The present invention provides a cutter for corn threshing. The cutter is mounted on a rotary food processor with a driving device, which comprises a cylinder with one open end; a cavity disposed in the cylinder to accommodate threshed corn cobs; a cutting member disposed at the middle of the open end of the cavity; and a locking portion disposed at the other end of the cylinder and connected to the driving device of the rotary food processor in a detachable manner. The present invention further discloses a rotary food processor with this cutter. The cutter for corn threshing and the rotary food processor both have the advantages of small volume, simple operation and high practicability.

A spreader system of an agricultural vehicle for spreading crop residue including first and second spreader devices and a chute. The first spreader device includes a plurality of first paddles configured to rotate about a first axis, the rotation of the first paddles producing a first stream of crop residue. The second spreader device includes a plurality of second paddles configured to rotate about a second axis, the rotation of the second paddles producing a second stream of crop residue. The chute receives the first stream of crop residue and the second stream of crop residue flow respectively from the first spreader device and the second spreader device. The first stream and the second stream of crop residue are combined in the chute.

A spreader system of an agricultural vehicle for spreading crop residue including first and second spreader devices and a chute. The first spreader device includes a plurality of first paddles configured to rotate about a first axis, the rotation of the first paddles producing a first stream of crop residue. The second spreader device includes a plurality of second paddles configured to rotate about a second axis, the rotation of the second paddles producing a second stream of crop residue. The chute receives the first stream of crop residue and the second stream of crop residue flow respectively from the first spreader device and the second spreader device. The first stream and the second stream of crop residue are combined in the chute.

A harvesting machine includes: a crop tank; a measuring device that measures an amount of crop that has been stored in the crop tank; an unloader apparatus that discharges crop that has been stored in the crop tank; a device control part that executes precise measurement oriented device setting processing; a measurement control part including a precise measurement execution part that performs, precise measurement which involves the precise measurement oriented device setting processing, and a simplified measurement execution part that executes, simplified measurement; an operational instruction processing part that outputs a precise measurement instruction and a simplified measurement instruction in response to an operation performed by a manual operation device; and a measurement result recording part that rewrites a simplified measurement result recorded based on a preceding simplified measurement instruction, with a precise measurement result that is based on a succeeding precise measurement instruction.

A harvesting machine includes: a crop tank; a measuring device that measures an amount of crop that has been stored in the crop tank; an unloader apparatus that discharges crop that has been stored in the crop tank; a device control part that executes precise measurement oriented device setting processing; a measurement control part including a precise measurement execution part that performs, precise measurement which involves the precise measurement oriented device setting processing, and a simplified measurement execution part that executes, simplified measurement; an operational instruction processing part that outputs a precise measurement instruction and a simplified measurement instruction in response to an operation performed by a manual operation device; and a measurement result recording part that rewrites a simplified measurement result recorded based on a preceding simplified measurement instruction, with a precise measurement result that is based on a succeeding precise measurement instruction.

An example agricultural harvesting machine includes a header and a feed system configured to feed material from the header through a threshing section along a conveyance path. The feed system includes a conveyance mechanism that conveys the material from the header to a rotating feed mechanism. The feed system also includes a drive system configured to rotationally drive the feed mechanism during a first state to convey the material along the conveyance path, and to reverse rotation of the feed mechanism during a second state. In one example, a drive system includes first and second drive mechanisms and a coupling mechanism configured to selectively couple one of the first or second drive mechanisms to an output mechanism, such as, but not limited to, a rotating feed mechanism in an agricultural harvesting machine.

A cutting longitudinal swaths grain harvesting and baling combine, includes a grain cutting and conveying system, a threshing and separation system, a grain cleaning apparatus, a grain collection and holding system, a straw compression and baling apparatus, a chassis travelling system, and a driving system; when the combine is harvesting grain in fields, the stalks are cut and conveyed to the threshing and separation system by the grain cutting and conveying system; the threshed and separated straw is compressed and baled by the straw compression and baling apparatus; the threshed and separated grain is cleaned by the grain cleaning apparatus; and the cleaned grain is conveyed by the grain collection and holding system to a grain storage bin. The combine can achieve harvesting of grain such as rice and wheat as well as compression and baling of threshed straw, having advantages of high working efficiency, stable performance, a simple process, and being time and labor saving.

A combine has a feeder house extending forward from the front of the combine, with the front of the feeder house defining a rectangular frame for supporting a harvesting head. A gauge wheel arrangement is supported on the rectangular frame and in turn supports the harvesting head. The gauge wheel arrangement includes a center frame that abuts the rectangular frame and pivots with respect to it. A left side frame with gauge wheels is hinged to the center frame. A right side frame with gauge wheels is hinged to the center frame. The center, left, and right frames can support the harvesting head and permit the harvesting head to pivot with respect to the feeder house, as well as supporting a part of the weight of the harvesting head on the gauge wheels.

A combine has a feeder house extending forward from the front of the combine, with the front of the feeder house defining a rectangular frame for supporting a harvesting head. A gauge wheel arrangement is supported on the rectangular frame and in turn supports the harvesting head. The gauge wheel arrangement includes a center frame that abuts the rectangular frame and pivots with respect to it. A left side frame with gauge wheels is hinged to the center frame. A right side frame with gauge wheels is hinged to the center frame. The center, left, and right frames can support the harvesting head and permit the harvesting head to pivot with respect to the feeder house, as well as supporting a part of the weight of the harvesting head on the gauge wheels.

A system for controlling the aggressiveness of a tailings processor that re-threshes tailings received from the grain cleaning system in an agricultural harvester is provided with at least one imaging device to image a grain sample. At least a portion of the grain sample has at least once passed through the tailings processor. A controller is connected to the imaging device and to an arrangement to automatically adjust the aggressiveness of the tailings processor. The controller is configured to automatically adjust the aggressiveness of the tailings processor using the arrangement, based on based on the level of broken grain and/or unthreshed grain determined from the image from the at least one imaging device by comparing the level of broken grain and/or unthreshed grain to the desired level.