A harvester comprising: a drive engine connected via a first drive train to ground engagement equipment of the harvester and via a second drive train to crop processing equipment of the harvester; an actuator configured to adjust the transmission ratio of the first drive train to control the propulsion speed of the harvester; and a controller configured to receive setpoint and actual values dependent on the crop throughput of the harvester, the controller configured to calculate an acceleration signal based on the setpoint and actual values, the acceleration signal representing an acceleration of the harvester suitable for minimizing the difference between the setpoint and actual values, and to determine a control signal for controlling the actuator based on the acceleration signal.

A method of autonomously controlling the ground speed of a harvester, such as a self-propelled or towed wind rower, uses both the engine speed and the header speed as control parameters to increase or decrease the ground speed as necessary to maintain efficient harvester operation over varying terrain and crop conditions. A control system includes a controller which receives signals from sensors indicative of engine speed, header speed and harvester ground speed and uses actuators to control the header speed, engine speed and harvester ground speed. An operator interface permits an operator to engage or disengage the autonomous mode of control system operation, as well as to directly control the harvester.

An agricultural harvester has a header and feeder drive system including a forward belt drive arrangement and a reverse belt drive arrangement. The forward belt drive arrangement includes a forward drive belt and a forward belt drive tensioner operated by an actuator. The reverse belt drive arrangement includes a reversing motor and a reverse drive belt selectively engaged with the feeder drive system by operation of the same actuator.

Agricultural machine (10, 10′) comprising an engine (11) for power delivery, at least one axle (12) provided with two wheels (13), a handlebar (14) and a power take-off (15), said agricultural machine (10, 10′) further comprising a hydromechanical clutch group (20) interposed between said engine (11) and said at least one axle (12) and a first (16) and a second lever (17) associated with said handlebar (14) controlling said hydromechanical clutch group (20), said hydromechanical clutch group (20) comprising a actuation piston (30) hydraulically controlled by said first (16) and second lever (17) movable between a first raised position, in which said actuation piston (30) imposes to said hydromechanical clutch group (20) the transmission of the motion from the engine to the wheels and to the tool, and a second lowered position in which said actuation piston (30) frees said hydromechanical clutch group (20) by kinematically disconnecting said engine from said wheels and said tool.

A light-weight portable hydraulic system for engagement with equipment requiring hydraulic fluid to operate. The system includes a reservoir; a pump and an oil filter engaged with each other. One or more handles are provided on the system so that the system may be carried by a single individual or may be lifted onto or off of a supporting unit upon which the system is mountable. A suitable supporting unit may be a zero-turn stand-on mower. An input shaft for the pump is operatively engaged with the engine of the mower and the pump is powered by that engine. The system is selectively connected to the equipment requiring hydraulic fluid for operation, such as a mower attachment, by way of hydraulic hoses that quick connect to ports on the pump. The system may be engaged with or disengaged from the mower in around thirty seconds and without tools.

A drive arrangement for the reciprocating drive of a cutter bar comprises a hydraulic gear motor with a housing and a gearwheel, which is set in motion around a first axis by a hydraulic medium, and an eccentric drive, which comprises an eccentric element that can be rotatably driven by a gearwheel around a second axis parallel to the first axis, and a drive element connected to the eccentric element, which is, or can be, connected to the cutter bar.

An articulating mower deck system. The system is adapted to disable power to a blade associated with the wing deck section before the wing deck section begins to lift—from an operating position toward a folded position—yet does not interfere with blade operation when the wing deck section floats relative to a center deck section during normal operation of the deck. Articulating decks of modular construction are also provided, allowing assembly of multiple deck widths with a minimum of modular deck sections.

An outdoor unit has a frame that carries a ground grooming or working implement, a traction drive, and a cooling fan, all of which comprises loads on a prime mover. A power management controller automatically reduces an operational speed of the traction drive when prime mover droop is present. The cooling fan cools two cooling fluids. The controller stores data representing variable fan speeds for cooling each cooling fluid in both normal and above normal temperature ranges and for use when prime mover droop is present. The controller uses the highest fan speed required for cooling the cooling fluids in the normal range unless the droop fan speed is lower in which case the lower droop fan speed is used but only to the extent that the lower droop fan speed is not lower than the highest fan speed required for cooling the cooling fluids in the above normal temperature range.

A feederhouse assembly for an agricultural harvester includes a feederhouse comprising an inlet end, a rotational shaft coupled to the feederhouse and defining a plurality of fluid passages therethrough, and a frame adjacent the inlet end and arranged to pivot about the rotational shaft relative to the feederhouse. The frame defines a crop opening therethrough and is configured to carry a harvesting header. An agricultural harvester includes a chassis, the feederhouse assembly mounted to the chassis, and a processing system carried by the chassis and structured to receive crop material from the feederhouse.

Agricultural implements include equipment designed for harvesting, cleaning and storing farming produce. The farming produce it is designed to process particularly includes peanuts, beans or any other produce disposed in rows that can be gathered from the ground. The agricultural equipment can include a head (2), endowed with a collecting platform (3) with belts (5); with the head (2) including a transmission box (4) of the dual and pivotable type. The head (2) has complete hydraulic system with hydraulic oil tank (9), heat exchanger (9A) and filters, and the transmission box (4) further has an auxiliary input (11) to couple an accessory that can be hydraulic, pneumatic or electric, in order to drive auxiliary systems. In the rear part of the equipment are helicoids (6) that extend to the vertical transporter (7) and latter to the container (8).