A steering gear for a steering system of a motor vehicle includes a housing, a gearwheel, a pinion meshing with the gearwheel, and a pinion shaft with the pinion. The pinion shaft is mounted on one side of the pinion in a floating bearing that includes a rotary bearing that receives the pinion shaft. The rotary bearing is connected to a stop element, which is simultaneously arranged displaceably and non-rotatably within a receiving space. The pivoting mobility of the pinion shaft guided by a fixed bearing, on the other side of the pinion, is limited by a stop between the stop element and a wall of the receiving space. The stop element and the receiving space are configured such that, only in the event of such a stop, pivoting mobility of the pinion shaft is blocked about an axis oriented perpendicular to the pivot axis.

An electromechanical power steering system may include an electric servomotor that has a motor shaft and drives a shaft that meshes with a helical gear. The shaft is disposed in a gearbox housing and rotatably mounted in a bearing assembly. A pretensioning installation, for adjusting engagement between the helical gear and the shaft, resiliently pretensions a movable bearing element of the bearing assembly relative to the gearbox housing. The gearbox housing has a housing portion having first and second contact faces, the normals of which do not intersect. The bearing assembly has a bearing support that forms the movable bearing element and has a lever arm having a free end that extends from a main body of the bearing support and on the gearbox housing lies against the second contact face. The main body has an eccentric cam that on the housing lies against the first contact face.

The disclosure relates to a transmission housing unit and to a transmission unit which has said transmission housing unit. The transmission housing unit has a housing main body which has a through hole, through which a shaft which penetrates the housing main body in the axial shaft direction can be pushed into the housing main body, a wedge-shaped compensation element for axial play compensation between the shaft and the housing main body which engages around the shaft at least in a U-shaped or arcuate manner, and a pre-stressed spring element which is arranged between the obtuse end of the compensation element and the housing main body. The compensation element can be displaced radially in the direction of the shaft axis along a guide surface of the housing main body between an assembly position and an active position.

A worm shaft includes: an insertion portion; a wall surface; a tapered portion; and a main body portion, the gear portion is formed on the main body portion and the tapered portion such that a bottom land of the gear portion is positioned at radially outer side of a line extending in parallel with a rotation center axis of the worm shaft and passing through a boundary between the wall surface and the tapered portion.

Power takeoff devices (PTOs) are useful for mounting on transmissions and for performing, directly or indirectly, useful work via the mechanical energy generated by the PTO's rotatable output shaft. Systems and methods for reducing PTO gear rattle include a moveable input gear engaging and intermediate to an output gear and a transmission gear. The input gear is carried on an input gear carrier moveable such that the input gear centerline moves along a plane substantially perpendicular to a plane running between the centerlines of the output and transmission gears. The input gear travel is limited by the output and transmission gears such that the input gear is biased to engage at least one of the output gear and the transmission gear, thereby reducing or eliminating gear rattle from overly loose engagement between meshing teeth on the input gear and the transmission gear or output gear.

A bearing adjustment assembly is provided. The assembly includes a worm engaged with a worm gear. The assembly also includes a worm bearing located proximate an end of the worm. The assembly further includes a spring disposed in a spring bore defined by the housing. The assembly yet further includes a compensation mechanism engaging the worm bearing and the spring, the compensation mechanism being adjustable to bias the worm bearing to maintain or adjust a gear mesh load between the worm gear and the worm, wherein compression of the spring adjusts the compensation mechanism biasing of the worm bearing. The assembly also includes a spring retainer comprising a pin retainer portion disposed within an interior of the spring, the pin retainer portion extending from a main body portion of the spring retainer.

A worm reducer has: a housing having a wheel housing portion and a worm housing portion; a worm wheel; a worm, a support bearing having an inner ring externally fitted to the tip end portion of the worm and an outer ring; an elastic biasing means elastically biasing the outer ring toward the worm wheel side; and an elastic holding means elastically holding the outer ring from both sides in a direction orthogonal to a biasing direction by the elastic biasing means and to a center axis of the worm housing portion.

A gearbox assembly includes a housing, a first shaft assembly having a worm gear and supported relative to the housing by a first bearing assembly, and a second shaft assembly including a wheel gear which is also supported relative to the housing by a second bearing assembly, the wheel gear engaging with the worm of the worm gear to permit the transfer of torque between the two shaft assemblies, wherein the first shaft assembly includes an elongate shaft carrying the worm gear, and a separate dog drive mechanism secured to one end of the elongate shaft by the first bearing such that in use torque is transferred between the elongate shaft and the dog drive mechanism.

An electric power steering system with a worm gear includes a worm shaft and a worm wheel, wherein an electric motor is associated with the worm shaft, which is connected to the worm shaft in a force-transmitting manner. A bearing element, arranged on the worm shaft at the end of the worm shaft facing away from the electric motor, is received in a guide bush, wherein the guide bush has, on its circumferential side, a passage opening. It is provided a pre-tensioning device comprising a spring-loaded actuator element extending through the passage opening of the guide bush and acting on the worm shaft in the direction of the worm wheel with a defined pre-tensioning force (K), wherein the pre-tensioning device comprises a limiting device which is adapted to limit a pivoting movement that displaces the worm wheel away from the worm shaft. Furthermore, it is proposed a method for the production of steering systems and a test system for performing the method.

An actuating mechanism includes a transmission element configured to be displaced parallel to a transmission direction, an actuating element configured to perform an actuating movement to cause the displacement of the transmission element in the transmission direction, a conversion mechanism arranged between the transmission element and the actuating element which converts the actuating movement of the actuating element into the displacement of the transmission element, and a bracing element configured to introduce a pretension, preferably an elastic pretension, at least into the conversion mechanism. The invention also relates to a clutch actuator and a transmission actuator having an actuating mechanism in accordance with the present invention.