The present invention generally relates to vehicle and machinery in agriculture, construction, forestry, mining and powersport. It further generally relates to track systems and traction assemblies used with such vehicles. The track assembly includes components having particular features that, alone or in combination, participate in decreasing the vibrations 5 undergone by the vehicle. According to embodiments, split frames are used with suspension, tandem subassemblies, “tridem subassemblies”, adjustable damping components, drive shaft openings, lowering of resulting the track band tension and rosta assemblies.

A steering system includes a motor, a rack shaft, and a nut that is screw-thread on the rack shaft via a plurality of balls. The steering system further includes a reduction mechanism having a driving pulley, a driven pulley, a belt, and an idler pulley that applies tension to the belt. The steering system further includes a housing that houses the motor, the rack shaft, the nut, and the reduction mechanism. Compressive rigidity in an axial direction is set to vary between a near-end area and a far-end area of the housing. The idler pulley is provided so as to contact a portion of the belt which is loosened when end contact occurs at an axial end of the housing where the compressive rigidity is set to a larger value.

A pulley device for a belt that includes an eccentric adjusting member fixed on a support, an eccentric hub rotatably mounted on the eccentric adjusting member, a torsion spring between the eccentric adjusting member and hub to exert a biasing force, and a pulley rotatably mounted on the hub. The hub provides an upper radial surface and the eccentric adjusting member provides a radially outwardly projecting flange formed at an upper end of the eccentric adjusting member and forming an axial abutment for the upper radial surface. The upper radial surface provides a pair of axially projected stops formed integrally within, each stop being dedicated to come into abutment against a corresponding stop provided by the radially outwardly projecting flange of the eccentric adjusting member. The hub further provides engaging means adapted to cooperate with an external tool, the engaging means circumferentially located between the projected stops of the hub.

A clutch comprising a drive pulley, a driven pulley, a belt selectively rotationally coupling the drive pulley and the driven pulley, at least one idler pulley positioned between the drive pulley and the driven pulley, and a friction brake. The idler pulley being moveable between a belt engaged position and a belt disengaged position. The friction brake has a friction element and a clamping face. The clamping face is moveable between a first position wherein the clamping face is spaced a first distance from the friction element such that the belt may freely rotate and frictionally engage the drive pulley and the driven pulley when the idler pulley and a second position wherein the clamping face is spaced a second distance from the friction element such that the belt is securely clamped by the friction element and the clamping face.

A drive assembly having a rotator system and including a drive pulley, a driven pulley spaced apart from the drive pulley, a drive belt, a rotator pulley, and a rotator belt. The driven pulley supports a tool assembly, and the drive belt is connected to the drive pulley and the driven pulley. The drive belt is selectively tensioned to couple the drive pulley and the driven pulley so that rotation of the drive pulley causes the driven pulley to rotate and de-tensioned to decouple the drive pulley and the driven pulley allowing the drive pulley to rotate without causing the driven pulley to rotate. The rotator belt couples the rotator pulley and the driven pulley in a way that when the drive belt is decoupled from the drive pulley and the driven pulley rotation of the rotator pulley causes the driven pulley and the tool assembly to rotate.

A belt tensioning device comprises a base member having an attachment portion and an opening for a drive shaft; first and second tensioning arms that are pivotably supported by first and second bearings on the base member around first and second pivot axes and have first and second tensioning rollers 5, 7. A spring arrangement pretensions the two tensioning arms in a circumferential direction towards each other; wherein the spring arrangement has at least one bow-shaped spring that has a circumferential extension of less than 360° around the first and the second pivot axis; wherein the at least one bow-shaped spring has first and second support portions that are supported on the first and second tensioning arm as well as a spring portion extending between the first and second support portion; wherein the at least one bow-shaped spring has an axial length in the area of the first and the second support portion which is axially shorter than a total axial length of the bow-shaped spring.

A motorized wheelbarrow including a motor and a drive pulley that rotates when the motor is operating. The motorized wheelbarrow also includes wheels and a drive train assembly for transmitting power from the motor to the wheels. The motorized wheelbarrow also includes a clutch assembly movable between a connected condition, in which the motor and the drive train assembly are connected by the clutch assembly, and a disconnected condition, in which the motor and the drive train assembly are not connected with each other, and a brake assembly movable between an engaged condition, in which the brake assembly resists rotation of the wheels, and a disengaged condition, in which the brake assembly does not resist rotation of the wheels. Both of the clutch assembly and the brake assembly are controlled by a single control assembly so that the clutch assembly and the brake assembly are mutually functionally exclusive.

Described embodiments include a reconfigurable belt tensioner that can be used to add, remove, and/or reposition peripheral accessories of an engine installation, for example, in an automobile or another vehicle. The tensioner has a housing, an arm with an axle, and a spring installed in the housing. The axle is inserted into and fastened to the housing. The arm rotates around the axle. When the arm is rotated, the spring provides the force that tends to return the arm and the housing to the original position. The tensioner can be reconfigured by repositioning the spring relative to the housing and/or the arm, changing the angle between the housing and the arm. The tensioner may be used, for example, on an LS-based GM small-block engine, and allow operation with and without the air conditioning compressor or other accessories.

An axle in particular of a universal carrier frame, which includes an arm of the axle, a power drive unit, swivel drive units, swivel distribution systems, travel distribution systems. At one end of the arm of the axle, a front portal suspension of a front wheel is rotatably arranged. At the other end of the arm of the axle, a rear portal suspension of the rear wheel is rotatably arranged. The front portal suspension of the front wheel and the rear portal suspension of the rear wheel comprise an angular chain transmission comprising a drive shaft having a longitudinal axis, a driven shaft having a longitudinal axis, a link chain for connecting the drive shaft and the driven shaft, and a pulley angular system of the link chain to define the angle (a) between the longitudinal axis of the drive shaft and the longitudinal axis of the driven shaft.

A heating ventilation, and/or air conditioning (HVAC) system includes a support structure having a mounting rail, a first mounting bracket coupled to the mounting rail and configured to be adjustably positioned along a first axis of the mounting rail, and a second mounting bracket directly coupled to the first mounting bracket. The second mounting bracket is configured to support a fan motor mounted thereto, the second mounting bracket is configured to be adjustably positioned along a second axis of the first mounting bracket, and the second axis of the first mounting bracket is transverse to the first axis of the mounting rail.