A variable compression ratio device may include a connecting rod having a large end portion link-connected to a crankshaft and a small end portion link-connected to a piston by a piston pin, an eccentric cam rotatably installed at the small end portion of the connecting rod and at which the piston pin eccentrically passes through a rotation center, and an low-pressure outer plate and an high-pressure outer plate engaged with both side surfaces of the eccentric cam, formed to partially protrude outward, and selectively engaged with the connecting rod according to a compression ratio. In addition, the low-pressure outer plate and the high-pressure outer plate are selectively engaged with the connecting rod by a controller according to a supply direction of a hydraulic pressure.

A variable compression ratio device may include a connecting rod having a large end portion link-connected to a crankshaft and a small end portion link-connected to a piston by a piston pin, an eccentric cam rotatably installed at the small end portion of the connecting rod and at which the piston pin eccentrically passes through a rotation center, and an low-pressure outer plate and an high-pressure outer plate engaged with both side surfaces of the eccentric cam, formed to partially protrude outward, and selectively engaged with the connecting rod according to a compression ratio. In addition, the low-pressure outer plate and the high-pressure outer plate are selectively engaged with the connecting rod by a controller according to a supply direction of a hydraulic pressure.

This exhaust cam shaft (2) is provided with a shaft part (5) and cam parts (6 to 13) provided on the outer circumference of the shaft part (5). The shaft part (5) has holes (16, 17, 19) opened at predetermined positions on the outer circumferential surface of the shaft part (5). The holes (16, 17, 19) are formed so as to be gradually tapered from an outside of the shaft part (5) toward a center of the shaft part (5) in a radial direction.

An apparatus for axially adjusting a shifting element includes a shifting shaft, which can be rotated about an axis, an actuating body, which is connected to the shifting shaft for conjoint rotation and in an axially movable manner and which has at least two slotted guide sections designed as grooves on a peripheral surface, and a linear actuator, which is associated with the actuating body and has an actuatable actuator pin, which can engage in the slotted guide sections in order to axially move the actuating body. Each slotted guide section has an incoupling region for the actuator pin, an opposite outcoupling region for the actuator pin, and an adjusting region, which lies therebetween in the peripheral direction and is bent in a curved shape, for axially moving the actuating body. The incoupling region and the outcoupling region of the slotted guide sections that are adjacent in the peripheral direction are arranged at the same axial position.

An apparatus for axially adjusting a shifting element includes a shifting shaft, which can be rotated about an axis, an actuating body, which is connected to the shifting shaft for conjoint rotation and in an axially movable manner and which has at least two slotted guide sections designed as grooves on a peripheral surface, and a linear actuator, which is associated with the actuating body and has an actuatable actuator pin, which can engage in the slotted guide sections in order to axially move the actuating body. Each slotted guide section has an incoupling region for the actuator pin, an opposite outcoupling region for the actuator pin, and an adjusting region, which lies therebetween in the peripheral direction and is bent in a curved shape, for axially moving the actuating body. The incoupling region and the outcoupling region of the slotted guide sections that are adjacent in the peripheral direction are arranged at the same axial position.

A method for positioning a cam element on a shaft segment of a camshaft with an assembly aid element may comprise arranging the shaft segment relative to a first tool such that a first distal shaft segment end of the shaft segment lies flush against a surface of the tool that is directed towards the shaft segment; arranging the cam element on the shaft segment in a pre-position; arranging a first distal end of the assembly aid element to contact the surface of the first tool that is directed towards the shaft segment such that the assembly aid element forms a defined distance to the first tool along a shaft-segment longitudinal axis; and moving a second tool at least in sections along the longitudinal axis until the second tool contacts a second distal end of the assembly aid element, and pushing the cam element by means of the second tool to a final position.

A cam follower device includes: a bearing holding member that has a pair of opposing side walls disposed with a space therebetween and that is arranged with respect to a cam provided on a camshaft; a support shaft inserted into insertion holes provided coaxially in each of the pair of opposing side walls; an outer ring that has the support shaft inserted therethrough, is disposed between the pair of opposing side walls, and faces the cam; an inner ring formed by an outer peripheral surface of the support shaft; and a plurality of rollers disposed in an annular gap between the outer ring and the inner ring.

A rotor for a cam phaser, the rotor rotating about a rotation axis and the rotor including a first face; a receiving face arranged opposite to the first face; a central portion; at least one lobe that is arranged at the central portion and which extends away from the central portion in a radial direction; and a cam shaft receiving recess provided at the receiving face and configured to receive a cam shaft, wherein the cam shaft receiving recess includes an inside surface, wherein at least two cam shaft centering elements are arranged at the inside surface for centering the cam shaft, and wherein the cam shaft centering elements are configured as protrusions. The invention also relates to a joining kit.

A rotor for a cam phaser, the rotor rotating about a rotation axis and the rotor including a first face; a receiving face arranged opposite to the first face; a central portion; at least one lobe that is arranged at the central portion and which extends away from the central portion in a radial direction; and a cam shaft receiving recess provided at the receiving face and configured to receive a cam shaft, wherein the cam shaft receiving recess includes an inside surface, wherein at least two cam shaft centering elements are arranged at the inside surface for centering the cam shaft, and wherein the cam shaft centering elements are configured as protrusions. The invention also relates to a joining kit.

A torque drive transmission, having at least two counter-rotating cams bearing-mounted within a housing about a rotational axis. The counter-rotating cams are operative to: (i) convert a linear input to a rotary output, and (ii) drive a pair of coaxial drive shafts in opposite directions along the rotational axis. Furthermore, each counter-rotating cam defines a cam profile surface having drive and follower surfaces defining angles and respectively. The angles and are unequal to drive each cam and respective output drive shaft in an opposite rotational direction. As such, the cams may be driven in opposite directions irrespective the initial rotational position of the linear input, i.e., relative to each counter-rotating cam.