1. Field of the Invention
The present invention relates to agricultural implements for attachment to the power take-off of a tractor and, particularly, to an implement for the extraction and decimation of plant stalks including cotton.
2. Discussion of the Prior Art
Cotton is picked using a harvester having heads for picking several rows at once, usually four to six rows. After cotton is picked, the stalks are left in the field and require additional processing for removal so that a subsequent crop can be planted. Further, cotton is a perennial plant and can re-grow following harvest, providing the potential for development of hostable fruit (squares and bolls) for boll weevil feeding and reproduction. Under good environmental conditions, cotton plants can generate hostable fruit in three to four weeks. Thus, it is considered important to destroy cotton stalks as soon as the crop has been harvested to aid in reducing costs for the boll weevil eradication. Present practices require several passes by mowers and disc harrows to effectively process these stalks. These several passes cause wear and tear on expensive cotton harvesting machines and require the use of fuel that is costly and harmful to the environment. Thus, what is needed is a method for removal of cotton stalks or similar plant crop stalks more efficiently.
Conventional rotary mowing can leave long pieces of crop stalks that will interfere with future field operations and hinder decomposition of plant matter. It would be more desirable to process plant stalks and leave only small debris or chips of plant material that will readily rot and become organic soil matter. Despite this long-felt need, nothing on the market today effectively pulls and shreds the stalk of a cotton plant to the root, especially with only one trip through a post-harvest crop field. Previous attempts to solve for this need have failed at least in part. For example, the Amadas puller/chopper (U.S. Pat. No. 5,953,895), pulls and chops crop matter in 12″-18″ long sections using pneumatic tires. The Amadas puller only pulls and holds a stalk momentarily and does not promote further processing of the stalk. Thus, the Amadas puller deposits the crop litter in a concentrated band, unfortunately leaving long stalks on the ground. The concentration of the band of stalks left on the ground causes future difficulty in tillage for planting new crops. The remaining root pullers available in the art, such as shown in U.S. Pat. No. 4,779,684, require the crop to be mowed before the root can be pulled, and then when the root is pulled a 12″-20″ length of usually very thick root end of stalk remains on the ground. No implement currently performs the desirable functions of removing plant stalks and then decimating those stalks into small bits for conversion to mulch.
In addition to the above deficiencies, both the Amadas chopper and the disc puller (U.S. Pat. No. 4,779,684) cause an undesirable amount of soil disturbance, which especially in a conservation tillage system does not contribute to an acceptable seed bed preparation for following crops. Stalks are often partially buried creating problems with further field work.
Thus, what is needed is an improved implement for the extraction and decimation of plant stalks such as cotton stalks that overcomes the limitations of the prior art. In particular, a need exists to pull cotton stalks from the root and then decimate these cotton stalks so that future field work can be completed without the obstacle of long and thick cotton stalks damaging equipment or inhibiting proper tillage and field preparation.
The present implement for extraction and decimation of plant stalks operates to both extract plant stalks such as cotton stalks from the ground and shred these stalks into small pieces. Both above ground growth and below ground stem and root are pulled by two rubber track belts with interlocking protrusions that are powered by a hydraulic motor. The pair of track belts provides a puller unit that grasps the plant stalk, typically at the base of the plant, and holds the stalk as the machine moves forward. Multiple puller units are provided on the implement in accordance with the number of rows desired, usually between 4-8 rows.
The implement operates in a combination of forward ripping of plant roots and lifting the plant stalks as the plant is conveyed rearward and elevated by the angle of the puller unit. The puller unit is angled higher to the rear of the implement to fully separate the plant from the ground. The track belts evenly convey the crop stalk mass to a flail shredding unit to reduce the plant stalk and root to small mulch type chips that are then distributed evenly across the working width of the machine to the soil surface. In doing away with the normal stalk and root stubble this greatly eliminates future problems associated with a line of sharp sticks that cause plugging of tillage equipment and damage such as premature wear of tires be it on tractors or transport wheels on implements. Also, when root matter is removed from the ground the problem with the plants re-growing is eliminated, which eliminates wintering habitat for soil pest; be it disease, insects or nematodes.
The current implement improves removal of plant stalks by both removing and shredding the stalks from its root up, all in one pass. This size reduction of plant stalk material is greatly superior to the standard practice of rotary mowing, because it cuts all of the plant including the root into to small mulch like pieces. This process provides surface mulch that greatly reduces wind and water caused erosion and ultimately improves soil tilth and biology by providing a slow decaying surface covering of organic matter. Meanwhile, the present implement operates above the soil surface and does not disturb or molest the soil profile. The only soil movement is the narrow band where the root pulls up a minor amount of soil, unless the hardness or type of soil requires conditioning. Where desirable, such as heavier clay based soils, an optional plow may be used to loosen soil around the root of the plant prior to pulling.
Referring now to the drawings, an implement 2 for the extraction and decimation of plant stalks is shown in
The puller section of the implement includes a puller unit 10 for each row having a pair of track belts 12 to extract plant stalks from the ground. As a tractor pulls the implement, plant stalks enter the front of the downward sloping puller units 10. The puller section includes a puller drive assembly 40 for driving the puller units 10. After the stalks are extracted by the puller units 10, the stalks exit the puller section into the flail section for decimation.
The puller section, having a combination of a puller drive assembly 40 and puller units 10, is shown in
The puller units 10 each include a pair of track belts 12 connected within the pulling unit in parallel interlocking relationship. The track belts 12 are supported on a support structure 26 including a belt drive sprocket 14 on one end and an idler wheel 28 on the opposing end of the support structure. Each belt drive sprocket 14 includes teeth. These teeth engage holes 16 in the respective track belt 12 to drive the track belt in a loop around the belt drive sprocket 14 and the idler wheel 28. The combination of the teeth on the belt drive sprocket 14 and the holes 16 in the respective track belt 12 forms an operating roller track.
Each of the track belts 12 includes a plurality of spaced track protrusions 24 along the outer surface of the track. These track protrusions 24 on each track belt 12 are arranged in opposing relationship for the parallel track belts 12 such that the track protrusions overlap each other by resting within the gaps between the opposing tracks protrusions to form the interlocking relationship of the pair track belts 12 in a puller unit 10. The interlocking track protrusions 24 improve the grip of puller unit 10 on the crop material and convey the crop material along the track by gripping and moving the crop mass rearward and upward toward the flail unit in accordance with the mechanical angle and arrangement of the track belts 12. The typical rubber track belt 12 that is provided in the invention will be about 7 inches in width and provide for gripping a substantial portion of the plant stalk for extraction thereof.
In addition to the gripping proficiency of the track belts 12, the upward elevation angle of the puller unit 10 as shown in
In an alternative embodiment with adjustable puller units 10, the angle of the puller units may be adjusted through hydraulic pumps connected to the support structure 26 to pivot and raise or lower the puller units. Thereby, the optimum height and angle of the puller unit 10 can be determined for a particular crop of plant stalks for optimum decimation. Of course, a fix angle may be provided that is optimized for most crop scenarios to reduce the complexity and cost of the implement. In addition, the length of the puller unit 10 may vary. The typical length of a desirable puller unit 10 will be approximately 36 inches from the entry end of the track belts 12 to the exit end where the crop mass is engaged by the flail unit, providing a 3 foot grip length for extraction and removal of plant stalks.
The combination of the belt drive sprocket 14 and idler wheel 28 maintains each track belt 12 in sufficient tension for rotation of the track belt around the support structure 26. The idler wheel 28 moves rearward on a slide track 30 to remove any excess slack between the idler wheel and the track belt 12. A tension adjustment bolt 32 moves the idler wheel 28 to tighten and adjust the tension. Once the proper desired tension is achieved, then retention bolts 36 are tightened to retain the position of the idler wheel 28 within the plates 34 forming the portion of the support structure 26 that supports the idler wheel. In a preferred embodiment, the idler wheel 28 provides a smooth rolling surface on the back of the support structure for the track belt 12, as opposed to the toothed belt drive sprocket 14 that operates to engage the track belt with force.
The belt drive sprocket 14 for each track belt 12 is supported on the support structure 26 by a pair of support bearings 22a, 22b providing top support bearing 22a and bottom support bearing 22b. A belt drive sprocket 14 shaft extends from each belt drive sprocket as shown in
The universal joint 20 connects the belt drive sprocket shaft 18 to the puller drive assembly 40 via a bottom output shaft on a respective gearbox 60, 66. Each puller unit 10 may have a separate gearbox output as shown in the exemplary embodiment of
A typical arrangement as shown includes a slip clutch 58 attached to the front counter shaft 50 that will momentarily disconnect power transmission to the front counter shaft 50 in the event the implement encounters an obstruction such as a root or rock that is pulled into a puller unit 10. The slip clutch 58 helps to avoid damage to the track belts 12 or gearboxes in the case of an impassable object. Universal joints 56 connect the front counter shaft 50 to each three shaft gearbox 60, 66 to transfer power from the slip clutch 58 to each gearbox and respective puller unit 10. As shown in the embodiment of
Referring now to
The flail knives 86 are “L” shaped and combined in pairs for connection to the flail rotor 90 as shown in
A flail hood 92 of the flail shredder assembly covers the flail unit 80 as shown in
The present application claims benefit of U.S. Provisional Patent Application No. 61/728,287 filed on Nov. 20, 2012.
Number | Date | Country | |
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61728287 | Nov 2012 | US |