The present disclosure relates generally to systems and methods for separating various materials. In particular, the present disclosure relates to harvesters and separating various crops, for example tree nuts, from twigs, dirt, dust, and other debris.
Some harvesters presently on the market use various screening/roller assemblies to separate debris from harvested crop product. Separation of the debris from the crop in or near the location of harvesting may decrease the weight of the harvested crop and thus the cost of transportation, decrease the cost of disposal of the debris because it may be left in or near the harvesting location, and decrease the likelihood of contamination of the harvested product with the debris during transport. These screening/roller assemblies may have a series of rotating spaced parallel shafts, each of which has a series of disks. The screening/roller assemblies permit debris to pass downward through spaces between disks, while the harvested crop product remains over the disks and advances out of the screening/roller assembly to a collector. U.S. Pat. No. 8,683,918 presents an example of a known harvester.
A problem with known harvesters, such as the one of U.S. Pat. No. 8,683,918, is jamming. Screening/roller assemblies having disks with teeth or open-ended slots along the edge of the disk may create non-uniform spacing between disks on adjacent parallel shafts during rotation. The non-uniform spacing can result in debris or crop product being caught and jamming up the disks causing stoppages. Even if the jamming may not cause the entire apparatus to stop completely, it may cause momentary stoppages. Such stoppages may cause substantial mechanical shock that eventually results in premature failure of various components of the screening/roller assembly.
Disks that do not have open-ended slots along the edge of the disk are known, for example as disclosed in U.S. Pat. No. 5,960,964. However, assemblies such as the one in U.S. Pat. No. 5,960,964 have large axial gaps between disks mounted along a common shaft. These axial gaps are much larger than the radial gaps between cooperating disks on adjacent parallel rotation shafts. Such assemblies are not suitable for separating crop product from debris. Some crop product and debris will fall through the large gaps while other crop product and debris will not fall through the smaller gaps between the disks. Thus, such assemblies cannot reliably sort crop product from debris.
Another problem with known harvesters is dust created by the harvester. Typically, harvesters utilize high-volume air generated by an on-board fan assembly to assist the screening/roller assemblies in separating crop product from debris. These fan assemblies generate large amounts of dust. The dust can result in air pollution, water pollution, soil loss, human and animal health problems, and hazardous reductions in visibility during operation of the harvester. Additionally, dust can adversely impact various plants and crop product. Dust generation from agricultural machinery is particularly problematic in arid areas or areas with dusty or sandy soil conditions. In an effort to reduce dust production, some jurisdictions impose various air pollution control measures on agricultural equipment.
Thus, a need exists a need for improved systems for reliably and effectively separating harvested crop product from debris without being prone to jamming or generating large amounts of dust.
In one aspect of the present disclosure, a disk is provided for use in a harvester. The disk can have a non-circular unitary body, a hole extending through the body, a first segment of the body, and a second segment of the body. The hole extending through the body defines a first rotational axis. The second segment is adjacent to the first segment, and a second outside perimeter of the second segment is smaller than a first outside perimeter of a first segment. The first segment has a first segment thickness and the second segment has a second segment thickness.
The disk can be configured to cooperate with disks mounted along a second rotational axis parallel to the first rotational axis, whereby a first axial gap and a second axial gap between cooperating disks combine to equal the second segment thickness minus the first segment thickness, and a radial gap is defined by a distance between the first outside perimeter of a disk mounted along the first rotational axis and a second outside perimeter of a cooperating disk mounted along the second rotational axis.
In another aspect of the present disclosure, a roller assembly is provided. The roller assembly can include a first roller including a plurality of disks mounted to rotate about a first rotational axis; a second roller including a plurality of disks mounted to rotate about a second rotational axis; wherein the disks are noncircular and configured to cooperate with the disks mounted adjacent along the first roller and with corresponding disks mounted along the second roller, whereby the gaps formed between the disks are effectively constant during rotation of the rollers. In another aspect, the roller assembly can include a first rotational shaft mounted to a roller assembly frame, wherein the first rotational shaft coincides with a first rotational axis and includes a plurality of disks axially mounted thereon, and a second rotational shaft mounted to the roller assembly frame parallel to the first rotational shaft, wherein the second rotational shaft coincides with a second rotational axis and includes a plurality of disks axially mounted thereon. The plurality of disks can have a non-circular unitary body, a hole extending through the body, a first segment of the body, and a second segment of the body. The hole extending through the body coincides with a rotational axis. The second segment is adjacent to the first segment, and a second outside perimeter of the second segment is smaller than a first outside perimeter of a first segment. The first segment has a first segment thickness and the second segment has a second segment thickness.
The plurality of disks can be configured to cooperate with disks mounted adjacent along the first rotational shaft and disks mounted along the second rotational shaft, whereby a first axial gap and a second axial gap between cooperating adjacent disks along the first rotational shaft combine to equal the second segment thickness minus the first segment thickness, and a radial gap is defined by a distance between the first outside perimeter of disks mounted along the first rotational shaft and the second outside perimeter of cooperating disks mounted along the second rotational shaft.
In another aspect of the present disclosure, a nut harvester is provided. The nut harvester can include a roller assembly, a roller assembly drive mechanism, a linkage for operating a roller assembly, a fan assembly, and an exit conveyor. The roller assembly can include a first rotational shaft mounted to a frame, wherein the first rotational shaft coincides with a first rotational axis and includes a plurality of disks axially mounted thereon, and a second rotational shaft mounted to the frame parallel to the first rotational shaft, wherein the second rotational shaft coincides with a second rotational axis and includes a plurality of disks axially mounted thereon.
Each of the plurality of disks can have a non-circular unitary body, a hole extending through the body, a first segment of the body, and a second segment of the body. The hole extending through the body coincides with a rotational axis. The second segment is adjacent to the first segment, and a second outside perimeter of the second segment is smaller than a first outside perimeter of a first segment. The first segment has a first segment thickness and the second segment has a second segment thickness.
The plurality of disks can be configured to cooperate with disks mounted adjacent along the first rotational shaft and disks mounted along the second rotational shaft, whereby a first axial gap and a second axial gap between cooperating adjacent disks along the first rotational shaft combine to equal the second segment thickness minus the first segment thickness, and a radial gap is defined by a distance between the first outside perimeter of disks mounted along the first rotational shaft and the second outside perimeter of cooperating disks mounted along the second rotational shaft.
The apparatuses described here improve crop product harvesting by cleanly separating crop product from dirt, dust, and debris without being prone to jamming. The relatively clean separating of crop product from dirt, dust, and debris allows for less reliance on a fan assembly, and in some instances the fan assembly does not need to be operated at all. Thus, the apparatuses described here can significantly reduce dust generation.
In another aspect of the present disclosure, a method for removing dirt and debris from harvested crop product is provided. The method includes providing a roller assembly, simultaneously rotating a first and second rotational shaft of the roller assembly, and allowing dirt and debris to fall through spacing gaps in the roller assembly. The roller assembly can include the first rotational shaft mounted to a roller assembly frame, wherein the first rotational shaft coincides with a first rotational axis and includes a plurality of disks axially mounted thereon, and a second rotational shaft mounted to the roller assembly frame parallel to the first rotational shaft, wherein the second rotational shaft coincides with a second rotational axis and includes a plurality of disks axially mounted thereon.
Each of the plurality of disks can have a non-circular unitary body, a hole extending through the body, a first segment of the body, and a second segment of the body. The hole extending through the body coincides with a rotational axis. The second segment is adjacent to the first segment, and a second outside perimeter of the second segment is smaller than a first outside perimeter of a first segment. The first segment has a first segment thickness and the second segment has a second segment thickness.
The plurality of disks can be configured to cooperate with disks mounted adjacent along the first rotational shaft and disks mounted along the second rotational shaft, whereby a first axial gap and a second axial gap between cooperating adjacent disks along the first rotational shaft combine to equal the second segment thickness minus the first segment thickness, and a radial gap is defined by a distance between the first outside perimeter of disks mounted along the first rotational shaft and the second outside perimeter of cooperating disks mounted along the second rotational shaft.
Refer now to
The harvester 22 has a power take-off 28 that drives a hydraulic pump 30. The hydraulic pump 30 drives a hydraulic motor 40 that then mechanically drives the roller assembly 38. The hydraulic motor 40 has a mechanical connection 42 to rotational shafts of the roller assembly 38 by a series of belts or chains 42. When the power take-off 28 is engaged, power is transferred from the towing vehicle (not pictured) to the rotational shafts through the power take-off 28, the hydraulic pump 30, the hydraulic motor 40, and the mechanical connection 42. Alternatively, the harvester 22 can be configured to transfer power from the towing vehicle to the rotational shafts entirely mechanically, without the use of hydraulic pumps and motors. In other embodiments, the harvester 22 can have a mechanical transmission for transfer of the power from the power take-off to the rotating shafts, or can have its own power generation source that transfers mechanical power to the rotational shafts. In this later embodiment, the harvester 22 does not require a power take-off connected to a towing vehicle.
Each rotational shaft turns on its rotational axis. For example, with reference to
With reference to
The rotational shafts, for example the first rotational shaft 50 and the second rotational shaft 52, each have a plurality of disks 60 mounted axially along the shaft. The disks 60 mounted along the first rotational shaft 50 cooperate with corresponding disks 60 mounted along the second rotational shaft 52.
Spacing between the disks 60 depends on the shape of the disks 60 and the distance between adjacent disks. The disks 60 are designed so that as they rotate, the spacing between cooperating disks 60 remains effectively constant. “Effectively constant” for purposes of this description means that the spacing remains sufficiently constant for the purposes of separating crop product from twigs, dirt, dust, and other debris. The effectively constant spacing is important for separating crop product from twigs, dirt, dust, and other debris, without being prone to jamming.
Refer now to
The first segment 68 of the body 62 has a first outside perimeter 70. The first outside perimeter 70 has a plurality of disk sides, including a first side 78, a second side 80, and a third side 82. The sides meet at apexes 84 of the first outside perimeter 70. As illustrated in
The second segment 86 of the body 62 is adjacent to the first segment 68 and is positioned on the first face 74 or second face 76 of the first segment 68. In the exemplary embodiment of
The second segment 86 has a second segment thickness 90 that is greater than the first segment thickness 72. In an exemplary embodiment, the second segment thickness 90 can be approximately twice as thick as the first segment thickness 72. In alternative embodiments, the second segment thickness 90 may be greater than twice as thick as the first segment thickness 72, or less than twice as thick has the first segment thickness 72. The first and second segment thicknesses 72, 90 impact the size of the gap between disks. Therefore, the thicknesses may be any suitable thickness depending on the crop product or other material to be separated from debris. Since gaps between disks must be smaller than the crop product or other material to be separated from the debris, the relative thicknesses of the first segment and second segments may be different for different crop products.
The hole 64 has a number of hole sides 66 that differs from the number of sides of the first and second outside perimeters 70, 88. In the exemplary embodiment of
The disks 60 are designed so that axial spacing between adjacent disks 60 mounted along the same rotational shaft remains effectively constant during operation. Furthermore, radial spacing between disks 60 on parallel shafts also remains effectively constant. Thus, during operation, about the same amount of space between disks will be present regardless of the rotational position of the disks 60. Moreover, the size and thickness of the disks may be configured to cooperate with the disks mounted adjacent along the first roller and with corresponding disks mounted along the second roller, whereby the gaps formed between the disks are effectively constant during rotation of the rollers. The effectively constant spacing allows for uniform separation of crop product from dirt, twigs, dust, and other debris.
The first segment 68 of a disk 60 on the first rotation shaft 50 cooperates with the second segment 86 of a corresponding disk 60 on the second rotational shaft 52. Similarly, the first segment 68 of a disk 60 on the second rotation shaft 52 cooperates with the second segment 86 of a corresponding disk 60 on the first rotational shaft 50. The shape of the first outside perimeter 70 and the second outside perimeter 88 allow cooperating disks on parallel shafts to maintain effectively constant spacing between each other. Referring to
The radius of the arcs can be adjusted as necessary depending on the desired application. Generally, as the size of the second outside perimeter 88 increases, the radius of its arcs decreases. As the radius of the arcs decreases, the first and second outside perimeters 70, 88 become more circular. Conversely, as the size of the second outside perimeter 88 approaches the size of the first outside perimeter 70, the radius of the arcs increases. A larger arc radius thereby creates sharper points on the first and second outside perimeters 70, 88. Perimeters having sharper points result in more agitation and less space for debris to fall through. More circular perimeters result in less agitation but more space for debris to fall through.
The first and second outside perimeters can alternatively be any suitable polygon. For example, if the polygon has four sides, the first and second outside perimeters would each have four apexes and four arcs connecting the apexes. The radius for the arcs can be calculated for any polygon by solving Eq. 1 for R:
S sub L is the length of a side of the large polygon, S sub S is the length of the small polygon, and theta is the degrees of a bisected, included angle of the polygon (360/number of sides/2).
Alternatively, the first and second outside perimeters 70, 88 can be approximately a Reuleaux triangle. A Reuleaux triangle is a shape formed from the intersection of three circles of the same size, each having its center on the boundary of the other two. The three center points form the three apexes of the Reuleaux triangle, with the resulting shape having an effectively constant width regardless of its orientation. Alternatively, other suitable shapes may also be used.
The first outside perimeter 70 and the second outside perimeter 88 are effectively the same shape but have different sizes. In the illustrated embodiment, the size relationship (or scale) of the first outside perimeter 70 to the second outside perimeter 88 is about three to two. However, other scales may be used as appropriate for the crop product or other material being processed. The scale impacts the size of the gaps between cooperating disks.
With reference to
Gaps between cooperating disks remain effectively constant during rotation. The first outside perimeter 70 of a disk 60 is configured to cooperate with the second outside perimeter 88 of a corresponding disk 60 mounted on an adjacent rotational shaft. The space between disks 60 mounted along the first rotational shaft 50 and disks 60 mounted along the second rotational shaft 52 creates axial and radial gaps.
In the example embodiment of
With reference to
The shapes of the disks allow the radial gap 106 to remain effectively constant during rotation. However, due to the non-circular shape of the first and second outside perimeters 70, 88, the location of the radial gap 106 constantly moves when the shafts are rotating. The disk 60 has a first segment 68 with three sides (arcs) and three apexes 84. When the apexes 84 are pointed directly at an adjacent parallel shaft, the first segment 68 is at an approximately maximum point. When the middle of an arc is pointed directly at an adjacent parallel shaft, the first segment 68 is at an approximately minimum point.
The first segment 68 cooperates with a second segment 86 of a cooperating disk 60 on a parallel shaft. Similar to the first segment 68, the second segment 86 as three sides (arcs) and three apexes 98. When the apexes 98 are pointed directly at an adjacent parallel shaft, the second segment 86 is at an approximately maximum point. When the middle of an arc is pointed directly at an adjacent parallel shaft, the second segment 86 is at an approximately minimum point.
In order for the radial gap 106 to remain effectively constant, the cooperating disks 60 rotate in a complimentary fashion. When the first segment 68 of a disk on the first rotational shaft 50 is at an approximately maximum point, the second segment 86 of a cooperating disk on the second rotational shaft 52 is at an approximately minimum point. As the disks 60 perform one full rotation, they each cycle through three maximum points (the number of apexes) and three minimum points (the number of arcs). Alternative embodiments with a different number of apexes and arcs would have a corresponding number of maximum and minimum points during one full rotation.
Throughout one full rotation, the radial gap 106 remains effectively constant due to the complimentary arrangements of the disks. This also illustrates that the physical position of the radial gap 106 constantly moves while the disks 60 rotate. When the first segment 68 of a disk on the first rotational shaft 50 is at an approximately maximum point, the location of the radial gap 106 will be closer to the second rotational shaft 52. When the first segment 68 of a disk on the first rotational shaft 50 is at an approximately minimum point, the location of the radial gap 106 will be closer to the first rotational shaft 50. In this way, the roller assembly 38 generates an advantageous sifting or agitation effect.
The agitation increases the effectiveness of the roller assembly 38 in separating crop product or other material from debris, while still maintaining effectively constant gap sizes. This is in contrast to toothed disks, where the gap between disks depends on the position of the disk. The disparity in gap distance in toothed disks tends to pinch materials between a disk and its cooperating disk, which may result in frequent jamming. The present disks 60 overcome this issue while also advantageously moving debris up and down in a fashion that creates a sifting effect.
The roller assembly 38 includes disks 60 mounted along a rotational shaft. Each disk 60 has a different orientation from the disks adjacent to it. Since the hole 64 has four sides, adjacent disks 60 can be mounted to a four-sided rotational shaft such that a different hole side is at a top side of the shaft. For example, each adjacent disk can be mounted at ninety degree turns from each other. Since the three arcs are all the same length, the effect is that mounting adjacent disks 60 at ninety degree turns from each other results in the apexes 84 being offset by thirty degrees. In other embodiments, other arrangements could be used to obtain the desired angular disk offset, such as for example using a round shaft, a round disk hole, and a set screw to fix the disk at the desired angle.
As illustrated in
Refer now to
The second embodiment of the roller assembly 138 differs from the first embodiment in that the disks 60 are oriented in the same direction such that the apexes 84 of the first outside perimeter 70 of adjacent disks 60 are aligned. Such an alignment of the disks 60 creates a wave-type agitation action in the crop product during operation that allows the debris to fall out and separate from the crop product.
Other alignments of adjacent disks mounted along a rotational shaft are also possible. For example, disks can be grouped in sets of two, where the two disks in the set are aligned with each other but offset from adjacent sets of two. Similarly, sets of three may be used. Any arrangement between disks mounted along a rotational axis may be suitable, as long as the disks mounted on adjacent parallel shafts cooperate in a complimentary fashion. Therefore, a person of ordinary skill in the art may consider various other alignment patterns that allow cooperating disks to maintain the axial and radial gaps described above.
With reference to
The first segment 168 of the body 162 has a first outside perimeter 170. The first outside perimeter 170 has a plurality of disk sides. For example, the first outside perimeter 170 has a first side 178, a second side 180, and a third side 182. The sides meet at apexes 184 of the first outside perimeter 170. As illustrated in
The second segment 186 of the body 162 is adjacent to the first segment 168 on the first face 174 or second face 176. In the exemplary embodiment of
The second segment 186 has a second segment thickness 90 that is greater than the first segment thickness 172. In an exemplary embodiment, the second segment thickness 190 can be approximately twice as thick as the first segment thickness 172. In alternative embodiments, the second segment thickness 190 may be greater than twice as thick as the first segment thickness 172, or less than twice as thick as the first segment thickness 172. The first and second segment thicknesses 172, 190 impact the size of the gap between disks. Therefore, the thicknesses may be any suitable thickness depending on the crop product or other material to be separated from debris. Since gaps between disks must be smaller than the crop product or other material to be separated from the debris, the relative thicknesses of the first segment and second segments may be different for different crop products.
The second outside perimeter 188 of the disk 160 is a first hollow projection 224 that has a cavity 226. The second segment 186 further includes a second hollow projection 228 in the shape of the perimeter of the hole 164. Together, the first and second hollow projections 224, 228 make up the second segment 186 of the body 162.
The third segment 210 of the disk 160 is positioned adjacent to the first segment 168 on the face of the first segment 168 that is opposite to the second segment 186. In the embodiment of
The third segment 210 is a third hollow projection 230 that is configured to nest within the cavity 226 of the second segment 186 of an adjacent disk. The third segment 210 has a third segment thickness 214 as illustrated in
In the exemplary embodiment of
The third hollow projection 230 interlocks with the cavity 226 of an adjacent disk in only one orientation. For example, the third hollow projection 230 is oriented with its apexes 222 offset from the apexes 184 of the first segment 168 and the apexes 198 of the second segment 186 by, for example, approximately thirty degrees. When the third hollow projection 230 of the disk 160 interlocks with a cavity 226 of an adjacent disk 160, the adjacent disk 160 is offset by the same degree of offset between the apexes 222 of the third hollow projection 230 and the apexes 184 of the first segment 168. Thus, the offset of the apexes 222 of the third hollow projection 230 compared to the apexes 184 of the first segment 168 determines the degree of offset between the apexes 184 of adjacent disks. When the apexes 222 of the third hollow projection 230 are rotated by thirty degrees as compared to the apexes 184 of the first segment 168, the disk 160 will interlock or nest with an adjacent disk 160 such that the apexes 184 of adjacent disks are offset by thirty degrees. Other embodiments can have different offsets, for example, approximately forty-five degrees. The disk 160 is used in a roller assembly configuration where adjacent disks are offset from each other, for example as described in
With reference to
The disks 60, 160, 260 described herein can be connected to adjacent disks on the same rotational shaft by means any suitable means. For example, adjacent disks can be connected by set screws, adhesives, nut and bold assemblies, interference fits, or other suitable means. The disks 60, 160, 260 may also be mounted along a rotational shaft in a manner that does not require being connected to adjacent disks. For example, adjacent disks may all be mounted up against each other such that no space exists between adjacent disks. In this embodiment, end collars 54, 154 can be mounted on each end of the rotational shaft to prevent the disks 60, 160, 260 from moving apart from each other over time. For the second and third embodiments of the disk 160, 260, the means described above can be used separately from or in conjunction with interlocking or nesting.
The disks 60, 160, 260 may be constructed from any suitable material known in the art, for example Acetal made by the Dupont Company under the trade name Delrin®. The disks 60, 160, 260 may alternatively be constructed from various other metals, alloys, plastics, and rigid rubbers known in the art. However, materials that can bend or flex tend to jam more frequently than harder materials. Hard, rigid disks tend to decrease the likelihood of jamming. Therefore, it is generally preferable to form the disks 60, 160, 260 from a harder material, though the choice of material may change according to the desired application and a balancing of strength, durability, and propensity to jam.
In an exemplary embodiment where the disks 60, 160, 260 are formed of Acetal made by the Dupont Company under the trade name Delrin®, the disks may be injection molded according to methods known in the art. The injection molding process may utilize techniques known to injection molders to mitigate undesirable warping during cooling, and to maintain structural integrity. For example, ridges or projections can be added along a flat surface that may be susceptible to warping, as shown in the disk 160 of
While the present disclosure refers to a first rotational shaft 50, 150 and a second rotational shaft 52, 152, it is understood that the roller assembly 38, 138 is not constrained to having two rotational shafts and can have any additional number of rotational shafts.
A method for removing dirt and debris from harvested crop product, for example tree nuts, comprises providing the roller assembly 38, 138 according to any of the embodiments described above, simultaneously rotating the first and second rotational shafts, and allowing dirt and debris to fall through spacing between the disks of the roller assembly 38, 138.
The roller assembly 38, 138 can include a first rotational shaft 50, 150 mounted to a roller assembly frame 48, 148, wherein the first rotational shaft 50, 150 coincides with a first rotational axis 56, 156 and includes a plurality of disks 60, 160 axially mounted thereon. A second rotational shaft 52, 152 is mounted to the roller assembly frame 48, 148 parallel to the first rotational shaft 50, 150, wherein the second rotational shaft 52, 152 coincides with a second rotational axis 58, 158 and includes a plurality of disks 60, 160 axially mounted thereon. The disks 60, 160, 260 can be any embodiment as described herein.
The apparatus and methods of the present disclosure offer improvements in crop product harvesting by more cleanly separating harvested crop product from dirt, dust, and debris. The ability to separate the crop product from dirt, dust, and debris in such a clean manner reduces the need to operate a fan assembly. For example, in dry or sandy conditions, the apparatuses and methods described herein can cleanly separate the crop product from dirt, dust, and debris without operating a fan assembly at all, thus greatly reducing dust generation. The apparatuses and methods of the present disclosure also are less prone to jamming and binding up, resulting in less down time and less stress being placed on components that can, over time, result in premature failure.
The above description and drawings are only illustrative of preferred embodiments, and are not intended to be limiting. For example, the illustrated embodiments include a disk with two segments, which may be different sizes. Other embodiments may instead include two disks of single segments, which may be different sizes. Any subject matter or modification thereof which comes within the spirit and scope of the following claims is to be considered part of the present inventions.
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