An accumulator piston configured to be situated within an accumulator bore of a housing for use in vehicle transmissions. The accumulator piston including a casing, the casing including a top surface, a bottom surface opposite the top surface, and a side wall situated between the top surface and the bottom surface, a pin guide protruding from the top surface of the casing, the pin guide including a centrally disposed aperture, the aperture configured to receive an elongated pin, and a sealing member encircling the side wall of the casing such that the sealing member covers any exposed surface of the side wall.

A P2 transmission and engine assembly includes a transverse mounted transmission having: a transmission first end and a transmission second end oppositely positioned with respect to the transmission first end; and a transmission gearbox portion having a first cavity positioned at the second end. A torque converter is positioned at the transmission first end. An electric motor is positioned within the first cavity and is rotatably connected to the torque converter using a turbine shaft. A one-way clutch is connected to the turbine shaft and releasably connects the turbine shaft to the torque converter. The one-way clutch when disengaged disconnects the torque converter from the turbine shaft.

A shipping strap for a hybrid module includes a first annular surface, a second annular surface, and a central bore. The first annular surface includes a first orifice for receiving a first fastener for fixing the shipping strap to a hybrid module housing, or receiving a dowel pin for radially positioning the shipping strap relative to the hybrid module housing. The second annular surface includes a second orifice for receiving a second fastener for securing the shipping strap to a rotor for an electric machine to axially position the rotor in the hybrid module housing. In some example embodiments, the shipping strap has a through bore aligned with the central bore, and a lifting element installed in the central bore for installing the hybrid module in a multi-speed transmission. In an example embodiment, the lifting element is installed in the central bore by a threaded connection.

A cone-pulley flexible transmission is disclosed that comprises a first shaft having a first cone-pulley pair and a second shaft having a second cone-pulley pair. The first and second cone-pulley pairs each have a first cone pulley movable in an axial direction and a second cone pulley stationary in the axial direction. A flexible transmission means may be arranged between the first and second cone-pulley pairs for torque transmission. The first and second shafts may be rotatably supported by a bearing. The bearing of the first shaft or the second shaft may be a fixed bearing. The fixed bearing may include an inner bearing ring arranged on an outer circumferential surface of a corresponding shaft and an outer bearing ring fastened to a transmission housing by a sleeve extending through a wall of the transmission housing.

An automatic transmission according to one aspect of the present invention includes: a transmission mechanism including a rotational element; a valve body configured to control the transmission mechanism; an electronic control unit configured to perform electronic control of the valve body; and a transmission casing in which the transmission mechanism, the valve body, and the electronic control unit are arranged. The electronic control unit is formed such that an inner peripheral surface of the electronic control unit extends in a circumferential direction along an outer peripheral surface of the transmission mechanism.

An output shaft support structure includes: an output shaft; and a supporting body that supports the output shaft, the output shaft including: a rotating shaft; a first rolling bearing fixed to one end section of the rotating shaft; a second rolling bearing fixed to the other end section of the rotating shaft; and a secondary reduction driven gear including a boss section fixed to the rotating shaft. For a predetermined period, the boss section of the secondary reduction driven gear contacts the second rolling bearing, and a lower end of the rotating shaft is always separated from the supporting body.

A breather device for a casing structure of a vehicular power transmitting system including an electric motor and a transmission, the casing structure having motor and transmission accommodating casings, the breather device including first and second breather apertures formed in communication with inside spaces, and a breather outlet communicating with an outside atmosphere outside the casings, the first and second breather apertures permitting flows of air from the inside spaces within the casings, into the outside atmosphere through the breather outlet, to prevent an excessive rise of air pressures within the inside spaces, the breather device including a communication conduit for communication between the first and second breather apertures, and a single breather conduit held in communication at one of its opposite ends with the communication conduit and at the other end with the breather outlet, whereby the inside spaces are open to the outside atmosphere.

A dual clutch transmission arrangement (4) includes a first clutch (K1) and a second clutch (K2) for connecting a drive unit (2) to a first sub-transmission and to a second sub-transmission. The first clutch (K1) is connected to both transmission input shafts. A motor vehicle with the dual clutch transmission arrangement (4) is also provided.

An accumulator piston configured to be situated within an accumulator bore of a housing for use in vehicle transmissions. The accumulator piston including a casing, the casing including a top surface, a bottom surface opposite the top surface, and a side wall situated between the top surface and the bottom surface, a pin guide protruding from the top surface of the casing, the pin guide including a centrally disposed aperture, the aperture configured to receive an elongated pin, and a sealing member encircling the side wall of the casing such that the sealing member covers any exposed surface of the side wall.

The invention relates to a method for assembling a clutch control unit (30; 30a; 50; 50a) in a transmission clutch housing (24; 31) of a vehicle, the method comprising the steps of coupling the clutch control unit (30; 30a; 50; 50a) to the transmission clutch housing (24; 31) by a first guide means (33) comprising a first pin (34; 34a; 54; 54a) and a first slot (35; 35a; 55; 55a); coupling the clutch control unit (30; 30a; 50; 50a) to the transmission clutch housing (24; 31) by a second guide means (36) comprising a second pin (37; 37a; 57; 57a) and a second slot (38; 38a; 58; 58a); and displacing the clutch control unit (30; 30a; 50; 50a) from a first position at least partially outside the transmission clutch housing (24; 31) to an operative second position within the transmission clutch housing (24; 31); wherein the clutch control unit (30; 30a; 50; 50a) is guided by the first and second guide means (33; 36) along a predetermined path during the displacement between the first position and the second position.