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This paper reports the results of a back-to-back comparison of the squeal and judder propensity of simple cast iron and siliconised carbon disk brake systems. A finite element simulation approach is used to predict the squeal propensity of the two systems based on the results of a complex eigenvalue analysis. These results which are validated by dynamometer noise tests carried out according to the SAE J2521 [1] standard procedure show that the siliconised carbon rotor is much less prone to squeal over the range of conditions considered. The combined experimental and numerical simulation approach is also applied to the problem of hot judder for the two rotors. The critical rotational speeds for hot spots to form are predicted to be an order of magnitude higher for the siliconised carbon rotor system. These results demonstrate the potential of the new carbon composite rotor material to reduce the occurrence of noise and vibration problems in automotive brakes.

Reducing exhaust emissions has been a major focus of research for a number of years since internal combustion engines (ICE) contribute to a large number of harmful particles entering the environment. As a way of reducing emissions and helping to tackle climate change, many countries are announcing that they will ban the sale of new ICE vehicles soon. Electrical vehicles (EVs) represent a popular alternative vehicle propulsion system. However, although they produce zero exhaust emissions, there is still concern regarding non-exhaust emission, such as brake dust, which can potentially cause harm to human health and the environment. Despite EVs primarily using regenerative braking, they still require friction brakes as a backup as and when required. Moreover, most EVs continue to use the traditional grey cast iron (GCI) brake rotor, which is heavy and prone to corrosion, potentially exacerbating brake wear emissions.

Aluminium alloys have been used extensively in the automotive industry to reduce the weight of a vehicle and improve fuel consumption which in turn leads to a reduction in engine emissions. The main aim of the current study is to replace the conventional cast iron rotor material with a lightweight alternative such as coated aluminium alloy. The main challenge has been to meet both the cost and functional demands of modern mass-produced automotive braking systems. A sensitivity analysis based on the Taguchi approach was carried out to investigate the effect of various parameters on the thermal performance of a typical candidate disc brake. Wrought aluminium disc brake rotors coated with alumina on the rubbing surfaces were determined to have the best potential for replacing the conventional cast iron rotor at reasonable cost. Optimisation of the structure was subsequently carried out using a genetic algorithm on the selected coated aluminium disc brake rotor.