An agricultural utility vehicle includes a working power takeoff drivable by means of an internal combustion engine for operating an implement. The utility vehicle further includes an auxiliary power takeoff, which can be driven by an energy storage device and is coupled to the working power takeoff in such a manner that the working power takeoff is additionally driven at least transiently by the auxiliary power takeoff.

A baler includes a baling chamber that includes a bale-forming channel including at least one adjustable friction control element, a plunger mounted within the channel, and a rotary drive mechanism for driving reciprocating movement of the plunger. A control system controls operation of the baler, the control system configured to determine an actual maximum torque value associated with the rotary drive mechanism, compare the actual maximum torque value with a selected desired maximum torque value, and adjust the friction control element to regulate the actual maximum torque value according to the desired maximum torque value.

An agricultural baler includes a chassis, a flywheel carried by the chassis, and a driveline associated with the flywheel and couplable with a power take-off (PTO) of a traction unit. The agricultural baler further includes an auxiliary power system coupled with the driveline. The auxiliary power system is configured for receiving power from the driveline, storing the power, and transmitting the stored power back to the driveline.

A baler having a compression system for forming a bale includes a plunger that reciprocates within a baling chamber between an extended position and a retracted position. The baler also includes a controller configured to detect and calculate the amount of work exerted by the plunger as it reciprocates within the baling chamber. The controller generally calculates the work exerted by the plunger by determining the force applied to the plunger and the distance the plunger has traveled with respect to the baling chamber.

An agricultural harvesting machine for crop material including a crank arm connected to a rotational power source, a plunger having an extended position which is located further rearward in a compression chamber than a retracted position, and a connecting link connected between the plunger and the crank arm. One of the connecting link and the crank arm has a variable length. The plunger moves between the retracted and extended positions during a run mode as the crank arm rotates. The plunger changes speeds during an event phase based upon one of the connecting link and the crank arm varying lengths.

An agricultural baler for producing rectangular bales, having a reciprocating plunger moving back and forth in the enclosure formed by walls, thereby compressing crop material and forming rectangular bales, and further including at least one actuator for adapting the cross-section of the enclosure depending on the required pressure that needs to be exerted on the advancing bale. Actuators can apply their force on the sidewalls along transversal support beams or brackets forming the density belt. The baling chamber is provided with one or more friction or moisture sensors which are placed at the location or in the immediate vicinity of one or more side wall reinforcements.

A baling system including a working component, where the working component has at least one of a pickup assembly, a rotor assembly, or a lifter assembly, a frame supporting the working component, a first drive system configured to drive the working component, a second drive system configured to drive the working component, and a remote controller configured to selectively control the operation of the second drive system when the first drive system is operatively disengaged from the working component.

An agricultural baler including a base unit, a plurality of ground engaging devices and a transmission. The plurality of ground engaging devices support the base unit. The transmission is mounted on the base unit. The transmission includes an input shaft and an other shaft. The other shaft is separate from the input shaft. The other shaft is drivingly coupled to the input shaft. The other shaft is connected to a flywheel and/or a hydraulic pump. The other shaft is configured to operate at a different speed than the speed at which the input shaft operates.

Agricultural harvesting machines and methods of operation thereof are disclosed herein. A harvesting machine includes a main frame, a drive mechanism, a plunger, and a linkage system. The drive mechanism is coupled to the main frame and has at least one crank arm that is rotatable about a crank arm axis. The plunger is movable along a longitudinal axis in a compression chamber between a de-stroked position and a stroked position that is located rearward of the de-stroked position along the longitudinal axis. The linkage system couples the plunger to the main frame.

The present invention relates in general to working machines with working units which are subject to fluctuating loads or have a fluctuating power consumption. The invention relates in particular to a drive train assembly for driving such a working unit, the drive train assembly having a flywheel accumulator for mitigating the load impacts or load fluctuations. According to the invention, a starting aid for easier starting up of the flywheel accumulator into its desired operating speed range is provided, the starting aid having a planetary transmission, which is connected in terms of drive to the flywheel accumulator, and a control actuator for braking and/or accelerating a planetary transmission element in order to adjust the step-up/step-down ratio of the planetary transmission when starting up the flywheel accumulator. Furthermore, for refined smoothing of the power consumption in the started-up working mode, a control device is provided which accelerates and can brake the flywheel accumulator cyclically by adjusting the planetary transmission in accordance with the operating fluctuations of the working unit.