An adjustment device configured to move first bevel gear and second bevel gear that are disposed on base and are meshed with each other. Adjustment device includes first adjustment assembly, and second adjustment assembly. First adjustment assembly includes first fluid-driven power source, first brake component and first displacement sensor. First fluid-driven power source includes first cylinder housing and first piston. First cylinder housing is configured to be disposed on base. First piston is movably disposed on first cylinder housing. First bevel gear is configured to be disposed on first piston. First piston is configured to move first bevel gear along first axial direction. First brake component is configured to be disposed on base and configured to stop or release first piston. First displacement sensor is disposed on first cylinder housing and configured to generate displacement data related to first piston.

A method for assembling an axle assembly for a vehicle including that a pinion gear is inserted into a differential housing. The pinion gear having a first end and a second end opposite the first end. The pinion gear further includes a gear head at the first end, external threads proximate the second end, and external splines located a first distance away from the second end. The method further includes that a flange is slid over the second end of the pinion gear. The flange including internal splines. The method also includes that the internal splines of the flange are engaged with the external splines of the pinion gear and the flange is anchored to prevent the flange and the pinion gear from rotating. The method may further include that ultrasonic sound waves are transmitted through the pinion gear and reflections of the ultrasonic sound waves are detected.

A two-stage actuating gear mechanism comprises a spur gear transmission as the first transmission stage and a harmonic drive as the second transmission stage. A spur gear transmission gear with inward facing teeth is designed simultaneously as a component of a harmonic generator of the harmonic drive. A gear with outward facing teeth that meshes with the gear with inward facing teeth is rigidly connected to a rotor of an electric motor, the motor housing of which is secured to the transmission housing of the harmonic drive. The motor housing is positioned relative to the transmission housing by means of a centering device which is eccentric to the rotational axis (A.sub.E) of the rotor. An adjustable backlash between the gear with outward facing teeth and the gear with inward facing teeth is provided by a pivoting capability between the motor housing and the transmission housing.

A two-stage actuating gear mechanism comprises a spur gear transmission as the first transmission stage and a harmonic drive as the second transmission stage. A spur gear transmission gear with inward facing teeth is designed simultaneously as a component of a harmonic generator of the harmonic drive. A gear with outward facing teeth that meshes with the gear with inward facing teeth is rigidly connected to a rotor of an electric motor, the motor housing of which is secured to the transmission housing of the harmonic drive. The motor housing is positioned relative to the transmission housing by means of a centering device which is eccentric to the rotational axis (A.sub.E) of the rotor. An adjustable backlash between the gear with outward facing teeth and the gear with inward facing teeth is provided by a pivoting capability between the motor housing and the transmission housing.

A mounting system for a portal lift assembly of an off-road vehicle includes a housing having a rear wall, a front wall, and a side wall. The rear wall includes an opening to receive the end of one of the vehicle's axles, and the front wall includes an opening to allow an output shaft to extend outward from the housing. The rear wall also includes one or more integral mounting brackets effective to mount the box to the suspension of the vehicle. Such integral mounting brackets may include an upper A-arm connection bracket to connect the upper A-arm directly to the rear wall, and/or a lower A-arm connection bracket to connect the lower A-arm directly to the rear wall. When the wheel is a steerable wheel, the rear wall also may include an integral mounting bracket effective to allow a steering linkage to connect directly to the rear wall.

A mounting system for a portal lift assembly of an off-road vehicle includes a housing having a rear wall, a front wall, and a side wall. The rear wall includes an opening to receive the end of one of the vehicle's axles, and the front wall includes an opening to allow an output shaft to extend outward from the housing. The rear wall also includes one or more integral mounting brackets effective to mount the box to the suspension of the vehicle. Such integral mounting brackets may include an upper A-arm connection bracket to connect the upper A-arm directly to the rear wall, and/or a lower A-arm connection bracket to connect the lower A-arm directly to the rear wall. When the wheel is a steerable wheel, the rear wall also may include an integral mounting bracket effective to allow a steering linkage to connect directly to the rear wall.

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.

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.

The invention relates to a worm drive comprising a worm shaft and a first receiving unit. The worm shaft is rotatably mounted in the first receiving unit. Furthermore, the worm drive comprises a worm wheel and a second receiving unit. The worm wheel is rotatably mounted in the second receiving unit. The first receiving unit is arranged on the second receiving unit and the rotatably mounted worm shaft is in contact with the worm wheel of the second receiving unit in order to transmit a torque. Furthermore, the worm drive comprises guide pins for detachably connecting the first receiving unit to the second receiving unit. More particularly, the first receiving unit receives at least part of the guide pins and the second receiving unit is connected to one of the guide pins, preferably to a first end of the guide pin. A spring element is arranged on a second end of the guide pin between the first receiving unit and a fastening means.

The invention relates to a worm drive comprising a worm shaft and a first receiving unit. The worm shaft is rotatably mounted in the first receiving unit. Furthermore, the worm drive comprises a worm wheel and a second receiving unit. The worm wheel is rotatably mounted in the second receiving unit. The first receiving unit is arranged on the second receiving unit and the rotatably mounted worm shaft is in contact with the worm wheel of the second receiving unit in order to transmit a torque. Furthermore, the worm drive comprises guide pins for detachably connecting the first receiving unit to the second receiving unit. More particularly, the first receiving unit receives at least part of the guide pins and the second receiving unit is connected to one of the guide pins, preferably to a first end of the guide pin. A spring element is arranged on a second end of the guide pin between the first receiving unit and a fastening means.