A baling device to form bales of crop material, including a frame, an intake device, a bale forming device for forming a bale of the crop material, the bale forming device including at least one endless belt to delimit a baling chamber, and a number of guiding elements to guide the endless belt, the outlet of the intake device is located at a fixed position with respect to the frame, and at least three guiding elements are movably mounted with respect to the outlet of the intake device to position for subsequent bales different pairs of two guiding elements of the at least three movable guiding elements at the opposite sides of the outlet.

A system comprising a work machine ECU configured to communicate with a vehicle, a vehicle ECU configured to communicate with a work machine, the vehicle ECU configured to control operation of the vehicle at in a first mode, the first mode being determined by a first signal transmitted from the work machine ECU to the vehicle ECU, the vehicle ECU configured to operate the vehicle in a second mode, the second mode being determined by a second signal transmitted from the work machine ECU to the vehicle ECU, and an actuator configured to send a command to the vehicle ECU to operate the vehicle in a third mode, the third mode being determined by a third signal transmitted from the work machine ECU to the vehicle ECU.

A baler ejection system, that may be used with an agricultural harvester, such as a round baler, waste baler, combine, or cotton harvester, uses the motion of a pair of parallel arms that extend transversely from the sidewalls of a bale chamber a set of distinct pivot points. When activated the parallel arms raise to expose an outlet through which the bale may be ejected. A formed bale may become ejected by one or more conveyer belts that exert a rearward force on the bale within the bale chamber.

Systems for improving fire safety in agricultural machinery are configured for detecting, at least partially controlling, and/or suppressing adverse fire-related conditions. The adverse fire-related conditions can include sparks, embers, and/or flames in the agricultural machinery.

Systems for improving fire safety in agricultural machinery are configured for detecting, at least partially controlling, and/or suppressing adverse fire-related conditions. The adverse fire-related conditions can include sparks, embers, and/or flames in the agricultural machinery.

An agricultural work machine, an agricultural work machine control system, and method for an agricultural work machine having Bluetooth enabled RFID tags to determine a fault condition of machine components, devices, parts or systems. The Bluetooth enabled RFID tags are located on, at, or near machine components or systems to sense a temperature of those components or systems. The Bluetooth enabled RFID tags are interrogated to determine sensed temperatures and component identifiers. A controller receives the temperatures and component identifiers and compares the received temperatures to a threshold to determine whether a fault condition exists. If so, the controller transmits an alert signal to a user interface to indicate that a fault condition exists with an identified component, part, device, or system.

An agricultural vehicle includes: a chassis; a crop material handler carried by the chassis and configured to handle crop material; a communication interface carried by the chassis; and a controller operatively coupled to the communication interface and configured to: define a field map corresponding to a field; receive a bale drop zone input signal; define a bale drop zone within the field map based on the received bale drop zone input signal, the bale drop zone defining a location and a bale drop area within the field map; determine if the bale drop zone is sufficiently sized for a number of bales formed from crop material on the field to be placed in the bale drop zone; and output a drop zone insufficient signal if the bale drop zone is not sufficiently sized for the number of bales to be placed in the bale drop zone.

A bale retriever for retrieving bales which includes a bale pick up configured to contact and pick up a bale, a steering assembly configured to steer the bale retriever, at least one sensor configured to sense at least one bale feature of the bale, and a controller operatively coupled to the steering assembly and the at least one sensor. The controller is configured to receive bale drop location information, receive at least one bale feature signal from the at least one sensor, identify an exact bale location of the bale based at least partially on the bale drop location information and the at least one bale feature signal from the at least one sensor, generate a steering control signal based at least partially on the exact bale location, and output the steering control signal to the steering assembly.

An agricultural work machine, an agricultural work machine control system, and method for an agricultural work machine having RFID tags to determine a fault condition of machine components, devices, parts or systems. The RFID tags are located on, at, or near machine components or systems to sense a temperature of those components or systems. A receiver/transmitter interrogates the RFID tags and receives the sensed temperatures, and component identifiers. A controller receives the temperatures from the receiver/transmitter and compares the received temperatures to a threshold to determine whether a fault condition exists. If so, the controller transmits an alert signal to a user interface to indicate that a fault condition exists with an identified component, part, device, or system.

An agricultural work machine, an agricultural work machine control system, and method for an agricultural work machine having RFID tags to determine a fault condition of machine components, devices, parts or systems. The RFID tags are located on, at, or near machine components or systems to sense a temperature of those components or systems. A receiver/transmitter interrogates the RFID tags and receives the sensed temperatures, and component identifiers. A controller receives the temperatures from the receiver/transmitter and compares the received temperatures to a threshold to determine whether a fault condition exists. If so, the controller transmits an alert signal to a user interface to indicate that a fault condition exists with an identified component, part, device, or system.