Mower (1), having a plurality of mowing elements (2), which are positioned next to one another forming a mower bar (3), having a roller conditioner (4), which is arranged behind the mower bar (3), as seen in the material flow direction of mowed crop, and which has an upper conditioning roller (5) and a lower conditioning roller (6), wherein the lower conditioning roller (6) is rotatable about a lower, positionally fixed axis of rotation (8), wherein the upper conditioning roller (5) is rotatable about an upper, shiftable axis of rotation (9) in such a manner that, as a result of shifting the upper axis of rotation (9) relative to the lower axis of rotation (8), a gap (7) between the conditioning rollers (5, 6) is changeable, wherein the lower conditioning roller (6) and the upper conditioning roller (5) are coupled to each other via a scissors-like transmission (10), and wherein a first transmission part (11) is coupled to the lower conditioning roller (6) and a second transmission part (2) is coupled to the upper conditioning roller (5), wherein the transmission parts (11, 12) are operatively connected to each other and are shiftable in a scissors-like manner with respect to each other.

A drive on an all wheel drive mower/slasher having on each side an assembly comprises appropriate brackets and fittings, axles, chains and tensioners where the worm gear output carries a forward direction spur gear and then extends to clutch. The clutch has an output gear and a forward chain travelling over a chain gear on reversible shaft, the reversible shaft is journaled in bearings. Chain gears and deliver drive to the wheel chain gears via respective chains. The spur gear is in mesh with a same sized gear so that when clutch 31 is disengaged and clutch engaged the wheels on one side are set forward. The brake clutches are disengaged. Chain and belt tensioners are provided in the usual way. The pulley has fan blades set above the pulley and the pulley has fan blades set below. Brakes are engaged on the turn side for skid steering.

A drive on an all wheel drive mower/slasher having on each side an assembly comprises appropriate brackets and fittings, axles, chains and tensioners where the worm gear output carries a forward direction spur gear and then extends to clutch. The clutch has an output gear and a forward chain travelling over a chain gear on reversible shaft, the reversible shaft is journaled in bearings. Chain gears and deliver drive to the wheel chain gears via respective chains. The spur gear is in mesh with a same sized gear so that when clutch 31 is disengaged and clutch engaged the wheels on one side are set forward. The brake clutches are disengaged. Chain and belt tensioners are provided in the usual way. The pulley has fan blades set above the pulley and the pulley has fan blades set below. Brakes are engaged on the turn side for skid steering.

A lawn mower includes a blade housing and a height adjusting mechanism for adjusting a height of the blade housing with respect to the associated ground. The height adjusting mechanism includes rear wheel support members for supporting rear drive wheels. Each rear drive wheel includes a cover having an exterior cover part and an interior cover part. The interior cover part is directly connected to one of the support members without the use of separate associated mechanical fasteners.

A hydrostatic transaxle includes: a casing; a hydraulic continuously variable transmission; and an oil filter that includes a filter body for filtering the hydraulic oil and a filter holding member configured to guide clean oil filtered in the filter body to a suction oil reservoir, in which the filter holding member includes a filter installation portion for installing the filter body, and a suction oil reservoir provided at a position different from the filter installation portion, and the filter installation portion and the suction oil reservoir are configured to be separable from each other and be couplable to each other to freely flow.

A corn header for an agricultural vehicle includes two gathering chains which together draw plants into a snapping gap; two snap rolls positioned beneath the two gathering chains; a first brushless DC motor (BLDC) connected to at least one of the two gathering chains for moving the at least one of the two gathering chains; a chopping unit including a movable blade positioned beneath the snap rolls for fragmentizing stalks of the plants drawn into the snapping gap; and a second BLDC connected to the chopping unit for moving the blade and fragmentizing the stalks of the plants.

A corn header for an agricultural vehicle includes two gathering chains which together draw plants into a snapping gap; two snap rolls positioned beneath the two gathering chains; a first brushless DC motor (BLDC) connected to at least one of the two gathering chains for moving the at least one of the two gathering chains; a chopping unit including a movable blade positioned beneath the snap rolls for fragmentizing stalks of the plants drawn into the snapping gap; and a second BLDC connected to the chopping unit for moving the blade and fragmentizing the stalks of the plants.

A chopper system for a sugarcane harvester comprises a chopper and a timing-adjustment tool. The chopper comprises a first chopper drum mounted for rotation about a first axis of rotation and comprising blades, a second chopper drum mounted for rotation about a second axis of rotation and comprising blades that cooperate with the blades of the first chopper drum to sever sugarcane stalks into billets upon rotation of the first and second chopper drums respectively about the first and second axes of rotation, and a gearbox that coordinates rotation of the first and second chopper drums relative to one another to establish a timing of operation between the blades of the first and second chopper drums. The timing-adjustment tool removably mounts to the chopper to adjust the timing of operation.

A chopper system for a sugarcane harvester comprises a chopper and a timing-adjustment tool. The chopper comprises a first chopper drum mounted for rotation about a first axis of rotation and comprising blades, a second chopper drum mounted for rotation about a second axis of rotation and comprising blades that cooperate with the blades of the first chopper drum to sever sugarcane stalks into billets upon rotation of the first and second chopper drums respectively about the first and second axes of rotation, and a gearbox that coordinates rotation of the first and second chopper drums relative to one another to establish a timing of operation between the blades of the first and second chopper drums. The timing-adjustment tool removably mounts to the chopper to adjust the timing of operation.

A non-row sensitive forage harvester header is formed with a single rotary member driven by a simplified drive mechanism coupled to the primary drive of the forage harvester to which the header is mounted. A horizontal drive shaft transfers the rotational power laterally to a gear box. The vertical output shaft from the gearbox has a first drive sprocket mounted thereon to connect directly with a drive chain fixed to the crop transfer disks, and a second drive sprocket mounted thereon and coupled to a drive chain entrained around a driven sprocket on the cutting disk to provide a drive speed differential with respect to the crop transfer disks. The crop guides are formed with rearwardly angled transfer arms cooperable with sweeper members on the crop transfer disk to direct the severed crop into engagement with the transfer disks for feeding into the forage harvester.