The present invention relates to forage harvesters, and more particularly to a material applicator system and related method to precisely apply treatment material to crops harvested by a forage harvester.
In the farming industry, when crops are harvested, it is frequently helpful to apply additives, for example, chemical or biological treatments such as preservatives to those crops, also referred to as forage herein, to improve, preserve or maintain the feed or other value of the forage. Applying the additive materials in the correct amounts can be a challenge because the rate of harvesting varies with factors such as the particular forage harvester used in the harvest, the speed and operation of the harvester, the crop quality and its density. Adding incorrect amounts of additives can lead to a waste of expensive additives and/or deterioration of the harvested forage when it is stored.
Several manufacturers provide application systems to address the issue of adding the correct amount of such additives. One manufacturer is Great Lakes Forage Systems, LLC of Grand Rapids, Michigan Its system is disclosed in U.S. Pat. No. 10,426,090 to Henne, which is incorporated by reference in its entirety here. A system disclosed in this patent utilizes a long, uninterrupted tube, which is secured to various parts of the harvester, to move a supply of material agglomerated and stacked upon itself within the tube toward a chute. When the material reaches the chute, a vacuum drawn in chute of a forage harvester pulls treatment material agglomerated in and filling the tube's diameter, directly into the chute. While this system works well, the vacuum can pull moisture, humid air and/or rain from the environment into the chute. Some treatment materials can be highly hydroscopic, so this added moisture can cause the material to clump and in some cases clog inside the tube, where the material agglomerates for a time as it moves though and fills the tube. Thus, the material is impaired from being applied in some cases. Further, where bins storing the treatment material encounter wet or rainy environments, they sometimes can leak, allowing liquids to enter the bin and cause the material to clump so that it cannot easily exit the bin.
Accordingly, there remains room for improvement in the field of forage harvesting and related equipment, and in particular, protection of forage treatment materials from the elements and/or ease of addressing clogs in a system.
A system and related method of applying forage treatment material to harvested forage is provided.
In one embodiment, the system can include a chute, a vacuum source that produces a vacuum, which conveys harvested forage through the chute, and a bin that stores granular treatment material for dispensation.
In another embodiment, the chute can be joined with a catch tube having a catch opening. A dispensing tube can extend from the bin toward the catch tube, but can be separated from the catch opening by an open gap.
In still another embodiment, the granular treatment material can be dispensed from the dispensing tube into the open gap. The granular treatment material can be drawn across the open gap and into the catch opening, through the catch tube and into the chute, under a suction force exerted by the vacuum so that the granular treatment material mixes with the harvested forage moving along the pathway in the chute.
In yet another embodiment, the bin, the dispensing tube, the catch tube, and the open gap all can be located in an interior compartment to shield these components from ambient elements, which can include environmental precipitation, such as rain, snow, sleet, and the like, as well as general moisture, humidity and wet conditions. In cases where the granular treatment material passes from the dispensing tube to the catch tube in the open gap, that material is less prone to becoming damp, moist or wet because it is inside the interior compartment of the forage harvester.
In even another embodiment, the system can be mounted on a motorized forage harvester capable of conveying itself along the ground. The interior compartment can be a service bay located interiorly within the forage harvester. The service bay can include a plurality of panels that at least partially surround or conceal the interior compartment, safeguarding it from ambient elements. The service bay can provide access to a motor, belts, operating systems, vacuum sources, such as blowers or fans, and other components of the forage harvester.
In a further embodiment, the catch tube can be a short tube attached to the chute, optionally in a cantilevered manner. The catch opening of the catch tube can be sized to enable a tool to extend from the open gap into the catch tube to loosen and/or remove granular treatment material from an interior surface of the catch tube while the catch tube remains joined with the chute, without disassembly or movement of the catch tube, the dispensing tube or parts of the bin and its components. In some cases, the catch opening can be 2″, 3″, 4″, 5″, 6″ or more in dimension or diameter, so that a user can plunge and scrape any accumulated, clumped treatment material from the interior surfaces of the catch tube with a tool, such as a scraper, screwdriver, dowel, stick or the like. Again, due to the open gap adjacent the catch opening, the user need not disassemble the tubes, the catch opening, the chute, or other components to reach and address the clumped or agglomerated treatment material.
In still a further embodiment, the harvester can include a longitudinal axis extending from a front to a rear, a motor, a body driven by the motor, a cutting head forward of the body, and an ejector chute that propels the harvested forage from the motorized forage harvester along a trajectory through the air toward a container distal from the motorized forage harvester.
In yet a further embodiment, the catch opening can be upwardly oriented, and the tube opening can be downwardly oriented. The granular treatment material can fall under the force of gravity out the tube opening. Due to the vacuum in the catch tube exerting a suction force in a suction force zone around the catch opening, in the open gap and optionally inside the interior compartment, the vacuum pulls the falling granular material a trajectory toward the catch opening with the suction force. Optionally, the trajectory can be an arched trajectory that curves toward the catch opening, due to the suction force altering the vertical trajectory due to gravity pulling the material downward.
In even a further embodiment, an access panel can be disposed in the interior compartment adjacent the bin. This access panel can provide access to the chute, or a vacuum source, such as a blower, associated with the chute, or some other component. The bin can be selectively moveable relative to the access panel to enable a user to access the access panel, optionally without disassembling or disconnecting any components of the bin from other items. In this movement, the dispensing tube can simply move away from the catch tube. The tubes optionally need not be disconnected because they can already be separated from one another across the open gap.
In another, further embodiment, the bin can be moveable. The access panel can be obstructed by the bin when the bin is in an application mode. The access panel is not obstructed by the bin when the bin is in an access mode. The bin can move in transitioning from the application mode to the access mode. The bin can be mounted to a frame that includes a hinge and can be mounted to a bar. The frame and bin can rotate about the hinge and/or bar, or can pivot about a pivot axis in some cases, to provide access to the access panel.
In another embodiment, a method of using an agricultural forage treatment applicator system to deliver a granular treatment material to forage during harvesting is provided. The method can comprise: harvesting forage from a field with a mobile forage harvester as the harvester moves in the field; providing a vacuum and conveying harvested forage through a chute and along a pathway with the vacuum, the chute joined with a catch tube having a first end adjacent an interior of the chute, and a second end distal from the first end and defining catch opening; providing a bin mounted in an interior compartment inside the mobile forage harvester; providing a tube extending away from the bin toward the catch tube, the tube including a tube opening separated from the catch opening by an open gap; moving a granular treatment material so that the granular treatment material moves out of the tube into the open gap; and drawing the moving granular material across the open gap and into the catch opening with the vacuum exerting a suction force on the granular treatment material as the granular treatment material moves within the open gap between the catch opening and the tube opening so that the granular treatment material mixes with the harvested forage moving along the pathway in the chute.
In still another embodiment, the granular treatment material can fall under the force of gravity out the tube opening after the moving step. As the granular treatment material is airborne and falling through the air, the granular treatment material also can be pulled via a suction force of the vacuum along a trajectory toward the catch opening. Optionally, this trajectory can be an arched trajectory that curves toward the catch opening.
In yet another embodiment, the granular treatment material falls through the air along a trajectory that is dictated by a suction force that can be exerted directly on the falling granular treatment material by the vacuum. Optionally, the trajectory deviates from a normal vertical trajectory due to the force of gravity acting on the granular treatment material because the suction force can act directly on individual particles of the material and pull them off the vertical trajectory toward the catch opening from which the suction force produced by the vacuum is emanating.
In yet another embodiment, the catch tube can extend directly from the chute in a cantilevered manner. The catch tube can remain relatively open as the material is suctioned through the catch tube, without the material stacking, agglomerating or backing up to occlude the catch tube. The catch tube can be less than 3 or 4 feet long so that the suction force acts on and pulls the material particles through the catch tube from the open gap to the interior of the chute.
The current embodiments of the system and related method of applying forage treatment material to harvested forage provide benefits in crop treatment that previously have been unachievable. For example, forage treatment material can be precisely metered and applied to harvested forage as the forage is harvested. Where the storage bin, dispensing tube and catch tube are disposed in an interior compartment of the harvester, the granular treatment material can stay dry. The interior compartment can shield these components and the material from ambient elements, such as moisture, rain, sleet, snow and excess humidity. Where the vacuum pulls the material into the chute, the ambient elements also are less likely to be pulled in with the material because the suction is being exerted primarily inside the interior compartment, rather than out in an open environment. The material can be less prone to clumping, jamming or clogging the catch tube due to the shielding of the bin and material from ambient elements. Further, where the catch tube with a catch opening is included, and accessible within the interior compartment, a user can insert a tool manually from the open gap into the catch tube to remove granular treatment material from an interior surface of the catch tube while the catch tube remains joined with the chute and while the dispensing tube remains attached to the bin. This can reduce the amount of disassembly and assembly for the user to remove any material inside the catch tube that might impede flow of material into or through the chute. Where the bin is moveable within the interior compartment, the bin can be easily reoriented to gain access to other components inside the interior compartment, and can be easily returned to a precise location to later continue dispensing of the granular treatment material.
These and other objects, advantages, and features of the invention will be more fully understood and appreciated by reference to the description of the current embodiment and the drawings.
Before the embodiments of the invention are explained in detail, it is to be understood that the invention is not limited to the details of operation or to the details of construction and the arrangement of the components set forth in the following description or illustrated in the drawings. The invention may be implemented in various other embodiments and of being practiced or being carried out in alternative ways not expressly disclosed herein. Also, it is to be understood that the phraseology and terminology used herein are for the purpose of description and should not be regarded as limiting. The use of “including” and “comprising” and variations thereof is meant to encompass the items listed thereafter and equivalents thereof as well as additional items and equivalents thereof. Further, enumeration may be used in the description of various embodiments. Unless otherwise expressly stated, the use of enumeration should not be construed as limiting the invention to any specific order or number of components. Nor should the use of enumeration be construed as excluding from the scope of the invention any additional steps or components that might be combined with or into the enumerated steps or components.
A current embodiment of the agricultural forage treatment applicator system is illustrated in
The system 10 also will be described in conjunction with the harvest of forage F. Forage F can be any type of crop, for example, grains such as corn, wheat, oats, barley, and any other type of crop, such as alfalfa, timothy, grasses, legumes, brassicas and the like. Further, the system 10 will be described in conjunction with the dispensation and application of a generally dry, granular treatment material 100. This granular treatment material optionally can comprise a particulate matter that is coated with, admixed with or otherwise joined or associated with a chemical and/or biological material, for example, a preservative and/or one or more bacteria strains. As another example, the particulate matter can be in the form of sand or a silica-based or inert, nontoxic carrier type dry material having low or no moisture content. The material can be coated with and/or mixed with a preservative such as potassium sorbate. The treatment material, for example the particulate matter, also can be admixed with a powder or have coated thereon or otherwise associated there with one or more bacteria strains in a dormant, non-multiplying form. Optionally, one, two, three or more types of bacteria strains can be included in the treatment material. These bacteria strains can be fermenting bacteria, such as lactic acid producing bacteria and/or other silage fermentation organisms. The treatment material optionally can include enzymes, such as cellulases, amylases, hemicellulases, pectinases and xylanases, or other ingredients that facilitate the breakdown of organic compounds of the forage into substances that animals and microbes can use as a source of nutrients. Further optionally, the treatment material can include glucose or molasses as a source of sugar to stimulate bacterial action to get the bacteria to start fermentation immediately. It will be appreciated that although the granular treatment material described herein can be a type of preservative, other types of biological, chemical or other types of treatment materials can be applied to the forage with the applicator system herein.
With reference to
With reference to
The bin and the various components as described below can be installed in the interior compartment 50 to shield the bin, the motor, the auger, and the granular treatment material inside the bin, and various other components, from ambient elements. As used herein, ambient elements can include rain, snow, moisture, excessive humidity, sleet, hail or other types of moisture or precipitation. By preventing and/or impairing the ability of ambient elements to come in contact with the granular treatment material 100, for example when it is being dispensed from the bin and before it enters the chute 8, the material can be prevented from clumping, sticking or agglomerating to itself and to other surfaces or components within the system 10. In turn, this can impair or prevent the material from becoming clogged in the various components of the system. Accordingly, the system 10 can continue to run with the material being efficiently and consistently transferred to the chute 8 to combine with the harvested forage HF moving through the chute. Optionally, where the granular treatment material is hygroscopic, the positioning of the bin, and the material 100 stored within the bin, inside the interior compartment 50 can prevent and/or impair moisture as well as any other ambient elements from contacting the material to prevent it from clumping, sticking and/or agglomerating.
The bin 20 can be mounted in the interior compartment 50 rearward and/or under the operator cab 4 of the harvester 1. The bin 20 can be mounted rearward of the chute 8 and rearward of the blower 6 of the harvester. The bin 20 can include a cover 20C to prevent debris or other elements from entering the interior 20I of the bin. The cover 20C also can prevent the treatment material 100 from being pulled out of the bin 20 via the suction force SF produced by the vacuum V in the chute 8 that is exerted in the interior compartment 50. The bin 20 can be selectively sized to accommodate a given amount of treatment material 100, which as illustrated, is a granular treatment material in dry and flowable form. As shown in
As shown in
As mentioned above, the granular treatment material 100 can be fed toward the auger 30 under the force of gravity. In so doing, the material can slide down and/or along the sidewalls 20W, as well as along the slanted walls 20SW toward the auger. The auger can be rotated via a motor 38. The motor 38 can be powered by a battery or other power source on board the harvester 1. The motor can supply the rotational force and torque to rotate the auger 30 to convey the material 100 in the bin 20 toward the opening 20O. The motor 38 can be electrically coupled to a controller of the system 10, which can be mounted in the operator cab 4 of the harvester 1, in plain view of the operator O. The motor can rotate the flexible auger at one or more RPMs, depending on the feed rate of the material from the bin to the chute to treat the harvested forage HF in the chute.
As illustrated in
The dispensing tube 40, it can extend from the opening 20O of the bin adjacent and/or away from the chute 8 within which the forage material HF is conveyed, optionally under a vacuum V. The tube 40 can include a first or proximal end 41 that is adjacent and/or joined with the bin. The tube can include a second or distal end 42. Optionally, the distal end 42 of the tube 40 can include a drop tube or pipe 44 and/or a vent 45. The vent 45 and the drop pipe 44 can be joined with or included in the dispensing tube 40 in a T configuration as shown, or some other configuration. The drop pipe 44 can extend downward or laterally or transversely from the distal end 42 and can include an ejection or tube opening 44O, which can be disposed below or under the auger axis AA, and optionally below the bin 20. The opening 44O can extend or face toward a catch tube 70 as described below, with the material conveyed in the tube thus ejected out the opening 44O and eventually entering the chute or some other part of the machine, to mix with the harvested forage HF. That forage can be drawn by the vacuum V.
As shown in
The bin 20 that stores the material 100 can be movable within the interior compartment 50. As shown in
The frame 60 can include sleeves or brackets 63 that attach to the bar 62 so that the frame 60 and the attached bin 20 can rotate about a pivot axis PA. This pivot axis can correspond to the axes of rotation of the hinge 60H, or to a longitudinal axis of the bar 62. The brackets or sleeves can include one or more bushings or bearings (not shown) to facilitate rotation of the bin 20. The frame 60 can be removably secured to the sleeve 63 so that the frame 60, bin 20 and/or motor 38 can be removed from the bar 62 and from the interior service bay and/or repair. The sleeve and thus the frame 60 can be held in a predetermined location along the bar 62 via one or more collars 65 that can be fixed and immovable relative to the bar 62. Optionally, in other applications, the frame can include a hinge 60H that simply secures the bin to the bar 62 or some other panel or component inside the interior compartment 50. Further optionally, the hinge 60H can be a complex hinge, structured as a parallelogram hinge, an articulated hinge, telescoping hinge or some other complex hinge capable of providing a combination of linear, lateral or rotational movement to move the bin, for example, from the application mode to the access mode and vice versa. In some cases, the bin can be moveable from one position to another for simple loading operations, servicing, repair or other adjustment of the bin and system, rather than to provide access to a panel or application of the material. In such cases, when the bin moves from one location to another, it can still be considered to be moving between modes.
With reference to
Optionally, the bin and associated components can be movable to provide access to certain components of the harvester in the interior compartment. For example, as shown in
As shown in
Optionally, due to the rigid and secure attachment of the bin to the frame and the bar 62 or some other element, when the bin and its components are returned to the application mode, the dispensing tube 40 and the drop tube 44 as well as the tube opening 44O can return to a precise orientation and linear distance LD from the catch tube 70 and its catch opening 70O. As shown, the bin 20 and the associated components, such as the dispensing tube 40 and the motor 38, can be secured to the bar 62 or some other component in the interior compartment 50 in a swinging and cantilevered manner. The bin 20 frame 60, as well as all the material 100 inside the bin, can be entirely supported by the frame on the bar 62. In some cases, there is no other connection to the bin distal from the bar 62. Thus, the bin can project outwardly from the bar, mounted to the frame 60, in a cantilevered manner. Further optionally, the frame and/or bin can be supported at multiple locations, on opposing sides or upper and lower portions of those elements. Yet further optionally, the frame, bin and other parts of the system 10 can be joined to a frame of the forage harvester, a panel or of the forage harvester, or some other structure inside the service bay or elsewhere on the forage harvester.
As mentioned above, the system can include a catch tube 70 including a catch opening 70O. This catch tube 70 and its configuration within the system 10 can be understood with reference to
The catch tube 70 can be joined with a panel of the chute 8, for example a side panel 8S or rear panel 8R of the chute 8. The catch tube first end 71 can be welded, fastened or otherwise secured to the panel of the chute. The catch tube 70 can extend from the panel in a cantilevered configuration. In this configuration, catch tube can be supported substantially by its attachment of the first end 71 to the chute 8. The catch tube can project outward and away from the chute. The catch tube can extend optionally a distance of less than 4 feet, less than 3 feet, less than 2 feet or less than 1 foot before terminating at the second end 72 and the associated catch opening 70O. Other distances can be selected, however, the distance can be sufficient so that the vacuum V can be drawn through the catch tube 70 to produce a suction force zone SFZ within the interior compartment 50 of sufficient force to pull the dispensed granular material 100 into the catch tube 70 as the material falls within the interior compartment or generally relative to the dispensing tube 40.
The catch tube 70 optionally can include an inner diameter ID that is sufficient to allow the vacuum V to exert a suction force SF to pull the granular treatment material 100 through the catch tube without the material accumulating in the catch tube, for example, without the material stacking, piling up, agglomerating, accumulating or backing up inside that tube. In some cases, the particles of the material 100 can simply transition and fly through the catch tube from the second end to the first end and then into the interior of the chute where they are mixed with the harvested forage material HF. The inner diameter ID can be optionally greater than 2 inches, greater than 3 inches, greater than 4 inches, greater than 5 inches, greater than 6 inches, between 2 inches and 8 inches, inclusive, between 3 inches and 6 inches inclusive, or between 3 inches and 5 inches, inclusive. The catch opening 70O can have a similar dimension or diameter to those mentioned above. Of course, the catch tube in some cases can be polygonal so that its interior dimension is not a diameter, in which case, the interior dimension can be equal to the above inner diameters.
As shown in
With the catch opening 70O distal from the tube opening 44O, an open gap OG is formed between these openings, and the catch tube and dispensing tube in general. As shown in
In some cases, the granular treatment material falls under the force of gravity initially parallel to or along a vertical line VL as shown in
As mentioned above, the catch opening 70O can be separated from the tube opening 40O by linear distance LD. This linear distance LD can be sufficient to provide access to the catch opening 70O by a user through the open gap OG. The catch opening also can be sufficiently sized to enable a tool to extend from the open gap OG into the catch tube to remove granular treatment material from an interior surface of the catch tube 70 while the catch tube remains joined with the chute 8. For example, the catch opening can be sufficiently large so that a user can insert a scraper, screwdriver, dowel, stick or other tool into the interior of the catch tube 70 through the catch opening 70O. The user can plunge, scrape and/or remove any agglomerated or clumped treatment material on the inside surfaces of the catch tube 70, removing it either into the service area 50 or pushing it through the catch tube 70 to the chute 8. To gain access to the opening 70O, the user need not move the bin or any other components inside the service bay because the open gap OG is large enough sufficient enough for user to insert the tool and any associated handle into the catch tube 70, and perform the activity of inspecting the catch tube and optionally removing any clumped or agglomerated treatment material therein.
A method of using the applicator system 10 of the current embodiment to deliver a granular treatment material to forage during harvesting will now be described. The method can generally include: harvesting forage HF from a field with a forage harvester 1 as the harvester moves; providing a vacuum V and conveying harvested forage through a chute 8 and along a pathway P with the vacuum, the chute 8 joined with a catch tube 70 having a first end 71 in communication with an interior of the chute, and a second end 72 distal from the first end and defining catch opening 70O; providing a bin 20 mounted in a compartment 50 inside the mobile forage harvester 1; providing a tube 40, 44 extending away from the bin toward the catch tube 70, the tube including a tube opening 44O separated from the catch opening by an open gap OG; moving a granular treatment material 100 so that the granular treatment material moves out of the tube 40 into the open gap OG; and drawing the moving granular material across the open gap OG and into the catch opening 70O with the vacuum so that the granular treatment material mixes with the harvested forage HF moving along the pathway P in the chute 8.
More particularly, with reference to
The treatment material 100 can be pulled and introduced into, or otherwise mixed in and/or with the harvested material and dispersed throughout it as the material and the forage continue to flow and tumble and intermix through the remainder of the machine. By the time the harvested forge material reaches the ejector chute 7 and is ejected out of the chute into another container T, the treatment material 100 is adequately mixed with and through the forage HF to provide desired effect of treatment of the harvested forage.
The system 10 can be in full operation during the harvest activity, as the harvester moves and harvests the forage F. The bin 20 contains a supply of treatment material 100 such as those described herein. The treatment material 100 is fed by gravity, traveling downward toward the bottom, optionally funneled by the slanted walls 20SW toward the auger 30. Power is provided by a power source on board the harvester 1 to the motor 38 of the system. The motor rotates the helical auger 30 in the bottom of the bin to engage the material. The auger or some other material mover can move the granular treatment material into the dispensing tube 40 and out the tube opening 44O, which optionally can be at the bottom of a drop pipe 44. Air can feed into the top of the vent to facilitate movement out of the opening 44O.
With reference to
As also mentioned above, the bin 20 is outfitted with material mover, such as an auger 30. As the auger rotates, it moves the granular treatment material 100 through the tube 40 and out the tube opening 44O. As the individual particles of the granular treatment material 100 fall from the opening 44O, they are subject to the suction force SF within the suction force zone SFZz. Under conditions where the suction force of the vacuum is not exerted, these particles would typically fall vertically, generally parallel to the vertical line VL, under the force of gravity downward. However, with the suction force SF produced by the vacuum V within the suction force zone SFZ, when the particles fall, at some point they begin to be pulled by the suction force SF toward the catch opening 70O. The particles can begin to be pulled off of a vertical trajectory under the force of gravity to a curved or arched trajectory, for example, along the curved axis CA immediately after leaving the tube opening 44O. In some cases, the particles can fall less than 1 inch, less than 2 inches, less than 3 inches, less than 4 inches less than 5 inches and then under the force of gravity, and then begin to change course along an arched trajectory generally following a curved axis CA toward the catch opening 70O.
Optionally, the suction force SF can be strong enough so that it begins to pull the particles of the granular treatment material before they even exit the tube opening 44O. The linear distance LD of the catch opening 70O can be selected so that the suction force within the suction force zone SFZ pulled by the vacuum V is not strong enough to pull the treatment material out from the bin without the conveyance or movement by the auger or other material mover. Further, the linear distance LD can be selected so that suction force SF does not pull material out from the vent tube 45 or from the top of the bin 20 of the system.
As the particles of the granular treatment material fall, through the air, and through the interior compartment 50, they are acted on by both a force of gravity pulling them vertically downward, as well as a cooperative suction force SF within the suction force zone SFZ created by the vacuum V though the chute. With these two different forces acting on the granular treatment material simultaneously, the particles can move along an arched trajectory having a curved path or curved axis that is along, aligned with or parallel to the curved axis CA until those particles enter the catch opening 70O.
When the granular treatment material enters the opening 70O, it can be further pulled by the suction force SF produced by the vacuum V toward the chute 8 through the catch tube 70. As the individual particles enter the catch tube 70, many remain airborne and proceed along a trajectory within the catch tube 70 without stacking, piling or accumulating within the catch tube 71. Of course, some particles may collide with the interior surfaces and walls of the catch tube 70. In cases of extreme moisture, such as high humidity, some of the particles can agglomerate on the interior of the catch tube 70. However, due to the continuous high velocity of the of the incoming particles of treatment material, the clumping and accumulation can be minimized and sometimes broken up. Optionally, the particles move through the catch tube primarily under the suction force SF exerted by the vacuum V, rather than under the force of gravity. In some cases, the particles of the treatment material, and the treatment material in general, can move through the catch tube 70 at a velocity of optionally at least 10 miles per hour, at least 20 miles per hour, at least 30 miles per hour, at least 40 mph, at least 50 mph or more from the second end 72 to the first end 71. While doing so, most the majority of particles of the treatment material can remain airborne in the catch tube without stacking, piling up upon one another, accumulating and/or agglomerating under the force of gravity within the lower portion of the catch tube 70.
After the particles traverse the catch tube 70 from the second end 72 to the first end 71, the particles can be immediately launched into and can enter the chute 8. As the treatment material 100 enters the chute, it can remain under suction force of the vacuum V, along with the harvested forage HF. As the harvested forage HF continues through the machine, through the chute 8, and out the ejector chute 7, the treatment material and harvested forge can thoroughly mix with one another so that the treatment material is dispersed within the harvested forage HF by the time it is shot along a trajectory and/or dumped into the container T.
Directional terms, such as “vertical,” “horizontal,” “top,” “bottom,” “upper,” “lower,” “inner,” “inwardly,” “outer” and “outwardly,” are used to assist in describing the invention based on the orientation of the embodiments shown in the illustrations. The use of directional terms should not be interpreted to limit the invention to any specific orientation(s).
In addition, when a component, part or layer is referred to as being “joined with,” “on,” “engaged with,” “adhered to,” “secured to,” or “coupled to” another component, part or layer, it may be directly joined with, on, engaged with, adhered to, secured to, or coupled to the other component, part or layer, or any number of intervening components, parts or layers may be present. In contrast, when an element is referred to as being “directly joined with,” “directly on,” “directly engaged with,” “directly adhered to,” “directly secured to” or “directly coupled to” another element or layer, there may be no intervening elements or layers present. Other words used to describe the relationship between components, layers and parts should be interpreted in a like manner, such as “adjacent” versus “directly adjacent” and similar words. As used herein, the term “and/or” includes any and all combinations of one or more of the associated listed items.
The above description is that of current embodiments of the invention. Various alterations and changes can be made without departing from the spirit and broader aspects of the invention as defined in the appended claims, which are to be interpreted in accordance with the principles of patent law, including the doctrine of equivalents. This disclosure is presented for illustrative purposes and should not be interpreted as an exhaustive description of all embodiments of the invention or to limit the scope of the claims to the specific elements illustrated or described in connection with these embodiments. For example, and without limitation, any individual element(s) of the described invention may be replaced by alternative elements that provide substantially similar functionality or otherwise provide adequate operation. This includes, for example, presently known alternative elements, such as those that might be currently known to one skilled in the art, and alternative elements that may be developed in the future, such as those that one skilled in the art might, upon development, recognize as an alternative. Further, the disclosed embodiments include a plurality of features that are described in concert and that might cooperatively provide a collection of benefits. The present invention is not limited to only those embodiments that include all of these features or that provide all of the stated benefits, except to the extent otherwise expressly set forth in the issued claims. Any reference to claim elements in the singular, for example, using the articles “a,” “an,” “the” or “said,” is not to be construed as limiting the element to the singular. Any reference to claim elements as “at least one of X, Y and Z” is meant to include any one of X, Y or Z individually, any combination of X, Y and Z, for example, X, Y, Z; X, Y; X, Z; Y, Z, and/or any other possible combination together or alone of those elements, noting that the same is open ended and can include other elements.
This application is a continuation in part of U.S. application Ser. No. 16/996,677, filed Aug. 18, 2020, which is incorporated by reference in its entirety.
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Number | Date | Country | |
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20220053698 A1 | Feb 2022 | US |
Number | Date | Country | |
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Parent | 16996677 | Aug 2020 | US |
Child | 17175977 | US |