Sugar Beet Harvest Apparatus

Abstract

A sugar beet harvest apparatus provides in sequence a pair of field cultivator teeth, a pair of discs or helical screw propellers, and a V-shaped basket of helical screw propellers. The field cultivator teeth and discs may be spaced nominally to engage both sides of a single crop row, or to engage one side of a first crop row, and the opposed side of a second adjacent crop row. In either case, the field cultivator teeth pierce the soil and gently lift the root crop. The discs or helical screw propellers lift the beets and soil into the V-shaped basket of helical screw propellers. Within the V-shaped basket, a pair of ground-level helical screw propellers lift the root crop, while pulverizing the soil and cleaning the root crop. Subsequent helical screw propellers continue to lift the root crop, while pushing rocks and soil rearward proximate to the soil surface.

Claims

1. A root crop harvest apparatus, comprising: a frame having a coupling adapted to mechanically couple with a tractor; at least one field cultivator affixed to said frame and having a ground piercing tooth; at least one disc affixed to said frame, displaced from and trailing said at least one field cultivator along a longitudinal axis of said root crop harvest apparatus; and at least four helical screw propellers affixed to said frame, displaced from and trailing said at least one field cultivator and said at least one disc along said longitudinal axis of said root crop harvest apparatus; a first pair of said at least four helical screw propellers arranged in a V-shaped configuration within a plane immediately adjacent to and generally parallel to a surface of the earth; and a second pair of said at least four helical screw propellers arranged in a V-shaped configuration within a plane parallel to and above said plane defined by said first pair of said at least four helical screw propellers, and extending more distally to said at least one field cultivator than said first pair of said at least four helical screw propellers.

2. The root crop harvest apparatus of claim 1, wherein said at least one disc further comprises a pair of discs configured to form a plow furrow and ridge in the earth, said first pair of said at least four helical screw propellers operative on opposed slopes of said plow ridge.

3. The root crop harvest apparatus of claim 1, wherein said at least one field cultivator further comprises a pair of field cultivators spaced from each other in a direction generally transverse to said longitudinal axis, each of said pair of field cultivators having a ground piercing tooth.

4. The root crop harvest apparatus of claim 2, wherein said at least one field cultivator further comprises a pair of field cultivators spaced from each other in a direction generally transverse to said longitudinal axis, each of said pair of field cultivators having a ground piercing tooth.

5. The root crop harvest apparatus of claim 1, wherein each individual one of said at least four helical screw propellers further comprises a rotary motor coupled to and driving a rotary shaft having a helically wrapped screw thread.

6. The root crop harvest apparatus of claim 5, wherein said at least four helical screw propellers further comprises eight individual helical screw propellers arranged in four V-shaped configurations, each of said four V-shaped configurations extending progressively more rearward and upward than the next lower adjacent V-shaped configuration.

7. A sugar beet harvest apparatus, comprising: a frame having a coupling adapted to mechanically couple with a motive power source; at least four helical screw propellers affixed to said frame; a first pair of said at least four helical screw propellers arranged in a V-shaped configuration within a plane immediately adjacent to and generally parallel to a surface of the earth; and a second pair of said at least four helical screw propellers arranged in a V-shaped configuration within a plane parallel to and above said plane defined by said first pair of said at least four helical screw propellers, and extending more distally than said first pair of said at least four helical screw propellers.

8. The sugar beet harvest apparatus of claim 7, further comprising at least one field cultivator affixed to said frame and having a ground piercing tooth, said at least one field cultivator leading said at least four helical screw propellers along a longitudinal axis of said sugar beet harvest apparatus.

9. The sugar beet harvest apparatus of claim 8, wherein said at least one field cultivator further comprises a pair of field cultivators spaced from each other in a direction generally transverse to said longitudinal axis, each of said pair of field cultivators having a ground piercing tooth.

10. The sugar beet harvest apparatus of claim 7, further comprising at least one disc affixed to said frame, said at least one disc leading said at least four helical screw propellers along a longitudinal axis of said sugar beet harvest apparatus.

11. The sugar beet harvest apparatus of claim 10, wherein said at least one disc further comprises a pair of discs spaced from each other in a direction generally transverse to said longitudinal axis and configured to form a plow furrow and ridge in the earth, said first pair of said at least four helical screw propellers operative on opposed slopes of said plow ridge.

12. The sugar beet harvest apparatus of claim 10, further comprising at least one field cultivator affixed to said frame and having a ground piercing tooth, said at least one field cultivator leading said at least one disc along a longitudinal axis of said sugar beet harvest apparatus.

13. The sugar beet harvest apparatus of claim 7, wherein each individual one of said at least four helical screw propellers further comprises a rotary motor coupled to and driving a rotary shaft having a helically wrapped screw thread.

14. The sugar beet harvest apparatus of claim 7, wherein said at least four helical screw propellers further comprises eight individual helical screw propellers arranged in four V-shaped configurations, each of said four V-shaped configurations extending progressively more rearward and upward than the next lower adjacent V-shaped configuration.

15. The sugar beet harvest apparatus of claim 8, further comprising at least one helical screw propeller affixed to said frame and trailing said field cultivator, while leading said at least four helical screw propellers along a longitudinal axis of said sugar beet harvest apparatus.

16. A sugar beet harvest apparatus configured to traverse and harvest sugar beets grown in parallel rows within the earth, said parallel rows defining a direction of sugar beet harvest apparatus travel, comprising: a frame having a coupling adapted to mechanically couple with a tractor; a pair of field cultivators affixed to said frame, each of said pair of field cultivators having a ground piercing tooth; a pair of helical screw propellers affixed to said frame, displaced from and trailing said at least one field cultivator along a longitudinal axis of said root crop harvest apparatus; and at least four helical screw propellers affixed to said frame, displaced from and trailing said pair of helical screw propellers along said longitudinal axis of said root crop harvest apparatus, each individual one of said at least four helical screw propellers having a rotary hydraulic motor coupled to and driving a rotary shaft having a helically wrapped screw thread; a first pair of said at least four helical screw propellers arranged in a V-shaped configuration within a plane immediately adjacent to and generally parallel to a surface of the earth; and a second pair of said at least four helical screw propellers arranged in a V-shaped configuration within a plane parallel to and above said plane defined by said first pair of said at least four helical screw propellers, and extending more distally to said at least one field cultivator than said first pair of said at least four helical screw propellers.

17. The sugar beet harvest apparatus of claim 16, wherein said at least four helical screw propellers further comprises eight individual helical screw propellers arranged in four V-shaped configurations, each of said four V-shaped configurations extending progressively more rearward and upward than the next lower adjacent V-shaped configuration.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0018] The foregoing and other objects, advantages, and novel features of the present invention can be understood and appreciated by reference to the following detailed description of the invention, taken in conjunction with the accompanying drawings, in which:

[0019] FIG. 1 illustrates a preferred embodiment sugar beet harvest apparatus designed in accord with the teachings of the present invention from a side elevational view, and further illustrating the movement of soil and beets during harvest.

[0020] FIG. 2 illustrates the preferred embodiment sugar beet harvest apparatus of FIG. 1 from a sectioned view taken along section line 2′ of FIG. 1.

[0021] FIG. 3 illustrates the preferred embodiment sugar beet harvest apparatus of FIG. 2 from a front elevational view.

[0022] FIG. 4 illustrates the preferred embodiment sugar beet harvest apparatus of FIG. 2 from the sectioned view taken along section line 2′ of FIG. 1, in further combination with soil and a single row of topped beets during harvest.

[0023] FIG. 5 illustrates the preferred embodiment sugar beet harvest apparatus of FIG. 2 from the sectioned view taken along section line 2′ of FIG. 1, in further combination with soil and two rows of topped beets during harvest.

[0024] FIG. 6 illustrates a first alternative embodiment sugar beet harvest apparatus having two stage helical screw propellers designed in accord with the teachings of the present invention from a side elevational view, and further illustrating the movement of soil and beets during harvest.

[0025] FIG. 7 illustrates the first alternative embodiment sugar beet harvest apparatus of FIG. 6, from a sectioned view taken along section line 7′ of FIG. 6 and similar to that of FIG. 5 for comparison purposes, in further combination with soil and two rows of topped beets during harvest.

BEST MODE FOR CARRYING OUT THE INVENTION

[0026] Manifested in a preferred embodiment of the invention illustrated in FIG. 1, a sugar beet harvest apparatus 10 is optimally configured to lift sugar beets from the earth while simultaneously removing soil from the beets. While preferred embodiment sugar beet harvest apparatus 10 has been specifically designed for optimum operation with sugar beets, it will be apparent from the following description that the present invention may also be applied with few or no modifications to other root crops, and so any references herein to sugar beets will be understood to be referencing the preferred embodiment, but that other root crops may also be accommodated in either the preferred or alternative embodiments, depending upon the crop and soil.

[0027] Preferred embodiment sugar beet harvest apparatus 10 may be provided with a frame 11 or other suitable apparatus that may for exemplary and non-limiting purpose be coupled to a motive power source such as a prior art tractor. The motive power source will be configured as is well known in the industry to pull or otherwise propel sugar beet harvest apparatus 10 in a forward direction illustrated by direction arrow 4.

[0028] As sugar beet harvest apparatus 10 is propelled in the forward direction, a set of helical screw propellers 40 work cooperatively with a pair of discs 50 and field cultivators 55 to lift and separate topped sugar beets 3 or other suitable root crops from the earth 2. The pair of field cultivators 55 first engage with and break up the soil, while also lifting beets 3a and the surface of soil 2a to the positions illustrated by soil 2b and beet 3b. Field cultivators 55 will also lift larger obstacles and debris such as rocks out of the earth. Next, a pair of discs 50 will form a small furrow and ridge along the outsides of the planting row, for exemplary purposes only a few inches deep in the furrow, while also deflecting debris away from the crop row. This once again will lift soil to 2c and roll beets 3c into alignment with the set of helical screw propellers 40. The furrow and ridge formed by discs 50 allow a lowermost left and right pair of helical screw propellers 40a to operate on the sides of the ridge, reducing the likelihood for the helical screw threads 42a to contact the root crop in the downward half of rotation, while more extensively contacting the crop and earth in the upward half of rotation. This reduces the rotational resistance and driving power required, while also improving the efficiency of the pair of helical screw propellers 40a at lifting root crops 3 from the soil. In addition, the furrow produced by discs 50 provide a clear path for the lowermost portion of support structure 16.

[0029] As the sugar beets 3 are progressively lifted from earth 2by the set of helical screw propellers 40, as illustrated by the sequence of sugar beets 3d, 3e, and 3f, soil is removed therefrom and dropped back to ground 2d at the trailing side of the set of helical screw propellers 40. Sugar beets 3 that have been fully cleaned and lifted by the set of helical screw propellers 40 will then be dropped or otherwise transferred onto suitable conveyance to propel lifted sugar beets into a prior art storage bin or the like, where they may be retained for some period during field harvesting, and from which they may be ultimately transferred to a land transportation vehicle such as a truck or rail car for ultimate delivery to a sugar beet processing plant. In an alternative embodiment, and not normally required or beneficial, additional prior art apparatus may be provided, for exemplary and non-limiting purpose including grabrolls, cleaning rollers, agitators, or other variants that are designed to further separate soil from the sugar beets.

[0030] Each of the Figures illustrate a single preferred embodiment sugar beet harvest apparatus 10. A single preferred embodiment sugar beet harvest apparatus 10 will be used to lift either a single row of sugar beets from the earth during harvest, as illustrated in FIG. 4, or two parallel rows of sugar beets as illustrated in FIG. 5. However, and as may be appreciated from FIG. 1, there is sufficient space at the rear of the tractor for a plurality of preferred embodiment sugar beet harvest apparatuses 10. In fact, and most preferably, as many preferred embodiment sugar beet harvest apparatuses 10 will be provided as may be safely attached to and reliably powered and pulled by a prior art tractor or other motive power source, and for which a suitable prior art conveyor system may receive and where appropriate further process root crop from.

[0031] As may be apparent, each single preferred embodiment sugar beet harvest apparatus 10 will be aligned with either one or two rows of sugar beets. Consequently, the spacing between adjacent ones of preferred embodiment sugar beet harvest apparatus 10 will need to be set to correspond to the planting of the field. This setting may be fixed at the time of fabrication, or may be adjustable.

[0032] A plurality of rotary hydraulic motors 25a-25d are provided that may, for exemplary purposes, be powered from a pressurized hydraulic fluid ultimately delivered from a prior art tractor, owing to the availability of substantial hydraulically delivered power available from most commercially available tractors. However, in alternative embodiments these motors may be driven by other power source, for exemplary and non-limiting purpose including electrical and pneumatic power sources, though any suitable source of rotary drive may be used and will be understood to be incorporated herein.

[0033] Each one of rotary hydraulic motors 25a-25d rotate and directly drive a respective one of helical screw propellers 40a-40d. In an alternative embodiment, gearing or other suitable power transmission may be provided between one or more of the rotary hydraulic motors 25a-25d and helical screw propellers 40a-40d. For exemplary and non-limiting purpose, each one of rotary hydraulic motors 25a-25d may be affixed to and rigidly supported by support structure 16, which is in turn affixed to and rigidly supported by frame 11. Rotary hydraulic motors 25a-25d are configured to directly engage respective ones of rotary shafts 41a-41d. Extending along a portion of each one of rotary shafts 41a-41d distal from hydraulic motors 25a-25d is a respective helical screw thread 42a-42d.

[0034] From the front view of FIG. 3, the right side helical screw propellers 40a-40d have the respective helical screw threads 42a-42 wrapped in a counter-clockwise spiral, while the left side helical screw propellers 40a-40d have the respective helical screw threads 42a-42 wrapped in a clockwise spiral. The right side helical screw propellers 40a-40d are driven to rotate in a clockwise direction, while the left side helical screw propellers 40a-40d will be rotating in a counter-clockwise direction. This direction of helical screw thread wrap and direction of rotation causes sugar beets 3 to be lifted, and dirt to be pushed in a rearward direction. In the unlikely event of a jam, it is preferable to enable rotary hydraulic motors 25a-25d or any provided power transmission to be reversed.

[0035] The left and right side helical screw propellers 40a-40d rotate at sufficiently high speed to both lift and drive sugar beets 3 rearward. By ensuring that the speed of rotation is great enough that the helical screw threads move beets 3 more rearward than the rate of forward travel of frame 11, there will be no accumulation or piling of beets and soil against the upper screw propellers 40c and 40d, ensuring that the beets are fully separated from the soil prior to being rearwardly discharged from left and right side helical screw propellers 40a-40d.

[0036] In the process of driving beets 3 rearward and upward from the soil, the sugar beet will be pushed through adjacent soil. Lowermost helical screw propellers 40a are most preferably running immediately adjacent to an undisturbed surface of the earth such as at the level illustrated at 2a. Since the soil 2b and beet 3b are lifted slightly by field cultivator 55, and then the soil 2c and beet 3c are lifted and rolled by disc 50, this means that the lowermost helical screw propellers 40a will engage with a substantial amount of soil, thoroughly pulverizing the soil. The pulverized soil 2d is agitated with and thereby pressed against the surface of beets 3d that are in the process of being lifted from the earth. The result is a “brushing” effect of the soil surrounding the beet, where loose and pulverized soil adjacent the beet contacts and lightly brushes the surface of the sugar beet, further removing any stuck or adhered dirt. This brushing effect, which will occur in all soil types and conditions, is most pronounced with lowermost helical screw propellers 40a, when the beets are most adjacent to the dirt 2d. As a result of the combined “brushing” with surrounding soil and the agitation induced by the helical screw threads in contact with both adjacent soil and sugar beets, a large portion of the soil that would otherwise adhere to the sugar beet will be removed therefrom.

[0037] The setting of speed of rotation, selection diameter of rotary shaft 41a and helical screw thread 42a, and selection of speed of forward travel of preferred embodiment sugar beet harvest apparatus 10 for a selected root crop enables the root crop to be cleanly extracted from the soil. Both the speed of rotation and speed of forward travel will preferably be selectable by the machinery operator, and will be adjusted to accommodate soil and crop conditions at the time of harvest. When the helical screw threads 42 are properly configured and then rotated at an appropriate rotational velocity, the pair of helical screw propellers 40 are far more efficient at removing soil and debris from sugar beets than the prior art Oppel wheels and lifting shares, and without the need for subsequent grabrolls, cleaning rollers, agitators, or other variants that are designed to further separate soil from the sugar beets. Proper configuration of the helical screw threads includes a combination of thread depth, thread count or thread pitch such as the number of threads per longitudinal foot of rotary shaft 41 or the spacing between threads along an axis parallel to the longitudinal axis of rotary shaft 41, and the geometry of the threads themselves. In the preferred embodiment, helical screw threads 42 are continuous, and rounded on their exterior surface distal to rotary shaft 41. This rounded exterior reduces the likelihood that threads 42 will scrape or cut the sugar beets, while the thread depth is sufficient to provide good movement of soil and sugar beets. In alternative embodiments such as may be desired with other crops or different soil types, threads 42 may be designed with different thread depth, different thread pitch or count, or more or less aggressive thread exterior. In further alternative embodiments, the threads may even be discontinuous, such as discrete thread segments, each segment separated from the next by a gap where no thread is provided. In a yet further embodiment, rather than a single helix as illustrated, several thread helixes may simultaneously wrap around rotary shaft 41. In a yet further alternative embodiment, the threads may have a rotary pattern around rotary shaft 41 that deviates from the smooth and continuous geometry of a helix, thereby potentially creating additional agitation in the soil and sugar beets.

[0038] As a result of the better effectiveness at removing soil and debris from sugar beets than the prior art, the sugar beets may be fed directly, such as by conveyor, from preferred embodiment sugar beet harvest apparatus 10 to a holding or transport bin. Prior art sugar beet harvesting equipment normally requires large and complex apparatus to remove excess soil and debris, such as grab rollers and the like. Since these are not needed in the preferred embodiment, a sugar beet harvest apparatus designed in accord with the teachings of the present invention may be substantially smaller and lighter than a prior art harvester. A lighter and less complex harvesting apparatus as taught in the present invention will have intrinsically lower materials and fabrication cost, will generate less tare, reduce overall cost at the processing facility owing to less maintenance of separating and washing tanks and the like, will generally require lower horsepower to drive the harvesting apparatus, and may be used in wetter or muddier fields with less chance of becoming stuck. In addition, the preferred embodiment sugar beet harvest apparatus 10 has improved durability that is inherent in the design when compared to the prior art. The preferred embodiment sugar beet harvest apparatus 10 is much more difficult to clog or jam with rocks, and incorporates parts that are generally not susceptible to damage if contact with large rocks and the like. As a result, apparatus designed in accord with the teachings of the present invention may also be used in soil conditions worse than those that could be traversed by the prior art.

[0039] In preferred embodiment sugar beet harvest apparatus 10, the pairs of left and right helical screw propellers 40 are not parallel to each other, and instead are angularly offset so that the leading or most forward end of the pair of helical screw threads 42, immediately adjacent to rotary hydraulic motors 25, are spaced apart farther than the trailing or most rearward end distal thereto. This angular orientation between the individual ones of rotary shafts 41 enables the pairs of left and right helical screw propellers 40 to lift larger sugar beets more nearly adjacent to rotary hydraulic motors 25, while smaller sugar beets will pass more rearward before coming into contact with the left and right pairs of helical screw threads 42 and thereby being lifted from the earth.

[0040] While not separately illustrated herein, in an alternative embodiment the spacing between left and right helical screw propellers 40 may be adjustable. For exemplary purposes only and not solely limiting the invention thereto, the couplings to frame 11 may be adjustable couplers, which may for exemplary and non-limiting purpose comprise U-bolts or the like. Similarly, the couplings between rotary hydraulic motors 25 and support structure 16 may also be adjustable. This allows an operator to adjust the spacing between the individual ones of rotary shafts 41a-41d. Varying the spacings can enable preferred embodiment sugar beet harvest apparatus 10 to accommodate differing row spacings, differing sizes of root crops being harvested, or differing soil conditions.

[0041] While normally not required or desired, in further alternative embodiments, the couplings between rotary hydraulic motors 25 and support structure 16 may also be tiltable, such as providing a slot rather than a hole at either the leading or trailing edge through which fasteners will pass. Once again, this tilt may also be used to enable preferred embodiment sugar beet harvest apparatus 10 to accommodate differing sizes of root crops being harvested, or differing soil conditions.

[0042] As may be best illustrated in FIGS. 4 and 5, the same or only slightly adjusted preferred embodiment sugar beet harvest apparatus 10 may be used to harvest either a single row or two adjacent rows of sugar beets 3. As illustrated in FIG. 4, preferred embodiment sugar beet harvest apparatus 10 will move forward with the row of beets roughly centered between field cultivators 55. The beets will be progressively lifted by the left and right side helical screw propellers 40a-40d. The staggered unsupported ends of the left and right side helical screw propellers 40a-40d distal to rotary hydraulic motors 25 ensure that the beets will remain supported and not drop to the earth. The alternating patterns as visible in FIG. 2 lead to a sort of stair stepping of the beets, where beets that first engage with right side helical screw propeller 40a will be pushed upward toward right side helical screw propeller 40b, but also toward left side screw propellers 40a and 40b. Those beets in contact with left side screw propellers 40a and 40b will again not only be pushed upward, but also will be moved by the helical thread toward the unsupported end of right side helical screw propeller 40b. Similarly, beets in contact with right side screw propellers 40b and 40c will again not only be pushed upward, but also will be moved by the helical thread toward the unsupported end of left side helical screw propellers 40c and 40d. Finally, beets in contact with left side screw propellers 40c and 40d will again not only be pushed upward, but also will be moved by the helical thread toward the unsupported end of right side helical screw propeller 40d. After being fully lifted by the uppermost left and right side helical screw propellers 40d, as illustrated by beet 3f, the beets will then be discharged or dropped from the uppermost left and right side helical screw propellers 40d as illustrated by beet 3g. Sugar beets 3g that have been cleaned and lifted by the set of helical screw propellers 40 will then be dropped or otherwise transferred onto suitable conveyance to propel lifted sugar beets into a prior art storage bin or the like, where they may be retained for some period during field harvesting, and from which they may be ultimately transferred to a land transportation vehicle such as a truck or rail car for ultimate delivery to a sugar beet processing plant.

[0043] While a total of eight left and right side helical screw propellers are illustrated in preferred embodiment sugar beet harvest apparatus 10, it will be understood herein that a minimum of four helical screw propellers may be used, with two on each of the left and right sides. There is no limit to the number of propellers that may be used, but adding extra propellers beyond the eight illustrated decreases the benefit gained, while adding to the total parts count and increasing the weight and energy required to drive the apparatus.

[0044] FIG. 5 illustrates the simultaneous harvesting of two parallel rows with a single preferred embodiment sugar beet harvest apparatus 10. As illustrated, field cultivators 55 run adjacent to the outside edge of the two row pair, breaking up the soil and slightly lifting the beets. In an alternative embodiment, two additional field cultivators 55 may be provided, with each one of the pair adjacent to the inside of one of the pair of rows, thereby providing a field cultivator 55 on each side of each row of beets 3.

[0045] The beets in FIG. 5 are numbered to directly correspond to the illustration of FIG. 1, providing a top view of the movement of the beets. The discs 50 push the beets inward, tending to roll them along with the soil into the center, where they will be collected, cleaned, and lifted by the left and right side helical screw propellers 40a-40d, in the same manner as already described herein above.

[0046] As may be apparent from FIGS. 4 and 5, preferred embodiment sugar beet harvest apparatus 10 will accommodate very different row spacing, ranging for exemplary purposes from 17″ used in some locales to 30″ used in others. As noted herein above, row spacing in some embodiments will be varied by individual row. Likewise, since nothing within preferred embodiment sugar beet harvest apparatus 10 will trap or constrain the beets, and instead each of the components simply lift the beets, preferred embodiment sugar beet harvest apparatus 10 will accommodate and work very well with beets of very diverse size.

[0047] The helical screw propellers 40a-40d may be of different lengths. For exemplary and non-limiting purpose, in preferred embodiment sugar beet harvest apparatus 10, helical screw propellers 40a are approximately 12″ in length, while helical screw propellers 40d are approximately 34″ in length. Helical screw propellers 40a-40c are identical in diameter, while helical screw propellers 40d are preferably somewhat smaller to reduce bruising. There is minimal bruising to the root crop adjacent to helical screw propellers 40a-40c, owing to the presence of soil therein cushioning the root crop. However, by the top helical screw propellers 40d, there may not be sufficient soil to provide desired cushioning, and so a smaller diameter is preferred for these. Nevertheless, the length and diameter of the various helical screw propellers may be varied, and will be chosen by a designer in light of the present disclosure.

[0048] Preferred embodiment sugar beet harvest apparatus 10 will be suitably supported and positioned relative to the earth in a manner such as is also known in the prior art and for exemplary and non-limiting purpose taught and illustrated in the many patents incorporated by reference herein above. As but one example, a pair of adjustable support chains may be used to suspend a parallel linkage from a frame. The support chains set a maximum depth into the earth that preferred embodiment sugar beet harvest apparatus 10 will reach relative to the frame, by limiting the amount a top and generally horizontal arm of the parallel linkage may tilt down into the earth. Support chains may also be substantially shortened to facilitate transportation of preferred embodiment sugar beet harvest apparatus 10 to and from a field to be harvested. Once at the field and aligned with one or more rows to be harvested, an operator will then stop and extend the support chains, prior to starting to harvest.

[0049] One or a plurality of gauge wheels may also set and maintain a predictable height for discs 50 and field cultivators 55 relative to the top of the soil. These gauge wheels may be provided at the front, along the sides, or even at the rear of apparatus 10, and the number, size and location of these wheels will be selected by a machine designer to meet particular criteria that are well known and understood in the industry. In some embodiments, a computerized system of sensors and hydraulic actuators is used to raise and lower the machinery relative to the field.

[0050] A diagonal spring may be provided that runs diagonally across opposite corners of parallel linkage may be used to create tension that helps to pull the left and right pair of helical screw propellers 40a-40d down into the surface of the earth. However, when an obstacle such as a large rock is encountered, the diagonal spring will lengthen, allowing the parallel linkage to deflect and the left and right pair of helical screw propellers 40a-40d to lift from the soil surface. Consequently, this type of parallel linkage in combination with diagonal spring assists in depth control of each individual preferred embodiment sugar beet harvest apparatus 10 provided in combination with a tractor or other motive power source. When there are a plurality of these preferred embodiment sugar beet harvest apparatuses 10 provided to facilitate the harvesting of a plurality of rows simultaneously, this means each individual preferred embodiment sugar beet harvest apparatus 10 will follow the contour of the crop row which it is harvesting from, helping to ensure excellent harvesting regardless of the number of rows being harvested in a single pass. While springs and chains are described, other apparatus may be provided such as pneumatic tensioners or other known equivalent tensioners or adjusters, including those that incorporate sensors and electronic technology.

[0051] Various embodiments of apparatus designed in accord with the present invention have been illustrated in the various figures. The embodiments are distinguished by the hundreds digit, and various components within each embodiment designated by the ones and tens digits. However, many of the components are alike or similar between embodiments, so numbering of the ones and tens digits have been maintained wherever possible, such that identical, like or similar functions may more readily be identified between the embodiments. If not otherwise expressed, those skilled in the art will readily recognize the similarities and understand that in many cases like numbered ones and tens digit components may be substituted from one embodiment to another in accord with the present teachings, except where such substitution would otherwise destroy operation of the embodiment. Consequently, those skilled in the art will readily determine the function and operation of many of the components illustrated herein without unnecessary additional description.

[0052] In some particularly heavy and sticky soil types, discs 50 may not only lift beets up, they may also undesirably form the sticky soil into balls that resemble beets or other root crop in diameter and consistency. To eliminate the formation of these dirt balls, in one particularly preferred alternative embodiment the pair of discs 50 may be replaced with a pair of helical props.

[0053] FIGS. 6 and 7 illustrate a first alternative embodiment sugar beet harvest apparatus 110 having this configuration. A pair of screw propellers 150 are provided instead of discs 50 found in sugar beet harvest apparatus 10. Screw propellers 150 may be supported from frame 11 by support arms 52, and are driven by an associated motor 151. Motors 151 may be direct drive hydraulic motors, similar to motors 25a-d, but like motors 25a-d in alternative embodiments there may be sources of power other than hydraulic, and there may be additional power transmission members including for exemplary and non-limiting purpose gears or chain and sprockets.

[0054] The angle of the pair of screw propellers 150, relative to the plane of the surface of the earth when rotated about a horizontal axis, and relative to the longitudinal axis of frame 11 when rotated about a vertical axis, may each be predetermined in some embodiments at the time of design. In other alternative embodiments, these angles may each be adjusted at the factory. In yet further alternative embodiments, these angles may be adjusted by a machinery operator in the field during harvest through the provision of two-axis adjustable couplings which are prevalent and well-known in the mechanical arts.

[0055] For exemplary and non-limiting purpose, the rotary shaft of screw propeller 150 visible in FIG. 6 is illustrated as extending longitudinally within a plane parallel to the surface of the earth. However, in many embodiments the end of the rotary shaft adjacent to motor 151 will be higher than the end of the rotary shaft distal to motor 151. This angular tilt about a horizontal axis helps to keep motor 151 raised slightly above the earth and out of ground contact and interference, while keeping the end of screw propeller 150 distal to motor 151 in the earth and operative to lift beets such as beet 3c from the earth.

[0056] Screw propellers 150 are most preferably rotated in a direction which pushes the dirt downward and into the soil. In the illustration of FIG. 7 and viewing from the front of the machine and looking opposite to the direction of travel 4, the left side screw propeller 150 will rotate in a counter-clockwise direction, while the right side screw propeller 150 will rotate in a clockwise direction. The thread depth of the helical screw threads is preferably less than the radius of the smallest beets desirably harvested. This leads to the beets rolling off of the helical screw threads and thereby being lifted relative to the loosened soil, while the loose soil is driven by the helical screw threads back into the earth.

[0057] The replacement of discs 50 with the pair of screw propellers 150 results in a two stage helical screw propeller arrangement. The two stage arrangement further reduces undesirable tare in particularly heavy and sticky soil.

[0058] As noted herein above, the present invention eliminates the need for grab rollers and rock separators required by the prior art. As a result, the present invention is both lighter in weight and requires less power for operation.

[0059] In consideration thereof, in some alternative embodiments of the invention, a topper may be provided affixed to the front of the motive vehicle used to tow and power the sugar beet harvest apparatus 10, 110 of the present invention. The beet topper may for exemplary and non-limiting purpose comprise apparatus very similar to that already used in the industry, but explicitly suspended from the front of the motive power vehicle (a tractor for exemplary and non-limiting purpose). The savings in weight and power consumption of the present invention are sufficient for many embodiments to be adequate to power and support the topper without exceeding the weight and power consumption of prior art beet lifters.

[0060] Prior to the present invention, such toppers were used on an independent machine which was run through the field in a first pass, ahead of any beet lifting apparatus. The beet lifting apparatus was then run through the field in a second pass, either requiring two machine operators, or requiring a machine operator to first traverse the field topping the beets and then traverse the field harvesting the topped beets.

[0061] Consequently, a first benefit of this combination topper and harvesting apparatus is the saving of time and labor during harvest. However, another important benefit is that, by combining the topper and harvest apparatus, the beet tops will most preferably be removed and dropped outside of the area being instantaneously harvested. For exemplary and non-limiting purpose, the two-row sugar beet harvest apparatus 10, 110 illustrated in FIGS. 5 and 7 might drop the beet tops just to the right of the rightmost field cultivator 55, or in other embodiments tot he rear of the machine, thereby keeping the tops out of the subsequent helical screw propellers 40. This will in some embodiments and circumstances also improve the operational efficiency of those screw propellers 40.

[0062] While the foregoing details what is felt to be the preferred embodiment of the invention, no material limitations to the scope of the claimed invention are intended. Further, features and design alternatives that would be obvious to one of ordinary skill in the art are considered to be incorporated herein. The scope of the invention is set forth and particularly described in the claims herein below.

INDUSTRIAL APPLICABILITY

[0063] The present invention is applicable generally to agriculture, and more particularly to the harvesting of root and tuber crops including but not limited to sugar beets. The present invention and the preferred and alternative embodiments have been developed with a number of objectives in mind. While not all of these objectives are found in every embodiment, these objectives nevertheless provide a sense of the general intent and the many possible benefits that are available from embodiments of the present invention.

[0064] A first object of the invention is to provide an improved sugar beet harvest apparatus. A second object of the invention is to provide an improved harvest apparatus that may be used to accommodate and efficiently harvest other types of root crops. Another object of the present invention is to accommodate and efficiently harvest different and potentially inconsistent row spacings. As a corollary thereto, an object of the present invention is to enable individual or single row widths to be altered, thereby allowing particular rows to be spaced at a custom width, which can be used to create larger spacings that may be used to accommodate tires and the like from larger equipment. A further object of the invention is to accommodate and efficiently harvest diverse sized root crops, thereby resulting in cleaner fields and better crop yields. An even further object of the invention is to optionally configure a single harvest apparatus to either harvest a single row at a time by directly engaging both sides of the row or to simultaneously harvest two adjacent rows by engaging only one side of each adjacent row. Yet another object of the present invention is to provide excellent harvesting with minimal tare and minimal crop damage in all soil types and conditions where harvesting machinery may reliably traverse the surface of the earth. An additional object of the invention is to use disaggregated soil during harvest to clean and scrub a root crop. An even further object of the invention is to provide a root crop harvesting apparatus that is inherently durable and difficult to clog or jam. Another object of the invention is to provide a root crop harvesting apparatus that may top, lift, and separate the root crop from the soil and rocks in a single pass of the machinery.

[0065] While the foregoing details what is felt to be the preferred embodiment of the invention, no material limitations to the scope of the claimed invention are intended. Further, features and design alternatives that would be obvious to one of ordinary skill in the art are considered to be incorporated herein. The scope of the invention is set forth and particularly described in the claims herein below.