An industrial work vehicle including a frame and a first shaft rotatably connected to the frame via first and second bearings. The work vehicle further includes a second shaft rotatably positioned in line with the first shaft and connected to the first shaft via a coupling. The second shaft is further connected to the frame via a third bearing. The coupling includes a first connection and a second connection. The first connection connects the first shaft to the second shaft via a fourth bearing adapted to support a radial load and to accommodate an axial rotation and an angular misalignment of one shaft with respect to the other shaft. The second connection connects the first shaft to the second shaft via flange elements which are interconnected via an intermediary element adapted to transmit a torque and to accommodate a misalignment of one shaft with respect to the other shaft.

The invention relates to a tine support (10) for a crop collecting device for connecting at least two tines (12) to a shaft (50), one tine (12, 32) having a securing region (18). The invention is characterized in that the tine support (10, 30) comprises at least two support elements (14A, 14B, 34A, 34B) on which the securing region (18) of at least one tine (12, 32) can be secured. Furthermore, the support element (14A, 14B, 34A, 34B) has a connection region (24) via which a rotationally fixed connection to the shaft (50) can be produced, and the tine support (10, 30) has a clamping element (26, 38) which clamps the support elements (14A, 14B, 34A, 34B) in a removable manner with respect to the shaft (50).

A baler having a frame, a feed system coupled to the frame, and a compression assembly in operable communication with the feed system. Where the compression assembly includes a baling chamber, a gearbox having an output shaft, and a crank arm defining a first mounting point and a second mounting point spaced a distance from the first mounting point, where the first mounting point of the crank arm is coupled to and rotatable with the output shaft of the gearbox. The compression assembly also includes a plunger positioned within and reciprocally movable with respect to the baling chamber, where the plunger defines a third mounting point thereon, and where the distance between the second mounting point and the third mounting point is variable during a baling process.

Windrow diverting apparatus and method of controlling same proximate a roll baler pick-up which laterally shifts the windrow relative to the roll bale pick-up during baling.

A high-efficiency pickup baler crawler and automatic bale stacking system, includes a straw pickup stubble harvesting device, continuous conveying preloading device, a lower feeding type compression and baling device, bale transportation and arraying device, bale stacking device, walking device and counting control. The counting control the amount of bale compression chamber discharge, which is used to control the bale conveying device and bale stacking device, achieve the goals of automatic conveying, pushing, stacking, avoids artificial secondary handling and improve the working efficiency of the system.

A high-efficiency pickup baler crawler and automatic bale stacking system, includes a straw pickup stubble harvesting device, continuous conveying preloading device, a lower feeding type compression and baling device, bale transportation and arraying device, bale stacking device, walking device and counting control. The counting control the amount of bale compression chamber discharge, which is used to control the bale conveying device and bale stacking device, achieve the goals of automatic conveying, pushing, stacking, avoids artificial secondary handling and improve the working efficiency of the system.

A driver unit for a conveyor is disclosed. The driver unit includes a drive finger, driving conveyed material, and a holding body for positioning the drive finger on the rotary conveyor. The holding body has a socket into which an end section of the drive finger can be inserted. Furthermore, a securing element is used to secure the drive finger to the socket, whereby the securing element includes a section arranged eccentric to an axis of the securing element to hold the drive finger in the socket.

An apparatus for transferring agricultural products, for agricultural machines designed for the formation of a bale is provided. The transfer apparatus includes at least one impeller rotor, which can be arranged between a pick-up drum of agricultural products and a chamber for the compression of the agricultural products. The rotor is facing a deck, for delimiting at least partially a channel. The deck is coupled to a fixed frame by way of at least two supports which can move on command. At least one first support includes at least one support pin, which is coupled to a first portion of the deck and moved, in a corresponding guiding slot, by a corresponding actuator. At least one second support includes at least one crank, which is coupled to a second portion of the deck and rotatable about a rotation axis that is perpendicular to the advancement direction.

A rotor apparatus for a baler is provided such that hay on the ground is picked up by a hay pick-up apparatus installed at the side of the baler and the picked-up hay is fed without being wound around the rotor feeding the hay to the region of the roll forming apparatus, whereby the hay of the hay pick-up apparatus is fed to the region of the roll forming apparatus quickly, precisely, and evenly. In addition, a load of the rotor is minimized when the hay is fed to the region of the roll forming apparatus, thereby extending the service life of the rotor.

A rotor apparatus for a baler is provided such that hay on the ground is picked up by a hay pick-up apparatus installed at the side of the baler and the picked-up hay is fed without being wound around the rotor feeding the hay to the region of the roll forming apparatus, whereby the hay of the hay pick-up apparatus is fed to the region of the roll forming apparatus quickly, precisely, and evenly. In addition, a load of the rotor is minimized when the hay is fed to the region of the roll forming apparatus, thereby extending the service life of the rotor.