A system to detect grain loss of a harvester during harvesting operations. The system includes at least two pans magnetically supported on the harvester above a ground surface, by separate electromagnets being electrically isolated from a power source while magnetically supporting the at least two pans. A signal controller generates a release signal when triggered by a user. A signal receiver responsive to the generated release signal electrically connects one of the electromagnets with the power source causing one of the at least two pans to be released to the ground surface while the second electromagnet remains electrically isolated from the power source and magnetically supported on the combine harvester until another release signal is triggered by the user causing the signal receiver to electrically connect the second electromagnet with the power source to release the second pan to the ground surface.

A system to detect grain loss of a harvester during harvesting operations. The system includes at least two pans magnetically supported on the harvester above a ground surface, by separate electromagnets being electrically isolated from a power source while magnetically supporting the at least two pans. A signal controller generates a release signal when triggered by a user. A signal receiver responsive to the generated release signal electrically connects one of the electromagnets with the power source causing one of the at least two pans to be released to the ground surface while the second electromagnet remains electrically isolated from the power source and magnetically supported on the combine harvester until another release signal is triggered by the user causing the signal receiver to electrically connect the second electromagnet with the power source to release the second pan to the ground surface.

In a grain cart having an auger fold actuator, a gate actuator, and at least one spout actuator, a grain cart control system has an input device received within an operator cab to generate command signals responsive to operator commands, an electronic controller operatively associated with selected actuators of the grain cart, a valve actuator connected to each valve of the selected actuators of the grain cart, and stored programmable criteria to generate activation signals for the valve actuators in response to the command signals. Each mechanical function that is controlled also has a rotary potentiometer for positional feedback. To actuate any sequence, a joystick will send commands to the controller to activate a sequence. Since the controls according to the present invention are driven by a logic-based controller, various functions can be automated.

In a grain cart having an auger fold actuator, a gate actuator, and at least one spout actuator, a grain cart control system has an input device received within an operator cab to generate command signals responsive to operator commands, an electronic controller operatively associated with selected actuators of the grain cart, a valve actuator connected to each valve of the selected actuators of the grain cart, and stored programmable criteria to generate activation signals for the valve actuators in response to the command signals. Each mechanical function that is controlled also has a rotary potentiometer for positional feedback. To actuate any sequence, a joystick will send commands to the controller to activate a sequence. Since the controls according to the present invention are driven by a logic-based controller, various functions can be automated.

A control system includes a controller configured to determine a target speed between a first target position of a haul vehicle relative to a harvester and a second target position of the haul vehicle relative to the harvester based on a flow rate of agricultural product through a conveyor of the harvester. The haul vehicle is coupled to a storage compartment, an outlet of the conveyor is aligned with a first unloading point within the storage compartment while the haul vehicle is positioned at the first target position, and the outlet of the conveyor is aligned with a second unloading point within the storage compartment while the haul vehicle is positioned at the second target position. Furthermore, the controller is configured to output a control signal indicative of instructions to direct the haul vehicle from the first target position to the second target position at the target speed.

A crop loss inhibiting device directs air flow upwardly into cut plants to prevent crops from falling to the ground prior to being collected by a combine. The device includes a combine having a head including a skid plate and a plurality of spaced cutting projections extending forwardly from the skid plate. The combine has a collector positioned rearwardly from the spaced cutting projections wherein the collector receives and collects plants cut by the spaced cutting projections. Each of a pair of manifold tubes is coupled to the combine rearwardly of the spaced cutting projections. Each of the manifold tubes has a plurality of holes facing upwardly away from the spaced cutting projections. A blower is coupled to the manifold tubes creating air flow out through the holes such that the air flow inhibits crops from falling to the ground prior to being collected by the collector.

A system and method for automated grain inspection and analysis of results during harvest, using an inspection system mounted on a combine harvester with geolocation tracking, allowing for real time analysis during harvest and tracking of grain quality by location of harvest.

A system and method for automated grain inspection and analysis of results during harvest, using an inspection system mounted on a combine harvester with geolocation tracking, allowing for real time analysis during harvest and tracking of grain quality by location of harvest.

A system and method for automated grain inspection and analysis of results during harvest, using an inspection system mounted on a combine harvester with geolocation tracking, allowing for real time analysis during harvest and tracking of grain quality by location of harvest.

A multi-layer segmentation/stalk cutter device for a first season of double-crop rice and a control method, and a combine harvester for a first season of double-crop rice, the multi-layer segmentation/stalk cutter device comprising: a cutting platform, a segmenting cutter and a stalk cutter, at least one segmenting cutter being disposed at a lower rear portion of the cutting platform, the segmenting cutter being hinged on a moving chassis, and a second execution mechanism controlling the cutting height of the segmenting cutter; the stalk cutter being disposed at a lower rear portion of the segmenting cutter, the stalk cutter being hinged on the moving chassis, and a third execution mechanism controlling the cutting height of the stalk cutter.