A torsional vibration damper that damps torsional vibration effectively in a low-speed range. In the torsional vibration damper, a spring holder is formed by apertures of an input element and an output element, and an elastic member is held in the spring holder. A first moveable range of a planetary element extending from an initial position in a drive direction is wider than a second movable range of the planetary element extending from the initial position in a counter direction.

A torque transmission arrangement is provided with a clutch device which has a clutch input and output, and a vibration damping device having at least two vibration damping units arranged at a radial offset with respect to one another, an input of the vibration damping device operatively connected to the clutch output, and an output of the radially outermost vibration damping unit being operatively connected by an intermediate transmission element to an input of the radially innermost vibration damping unit operatively connected via an output of the vibration damping device to an output unit, the clutch device partially axially overlapping with one of the vibration damping units, and being connected radially between the two vibration damping units to the intermediate transmission of the vibration damping device. The intermediate transmission is connected to an absorber mass carrier of an absorber system likewise assigned to the vibration damping device.

A torque converter for a vehicle includes an annular housing. A turbine member is fluidically connected to the pump member. A lock-up clutch is selectively engaged between the annular housing and the turbine member. A lock-up clutch actuator is connected to the lock-up clutch. A cavity is defined between the annular housing and the turbine member. A first fluid circuit is fluidically connected to the pump member, the cavity and a first side of the lockup clutch actuator. The first fluid circuit delivers a fluid to engage the lock-up clutch actuator. A second fluid circuit is hydraulically connected to the pump member and the cavity. The second fluid circuit guide the fluid from the annular housing. A third fluid circuit is hydraulically connected to a second side of the lock-up clutch actuator. The third fluid circuit selectively delivers a pressurized fluid to release the lock-up clutch.

A clutch arrangement has a first pressure chamber for exerting load clutch piston and a second pressure chamber for accommodating clutch elements and for feeding fluid for cooling the clutch elements. A first clutch element is connected to a first clutch element carrier and a second clutch element is connected to a second clutch element carrier. The first clutch element carrier accommodates the clutch piston and the second clutch element carrier exerts load on a torsional vibration damper and radially encloses the clutch unit over part of its axial extent length. The clutch piston is equipped with a flow passage for flow connection between the two pressure chambers, and the first clutch element carrier has a flow passage which interacts with a flow-guiding element provided on the second clutch element carrier, that is oriented relative to the flow passage of the first clutch element carrier at an angle.

A clutch arrangement is formed with drive-side and, output-side clutch elements and a clutch piston for operative connection and disengagement between the drive-side and output-side clutch elements. Associated with at least two clutch elements is an elastically deformable clutch element working mechanism through which the corresponding clutch elements can be acted upon in direction away from one another by an axial force to assist disengagement of the drive-side and output-side clutch elements. The clutch element working mechanism provides a considerable change in the gradient of the axial force exerted on the clutch elements as a result of even a small change of shape of the clutch element working mechanism so that a sharply rising axial force of the clutch element working mechanism works against the clutch piston.

A hybrid drive module (1) for a motor vehicle includes a housing (GG), a torque converter (TC), and an electric machine with a rotor (R) and a stator (S). The rotor (R) is arranged on a rotor carrier (RT), which is fixedly connected to a hub (N). The hub (N) is rotatably supported via at least one first bearing (L1) and is supported in radial and axial directions against a bearing shield (LS). The hub (N) is rotationally fixed to a converter housing (TCH) of the torque converter (TC) via a rivet joint (RI) or a screw connection. A drive train for a motor vehicle including such a hybrid drive module (1) is also provided.

A vibration damping apparatus includes a support member configured to rotate together with a rotational element, a restoration force generating member coupled to the support member so as to transmit and receive a torque with the support member, an inertial mass coupled to the support member via the restoration force generating member, a first guide surface provided on the restoration force generating member, a second guide surface provided on the inertial mass, and a coupling member having first and second rolling portions. The first and second guide surfaces are formed so that the first rolling portion rolls along the first guide surface and the second rolling portion rolls along the second guide surface along with rotation of the support member to cause the restoration force generating member to swing relative to a rotation center of the rotational element along a radial direction of the support member and cause the inertial mass to swing about the rotation center.

A friction plate that is used in a friction engagement device configured to engage an input rotary member and an output rotary member with each other, the friction plate including a base plate having an annular plate shape; and a friction member provided on the base plate in a circumferential direction of the friction plate.

A torque converter for a vehicle includes an impeller, a turbine, a stator positioned between the impeller and the turbine, a one-way clutch coupled to the stator and configured to couple to a fixed member, and a controllable clutch assembly. The controllable clutch assembly is configured to selectively engage the stator and the turbine such that the stator is able to rotate with the turbine to facilitate preventing the stator from reacting against the one-way clutch and applying a load to the fixed member and thereby facilitating reducing an output of the torque converter and reducing engine vibration during idle, and disengage the stator from the turbine to enable relative rotation between the stator and turbine.

A damper device that includes an elastic body support provided to the intermediate element to support both end portions of the third elastic body at least when torque is not transferred between the input and the output; and an elastic body abutment provided to one of the input and the output, the elastic body abutment not abutting against an end portion of the third elastic body at least when torque is not transferred between the input and the output, but abutting against one of the end portions of the third elastic body as a relative torsional angle between the one of the input and the output and the intermediate element is increased when torque is transferred between the input and the output.