This clutch control device includes an engine (13), a transmission (21), a clutch device (26) configured to connect and disconnect motive power transmission between the engine (13) and the transmission (21), a clutch actuator (50) configured to drive the clutch device (26) and change a clutch capacity, a hydraulic circuit (63) provided between the clutch device (26) and the clutch actuator (50), an air bleeding device (64) configured to perform air bleeding of the hydraulic circuit (63), a control unit (60) configured to calculate a control target value of the clutch capacity, a control mode changeover switch (59) configured to enable a control mode of the control unit (60) to be switched to an air bleeding mode, and an air bleeding switch (65) configured to enable a hydraulic pressure of the hydraulic circuit (63) to increase in the air bleeding mode.

A clutch device includes a plurality of clutches; a plurality of cylinder chambers provided to respectively correspond to the clutches; a pump configured to discharge a hydraulic fluid; a plurality of control valves each of which is configured to control the hydraulic fluid supplied from the pump to a corresponding one of the cylinder chambers; and an oil passage that distributes the hydraulic fluid discharged from the pump, to the control valves. The oil passage includes at least one split point at which the hydraulic fluid discharged from the pump splits. At least one check valve is provided between the at least one split point and at least one control valve among the control valves, the at least one check valve being configured to block a flow of the hydraulic fluid in a direction from the at least one control valve toward the at least one split point.

The invention relates to an apparatus having a plurality of hydraulic actuators (S.sub.i) and a piston-cylinder unit (K), one working chamber (AK.sub.1) of which is connected, via at least one hydraulic connection line (HL) and supply lines (ZL.sub.i), to working chambers (AS.sub.i) of the hydraulic actuators (S.sub.i), wherein each working chamber (AS.sub.i) of a hydraulic actuator (S.sub.i) is connected to a supply line (ZL.sub.i) and switch valves (EV.sub.i) for selective opening and closing of the hydraulic supply lines (ZL.sub.i) are provided such that, in the opened position of the associated switch valve (EV.sub.i), a pressure change in the working chamber (AS.sub.i) of the actuator (S.sub.i) or an adjustment of the actuator (S.sub.i) can occur, wherein at least one pressure sensor (DS.sub.i) for determining the pressure in a working chamber (AS.sub.i) of an actuator (S.sub.i) or a hydraulic line (HL, ZL.sub.i, AL.sub.i) and a control device (ECU) is provided, characterized in that, for simultaneous pressure change in at least two actuators, (S.sub.i, S.sub.k), the (ECU) permanently opens the switch valve (EV.sub.i) associated with a first actuator (S.sub.i) during the pressure change phase and adjusts or regulates the pressure by adjusting the piston (KK) of the piston-cylinder unit (K), and in that the control device (ECU) adjusts or regulates the pressure in at least one additional actuator (S.sub.k) by means of the switch valve (EV.sub.k), which is clocked during the pressure change phase, and in particular is controlled by pulse width modulation.

A drive force transmission apparatus is mountable on a four-wheel drive vehicle switchable between a four-wheel drive mode that transmits a drive force of an engine to front wheels and rear wheels, and a two-wheel drive mode that transmits the drive force to only the front wheels. The drive force transmission apparatus allows adjustment of the drive force to the rear wheels, and includes a multi-plate clutch, a piston for axially pressing the multi-plate clutch, an actuator for axially moving the piston, and a control unit for controlling the actuator. Upon satisfaction of a predetermined condition that indicates a high probability of the vehicle needing to be switched from the two-wheel drive mode to the four-wheel drive mode, the control unit causes the actuator to displace the piston by a predetermined amount with respect to an initial position of the piston toward the multi-plate clutch.

The invention relates to a hydraulic circuit having a first hydraulically actuable clutch that is closed in a rest state and a second hydraulically actuable clutch that is closed in the rest state, wherein the hydraulic circuit is configured in such a way that a hydraulic medium present in a main pressure line can be loaded with a working pressure by a pressure generating device and/or a pressure accumulator, and the hydraulic medium can be discharged for pressure dissipation via a main return line into the return reservoir. In some embodiments, the hydraulic circuit has a first distributor pressure line and a separate, first collector return line for the hydraulic supply of a first part circuit and at least one separate, second distributor pressure line and at least one separate, second collector return line for the hydraulic supply of a second part circuit, and the first clutch is assigned to the first part circuit and the second clutch is assigned to the second part circuit.

A hydraulic control device with a pressure control valve that has a control piston and a modulating piston which can move relative to one another. The control piston and the modulating piston are pushed apart from one another by at least one spring. At one end face of the modulating piston there is arranged a pressure chamber in such a manner that when the pressure chamber is filled, the modulating piston is caused to move in the direction toward the control piston. The pressure chamber can be filled by a first volume flow Q1 of a pressure medium. A venting line, with at least one further throttle, is connected to the pressure chamber. A second volume flow Q2 can be discharged, via the venting line, from the pressure chamber, The hydraulic control device can be utilized in a marine transmission,

The presently disclosed invention is related to methods to launch and a launch control transmission brake comprising a block, an input port and an output port defined in the block, a fluid path connecting the input port and the output port, an electrically actuated valve along the fluid flow path that closes the fluid path when the electrically actuated valve is actuated, an input path being the flow path between the input port and the electrically actuated valve, an output path being the flow path between the output port and the electrically actuated valve, and an actuator that actuate the electrically actuated valve.

A hydraulic system includes a normally open-type hydraulic clutch which connects or disconnects a power transmission line between an engine and a wheel, an actuator which supplies a hydraulic pressure to the hydraulic clutch, an oil flow path which connects the actuator to the hydraulic clutch, a valve member which is provided on the oil flow path and which enables to switch between an open state where the oil flow path communicates and a closed state where the oil flow path closes, a hydraulic pressure sensor which is provided on the oil flow path, and a bypass flow path which bypasses the valve member. A one-way valve, which permits a supply of a hydraulic pressure from an actuator side to a hydraulic clutch side and which shuts off a supply of a hydraulic pressure from the hydraulic clutch side to the actuator side, is provided on the bypass flow path.

A dual-clutch actuator with a hydraulic pump, a first and second clutch hydraulic circuits and at least a first shift hydraulic circuit, the shift hydraulic circuit being connected to the hydraulic pump and has a control valve with a return connection. The first clutch hydraulic circuit is connected to the return connection and has a control valve. The second clutch hydraulic circuit is connected to the hydraulic pump and has a control valve. A drive assembly for a vehicle axle of a motor vehicle having an electric motor, a gearbox with an input which is connected to the electric motor, a first and a second gear and an output, a dual clutch arranged between the electric motor and the input of the gearbox, a synchronization assembly arranged between the first gear and the output of the gearbox and an actuator of this kind. The first shift hydraulic circuit is coupled with the synchronization assembly of the first gear.

A rotational system can include a shaft assembly rotationally coupling a first rotor, a second rotor, and a fluid pump. A fluid circuit can include the fluid pump that can be configured to motivate a working fluid through the fluid circuit. A pressurizing valve can be disposed downstream of the fluid pump wherein the rotational system can be configured to rotationally decouple the first rotor from the second rotor by closing the pressurizing valve. The pressurizing valve can be actuated by a controller. A method can include raising a pressure differential across a fluid pump driven by a shaft assembly thereby applying an increased braking torque to the shaft assembly. The pressure differential can be raised by actuating a valve in hydraulic communication with the fluid pump. The shaft assembly can rotationally couple a first rotor with a second rotor, and increasing the braking torque can decouple the rotors.