An agricultural wagon having a plurality of load sensors between a tow bar and a chassis. The load sensors are configured to sense the load of the wagon. The load sensors may sense the load of the wagon when it is supported on a tow coupling or on a stand. The agricultural wagon also has a collapsible cross conveyor, a lift-out tail gate and plastic hungry boards. The direction in which the cross conveyor feeds out material can be automatically selected based on the position or movement of the cross conveyor.

An agricultural wagon having a plurality of load sensors between a tow bar and a chassis. The load sensors are configured to sense the load of the wagon. The load sensors may sense the load of the wagon when it is supported on a tow coupling or on a stand. The agricultural wagon also has a collapsible cross conveyor, a lift-out tail gate and plastic hungry boards. The direction in which the cross conveyor feeds out material can be automatically selected based on the position or movement of the cross conveyor.

An agricultural wagon, for example a grain cart, of the type including an upright unload auger at the front end of the grain receiving bin which can be pivoted between left side and right side discharge positions, further includes a gearbox supported at the bottom end of the unload auger. The gearbox has a main shaft directly coupled to the unload auger. An input shaft of the gearbox, coupled to the main shaft by gear reducing bevel gears, receives an input rotation from a drive source external of the gearbox, for example the PTO of a tractor, for driving the main shaft and the unload auger. A second pair of bevel gears transfer some of the input rotation of the main shaft to an output shaft of the gearbox which is connected to a lower auger along the bottom of the grain receiving bin.

An agricultural wagon, for example a grain cart, of the type including an upright unload auger at the front end of the grain receiving bin which can be pivoted between left side and right side discharge positions, further includes a gearbox supported at the bottom end of the unload auger. The gearbox has a main shaft directly coupled to the unload auger. An input shaft of the gearbox, coupled to the main shaft by gear reducing bevel gears, receives an input rotation from a drive source external of the gearbox, for example the PTO of a tractor, for driving the main shaft and the unload auger. A second pair of bevel gears transfer some of the input rotation of the main shaft to an output shaft of the gearbox which is connected to a lower auger along the bottom of the grain receiving bin.

A transport vehicle arrangement includes a transport vehicle, a transport implement coupled with the transport vehicle, a sensor arrangement for establishing an angular orientation of the transport implement relative to the transport vehicle, a wireless receiver for receiving harvester information related at least to the speed and direction of an agricultural harvester vehicle, and an electrical processing circuit coupled with the sensor arrangement and the wireless receiver. The electrical processing circuit is configured for steering the transport vehicle arrangement in a reverse direction such that the transport implement is positioned at a desired position relative to an unloading conveyance of the agricultural harvester vehicle, based upon the sensed angular orientation of the transport implement and the harvester information.

A transport vehicle arrangement includes a transport vehicle, a transport implement coupled with the transport vehicle, a sensor arrangement for establishing an angular orientation of the transport implement relative to the transport vehicle, a wireless receiver for receiving harvester information related at least to the speed and direction of an agricultural harvester vehicle, and an electrical processing circuit coupled with the sensor arrangement and the wireless receiver. The electrical processing circuit is configured for steering the transport vehicle arrangement in a reverse direction such that the transport implement is positioned at a desired position relative to an unloading conveyance of the agricultural harvester vehicle, based upon the sensed angular orientation of the transport implement and the harvester information.

A rotor feeder unit for an agricultural machine, such as an agricultural baler. The rotor feeder unit includes a rotor feeder, and a drive for driving the rotor feeder. The drive of the rotor feeder unit include an input that is configured to be coupled to a power source, an output coupled to the rotor feeder for rotating the rotor feeder about its axis of rotation, and a variable ratio transmission coupling the input and the output. The variable ratio transmission includes a variable-diameter input pulley, a variable-diameter output pulley, and a belt arranged between the input pulley and the output pulley.

A transport vehicle arrangement includes a transport vehicle, a transport implement coupled with the transport vehicle, a sensor arrangement for establishing an angular orientation of the transport implement relative to the transport vehicle, a wireless receiver for receiving harvester information related at least to the speed and direction of an agricultural harvester vehicle, and an electrical processing circuit coupled with the sensor arrangement and the wireless receiver. The electrical processing circuit is configured for steering the transport vehicle arrangement in a reverse direction such that the transport implement is positioned at a desired position relative to an unloading conveyance of the agricultural harvester vehicle, based upon the sensed angular orientation of the transport implement and the harvester information.

A transport vehicle arrangement includes a transport vehicle, a transport implement coupled with the transport vehicle, a sensor arrangement for establishing an angular orientation of the transport implement relative to the transport vehicle, a wireless receiver for receiving harvester information related at least to the speed and direction of an agricultural harvester vehicle, and an electrical processing circuit coupled with the sensor arrangement and the wireless receiver. The electrical processing circuit is configured for steering the transport vehicle arrangement in a reverse direction such that the transport implement is positioned at a desired position relative to an unloading conveyance of the agricultural harvester vehicle, based upon the sensed angular orientation of the transport implement and the harvester information.

An unloading arrangement includes and agricultural harvester and a transport vehicle arrangement. The agricultural harvester includes an unloading conveyance and a wireless transmitter for transmitting information relating at least to a speed and direction of the harvester. The transport vehicle arrangement includes a transport vehicle; a transport implement coupled with the transport vehicle; a sensor arrangement for establishing an angular orientation of the transport implement relative to the transport vehicle; a wireless receiver for receiving the transmitted information from the harvester; and an electrical processing circuit coupled with the sensor arrangement and the wireless receiver. The electrical processing circuit is configured for steering the transport vehicle arrangement in a reverse direction such that the transport implement is positioned at a desired position relative to the unloading conveyance, based upon the sensed angular orientation of the transport implement and the transmitted information received from the harvester.