Your search keyword '"Österle W"' showing total 3 results

1. Sliding Simulation of Automotive Brake Primary Contact with Variable Amounts of Copper and Graphite Nanoparticles.

Author

Dmitriev, A. I. and Österle, W.

Subjects

*AUTOMOBILE brakes, *GRAPHITE crystallography, *NANOPARTICLES, *PARTICLE dynamics analysis, *CELLULAR automata

Abstract

Copper is one of the most important components in brake pads and its amount can reach up to 14%. In spite of a number of positive features copper usage in brake pad formulations has recently become the subject of considerable discussions, primarily due to concerns about potential risks related to environmental impacts of copper particles. So, for developing new pad formulations with possible replacements of copper content, it is very important to understand the functionality of copper additions to brake friction materials. In the paper theoretical investigation of the role of copper as a pad ingredient was carried out on the basis of modelling by the method of movable cellular automata (MCA). In the study the concentration of copper particles in a Fe3O4-matrix was varied. The sliding simulations were performed while assuming material properties at 500°C in order to assess the beneficial role of copper during severe braking conditions corresponding to fading cycles during dynamometer testing. [ABSTRACT FROM AUTHOR]

Published

2016

2. Tribological screening tests for the selection of raw materials for automotive brake pad formulations.

Author

Österle, W., Deutsch, C., Gradt, T., Orts-Gil, G., Schneider, T., and Dmitriev, A.I.

Subjects

*TRIBOLOGY, *AUTOMOBILE brakes, *RAW materials, *LUBRICATION & lubricants, *NANOPARTICLES, *IRON oxides, *BALL mills

Abstract

Abstract: A modified pin-on-disc test was applied to determine tribological properties of typical brake pad constituents. Ball-milling of these ingredients together with iron oxide and graphite provided model materials displaying the main features of real third bodies. Solid lubricants like graphite affected the friction and wear behaviour of Fe3O4 powders considerably whereas further addition of hard nanoparticles induced only minor effects. This was corroborated by comparison with modelling results. MoS2 played a dual role. Depending on special conditions, this ingredient either reduced or increased friction. The latter could be explained, after nanoscopic characterization, by oxidation and destruction of the wear-protecting tribofilm. [Copyright &y& Elsevier]

Published

2014

3. Modelling the Sliding Behaviour of Tribofilms Forming During Automotive Braking: Impact of Loading Parameters and Property Range of Constituents.

Author

Dmitriev, A. and Österle, W.

Subjects

*SLIDING friction, *TRIBOLOGY, *AUTOMOBILE brakes, *CELLULAR automata, *SIMULATION methods & models, *MAGNETITE, *TEMPERATURE effect

Abstract

The impact of pressure, sliding velocity and property variation of constituents on the sliding behaviour of a model tribofilm was studied with the method of movable cellular automata (MCA). Whereas a clear pressure dependency of the coefficient of friction (COF) was always observed and could be correlated with the structure formation in terms of varying thickness of a mechanically mixed layer, the impact of the other parameters was either negligible or rather weak. Only if a brittle-to-ductile transition of the oxide-based tribofilm was assumed, a significant decrease in the COF level was predicted. Temperature-dependent property changes can be neglected during MCA modelling, unless this transition takes place. For magnetite-based tribofilms, the transition temperature is beyond 800°C, i.e. a temperature leading to fading effects during braking anyway. Thus, it could be concluded that, except for very severe braking conditions, sliding simulations with the MCA method yield meaningful results without considering temperature-dependent mechanical properties. [ABSTRACT FROM AUTHOR]

Published

2014