A harvest analysis system, intended to be used in a machine (2, 3) for harvesting agricultural products, e.g. combine (2), forage harvester (3) or the like, comprising at least one image acquisition device (4, 40) and at least one processing unit (1), connected to said acquisition device (4, 40) and in turn comprising: at least one memory module (10) in which at least a first reference image is stored; and at least one comparison module (11, 12) configured to perform a comparison between the images of the harvested products, acquired by said device (4, 40) and said reference image.

A leading vehicle loads material into a receiving vehicle during an unloading operation. An unloading control system detects and processes stop conditions to automatically stop a material conveyance mechanism when a stop condition arises.

A system for sensing harvested crop levels within an agricultural harvester may include a crop tank configured to receive harvested crop. The system may further include a sensor configured to emit a sensor beam into the crop tank for reflection off of the top surface of the harvested crop. Additionally, the system may include a reflection panel positioned at a minimum detectable crop level within the crop tank. The reflection panel may be configured to reflect the sensor beam when the current crop level is vertically below the minimum detectable crop level. A center of the reflection panel may be positioned closer to the sensor than an outer edge of the reflection panel such that the reflection panel diffuses the sensor beam as it reflects off of the reflection panel.

In one embodiment, a system comprising an impervious bin skirt, the bin skirt comprising at least one section, a top portion of a first section of the bin skirt to couple to a side wall of the bin to shield a portion of a base of the bin from moisture penetration.

A grain harvesting articulated combine includes a forward crop processing power unit (PPU), a rear grain cart, and an articulation joint that connects the PPU with the rear grain cart. The articulation joint includes a grain auger assembly running from the PPU to the rear grain cart for transferring clean grain from the PPU to the rear grain cart and has a forward end at the PPU and a rear end adjacent to the rear grain cart. The grain auger assembly is housed within a tube with a rotating auger housed therein. A grain yield sensor is carried by the rear grain cart and is located adjacent and to and beside the grain auger assembly wherein the auger housed therewithin throws grain against the grain yield sensor. The auger is terminated by a rotating paddle assembly that throws the grain against the grain yield sensor.

A combine harvester includes: a grain conveyance mechanism for conveying grains from a threshing apparatus to a grain tank; a grain discharge apparatus provided in an end area of the grain conveyance mechanism, the grain discharge apparatus having a discharge case provided with a grain discharge opening, and a discharge rotor rotatably arranged in the discharge case; a pressed portion that is subjected to a pressing force applied by grains immediately before the grains are discharged by the discharge rotor; a load detector for detecting the pressing force exerted on the pressed portion; and a yield evaluator for evaluating the amount of conveyed grain based on a detection signal from the load detector.

An embodiment includes a combine including a feeder housing for receiving harvested crop, a separating system for threshing the harvested crop to separate grain from residue, a grain tank for storing the separated grain, a grain tank level sensor for detecting a level of grain in the grain tank, an inclination sensor for detecting inclination of the combine, and a controller that controls the combine. The controller configured to receive the grain tank level from the grain tank level sensor, receive an inclination value from the inclination sensor, adjust the grain tank level based on the inclination value, and alert an operator of the adjusted grain tank level.

A feederhouse for an agricultural vehicle includes an assembled driveshaft having a shaft and at least one sprocket that is rotationally fixed to said shaft. A shield assembly is positioned adjacent the sprocket, wherein the shield assembly includes two components including a top component and a bottom component. The top component includes a first mating surface and a first wall. The bottom component includes a second mating surface and a second wall. When the two components are connected together by joining the first mating surface to the second mating surface, the two components form a first opening through which the shaft is positioned. A bearing component is configured to bear on both the first wall and the second wall for urging the first mating surface toward the second mating surface in order to limit the top component from separating from the bottom component.

An elevator assembly for a harvester may include an elevator housing and an elevator extending within the elevator housing between a proximal end and a distal end. As such, the elevator may be configured to carry harvested crops between its proximal and distal ends. Furthermore, the elevator assembly may include a storage hopper extending from the elevator housing at a location adjacent to the distal end of the elevator. The storage hopper may include a conveyor extending within the storage hopper between a first end and a second end, with the conveyor configured to carry the harvested crops between its first and second ends towards a discharge opening of the storage hopper.

A system for fastening a tension rod of a grain tank of an agricultural vehicle to a frame of the agricultural vehicle to which the grain tank is mounted. The tension rod includes an elongated body extending between a first connection end that is configured to be connected either directly or indirectly to the grain tank, and a second connection end including openings for respectively receiving fasteners. A first member is either configured to be mounted to the frame or associated with the frame. The first member includes (i) openings for respectively receiving the fasteners, and (ii) a first non-planar mounting surface. A second member includes (i) openings for respectively receiving the fasteners and (ii) a second non-planar mounting surface that is configured to be directly engaged with the first non-planar mounting surface to limit relative motion between the tension rod and the frame in an assembled state.