An articulated harvesting combine includes of a forward power processing unit (PPU, 12) and a rear grain cart (14), wherein the PPU carries dual axially mounted engines (36 and 38) with oppositely opposed crankshafts (100 and 102) with one toward the rear grain cart and the other engine away from the rear grain cart, wherein the dual engines share a common radiator, single air conditioning condenser, single alternator, common batteries, common fuel tank and exhaust fluid tank; but have separate hot exhaust treatment system, separate hot exhaust manifolds, and separate side-mounted charge air coolers.

Disclosed is a complete engine cooling system for an engine carried by a grain harvesting combine having an internal combustion engine and hot exhaust components, and having a front operator cab. The system includes a generally horizontal fan assembly located atop the harvesting combine for drawing in air, a radiator associated with the engine and over which air flows for engine cooling, and charge air coolers for combustion air cooling, and air conditioning and hydraulic coolers, a centrifugal scroll that takes the drawn in air and removes entrained particles to produce a clean exhaust air and dirty exhaust air; and a filter assembly through which the pre-cleaned exhaust air flows for producing filtered air for admittance into the engine for combustion.

A combine harvester grain cleaner. The grain cleaner includes an upper, relatively moveable framework supporting one or more grain sieves, one or more sources of drive for causing reciprocating movement of the one or more grain sieves, a lower, relatively fixed framework supporting one or more grain or tailings sheets, and a vibrator connected to the one or more grain and tailings sheets for causing a vibratory motion thereof and for, through the vibratory motion, causing movement of grain thereon in a predetermined direction. The vibratory motion has a higher frequency than a frequency of the reciprocation of the one or more grain sieves.

A grain cleaning system for use in an agricultural combine harvester comprises a return pan, a chaffer, and a grain chute. The return pan is arranged to reciprocate in a fore-aft manner to advance crop material forwardly and comprises openings allowing grain to fall from the return pan through the openings. The chaffer is arranged to reciprocate in a fore-aft manner to advance crop material rearwardly and underlies the return pan. The grain chute is positioned in communication with one or more openings of the openings in the return pan and in communication with the chaffer to guide grain received from the one or more openings to the chaffer in a manner that bypasses material-other-than-grain (MOG) advanced rearwardly by the chaffer. An agricultural combine harvester comprising a grain cleaning system with a grain chute is disclosed.

An agricultural harvester includes a chassis, a cleaning system carried by the chassis, a crop material elevator supplied with crop material that has passed through the cleaning system and has a first inlet and a second inlet, and an auger system supplying the crop material from the cleaning system to the crop material elevator. The auger system includes a first auger defining an auger axis that extends in a conveying direction toward the crop material elevator and is configured to supply crop material to the first inlet, a second auger defining a second auger axis that extends in the conveying direction, and a crop material conveyor configured to supply crop material from the second auger to the second inlet generally transverse to the second auger axis.

An adjustable vane system for use with a rotor cage of a threshing system of an agricultural harvester includes a vane. The vane includes: a generally helically curved inner profile; a surface being an outer profile that is opposite the inner profile and is generally helically curved over a portion of the vane, the outer profile being configured to be positioned closer to the rotor cage than the inner profile; and a flat portion located midway along the outer profile.

A combine harvester is disclosed with an infeed arrangement for receiving the harvested material, with a threshing device for degraining the harvested material, and with a cleaning device that is downstream from the threshing device for segregating the harvested material, and thereby separating the grain from the non-grain components. The cleaning device has a sieve device that can rotate about a rotational axis with an at least sectionally sieve-shaped sieve jacket that extends in a peripheral direction around the rotational axis. Separating the grain from the non-grain components is performed by the cleaning device by superimposing a rotary movement and oscillating movement of the sieve jacket such that the oscillating movement is directed transverse to the rotational axis of the sieve device, wherein the oscillating movement is caused by a segmentation of the sieve jacket in a peripheral direction, and a swinging of each peripheral segment of the sieve jacket about a pivot axis associated with the respective peripheral segment.

A preparation section of a combine harvester that is configured to receive a mixture of grain and material other than grain (MOG) from a threshing section of the combine harvester. The preparation section includes a conveyor positioned beneath the threshing section that is configured to transport the grain and MOG in a downstream direction toward a cleaning section, and a deflector positioned at a downstream end of a conveyor that is configured to launch the grain and MOG into the air and cause at least partial separation of the MOG and grain prior to falling onto the cleaning section.

A residue deflector is disposed in a combine body, and positioned along an airflow path to guide residue from an exit end of a cleaning shoe and a threshing and separation assembly, to a residue chopper. The deflector is configured with a plurality of spaced fingers so that air can pass through the deflector between the fingers.

A high strength sieve which is lightweight and durable without having to add springs, and without requiring a high level of force to effect adjustment of the louvers. The high strength sieve utilizes hollow tubes to support the louvers. Providing hollow tubes (i.e., rather than solid wires) allows for larger diameter holes to be used in the frame. This provides for increased bearing surfaces, as well as provides for better tolerances. This reduces the movement of the tubes within the holes. Preferably, the tubes are mounted in the frame through holes which are extruded, thereby providing for increased bearing surfaces and a tighter fit. The extruded holes also provide a natural lead-in for the insertion of the tubes (i.e., during assembly of the sieve). Alternatively, solid wires can be provided extending through the extruded holes instead of hollow tubes.