An unloading apparatus is arranged to direct material to a container. A controller determines a build-up speed of the material in the container; in accordance with the determined build-up speed, determine a rate of change to be applied when setting an attribute of at least one of the unloading apparatus and container; and set an attribute of at least one of the unloading apparatus and container in accordance with the determined rate of change in order to direct the material from the unloading apparatus to the container.

The measurement device comprises a transmitter for providing a transmitted signal at a frequency. The transmitter provides the transmitted signal to the transmitting antenna. A receiving antenna is arranged to receive the transmitted signal. A receiver is capable of receiving the transmitted signal from the receiving antenna. An electronic data processor is adapted to measure an observed parameter of the transmitted signal between the transmitting antenna and the receiving antenna to estimate the precise yield, where the observed parameter comprises observed attenuation, phase or both of the transmitted signal, as received at the receiver.

A process for weighing a harvested crop stored in a tank of a harvesting machine, a frame supporting the tank is mounted on a wheel set by a lifting device which is operable to move the frame upwardly and downwardly upon control of a hydraulic system. The process controlling the hydraulic system and includes the steps of: determining at least one height position of the frame on the displacement course; measuring a lowering pressure and a raising pressure in the hydraulic system at the position; calculating, from the measured pressures, a balancing pressure for the frame. The process is performed before unloading the stored crop in order to calculate a loaded balancing pressure and after the unloading in order to calculate an empty balancing pressure. The weight of the stored crop is calculated from a pressure variation between the loaded balancing pressure and the empty balancing pressure.

A return pan for an agricultural harvester has an inclined upper surface portion, disposed to receive grain from a threshing or separating mechanism and laterally convey grain under the force of gravity to an inlet of a grain flow sensor.

One or more techniques and/or systems are disclosed for automating the collection aggregation, and processing of data relating to harvesting or dispersion of an agricultural product. During harvesting and planting operations, data related to the product harvested or planted can be collected, aggregated, and used to improve the operation, and to help identification of the product at point of sale or point of dispersion. Further, certain operations can be automated during the harvesting or planting, such as automatic deployment of a field cart to offload/load product from/to the agricultural vehicle in the field. Additionally, load data can be automatically collected, aggregated, and identified, to follow the product through all stages.

A measuring device is provided for measuring a mass flow composed of bulk material, in particular grain, in a continuous, circulating conveyor enclosed in part by a housing, having planar conveyor elements, which conveys the bulk material from a lower bulk material receiving area to a higher bulk material delivery area. A substantially circular movement course is imposed on the bulk material delivered by the respective conveyor element in a substantially radial direction of an inner surface of a cover section of the housing by a guide surface formed in the upper region of the conveyor. The bulk material is deflectable toward a sensor surface of the measuring device. At least the sensor surface of the measuring device is disposed in the upper region of the conveyor such that there is a tangential course in the transition from the guide surface to the sensor surface.

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.

Systems, methods and apparatus for monitoring yield while harvesting. In one embodiment a mass flow rate sensor measures the mass flow rate of the harvested grain. A weight sensor measures the weight of the harvested grain. The measured mass flow rate is correlated with the weight of the harvested grain. Processing circuitry calculates any error in the measured mass flow rate using the measured weight. The calculated error is used to correct any inaccuracy in the measured mass flow rate.

A grain mass flow sensor assembly of an agricultural harvester has a continuously curved sensor plate positioned to receive a grain flow from an exit of the grain elevator. The continuously curved sensor plate is configured to change the direction of the grain flow in order to generate a reaction force for measuring the grain mass flow rate of the grain flow. The continuously curved sensor plate is attached to a sensor plate to load cell mounting bracket. The sensor plate to load cell mounting bracket is attached to a single point load cell torque or moment compensated force transducer at a single mounting point. The single point load cell torque or moment compensated force transducer produces a mass flow sensor signal that is proportionate to the grain mass flow rate.

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.