None.
Not applicable.
The present disclosure relates to a system and method to unload grain from a grain tank on an agricultural harvester to a transport vehicle, and specifically to a sliding end spout for an articulated agricultural harvester unloader.
At high flow rates approaching 9 bushels/second attainable by the grain cart disclosed in U.S. Ser. No. 14/946,842 filed Nov. 20, 2015, it is necessary to control the trajectory of the grain as it exits from the end of the unload auger. In the case of unloading into a truck that has a narrower (say, 8 feet) opening at its top, the flow must be directed primarily downwardly. If it is not done so, then, as the truck becomes nearly full, the horizontally outward momentum of the grain falling onto the grain already in the truck box, can cause a condition which in the fluid world is called “hydraulic jump”, which results in the grain actually rising above the static level at the far side of the truck box and being projected right over and off the side of the truck onto the ground. The net result is that the truck cannot be “topped off” or even reach an acceptable level of fullness without sincerely reducing the rate of flow. This same scenario holds true for current grain carts that have similar or greater grain flow rates.
Conversely, when unloading into a grain cart that is both taller and wider in the shape of it's “box”, and also typically has a higher “backstop” wall to push the grain flow against, it is often quite useful to have a material flow having a distinctive outward momentum to help fill the wider box and pile up against that backboard to achieve maximum capacity. It also is quite useful to have the stream of grain to be projected further outwardly to better fill the further regions of the wider cart box.
Therefore, there is need for a control mechanism to quickly and controllably move the unloader spout such that both functions are useable on command. Current mechanisms are exclusively dedicated to the hinging of a structure to make this change in trajectory. Such unloaders often get quite large, heavy, and quite long, resulting in issues of clearance when the unloader is in a down or home position and significant weight to support the great unloader length when it is extended outwardly. In both cases, the length of the mechanism (unloader) becomes a clearance issue versus the height of grain carts and perhaps truck boxes. In most cases, the harvester just does not accept the complexity of such units and foregoes the advantages to save the hassle and risk. Grain carts quite often do have such maneuverable spout mechanisms on the larger and more modern units with very high unload rates.
The presently disclosed combine unloader spout overcomes such issues by having a new sliding end spout.
An improved grain unloader for unloading grain from a grain storage bin of a grain harvesting combine is terminated by a hood having a lower grain exiting opening terminating the unloader wherein the hood reversibly moves laterally outwardly for directing the trajectory of the grain flowing therefrom. The hood has a lower grain exiting opening terminating the unloader wherein the hood includes an upper stationary slanted wall and a lower extendable hood portion, wherein the upper stationary slanted wall directs the grain downwardly when the hood is retracted and downwardly, and outwardly when the hood is extended. A linear actuator is attached between the hood and the unloader. Drawer slides connect the unloader and the hood for movement of the hood.
For a fuller understanding of the nature and advantages of the present method and process, reference should be had to the following detailed description taken in connection with the accompanying drawings, in which:
The drawings will be described in greater detail below.
The disclosed rear grain cart design addresses the foregoing shortcomings. All of the power needed to drive augers is transmitted to the rear module at hydrostatic pressures and flow rates in only two pump circuits—one circuit for the swinging the unloader auger that moves in and out, and the other circuit running all other augers in the rear grain cart. The two bottom drag augers (front and rear in the grain cart), the drawbar auger carrying grain from the front module to the rear module, the bubbler or inclined tank fill auger receiving grain from the drawbar auger to fill the grain cart grain bin, and the unloader lift auger are driven with power delivered to the rear module by a large hydrostatic motor that drives a common chain box for power distribution. By doing this, any one component of these augers can realize startup or clog-clearing torque (power) that can, perhaps, be as large as the level delivered by a large hydrostatic motor. With the inertias of each of the components being tied to the whole system, startup of a given component can harvest inertia from others that already may be turning, resulting in available power instantaneously exceeding even the output of the main motor (for an impulse period). It, then, becomes the art of configuring drive circuits that allow the main motor driven chain box to distribute the power to the various augers located in the rear grain cart (or rear module). The power, motors, and pumps delivering power to the rear grain cart augers are detailed in U.S. Ser. No. 15/643,685 filed Jul. 7, 2017.
The articulated agricultural harvester or combine (these terms being synonymous and used interchangeably) in the drawings is a Tribine™ harvester (Tribine Industries LLC, Logansport, Ind.) having a grain bin capacity of 1,000 bushels of clean grain and unloads the clean grain at a rate of 540 bushels per minute (9 bushels/second). Normal grain removal from an elevated grain bin uses an unload auger running from the back to the front of the grain bin for transferring grain to the unload arm assembly. When grain is unloaded from the grain bin in this fashion, grain preferentially is removed from the rear of the grain bin; thus, leaving the remaining grain in the front of the grain bin. This can cause weight on the tongue (articulation joint) to increase from near zero to around 8,600 lbs. The disclosed grain cart auger feed system and unload auger system evens out grain removal and unloads virtually all of the grain in the grain cart very rapidly.
Referring initially to
An off-loading auger assembly, 22, is in the folded home position and being carried by rear grain cart 14. Grain cart 14 also bears a foldable roof, 24, shown in an open position, but which can fold inwardly to cover grain stored in rear grain cart 14. Foldable roof 24 may be made of metal, plastic, or other suitable material, but may be made of durable plastic for weight reduction and easy folding/unfolding. Clean grain is stored in grain cart 14, the sides of which may be made of plastic also in keeping with desirable weight reduction; although, it could be made of metal also at the expense of weight. All plastic parts may be filled with particulate or fiber reinforcement in conventional fashion and could be laminate in construction.
Referring now to
Referring in more detail to
Referring now also to
Also seen in
The grain yield sensor assembly is seen if
In particular, tube 26 is inserted a bit (say, about 6″) into a larger diameter tube, 108. The flights of auger 100 terminate a short distance (say, about 2″) before the end of tube 26. Paddle assembly 102 start where the flights terminate and initially are a smaller diameter (say, about 11″), which, then, increases in diameter to its full diameter (say, about 14″) once inside larger diameter tube 108. This was done because the auger works best (most efficiently) at an RPM that proved to be too slow for the paddles to give the grain sufficient velocity to penetrate into the vertical auger flights at very high grain flow rates. Thereby, the tube surrounding the paddles is of larger diameter than the tube surrounding the auger. The auger works best (considering grain damage) with a clearance of about ¾″, while the paddles are best suited for clearance more near ¼″. The confluence of all these factors leads to the need for differential diameter.
One of the paddles at the tube 26 end is 90° offset to the end of the flight of auger 100 with the other paddle offset 180° from the first paddle. This feature both aids with the release trajectory of the grain, while also giving that transition flow greater capacity of flow volume. At the grain cart end of tube 108, an opening is created and a roof, 110, extends laterally over to and covers sensor 106 and the feed end of bubbler auger assembly 56. With sensor 106 being roughly 5″ wide, and the width of roof 110 being roughly about 14″ wide, and sensor 106 necessarily being about 1″ from the front wall, sensor 106 is sensing between about 30% to 40% (about 36% for the dimensions given) of the total width of grain flow flung by paddle assembly 102, which is sufficient given the normalizing effects of the above configurations. The 1″ gap is necessary to allow flow that is crushed sideways by the plate to be swept past the sensor without negatively affecting sensor reading. It should also be noted both of the paddles carry an end piece, such as an end piece, 112, seen in
Referring now to
As best seen in
It should be understood that hood 114 is tapered in that the hole at the bottom of hood 114 may be less wide and less long than at the top of hood 114, at the greatest diameter of auger tube 22. The size of the hole in the bottom must be such that it will pass all the material flow without congestion or significant slowing of material flow, but small enough that the material exits in a concentrated, uniform, and correctly directed stream downward, this being true of high flow rates, and significantly reduced flow rates such that the material is not “splattered” outside of the receiving container (truck or grain cart, etc.). The phantom arrows in
Hood assembly 114 is seen in is retracted position in
While the apparatus and method have been described with reference to various embodiments, those skilled in the art will understand that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope and essence of the disclosure. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the disclosure without departing from the essential scope thereof. Therefore, it is intended that the disclosure not be limited to the particular embodiments disclosed, but that the disclosure will include all embodiments falling within the scope of the appended claims. In this application all units are in the metric system and all amounts and percentages are by weight, unless otherwise expressly indicated. Also, all citations referred herein are expressly incorporated herein by reference.