One of the main problems in high-speed-train transportation systems is related to the current collection quality, that can dramatically decrease because of oscillations of the pantograph-catenary system. This problem has been addressed by means of active pantographs. In this paper we present some results about the possible implementation of variable structure control (VSC) techniques on a wire-actuated symmetric pantograph. Such an actuator was suggested in the literature as a viable solution to build an active pantograph by modifying a passive pantograph currently used by Italian railways. The use of VSC with sliding modes was considered in order to cope with the system uncertainties due to the overhead suspended catenary. Recent results about the frequency-based analysis of VSC systems featuring second-order sliding modes are exploited to avoid the performance-destroying effect of the resonant wire actuator and to get a continuous control force without using observers. We show by simulations that the contact force results to be very close to the desired set-point also in the presence of measurement noise.
Contact Force Regulation in Wire-Actuated Pantographs Via Variable Structure Control
PISANO, ALESSANDRO;USAI, ELIO
2007-01-01
Abstract
One of the main problems in high-speed-train transportation systems is related to the current collection quality, that can dramatically decrease because of oscillations of the pantograph-catenary system. This problem has been addressed by means of active pantographs. In this paper we present some results about the possible implementation of variable structure control (VSC) techniques on a wire-actuated symmetric pantograph. Such an actuator was suggested in the literature as a viable solution to build an active pantograph by modifying a passive pantograph currently used by Italian railways. The use of VSC with sliding modes was considered in order to cope with the system uncertainties due to the overhead suspended catenary. Recent results about the frequency-based analysis of VSC systems featuring second-order sliding modes are exploited to avoid the performance-destroying effect of the resonant wire actuator and to get a continuous control force without using observers. We show by simulations that the contact force results to be very close to the desired set-point also in the presence of measurement noise.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.