Experimental Characterization of Wet Clutch Friction Behaviors Including Thermal Dynamics

V. Ivanović, J. Deur, Z. Herold, M. Hancock, F. Assadian

SAE paper #2009-01-1360, SAE International Journal of Engines, Vol. 2, No. 1, pp. 1211-1220

2009

This paper presents an adaptive extended Kalman filter (EKF)-based sideslip angle estimator, which utilizes a sensor fusion concept that combines the high-rate inertial sensors measurements with the low-rate GPS velocity measurements. The sideslip angle estimation is based on a vehicle kinematic model relying on the lateral accelerometer and yaw rate gyro measurements. The vehicle velocity measurements from low-cost, single antenna GPS receiver are used for compensation of potentially large drift-like estimation errors caused by inertial sensors offsets. Adaptation of EKF state covariance matrix ensures a fast convergence of inertial sensors offsets estimates, and consequently a more accurate sideslip angle estimate. By using a detailed simulation analysis, it is found out that the main sources of estimation errors include inaccuracies of pre-estimated vehicle longitudinal velocity obtained from nondriven wheel speed sensors, the GPS velocity signal latency, and the road bank-related disturbances. Several compensation methods are proposed to suppress the influence of these errors.

wet clutch; friction coefficient; thermal dynamics

Clutches Active Differentials Clutch ModelingModeling and Control of Active Differential Wet ClutchModeling of Automatic Transmission Wet Clutches Modeling of Active Differential Wet Clutch

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