A cutting device for agricultural harvesters has a conveying channel and pivotably supported cutting knives arranged in a row on a frame. The cutting knives project in the cutting position into the conveying channel. A conveying member with conveying tines, rotatingly driven about a horizontal axis, interacts with the cutting knives for comminuting crop. Individual adjusting devices, each associated with one cutting knife, yieldingly support the cutting knives in the cutting position. A knife switching device is provided to move the cutting knives from the inoperative position into the cutting position. With a preselecting device a desired group of cutting knives can be selected that is pivoted into the cutting position upon activation of the knife switching device. The preselecting device is activatable with reduced force expenditure by eliminating resistances, caused by adjusting and connecting devices of the knife switching device, when preselecting the desired group of cutting knives.

A conveying arrangement conveys loose material in a conveying direction, in particular agricultural material. Several knives of a cutting assembly are mounted below a cutting area guiding surface. The material is first conveyed along the cutting area guiding surface and afterwards along a further guiding surface. Both guiding surfaces are mechanically supported by a connecting assembly. A positioning mechanism can pivot the connecting assembly upwards and downwards. This pivotal movement causes both guiding surfaces to be moved upwards and downwards. The cutting area guiding surface together with the cutting assembly can be shifted laterally, i.e. perpendicular to the conveying direction, and is guided during this lateral movement.

A conveying arrangement conveys loose material in a conveying direction, in particular agricultural material. Several knives of a cutting assembly are mounted below a cutting area guiding surface. The material is first conveyed along the cutting area guiding surface and afterwards along a further guiding surface. Both guiding surfaces are mechanically supported by a connecting assembly. A positioning mechanism can pivot the connecting assembly upwards and downwards. This pivotal movement causes both guiding surfaces to be moved upwards and downwards. The cutting area guiding surface together with the cutting assembly can be shifted laterally, i.e. perpendicular to the conveying direction, and is guided during this lateral movement.

A system conveying material-other-than-grain (MOG) from a harvesting machine to a packaging machine towed by the harvesting machine. The system includes an joint pivotably joining a harvesting machine hitch to a packaging machine hitch. An accelerator is mounted to the packaging machine hitch. The accelerator has a housing with a top-side inlet and a side outlet. A MOG-propelling disk is disposed in the housing and is rotatable about an axis. A conduit is disposed above the packaging machine hitch and has an inlet end and an outlet end, the inlet end coupled to the side outlet. The conduit has first and second opposing side portions and a top side portion without an opposing bottom portion, with at least part of the top side portion is parallel with the plane of the disk. The accelerator, conduit, and packaging machine are collectively in pivotal arrangement relative to the harvesting machine.

A system conveying material-other-than-grain (MOG) from a harvesting machine to a packaging machine towed by the harvesting machine. The system includes an joint pivotably joining a harvesting machine hitch to a packaging machine hitch. An accelerator is mounted to the packaging machine hitch. The accelerator has a housing with a top-side inlet and a side outlet. A MOG-propelling disk is disposed in the housing and is rotatable about an axis. A conduit is disposed above the packaging machine hitch and has an inlet end and an outlet end, the inlet end coupled to the side outlet. The conduit has first and second opposing side portions and a top side portion without an opposing bottom portion, with at least part of the top side portion is parallel with the plane of the disk. The accelerator, conduit, and packaging machine are collectively in pivotal arrangement relative to the harvesting machine.

A feeding mechanism for a crop baler having a leaf forming chute, quick feeding mechanism, hay guides, hay gates, hay leaf divider drum and a control mechanism to stop and start the rotation of the divider drum. The leaf forming chute guides the crop from the packing crank to the middle of the bale chamber. The quick feeding device moves hay from the divider drum to the compression area above or below the compression roller. A control devise stops and starts the rotation of the divider drum causing an equal amount of hay to be placed in the top of the bale as compared to the bottom of the bale. The same control devise to stop the rotation of the divider drum and to stop the movement of hay to the compression area during the tying cycle.

A feeding mechanism for a crop baler having a leaf forming chute, quick feeding mechanism, hay guides, hay gates, hay leaf divider drum and a control mechanism to stop and start the rotation of the divider drum. The leaf forming chute guides the crop from the packing crank to the middle of the bale chamber. The quick feeding device moves hay from the divider drum to the compression area above or below the compression roller. A control devise stops and starts the rotation of the divider drum causing an equal amount of hay to be placed in the top of the bale as compared to the bottom of the bale. The same control devise to stop the rotation of the divider drum and to stop the movement of hay to the compression area during the tying cycle.

A baler implement includes a lower passage wall defining a lower boundary of a pre-compression passageway. The lower passage wall includes a forward portion and an access panel. A pivotable connection interconnects the forward portion and the access panel at a lower and forward transverse edge of the access panel such that a rearward and upper transverse edge of the access panel moves vertically to provide access into the pre-compression passageway. Access is obtained from the rear of the baler implement, between the rearward transverse edge of the access panel and a bottom wall of the compression chamber, without the access panel hanging down from the compression chamber and obscuring access into the pre-compression passageway.

A baler implement includes a lower passage wall defining a lower boundary of a pre-compression passageway. The lower passage wall includes a forward portion and an access panel. A pivotable connection interconnects the forward portion and the access panel at a lower and forward transverse edge of the access panel such that a rearward and upper transverse edge of the access panel moves vertically to provide access into the pre-compression passageway. Access is obtained from the rear of the baler implement, between the rearward transverse edge of the access panel and a bottom wall of the compression chamber, without the access panel hanging down from the compression chamber and obscuring access into the pre-compression passageway.

A crank-operated packer mechanism includes a crank shaft including crank pins and crank arms. At least some of the crank arms are shaped in a way that deviates from a straight shape to such an extent that the crank shaft is statically balanced. The arms may, for example, be curved or hook-shaped. The crank shaft further includes crank pins and crank arms assembled by a tapered spline connection. The connection includes tapered spline features on outer ends of the crank pins and in openings provided at outer ends of the crank arms, which interlock when the crank pins are inserted in the openings.