BR132015013588E2 - ROWING UNIT FOR SEEDING MACHINE AND METHOD FOR DISPENSING SEED OF A MEMBER OF SEED DOSING FOR SULCO - Google Patents

Abstract

“Row unit for a sowing machine, and method for dispensing a seed from a seed dosage member to a furrow” this certificate of addition relates to a row unit for a sowing machine, and a method for dispense a seed from a seed dosage member into a furrow.

Description

“ROW UNIT FOR A SEEDING MACHINE, AND METHOD FOR DISPENSING A SEED FROM A SEED DOSAGE MEMBER TO A SULCO” PU000054-2 Certificate of Addition of Invention, deposited on 27/01/2010 Field of Certificate of Addition [ 001] This certificate of addition concerns a row unit for a sowing machine, and a method for dispensing a seed from a seed dosage member into a furrow.

Certificate of Addition Fundamentals [002] An agricultural seeder such as a tillage planter or fertilizer seeder places seeds to a desired depth in a plurality of parallel seed ditches formed in the soil. In the case of a row tillage planter, a plurality of row tillage units are typically buried using wheels, axles, sprockets, transfer boxes, chains and the like, or driven by electric or hydraulic motors. Each row crop unit has a frame that is movably coupled to a tool bar. The frame can carry a main seed hopper, herbicide hopper and insecticide hopper. If herbicides and insecticides are used, the dosage mechanisms associated with granular product dispensation in the seed ditch are relatively simple. On the other hand, the mechanisms needed to properly dose seeds and dispense seeds at predetermined relative locations in the seed ditch are relatively complicated.

[003] The mechanisms associated with seed dosing and seed placement in general can be divided into a seed dosing system and a seed placing system, which are in series communication with one another. The seed dosing system receives the seeds in a bulk form of the seed hopper supported by the planter frame or row unit. Different types of seed dosing systems can be used, such as seed plates, finger plates, seed disks, etc. In the case of a seed disk dosing system, a seed disk is formed with a plurality of seed cells spaced at the periphery of the disk. Seeds move to seed cells with one or more seeds in each seed cell, depending on the size and configuration of the seed cell. A positive differential vacuum or air pressure may be used in combination with the seed disk to assist in the movement of seeds into the seed cell. Seeds are individualized and discharged at a predetermined rate into the seed placement or distribution system.

[004] The most common seed distribution system can be categorized as a gravity drop system. In the case of the gravity drop system, a seed tube has an inlet end that is positioned below the seed dosing system. Individualized seeds from the seed dosing system merely fall into the seed tube and fall by the gravitational force of one discharge end thereof into the seed ditch. The seed tube may bend backwards to reduce seed bounce as it collides at the base of the seed ditch and to give the seed a horizontal velocity to reduce the relative velocity between seed and soil. Undesirable variation in resulting ground velocity spacing can be attributed to differences in how individual seeds leave the dosing system and fall through the seed tube. Spacing variation is exacerbated by higher velocities across the field that amplify the dynamic conditions of the field. Additional variations in seed spacing are caused by the inherent relative velocity difference between seeds and soil as the seeder moves through a field. This relative velocity difference causes individual seeds to bounce and fall in somewhat random patterns as each seed spreads in the ditch.

Several attempts have been made to reduce the variation in seed spacing resulting from gravity drop. U.S. Patent 6,681,706 shows two approaches. One approach uses a winged belt to carry seeds from the doser to the ground, while the other approach uses two belts to grab the seed and transport it from the doser to the soil. Although these approaches control the seed path and reduce variability due to dynamic events, no approach seeks to distribute the seed with the smallest horizontal velocity difference possible from the ground. U.S. Patent 6,651.57, 7,185,596 and 7,343,868 show a seed dispensing system using a near-ground brush wheel to regulate the horizontal velocity and direction of the seed as it leaves the sowing machine. However, there is still a gravity drop between the seed dispenser and the brush wheel that produces variation in seed spacing.

Summary of Certificate of Addition [006] This Certificate of Addition provides a row unit for a sowing machine having a seed dosing member with a plurality of holes through which an air pressure differential is applied to retain seed therein. , the movable seed dosage member for transporting seed from a seed reservoir, the row unit characterized in that it comprises: a housing for the seed dosage member; and a seed dispensing apparatus comprising a first pulley, a second pulley, and a continuous member configured to be driven by the first pulley and / or the second pulley, at least a portion of the continuous member positioned within the housing, wherein the member The continuous loop is positioned to move through at least one of the plurality of holes.

Alternatively, the row unit of is characterized in that the plurality of holes extends from one seed side to an opposite side of the seed dosage member, the seed side having a seed face, and wherein the continuous member is positioned to move through a portion of the seed face.

In another alternative, the row unit is characterized by the fact that the continuous member is positioned to make contact with the seed face portion.

Alternatively, the row unit of is characterized by the fact that the seed dosage member is in the form of a disk.

Alternatively, the row unit of is characterized in that the seed metering member is configured to rotate about a first geometry axis, and wherein the first pulley is configured to rotate about a second axis. having an orientation not parallel to the first geometric axis.

Alternatively, the row unit of is characterized in that the seed metering member is configured to rotate about a first geometry axis, and that the first pulley is configured to rotate about a second axis. having an orientation parallel to the first geometric axis.

Alternatively, the row unit of is characterized by the fact that the continuous member is in the form of a bristle belt.

The Certificate of Addition also provides a method for dispensing a seed from a seed dosage member into a furrow, the seed dosage member at least partially contained within a housing, the method comprising: releasing the seed from the seed dosage member; scanning a portion of the seed dosage member with a surface of a continuous member, the surface positioned within the housing; transporting the seed via a continuous member along an interior of a housing within which the continuous member extends; and discharging the seed from an opening in the housing to the furrow.

Alternatively, the method is characterized by the fact that it further includes driving the continuous member with a pulley.

Alternatively, the method is characterized by the fact that it further includes driving the seed dosage member independently of the continuous member.

Alternatively, the method is characterized in that releasing the seed from the seed dosage member means removing an air pressure differential applied to an orifice extending from the seed face to an opposite side of the seed dosage member. .

Alternatively, the method is characterized in that releasing the seed from the seed dosage member occurs prior to sweeping a portion of the seed dosage member.

Alternatively, the method is characterized in that the seed dosage member has a seed face to which the seed is adhered, and that sweeping a portion of the seed dosage member means sweeping a portion of the seed face. seed.

Alternatively, the method is characterized by the fact that scanning a portion of the seed face includes making contact with a portion of the seed face.

Alternatively, the method is characterized by the fact that the seed dosage member is in the form of a disk, and that sweeping a portion of the seed dispenser means sweeping a portion of the disk.

Alternatively, the method is characterized by the fact that the continuous member is in the form of a bristle belt, and that sweeping a portion of the seed dosage member with a surface of a continuous member means sweeping with a surface of the bristle strap.

Brief Description of the Drawings Figure 1 is a plan view of a planter with the seed distribution system of the present invention; Figure 2 is a side view of a planter row unit of Figure 1; Figure 3 is an enlarged side view of the seed distribution system of the present invention; Figure 4 is a top view of a planter row unit showing the orientation of the dosage system in an alternative arrangement of the dosage system and delivery system of the present invention; Fig. 5 is a top view similar to Fig. 4 illustrating the dispensing system with the dispenser housing removed; Fig. 6 is a side view of the row unit of Fig. 4; Fig. 7 is a perspective view of the seed disc used in the seed dispenser shown in Figs. 4-6; Figure 8 is a sectional view taken along line 8-8 of Figure 7 illustrating the orientation of the seed and brush disc or the seed distribution system of the present invention; Figure 9 is a side view of a row unit showing the orientation of the delivery system of the present invention and a vacuum belt seed dispenser; Figure 10 is a side view of another orientation of the seed distribution system of the invention with a vacuum belt seed dispenser; and Figure 11 is a side view illustrating the orientation of the seed delivery system of the invention with a finger picker.

Description Referring to Figures Referring to Figure 1, an example 10 planter or seeder containing the seed distribution system of the present invention is shown. Planter 10 includes a toolbar 12 as part of a planter frame 14. Mounted to the toolbar are multiple planting row units 16. Row units 16 are typically identical for a given planter, but there may be differences. A row unit 16 is shown in more detail in figure 2. Row row 16 is provided with a central frame member 20 with an upwardly extending pair of arms 21 (figure 4) at its front end. The arms 21 connect to a parallelogram joint 22 for mounting the row unit 16 to the tool bar 12 for relative up and down movement between the unit 16 and the tool bar 12 in a known manner. Seed is stored in the seed hopper 24 and provided to a seed dispenser 26. The seed dispenser 26 is of the type that uses a well known vacuum disc to dose the seed. Other types of feeders may also be used. From seed feeder 26, the seed is carried by a dispensing device 28 to a planting pit, or ditch, formed in the ground by pit openers 30. Gauge wheels 32 control the depth of the pit. Closing wheels 34 close the pit over the seed. Gauge wheels 32 are mounted on frame member 20 by arms 36. The tool bar and row unit are designed to move on the ground in a forward working direction identified by arrow 38.

Row unit 16 additionally includes a chemical hopper 40, a row cleaner attachment 42 and a downward force generator 44. Row unit 16 is shown as an example of the environment in which the tank distribution system is located. The present invention is used. The present invention can be used in any of a variety of planting machine types, such as, but not limited to, row tillage planters, fertilizer drills, air seeders, and the like.

Referring to Figure 3, the seed distribution system 28 is shown in more detail. The dispensing system 28 includes a housing 48 positioned adjacent to the seed dispenser seed disc 50. The seed disk 50 is a generally flat disk with a plurality of openings 52 adjacent the periphery of the disk. Seeds 56 are collected in the openings of a seed puddle and adhere to the disc by means of the air pressure differential on opposite sides of disc 50 in a known manner. The disk may have a flat surface in the openings 52 or have seed cells surrounding the openings 52. The disk rotates clockwise, seen in figure 3, as shown by arrow 54. At the top of figure 3, seeds 56 are shown adhered to the disco.

The seed distribution system housing 48 has spaced front and rear walls 49 and 51 and a side wall 53 therebetween. An upper opening 58 in the sidewall of the housing 53 admits the seed of the dosing disc 50 into the housing. A pair of pulleys 60, 62 are mounted within the housing 48. The pulleys support a belt 64 for rotation within the housing. One of the pulleys is a drive pulley, while the other is a crazy pulley. The belt has a base member 66 for engaging the elongate pulleys and bristles 70 extending therefrom. The bristles are joined at the base element at the near or radially inner ends of the bristles. Distal or radially outer ends 74 of the bristles touch, or close to, the inner surface 76 of the side wall of the housing 53. An opening of the lower housing 78 is formed in the side wall 53 and is positioned as close as possible to the base. 80 from the seed ditch. As shown, the lower aperture 78 is near or below the ground surface 82 adjacent the ditch. The side wall of the housing forms an exit ramp 84 in the lower opening 78.

Turning attention to the upper portion of Fig. 3, a loading wheel 86 is provided adjacent to the upper opening 58. The loading wheel is positioned opposite the seeds 56 from the brush 64 such that the path of the seeds in the disc carry the seeds to a through-opening 88 formed between the loading wheel and the distal ends 74 of the bristles 70. At the location of the through-opening 88, the air pressure differential across the seed disc 50 ends, releasing the seed from the openings 52 on the disk. The lower surface of the loading wheel facing the seed disk 50 has recesses 90 formed therein. The recesses 90 receive seed agitators 92 that protrude from the seed disc 50. The movable agitators, by engaging the recesses in the loading wheel, put the loading wheel in a clockwise rotation.

In operation, belt 64 is rotated counterclockwise. As the belt curves around the pulleys, the bristles open naturally, that is, separate from each other as the distal ends of the bristles travel a greater circumferential distance around the pulleys than the inner ends of the bristles. on the belt base element. This produces two beneficial effects, described below. The seeds are transferred from the seed dispenser to the dispensing system as the seeds are carried by the disc to the through opening 88. Then the seeds are released from the seed disc between the loading wheel and the bristles 70 to remove the seed. seed from seed disc and seed dispenser. Seeds are captured or trapped in the bristles by inserting the seed in the bristles in a radial direction, ie by the ends of the bristles in a direction parallel to the length of the bristle. This occurs as soon as the belt path around the pulley 60 ends, when the ends of the bristles are closing back over themselves, allowing the bristles to close and capture the seeds thereon. As the belt continues to move, the bristles move or transfer the seeds down to the bottom opening of the housing. The side wall 53 of the housing cooperates with the bristles 70 to hold the seed in the brush bristles as the seed moves to the lower opening.

The lower opening 78 and the ramp 84 are positioned along the path of the curved belt around the pulley 62. The distal ends of the bristles thus cause the linear velocity of the seeds to accelerate relative to the velocity of the base element of the pulley. belt 66 and housing shown by the two arrows 94 and 96. The seeds are then driven by the bristles over the ramp 84 and discharged through the lower opening 78 in the seed ditch. Ramp angle 84 can be selected to produce the desired relationship between vertical and horizontal seed velocities at discharge. The direction of travel in front of the row unit is to the left in Figure 3, shown by arrow 38. At discharge, the horizontal velocity of the seed relative to the ground is minimized to reduce seed rolling in the ditch.

The strap shown in figure 3 has relatively long bristles. Because of the long bristles and the seed loading point being at the end of the curved path of the brush around the pulley 60, the seeds are loaded on the belt while the bristles slow down. The speed of the bristles at loading is thus lower than the speed of the bristles at the discharge opening as the belt moves around the pulley 62. This allows the seed to be loaded onto the belt at a relatively slower rate while the seed is discharged into the pulley. lower extremity at a higher desired speed. As previously described, it is preferable that the horizontal velocity of the seed at the discharge be equal to the forward displacement speed of the planter, but in the rearward direction such that the horizontal velocity of the seed relative to the ground is close to or equal to zero. Long bristles can be used to increase seed velocity as it shifts around the pulley. However, a short fence brush can also be used. With a short bristle brush, there will be little acceleration in seed velocity as the seed shifts around the pulleys. The belt will have to be driven at a speed to produce the desired horizontal velocity of the seed at the discharge. Even with a short bristle brush, the seed is still accelerated in the horizontal direction. As the belt travels around the pulley, the seed travel direction changes from the predominantly vertical direction as the seed moves below the seed feeder to a predominantly horizontal direction in the discharge. This produces an acceleration of seed velocity in the horizontal direction.

With dispensing system 28, seed is captured by the dispensing system to remove seed from the seed dispenser. The seed then moves through the distribution system to the seed unloading point where the seed is accelerated in a horizontal direction backwards relative to the housing. From seed dispenser to discharge, seed displacement is controlled by the distribution system, thereby maintaining seed spacing relative to each other.

In the embodiment shown in Figure 3, the seed disc and the front and rear walls 49, 51 of housing 48 are arranged in planes which are generally parallel to each other. As shown, the distribution system plane is generally parallel to the row unit's direction of travel. Other relationships between the seed feeder and the distribution system are shown and described below.

As shown in Figure 3, the sidewall 53 is divided by the upper and lower openings 58, 78 into two segments 53a and 53b. Segment 53a lies between the upper and lower openings in the belt travel direction, while segment 53b lies between the lower and upper openings in the belt travel direction. It is the clearances in the sidewall 53 that form the upper and lower openings. However, it should be understood that the distribution system will function without the side wall segment 53b. It is only segment 53a that works in conjunction with the belt bristles to distribute the doser seed into the seed ditch. Thus, the term "upper opening" shall be interpreted to mean an open area before the sidewall segment 53a in the direction of belt travel, and the term "lower opening" shall mean an open area after the sidewall segment 53a in the direction of belt travel. of belt travel.

Referring to Figures 4-7, the dispensing system 28 is shown in combination with the seed dispenser and the row unit structure in an alternative arrangement of the seed dispenser and dispensing system 28. The seed dispenser 200 is shown mounted on the row unit with seed disc 202 in a vertical orientation, but at an angle to the forward direction of travel shown by arrow 38. Figure 4 shows the orientation of the seed dispenser on the row unit without the dispensing system 28. The seed dispenser includes a housing with two halves 204 and 206 releasably joined together in a known manner. The seed feeder is driven by a transmission 208 coupled to a drive cable, not shown.

In Figure 5, only the seed disc 202 of the doser is shown with the seed distribution system 28. As previously mentioned, the seed disc 202 is in a vertical orientation but is not arranged in a plane parallel to the forward direction 38. Instead, the dispenser is oriented such that the disc is at an angle of 60 ° from the forward direction when viewed from above. The seed of the dispensing system 28 is generally identical to that shown in figure 3 and is driven by a motor 65. The dispensing system, including the brush belt 64, is generally vertical and aligned with the planter longitudinal direction of such that the angle between the brush and the seed disc is approximately 60 °. The angle between the dispensing system and a seed disc produces a partial "transverse feed" of the seed in the brush. That is, the seed is fed into the brush at an angle with the longitudinal direction of the bristles. This is the opposite of Figure 3, where the seed enters the flow in a direction substantially parallel to the longitudinal direction of the brush bristles. If the brush and seed disc are oriented at 90 ° to each other, a total cross feed would be produced with seed entering the brush perpendicular to the bristles.

The seed disc 202 is shown enlarged in figures 7 and 8. The disc 202 has opposite sides, a vacuum side 216 and a seed side 218. The seed side 218 has a surface 219 near the defining periphery. a reference plane. The reference plane will be used to describe disk resources near the disk periphery. An outer peripheral ferrule 220 is lowered in the reference plane. Peripheral Ferrule 220 creates a radially outer edge face 222. A circumferential row of spaced openings 224 is arranged about a radially circular path into edge face 222. Each opening extends across the disc between the vacuum side. 216 and seed side 218. Radially inwardly of each opening 224 is a radially elongated recess 226. Recess 226 is axially lowered into the disc from the reference plane. In operation, the disc rotates counterclockwise, indicated by arrow 228. During rotation, recesses 226 agitate the seed in the seed puddle.

Surrounding each opening 224 is a tapered recess, or shallow seed cell 232 that extends axially to the disc from the reference plane. Seed cell 232 begins at an advancing edge 234 in the direction of rotation of the disc and progressively deeper on the seed side 218 to an escaping edge formed by an axially protruding wall 236. The tapered recess or seed cell 232 reduces the vacuum required to collect and retain seed in openings 224. The seed cell also allows the seed to set lower than the seed side 218 of the disc, allowing the seed to be retained while the seed singler removes it. double or multiple seed openings 224. In addition, recess wall 236 shakes seed into the seed puddle, further assisting in seed collection. The wall 236 extends longitudinally in a predominantly radial direction shown by the dashed line 238. The walls 236, although predominantly radial, are inclined in the radial direction such that the inner end of the wall 236 leads the outer end of the wall in the direction. of rotation. Immediately following each wall 236 as the disc rotates is a projection, or vertical pin 240, extending axially from the seed side of the disc. The pins fit seed into the seed puddle for agitation to aid in seed collection. The pins 240 are located slightly radially into the circular path of the openings 224 to avoid interference with the seed singulator.

Referring to Figure 8, disc 202 is shown in operation and in position relative to belt 64 in dispensing system 28. Seeds 244 are carried by disc 202 to brush bristles 64, wall 236 and pins 240 act to push seed 244 into brush bristles 64 and help prevent seed from being blocked in the disc upon initial seed contact with brush bristles. Once the seed is inserted into the brush bristles, a vacuum on the opposite side of the disc is cut, allowing the brush to sweep the disc seed in a predominantly radial direction relative to the disc. An insert 246 overlaps ferrule 220 at the seed release point to secure the seed to the brush bristles in the transition between the disc and the side wall 53 (figure 3) of the dispensing system housing. The disc 202 is angled at the length of the brush bristles at an angle of approximately 60 degrees. This produces partial cross feed of the seed in the brush bristles.

Figure 9 shows the brush belt seed dispensing system 28 in combination with a vacuum belt dosing system with a 302 dosing belt. The vacuum belt dispenser is described in detail in US patent 7,918,168. incorporated herein by reference. Belt 302 collects seed in a collection region 304 at a lower front belt path location and transports it to the distribution system in a release region 306 at an upper rear belt path location. In this belt feeder arrangement and brush dispensing system, the dispensing system is again partially fed transversely with feeder seeds.

Another arrangement of the dispensing system together with a vacuum metering belt is shown in Figure 10. The dispensing system 28 is in line with the belt metering unit 124. This allows the distal ends of the brush bristles to sweep the surface of the dosing belt 126 to capture its seed. The dosing belt 126 is wrapped in pulleys 128. The dosing belt 124 is similar and functions as a above-mentioned belt 302.

The dispensing system of the present invention may also be used with seed feeders other than differential air pressure feeders. For example, with reference to Fig. 11, a finger picker 130 is shown as described in U.S. Patent 3,552,601 and incorporated herein by reference. The seed is ejected from the feeder through an opening 132. The dispensing system 134 has a brush belt 136 wrapped around the pulleys 138 and 140. As shown, the belt pulley 138 shares a common drive shaft with the feeder picker. 130. A hub drive such as a spherically continuously variable drive or a three-speed hub can be used to drive belt 136 at a different speed from the feeder 130. The distribution system housing includes a sidewall 142. A ramp 146 is formed at the lower end of the wall 142 adjacent the lower aperture 148. At the upper end of the dispensing system, the upper aperture is formed in the rear wall of the housing adjacent the aperture 132 through which seeds are ejected from the seed dispenser. The seeds are laterally inserted into the brush bristles in a complete transverse feed. As in other embodiments, the seed is captured in the brush bristles, moved down to the lower opening, accelerated backward and discharged through the lower opening 148.

The endless element of the dispensing system has been described as a bristle brush belt. In a broad sense, the bristles form an outer periphery of the contiguous disunity surfaces that engage and grasp the seed. Although brush bristles are the preferred embodiment, and may be natural or synthetic, other types of materials may be used to grasp the seed, such as foam cushion, expanded foam cushion, mesh cushion or fiber cushion.

Claims (16)

1. Row unit for a seeder machine having a seed metering member with a plurality of holes through which an air pressure differential is applied to retain seed therein, the movable seed metering member for transporting seed from a seed container means the row unit characterized in that it comprises: a housing for the seed dosage member; and a seed dispensing apparatus comprising a first pulley, a second pulley, and a continuous member configured to be driven by the first pulley and / or the second pulley, at least a portion of the continuous member positioned within the housing, wherein the member The continuous loop is positioned to move through at least one of the plurality of holes. Row unit according to Claim 1, characterized in that the plurality of holes extend from one seed side to an opposite side of the seed dosage member, the seed side having a seed face. and wherein the continuous member is positioned to move through a portion of the seed face. Row unit according to Claim 1, characterized in that the continuous member is positioned to make contact with the seed face portion. Row unit according to Claim 1, characterized in that the seed dosage member is in the form of a disk. Row unit according to Claim 1, characterized in that the seed metering member is configured to rotate about a first geometrical axis, and wherein the first pulley is configured to rotate about a second. geometry axis having an orientation not parallel to the first geometry axis. Row unit according to claim 1, characterized in that the seed metering member is configured to rotate about a first geometrical axis, and wherein the first pulley is configured to rotate about a second. geometry axis having an orientation parallel to the first geometry axis. Row unit according to Claim 1, characterized in that the continuous member is in the form of a bristle belt. A method for dispensing a seed from a seed dosage member into a furrow, the seed dosage member at least partially contained within a housing, the method comprising: releasing the seed from the seed dosage member seed; scanning a portion of the seed dosage member with a surface of a continuous member, the surface positioned within the housing; transporting the seed via a continuous member along an interior of a housing within which the continuous member extends; and discharging the seed from an opening in the housing to the furrow. Method according to claim 8, characterized in that it further includes driving the continuous member with a pulley. A method according to claim 9, characterized in that it further includes driving the seed dosage member independently of the continuous member. Method according to claim 8, characterized in that releasing the seed from the seed dosage member means removing an air pressure differential applied to an orifice extending from the seed face to an opposite side of the dosage member. seed Method according to claim 11, characterized in that releasing the seed from the seed dosage member occurs prior to sweeping a portion of the seed dosage member. A method according to claim 8, characterized in that the seed dosage member has a seed face to which the seed is adhered, and that sweeping a portion of the seed dosage member means sweeping a portion of the seed. seed face. Method according to claim 8, characterized in that scanning a portion of the seed face includes contacting a portion of the seed face. A method according to claim 13, characterized in that the seed dosage member is in the form of a disk, and that sweeping a portion of the seed dispenser means sweeping a portion of the disk. Method according to claim 8, characterized in that the continuous member is in the form of a bristle belt, and that sweeping a portion of the seed dosage member with a surface of a continuous member means sweeping with a surface of the bristle belt.