A chain tensioner includes a sleeve fixedly disposed in a cylinder, with a first end of the sleeve inserted in a plunger and a second end of the sleeve protruding out of the plunger. A cylindrical space is defined between an outer periphery of the sleeve and an inner periphery of the cylinder. An oil supply passage opens to the cylindrical space. A communication passage is defined in the sleeve and provides communication between the cylindrical space and a reservoir chamber.

A snowblower belt drive system a tensioner pulley that can slide forwardly and rearwardly in a path that is substantially parallel to an endless drive belt between a drive pulley and a driven pulley. A drive belt engagement spring urges the tensioner pulley rearwardly along the slot to engage the drive pulley and driven pulley. A manual return spring urges the tensioner pulley forwardly along the slot to disengage the drive pulley and driven pulley.

A belt tensioner controls the pretension of a belt for an ancillary component such as a starter/generator. The ancillary component may apply torque in each direction at different times. The starter/generator has a generator shaft and a generator belt pulley around which the belt passes. A flange is fixed to the starter/generator with a bearing sleeve which surrounds the generator shaft. A first tensioning arm and a second tensioning arm are each formed as circular rings and mounted on the bearing sleeve so as to pivot against each other. One tensioning arm is supported on an inner side of the bearing sleeve while the other tensioning arm is supported on the outer side of the bearing sleeve. Two tensioning rollers are mounted on the tensioning arms and apply a pretensioning force to the belt before and after the generator belt pulley in the belt running direction.

A printing apparatus includes a conveyance unit to convey a print medium, a belt, a tensioner, and a control unit. The belt transmits a driving force of a drive unit to the conveyance unit. The tensioner is displaceable and makes pressure contact with the belt to generate tension. The control unit controls driving of the drive unit in a state where the tensioner is in pressure contact with the belt. The control unit performs first control in which the drive unit is driven with a first control value, which is not based on a driving amount detected by a detection unit. Where the detection unit detects the driving amount, the control unit subsequently performs second control in which the drive unit is driven with a second control value, which is based on the driving amount detected by the detection unit.

A mechanism for adjusting the tension of a flexible transmission component, comprising: a driver; a follower, with a center distance between the center of the driver and the center of the follower; a flexible transmission component, which is a closed loop passing around the driver and the follower; a first base connecting with the driver, wherein aid first base can move in a direction of movement parallel to the center distance and away from and/or forward to the follower; a second base connecting with the follower; and at least one elastic component connecting the first base and the second base.

A camera assembly includes a motor configured to generate a driving power; a motor shaft that extends from the motor, such as to define a first axis, and is configured to rotate by the driving power of the motor; a pulley configured to rotate on a second axis, that is spaced from the first axis, according to rotation of the motor shaft; a belt configured to couple the motor shaft and the pulley, and convert the rotation of the motor shaft to rotation of the pulley, and tension of the belt applies a force to the motor shaft in a direction towards the second axis; a camera module configured to be mounted on the pulley and rotate together with the pulley; and an elastic body configured to apply a biasing force to the motor shaft such as to bias the motor shaft in a direction away from the second axis.

A walk-behind tractor has an increased ground clearance to define a plant receiving space that has a greater height than a conventional walk-behind tractor having a straight axle. The walk-behind tractor has trailing drop arms from a frame that carry wheel axles that result in an elevated height of a driveshaft. The elevated driveshaft increases the ground clearance for taller plants to pass therebeneath during operation of the walk-behind tractor which would otherwise be too tall to pass below a conventional straight axle walk-behind tractor.

A belt tensioning system is described, which comprises: a housing pivotable about a pivot point; a pulley supported by said housing, said pulley to rotate a belt and said pulley rotatable about an axis of rotation; a motor to drive the pulley; and a biasing element coupled to said housing and to apply a tension to said belt via said housing and said pulley; wherein operation of said motor to effect rotation of said pulley about said axis of rotation: in a first direction effects pivoting of said housing in a direction about said pivot point, which pivoting movement, in combination with said biasing element, effects translational movement of said axis of rotation of said pulley in a first translational direction to a first axis position to alter said tension in said belt; and in a second direction effects pivoting of said housing in an opposite direction about said pivot point, which pivoting movement, in combination with said biasing element, effects translational movement of said axis of rotation of said pulley in a second translational direction to a second axis position to alter said tension in said belt.

To provide a tensioner and a relief valve unit that enable a reduction in the number of parts to be processed and the number of assembling steps, reduce the amount of oil flowing out to the outside, prevent damage to the check valve, and improve the oil recovery rate. The relief valve unit that releases oil when pressure inside an oil pressure chamber reaches or exceeds a predetermined high pressure includes a check valve unit that stops reverse flow of oil flowing into the oil pressure chamber as a valve element, the check valve unit being slidably inserted in the relief valve unit. The relief valve unit includes a unit pressing spring that presses the check valve unit toward a relief valve seat. The check valve unit includes an oil passage for allowing oil to flow between an inner side and an outer side of the check valve unit.

A transmission arrangement (113) comprising a first axle (24) that is rotatable about a first axis (33) and is connected to a first pulley (25) that is arranged to drive an endless power transferring means (26) that further is adapted to drive a second pulley (27) that is rotatable about a second axis (34), where the transmission arrangement (113) comprises a first idle pulley (101) and a second idle pulley (102) which both are adapted to guide the endless power transferring means (26), where the first idle pulley (101) is rotatable around a first idle pulley axis (103) and the second idle pulley (102) is rotatable around a second idle pulley axis (104), where the distance between the idle pulley axes (103, 104) is fixed and where the idle pulley axes (103, 104) are pivotable around a common pivot axis (105), wherein the first pulley (25) is positioned between the idle pulleys (101, 102) and the second pulley (27) such that a distance between any one of the idle pulley axes (103, 104) and the second axis (34) exceeds a distance between any one of the idle pulley axes (103,104) and the first axis (33).