download
Carbone, G., Putignano, C.: A novel methodology to predict sliding and rolling friction of viscoelastic materials: theory and experiments. J. Mech. Phys. Solids 61, 1822–1834 (2013)
Friederichs, J., Wegener, D., Eckstein, L., Hartung, F., Kaliske, M., Götz, T., Ressel, W.: Using a new 3D-printing method to investigate rubber friction laws on different scales. Tire Sci. Technol. 48, 250–286 (2020)
Gebhard, A.: Rapid prototyping: Werkzeuge für die schnelle Produktentwicklung, pp. 21–28. Hanser Fachbuchverlag, Munich pp (2000)
Hartung, F., Kienle, R., Götz, T., Winkler, T., Ressel, W., Eckstein, L., Kaliske, M.: Numerical determination of hysteresis friction on different length scales and comparison to experiments. Tribol. Int. 127, 165–176 (2018)
Kanafi, M.M., Tuononen, A.J.: Application of three-dimensional printing to pavement texture effects on rubber friction. Road Mater. Pavement Des. 18, 865–881 (2017)
Kienle, R., Ressel, W., Götz, T., Weise, M.: The influence of road surface texture on the skid resistance under wet conditions. Proc. Inst. Mech. Eng. Part J: J. Eng. Tribol. 234, 313–319 (2020)
Lorenz, B., Oh, Y., Nam, S., Jeon, S., Persson, B.: Rubber friction on road surfaces: experiment and theory for low sliding speeds. J. Chem. Phys. 142, 194701 (2015)
Meiners, W.: Direktes Selektives Laser Sintern einkomponentiger metallischer Werkstoffe. Ph.D. thesis, RWTH Aachen (1999)
Mooney, M.: A theory of large elastic deformation. J. Appl. Phys. 11, 582–592 (1940)
Persson, B.N.: Theory of rubber friction and contact mechanics. J. Chem. Phys. 115, 3840–3861 (2001)
Weise, M.: Einflüsse der mikroskaligen Oberflächengeometrie von Asphaltdeckschichten auf das Tribosystem Reifen-Fahrbahn. PhD thesis, Institute for Road and Transport Science, Universität Stuttgart (2015)
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Friederichs, J. et al. (2021). Numerical Friction Models Compared to Experiments on Real and Artificial Surfaces. In: Kaliske, M., Oeser, M., Eckstein, L., Leischner, S., Ressel, W., Wellner, F. (eds) Coupled System Pavement - Tire - Vehicle. Lecture Notes in Applied and Computational Mechanics, vol 96. Springer, Cham. https://doi.org/10.1007/978-3-030-75486-0_7
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