Abstract: A method for optimizing a power requirement of a motor vehicle that includes a speed control system for a drive unit and a temperature control system for a cooling circuit of the drive unit. A first power requirement of the drive unit to be expected and a second power requirement of the cooling circuit to be expected are determined based on at least one route parameter. A driving strategy corresponding to the route parameter is initially selected, and the first power requirement corresponding to the driving strategy and the second power requirement corresponding to the driving strategy are determined. Based on the determined first and second power requirements, the driving strategy is then adjusted in such a way that an overall power requirement of the motor vehicle is minimized.

Abstract: A drive train control arrangement for a motor vehicle drive train includes a main drive train, a first drive axle permanently driven by the main drive train, an auxiliary drive train and a second drive axle coupleable to the main drive train via the auxiliary drive train, which has a first clutch unit and a second clutch unit connected downstream in the power train of the first clutch unit for connecting the second drive axle to the main drive train, and a control unit, which in at least one operating mode that closes the at least one second clutch unit of the auxiliary drive train to shift into a standby operating mode when a defined operating condition is present, and with the standby operating mode activated, closes the first clutch unit of the auxiliary drive train to connect the coupleable second drive axle depending on at least one parameter.

Abstract: A method for optimizing a power requirement of a motor vehicle that includes a speed control system for a drive unit and a temperature control system for a cooling circuit of the drive unit. A first power requirement of the drive unit to be expected and a second power requirement of the cooling circuit to be expected are determined based on at least one route parameter. A driving strategy corresponding to the route parameter is initially selected, and the first power requirement corresponding to the driving strategy and the second power requirement corresponding to the driving strategy are determined. Based on the determined first and second power requirements, the driving strategy is then adjusted in such a way that an overall power requirement of the motor vehicle is minimized.

Abstract: A drive train control arrangement for a motor vehicle drive train includes a main drive train, a first drive axle permanently driven by the main drive train, an auxiliary drive train and a second drive axle coupleable to the main drive train via the auxiliary drive train, which has a first clutch unit and a second clutch unit connected downstream in the power train of the first clutch unit for connecting the second drive axle to the main drive train, and a control unit, which in at least one operating mode that closes the at least one second clutch unit of the auxiliary drive train to shift into a standby operating mode when a defined operating condition is present, and with the standby operating mode activated, closes the first clutch unit of the auxiliary drive train to connect the coupleable second drive axle depending on at least one parameter.

Abstract: In a drive train control arrangement for a motor vehicle drive train, which comprises at least one main drive train, a first drive axle driven permanently by means of the main drive train, at least one auxiliary drive train and a second drive axle coupleable to the main drive train via the auxiliary drive train, which has a first clutch unit and at least a second clutch unit connected downstream in the power train of the first clutch unit for connecting the second drive axle to the main drive train, and a control unit, which in at least one operating mode closes the at least one second clutch unit of the auxiliary drive train to shift into a standby operating mode when a defined operating condition is present, and with the standby operating mode activated, closes the first clutch unit of the auxiliary drive train to connect the coupleable second drive axle depending on at least one parameter.

Abstract: A vehicle wheel bearing apparatus that protects the encoder, improves the sensing ability of the detecting sensor, prevents penetration of rain water or dust, and prevents leakage of differential gear oil has an inboard side seal (13) with an annular supporting plate (17a) fit onto the outer circumferential surface of one of the inner rings (10). A purser ring (17), having an encoder (17b), is bonded on the outer circumferential surface of the supporting plate (17a). A sealing plate (16), including an annular core member (18 and 22), is fit onto one end of the outer member (4) and covers the cylindrical portion of the encoder (17b). A lip (19a) is bonded on the core member (18 and 22) and is in sliding contact with the inner ring (10). A detecting sensor (20) is suspended from an axle housing “H” and opposes the encoder (17b) via a predetermined radial gap.