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 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, that inspects grains using a plurality of light spectra, analyzes the results, and produces detailed reports from the analysis.

An automated crop harvester includes: (a) a frame; (b) a drive system supporting the frame for movement of the frame along a ground surface in a harvesting direction; and (c) a plurality of articulated robot arms mounted to the frame and spaced laterally apart from each other generally perpendicular to the harvesting direction for harvesting crops in corresponding crop rows. Each robot arm has end-of-arm tooling automatically movable laterally relative to the frame into alignment with respective crops projecting from the ground surface for cutting and collecting the crops.

An automated crop harvester includes: (a) a frame; (b) a drive system supporting the frame for movement of the frame along a ground surface in a harvesting direction; and (c) a plurality of articulated robot arms mounted to the frame and spaced laterally apart from each other generally perpendicular to the harvesting direction for harvesting crops in corresponding crop rows. Each robot arm has end-of-arm tooling automatically movable laterally relative to the frame into alignment with respective crops projecting from the ground surface for cutting and collecting the crops.

An outer stalk divider for an attachment for harvesting row crop, in particular for a corn picker or corn header, includes a base body that extends in a traveling direction and a surface that extends in the traveling direction on an upper side, a hood, which is situated at the front on the base body as viewed in the traveling direction, and tapers in the traveling direction, and a cover element which, in the traveling direction, is situated behind the hood and on the upper side. The cover element extends at least partially along the surface of the base body, and is at least partially arched in design on an outer surface facing away from the surface. The cover element may be adjustable relative to the base body.

An outer stalk divider for an attachment for harvesting row crop, in particular for a corn picker or corn header, includes a base body that extends in a traveling direction and a surface that extends in the traveling direction on an upper side, a hood, which is situated at the front on the base body as viewed in the traveling direction, and tapers in the traveling direction, and a cover element which, in the traveling direction, is situated behind the hood and on the upper side. The cover element extends at least partially along the surface of the base body, and is at least partially arched in design on an outer surface facing away from the surface. The cover element may be adjustable relative to the base body.

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.