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    • 专利摘要:
    The invention relates to a seed drill comprising a plurality of sowing elements, each sowing element comprising means of dosing and transport, controlling the flow of the seeds at the outlet of a hopper and delivering said seeds in a transfer conduit for supplying feeds. means for planting said seeds, each sowing element also comprising a regulating device mounted between said metering and transport means and said planting means, close to the latter. The regulating device comprises a seed-fed reserve zone (22a) via a supply inlet connected to said dosing and transport means by an upstream portion (24a) of said transfer conduit and a wheel (23) capable of taking off seeds in said reserve space (22a), by means of at least one row of teeth forming buckets, each ensuring the removal of a seed in said reserve zone (22a) and the release of said seed in a downstream part (24b) of said transfer conduit. Movable retaining means (27) delay the release of each seed, being able to take two positions: - a holding position of a seed; and - a seed release position, said holding means being temporarily moved away from said wheel (23).
    公开号:FR3050607A1
    申请号:FR1653845
    申请日:2016-04-28
    公开日:2017-11-03
    发明作者:Daniel Clochard;Nicolas Legaignoux
    申请人:SULKY BUREL;
    IPC主号:
    专利说明:

    Seeder equipped with a device for regulating the distribution of seeds, and corresponding regulating device. 1. Field of the invention
    The field of the invention is that of seed drills in line, especially for sowing cereals or legumes. The invention relates more specifically to the improvement of the distribution on the ground of the seeds at the time of their distribution, and concerns in particular the regulation of the distribution, downstream of a device for dispensing and dosing a sowing element. Seeds are here understood to mean seeds, and more generally any particles that can be distributed in the same way, for example fertilizer or seedling protection particles (slug pellets, for example). 2. Prior art and its disadvantages
    In the context of precision farming, it is desirable that seed distribution during planting be as regular and as accurate as possible. It is generally desired that the seeds be deposited in a furrow, at regular intervals, without lack or duplication.
    For this purpose, precision seed drills have been developed, often called precision seeders. These precision seeders are intended to specifically sow a predetermined type of seed (maize, beetroot, etc.). They are used for inter-row cultures larger than 25 cm. Each row is usually fed with seeds by an individual hopper connected to its own distribution, burial and re-pressing organs. These seeders are effective, but at a relatively high cost. They have specific means, able to seize seeds They are bulky, require many adjustments, a contribution in energy (including pneumatic, to provide a depression to maintain the seeds one by one) adapted, and require precisely calibrated seeds. Precision seeders are consequently expensive, and reserved for certain particular situations.
    In addition, the precision seeders lack versatility, and in particular have a footprint such that they do not allow the planting of certain seeds, for example wheat, for which an inter-row spacing of less than 25 cm is desired.
    There are also seeders "multigrain", or "online", used in particular for cereals, such as wheat or oats. They also make it possible to carry out direct sowing, the seeds being distributed to each sowing unit by means of a metering and transport device, fed by a hopper containing the seeds and directing the seeds towards the soil via a transfer duct. . Such a metering device is generally placed under the hopper, and is equipped with one or more wheels provided with cells or teeth forming lugs, each able to receive a determined volume of seeds (the wheels being adapted to the type of seed to be sown).
    These dosing and transport systems are designed to allow the seeds to be ejected in a relatively regular manner in the transfer duct so as to ensure their homogeneous distribution, in line, in the soil. However, it is found in practice that there are areas on a groove length where the seeds are absent or on the contrary deposited in packets. This uneven distribution of seeds results in an irregular distribution of the seedlings, and thus in a loss of yield for the farmer.
    Thus, while precision seeding with a precision seeder can reach 90 to 95% of well-placed seeds, it usually remains below 40% with an on-line seeder.
    To improve the accuracy of these seeders in line, the applicant proposed, to distribute the seeds more homogeneously, to regulate the seed distribution by adding a buffer tank arranged on the path of the seeds, between the metering device and transport and the end of the duct, near the ground. This approach is described in particular in patent document FR2691040, which thus presents a regulation system implementing a plurality of diabolos arranged at the outlet of the metering device. Diabolos seize the seeds right out of the feeder via a supply chute that serves as a buffer, to cushion the effect of package arrivals and seed gaps. The V-shape of the diabolo makes it possible to gather and imprison the seeds to align them one after the other, with a better precision.
    However, the control device is sensitive to shaking. It must be placed immediately after the feeder, and therefore remains far from the ground. As a result, a large part of the seed distribution regularity gain is here also canceled during the transport of the seed between the regulator outlet and the soil. In addition, blockages of seeds may appear in a diabolo, reintroducing gaps, followed by packets at the time of release.
    There is therefore a need for more efficient regulation, for the on-line seed drills, making it possible to limit the losses of regular seed distribution, without resorting to the complex means of the precision seeding machines, and in particular to pneumatic means for maintaining the seeds. .
    In particular, it is desirable to improve the accuracy of conventional seed drills, to approach the precision of precision seeders, without the complexity and bulk of the latter.
    It is also desirable to provide versatile solutions, allowing to sow with good precision many types of seeds, whether large (eg corn), intermediate (wheat for example) or reduced (rapeseed for example). 3. DISCLOSURE OF THE INVENTION The invention responds to this need by proposing a seed drill comprising a plurality of sowing units, each sowing unit comprising dosing and transport means, controlling the flow of seeds at the outlet of a hopper. and delivering said seeds in a transfer conduit for supplying means for planting said seeds, each sowing element also comprising a regulating device mounted between said metering and transport means and said planting means, close to these last, said regulator comprising a reserve area fed with seeds via a feed inlet connected to said dosing and transport means by an upstream portion of said transfer conduit.
    According to the invention, the regulating device comprises a wheel adapted to collect seeds in said reserve space, by means of at least one row of teeth forming buckets, each ensuring the removal of a seed in said reserve zone and releasing said seed in a downstream portion of said transfer conduit, and retaining means delaying said release of each seed, movable between two positions: a seed-holding position; and a seed release position, said holding means being temporarily moved away from said wheel.
    These movable retaining means, which are adapted to retain the seeds, keep them in contact with the wheel longer than if it fell directly. This ensures synchronization of seed release, and release at a location and / or at a time when said seeds are only subjected to the force of gravity.
    The retaining position is a default position, obtained by prestressing the retaining means and / or via return means. This is the standard, or basic, position of mobile restraints, to which they naturally tend to return. The release position assumes a displacement action, or offset, on the retaining element (or at least a part thereof, the part assigned to the row of teeth concerned: as will be seen later, retaining member can control multiple rows, with separate release times, and also provide flexible sidewall functions (e.g. in the embodiment using a broom) to temporarily move and move away from the wheel (Passing from the retaining position to the release position), and therefore from the seed that was retained, this action can in particular be implemented by one or more elements integral with the wheel, whose rotation ensures synchronization, and by As soon as the displacement action ceases, the retaining means return to the retaining position.
    According to a particular embodiment, said retaining means consequently ensure the release of a seed only after said seed has passed under a horizontal axis passing through the axis of rotation of said wheel.
    Said retaining means may comprise at least one movable element and prestressed towards the wheel so that a portion of said movable element extends along a portion of the periphery of said wheel, according to the direction of rotation of said wheel.
    According to a particular approach, at a time and / or a location before that where said seeds are only subjected to the force of gravity, said movable element forms with at least one of said bucket elements of said wheel, a holding corridor said seeds.
    Thus, the seeds are maintained in the "corridor" (or "tunnel") until the free end of the movable element is moved away from the wheel. At this time, the seed can escape the "corridor" by gravity, under the effect of its own weight only, and fall substantially vertically in the transfer conduit.
    According to a particular embodiment, a displacement of said movable member, said holding position to said seed release position, is controlled and / or provided by said teeth.
    Said movable element may include in particular at least one first blade comprising a bristle assembly of which at least the free portion extends substantially tangentially to the wheel and substantially vertically.
    These bristles do not extend radially to the wheel, nor substantially parallel to the axis of rotation of the wheel. They extend substantially tangentially to the wheel, "lying in the direction of rotation".
    Thus, some bristles may extend above the bucket, while other hairs come in the area between the wheel and the walls of the regulator, and / or in contact with the hub of the wheel, thus forming the "corridor" for maintaining seeds.
    According to one embodiment, said wheel comprises at least two rows of pins (or teeth) forming buckets.
    The presence of at least two rows of pins makes it possible to produce a compact control device, since it makes it possible to transport at least twice as many seeds as a device comprising a single row, and to reduce the necessary speed of rotation. 'as much. In addition, the presence of at least two rows of spurs can act as a seed stirrer in the reserve zone: indeed, when a row of spurs picks a seed in the reserve zone, the other seeds the zone can be naturally moved to the other row or rows of buckets.
    In the case where said wheel comprises two rows of lugs, said lugs may be arranged staggered with respect to each other.
    More generally, when the wheel comprises several rows of lugs, they can be angularly offset relative to each other regularly, to release regularly and alternately the seeds of each row.
    According to a particular embodiment, the regulating device comprises at least one second brush, comprising a bristle assembly of which at least the free portion extends substantially tangentially to the wheel and substantially horizontally above said wheel.
    Thus, the bristles of the broom prevent the rise of the seeds by the free space between the rows of lugs, their flexibility limiting the risk of blocking the rotation of the wheel even in case of misplaced seeds or rebound.
    According to a particular embodiment, said lugs have a housing adapted to maintain a seed, during the rise thereof, and a flat portion on which said seed moves progressively during the descent.
    Such a shape makes it possible to keep the seeds effectively retained in the cups, even in case of shaking.
    The size of each bucket can be adapted to the size of seeds to be sown, for example the hemispherical inner shape has a diameter of 8 mm to 10 mm for corn kernels.
    According to a particular embodiment, said lugs have at least one side wall. This keeps the seeds sideways.
    According to a particular characteristic, said row of lugs is disposed at a distance from a wall of said device substantially less than the diameter of said seeds.
    Thus, each row of buckets is placed closer to the wall of the housing (for example 1 mm), to prevent the passage of seeds along this wall.
    According to a particular embodiment, said wheel is rotated by a motor located inside said wheel.
    Thus, the control device forms a consolidated module capable of being fixed on different types of mobile elements such as seeding units of the drill.
    The motor is preferably electric, and the motor speed is slaved to the dose that comes from the dispensing and dosing means, in order to have a complete filling of the buckets. This speed is preferably proportional to the forward speed of the drill.
    In another particular aspect, said feed inlet has a grid allowing air to escape. This makes it possible to evacuate the air under pressure, in particular in the case of pneumatic distribution of the seeds.
    According to a particular embodiment, said feed inlet comprises an inclined plane, directing the seeds to a step formed substantially at half height of said regulating device, so as to slow the seeds arriving in said reserve zone.
    This prevents the seeds arrive suddenly in the reserve area, and are for example projected to the bucket wheel. In other words, a damping effect is introduced.
    According to another particular aspect, the regulating device comprises a drain hatch.
    According to a particular embodiment, said wheel is selected from a plurality of wheels each adapted to a size and a dose of seeds to be transported.
    Thus, the wheels used can be changed, for example when the variety or the dose of seeds to be sown varies. For example, maize-adapted wheels may comprise two rows of 8 buckets 7 mm wide; wheels adapted to wheat, three rows of 16 buckets 5 mm wide; and the wheels adapted to rapeseed, three rows of 16 buckets 3 mm wide. The invention also relates to a regulating device for a drill as described above, comprising in particular mobile retaining means delaying said release of each seed. 4. List of Figures Other objects, features and advantages of the invention will appear more clearly on reading the following description, given as a simple illustrative and non-limiting example, in relation to the figures, among which: FIGS. FIGS. 1A and 1B illustrate two examples of application of a regulating device according to the invention: FIG. 1A: general view of a disc sowing unit of an on-line seed drill, implementing a regulating device according to FIG. invention; FIG. 1B: example of implementation on a coulter unit; Figure 2 is a schematic view of a first embodiment of a device for regulating the seed distribution according to the invention, during operation; FIGS. 3A to 3C are views of the wheel according to a first embodiment, having teeth suitable for sowing maize seeds: FIG. 3A: three-dimensional view of the wheel; FIG. 3B: three-dimensional view of the wheel of FIG. 3A placed in the regulating device; Figure 3C: enlarged view of a bucket tooth; figure 3D: sectional view of a tooth; FIGS. 4A and 4B show two alternative embodiments of the wheel, with teeth provided for two other types of seeds: FIG. 4A: teeth adapted for sowing wheat seeds; Figure 4B: suitable teeth for sowing rapeseeds; Figure 5 is a view of the device according to a second embodiment further implementing a substantially horizontal brush; FIGS. 6A to 6C illustrate a first path portion of a seed during its transport by the toothed wheel, in simplified sectional views of FIG. 5: FIG. 6A: one of the seeds of the reserve is taken by a tooth; Figure 6B: the seed is held in the tooth and driven upwards; Figure 6C: the seed is held in the tooth, in the upper part, by the horizontal broom; FIGS. 7A to 7D illustrate the second part of the path of a seed, in sectional views showing in particular the role of the vertical brush: FIG. 7A: partial sectional view illustrating the positions of sections A and B; FIGS. 7B and 7C: section A, at two instants t0 (retaining position) and t1 (release position) in succession, respectively illustrating the delay of the release and the release of a seed; - Figure 7D: section B, at the hub of the wheel; Figure 8 illustrates the seed trajectory in the seed transfer path to the soil. 5. Detailed Description of Embodiments of the Invention 5.0 General Principle of a Seeder
    An example of a disk drill implement embodying the invention is illustrated in Figure 1A. A seeder structure of this type is described in particular in patent documents EP1212932 or EP2060163.
    This seed drill is supported on the ground by the sowing elements 12. In the side view of Figure lA, only one sowing element is illustrated. In fact, several similar sowing units are implemented in parallel.
    The drill is equipped with a hopper 13, fixed on a frame 11 and intended to contain the seed seeds. In the illustrated embodiment, the seed distribution is mechanically provided. Dosing devices 17a, 17b take the seeds from the bottom of the hopper 13, for example using a rotary dosing wheel.
    The distribution can also be pneumatic. In this case, a compressed air generator supplies a stream of compressed air to a distribution and dispensing head, and seeds picked up by the metering device are inserted into the air stream.
    Below the level of the frame 11, and secured thereto, is thus installed a series of sowing elements 12, only one of which is illustrated in FIG.
    In this embodiment, this sowing element comprises a carrying arm 121, connected to the frame 11 and carrying: a ground support wheel 128; a pair of sowing discs 129a, 129b each provided with a coulter, or skimmer 1210a, 1210b, capable of being fed with seeds via a flexible and flexible duct 151a, 151b and a control device 18a, 18b according to the invention described in more detail later; a pair of follower rollers 1211, adapted to roll on the ground and compact it. The invention can also be implemented on a coulter seed drill, as described for example in the patent document FR2658380. FIG. 1B illustrates a coulter of such a drill, which is conventional in itself, comprising a body 2 at the base of which is mounted a profiled and arcuate wear part 3. The front part of the share is directed to the left in this figure.
    According to the invention, the share is equipped with a regulating device 4 (described in more detail later), receiving seeds from the hopper, in the same way as previously explained, via the duct 5. The device of regulation 4 delivers the seeds regularly in the body of the share 2, which directs them to the wear part 3 which forms a groove. 5.1 General Principle of the Invention The invention proposes an effective and simple solution to implement to allow a more homogeneous distribution of the seeds, in particular for the seeds which need to be deposited one by one in a groove on the ground, so as to aligned and at regular intervals, such as wheat, rapeseed, maize, beet, pea, etc.
    The general principle of the invention is thus based on the implementation of a mechanical drive control device (without pneumatic means, at the level of this control device, as opposed to the precision planters), in addition to a control device. dosing and transport (hereinafter referred to as a dosing device) conventionally used in a seeder. Such a control device is placed on the path of the seeds between the metering device and the means for planting seeds, or sowing means.
    Thus, the control device is placed "cut" or "in series", by analogy with the vocabulary of electricity, on the transfer conduit (151a, 151b or 5) which usually directly connects the dosing device to the means planting.
    This transfer duct is therefore decomposed into two parts, an upstream part, connecting the output of the metering device to the input of the regulating device, and a downstream part connecting the output of the regulating device to the earthing means.
    It should be noted that this "cut" of the transfer duct can be performed not only on a new seeding unit, but also on an existing seeding unit, to improve the accuracy thereof. It suffices to mount a regulating device according to the invention on the existing transfer conduit.
    The regulating device therefore receives the seeds delivered by the metering device. Despite the efforts made for the effectiveness of such devices, it happens that the seeds are delivered "in packets", and that there are moments without seeds delivered. The regulating device receives these seeds, keeps a "buffer" reserve, and delivers them to the planting means as regularly as possible, one by one and at regular intervals, as far as possible.
    The control device is close to the ground, relative to the position of the metering device which is at the base of the hopper (and preferably placed as close to the ground as possible). It can in particular be fixed on the sowing element, at the entrance of the cannula or the coulter which directs the seeds towards the ground: the gain of regularity offered by the system is thus preserved when the seeds are deposited on the ground. The seeds are sown following each other, regularly and unitarily or practically unitary.
    The treatment of the seeds is gravitational, for the catch and for the release of the seeds. It is purely mechanical, and does not require the presence of pneumatic means.
    The control device should not be confused with a dosing device, which it supplements, but does not replace. Both devices do not have the same functions. The metering device is placed directly under the hopper, and thus receives the seeds directly from it, which assumes a strong pressure, due to the mass of seeds present in the hopper. The regulating device, on the other hand, is a small-sized element, having, for example, a side face of the order of 10 cm × 10 cm and a width of 3 to 5 cm. It has a reserve of seed seeds, which contains only a few tens or hundreds of seeds (depending on the size of the seeds), which are therefore not subjected to high pressure.
    Thus, while the output accuracy (ie the respect of a seed distribution one by one with a time interval, or space, desired at ground level) of the dosing device is generally of the order of 40%, that of a regulating device according to the invention can reach of the order of 75% to 80% or more under certain conditions. In other words, the device of the invention makes it possible to obtain a precision close to that of a precision planter, without the complexity of the latter, and while offering a versatility on different types of seeds.
    Such a control device therefore comprises a wheel provided with at least one row of teeth forming buckets (each capable of carrying a seed), driven in rotation. This wheel, housed in a housing, draws the seeds from a supply of seeds supplied by the metering device, via an upstream part of a transfer duct, and transports them, in its buckets, to a downstream part of a transfer duct (for example the aforementioned cannula).
    The device also includes at least one brush in contact with the wheel, the role of which is to keep the seed in the bucket until it is released under the effect of gravity in the transfer channel, rather than being ejected under the effect of centrifugal force. Thus, the broom retains the seed, in an intermediate space forming a "decompression zone" (which allows for example the jamming of a seed in the hollow of a too closed tooth), and delays its release, so that it is released (at the earliest) only after it has passed a horizontal line passing through the axis of the wheel. In this way the seed is only subject to the effect of gravity, and falls vertically as far as possible. It is not subject to deviations or centrifugal force, leaving the tooth early, which could cause rebounds on the edges of the cannula, and therefore positional offsets and / or delays.
    A suitable mechanism can ensure the temporary removal of the blade (or at least some of the bristles thereof), so that it deviates enough from the wheel to release the seed at the desired release time, to synchronize in an optimized manner the release of seeds. According to an effective approach, this temporary removal is ensured by a tooth (the one that contained the seed, in the illustrated embodiment, or a subsequent tooth according to the direction of rotation, in a possible variant), whose upper part (part la farther from the axis of rotation of the wheel) pushes and moves the bristles of the broom. It is the teeth that control the movement of the bristles. 5.2 Elements constituting the regulating device
    The various elements of the regulating device 1 according to a first embodiment are illustrated in FIG. 2, which represents the system being dispensed with seeds. This control device, compact in size, can easily equip a conventional sower unit equipped with a conventional metering device, so as to improve the accuracy and efficiency of the sowing operation.
    The regulating device is formed of a housing 22 comprising two communicating compartments 22a, 22b. The first compartment 22a forms a reserve of seeds, called "buffer reserve", where seeds are accumulating 100 from the metering device (not shown), while the second compartment 22b houses a wheel 23 with buckets, coming from the seeds 100 one by one in the buffer pool.
    The seeds 100 arrive, in this first embodiment, from the dispenser to the first compartment 22a of the housing 22 via a downstream portion of the transfer conduit 24a, secured to the top of the housing 22, and connected to an upstream portion of the conduit transfer 24b (or directly to the upper part of the cannula or the share).
    The downstream portion 24a is here oriented (in the vicinity of the housing) in a direction opposite to the direction of rotation of the wheel 3, for example at an angle α between 15 ° and 35 ° relative to the vertical. This allows to slow down and guide the seeds, in cooperation with a wall 25, extending the downstream portion first with the angle, then vertically. This wall 25 isolates the arrival zone of the seeds of the wheel 23, the compartment 22a thus comprising a seed arrival zone and a seed gripping zone.
    The seeds are thus directed towards the gripping zone without interfering with the filling of the buckets of the wheel 23. It is in fact desirable to avoid, or at least to limit, the bouncing of seeds arriving in the buffer reserve, and in particular that seeds come to be doubled up in a tooth, or come to strike and eject a seed present in a tooth.
    An opening 29 may be provided, in the upper part of the housing, to allow the evacuation of air, especially in case of pneumatic supply. Additional means (not shown) forming "sock" can direct the air, possibly dust-laden, to the ground.
    According to another embodiment, illustrated in FIG. 5, the upstream portion 51 of the conduit bringing the seeds delivered by the metering device is substantially vertical. The seeds arrive on an inclined plane 52, forming for example an angle of the order of 35 to 50 ° with the vertical axis defined by the upstream portion 51 of the conduit. This inclined plane 52 directs the seeds towards a step 53, substantially horizontal, which extends downwards by a second inclined plane 54, also forming an angle β of the order of 35 ° to 50 ° with the vertical (the two planes inclined 52 and 54 forming between them an angle of between 80 and 100 °).
    The step 53 and the second inclined plane 54 may be formed in one and the same piece, and extend through a bottom portion 55, extending optionally under the wheel 23, and substantially defining the buffer reserve, the filling level of which optimum corresponds substantially to the position of the walk 53.
    The inclined plane 52, then the step 53, absorb a significant portion of the energy accumulated by the seed during its fall. There is thus little bouncing effect, and the seizure of the seeds by the wheel 3 is not, or little, disturbed.
    This step (and possibly other elements) can be made of, or can carry, a damping material.
    It may be noted that an end portion 56 of the upstream portion 51 of the duct has a grid provided with openings for expelling the air, especially if the transfer of seeds is ensured pneumatically. Thus, the air under pressure is ejected before the regulating device, and does not disturb the operation of the latter, nor the flow of seeds in the downstream part of the conduit. This is particularly important for small seeds, especially for rapeseeds.
    The inclined plane 52 may extend in the extension of this portion 56.
    An arrival 58 of a complementary product, not requiring precise regulation, for example for an anti-slug product, can be provided (in the various embodiments). It is for example mounted on the housing so that this product is delivered above the upstream portion of the transfer conduit 24b. To prevent this complementary product from interfering with the seeds released, the inlet 58 may be mounted facing the hub of the wheel 23, in the case where it carries two rows of teeth.
    A drain hatch 40 (FIG. 3B) may also be provided for emptying the device, and for example for ridding the housing 22 of seeds that have been damaged, or have not been collected by the wheel 23.
    According to an alternative embodiment, this hatch 40 (or possibly another hatch) can lead directly or indirectly into the cannula. This makes it possible to short-circuit the regulating device, the seeds passing through the reserve zone and opening directly into the cannula (whose upper part is adapted to extend under the hatch), without passing through the wheel, without it is necessary to disassemble this regulating device. This can in particular be adapted to certain types of seeds that do not require, or are not adapted to, distribution via the wheel of the regulating device (for example, rye grass) and / or for high flow rates that do not require regulation.
    For example, the hatch can cooperate with a movable valve, extending substantially vertically when the hatch is closed, to form an upper portion of the conventional wall of the cannula, and moving and bowing when the hatch is open, for form, with the prolonged cheeks of the cannula, a funnel receiving the seeds directly from the reserve area.
    Thus, according to this approach, it is possible to regulate only when needed.
    An example of a wheel 23, particularly adapted to corn seeds, is shown, alone, in three dimensions in FIG. 3A. It is also shown placed in the second compartment 22b of the housing 22 in Figure 3B.
    This wheel 23 comprises at least one row of teeth forming buckets. According to a particular embodiment of the invention, the wheel 23 comprises two rows of teeth 31, 32 forming buckets positioned on either side of a central portion, or hub, 33. This hub 33 has a width for example greater than or equal to 1.5 times the size of a seed, so that such a seed penetrating the space defined by this hub can not get stuck there, and be trained and distributed supernumerary way. This large width allows the seed is redirected to the reserve, and not trained.
    The presence of two rows 31, 32 of teeth makes it possible to achieve a compact control device, without the speed of rotation being too high, because it can thus carry twice as many seeds as a device comprising a single row. In addition, the presence of two rows of bucket teeth acts as a seed stirrer in the reserve zone: when a row of buckets takes a seed from the reserve zone, the other seeds of the zone are naturally pushed to the other row of buckets.
    Each row of buckets 31, 32 is angularly offset, in other words staggered, so as not to affect the regularity of seed distribution. For example, the angular offset may be 360 / total number of buckets.
    The teeth of the wheel 23 each have a cavity, or housing, 35 forming bucket, or receptacle. That is, they preferably have a specific form, an example of which for maize is illustrated in FIG. 3C, thus enabling them to collect a seed in the seed bank, for example in the manner of spoon.
    The teeth may in particular have a curved shape, for example substantially spherical (or bowl), ensuring that the seed remains "trapped" in the bucket even in case of shaking or vibration (unlike existing diabolo or centrifugal type systems, which the seeds can be ejected in the presence of shaking and / or vibrations).
    The back 36 of the tooth may be substantially flat, forming a slide, for example 15 to 25 mm long, on which the seed will move progressively when it leaves the receptacle 35, while retaining and delaying the fall of the seed, in cooperation with the broom, 27, as described later. Thus, before the fall of the seed, it gradually leaves the hollow of the tooth, but remains on the back of the previous tooth until the desired moment for release, and therefore the gravity drop. The seeds are also held laterally by the side bristles of the broom.
    As seen in width (as illustrated in the section of FIG. 3D), each tooth may present, over all or part of its length, at least one side wall 37, 38, having for example a height of between 1 and 3 mm, participating in maintaining the seed. In the case of a large seed, for example maize, only one side wall can be provided, on the side of the hub of the wheel. For smaller seeds, one wall on each side can be used. The dimensions, height and thickness of the walls, can be adapted to different types of seeds.
    Moreover, the wheel 23 is preferably made of a soft material that is not very aggressive for fragile seeds (for example rapeseeds), for example polyurethane.
    Wheels of different shapes and / or sizes, with variable number of buckets, or made of other materials, may be used depending on the type and size of seeds to be dispensed. The housing 22 may for this purpose include a flange able to open without tools so as to easily replace the wheels.
    Thus, FIGS. 3A to 3C illustrate a first embodiment of the wheel 23 suitable for sowing maize seeds, according to which the wheel comprises 2 rows of 8 buckets each, the buckets having a thickness of 6 to 7 mm.
    FIGS. 4A and 4B illustrate two other embodiments of the wheel 23, in which the wheels are respectively adapted to sowing wheat and rapeseed. As illustrated in Figure 4A, a three-row wheel of sixteen buckets each, each having a thickness of about 5 mm, is particularly suitable for sowing wheat. A three-row wheel of sixteen buckets, each having a thickness of 3 mm, is rather intended for sowing rapeseed (Figure 4B).
    As shown in FIG. 3B, the wheel is positioned in the second compartment 22b of the housing 22 so that each row of buckets 31, 32 is placed as close as possible to the walls 221 of the housing (for example with a space of the order of 1 mm), to prevent seeds from passing and / or getting stuck along these walls. In the same way, the space under the wheel is reduced (for example, not more than 2 mm) so as to prevent the passage of seeds to the transfer conduit 24b, as well as jams of debris, straw ends, etc. . To further reduce the risks, a broom (not visible in the figures) can also be provided at the bottom of the housing.
    A motor 39, for example of the electric type, drives the wheel 23 in rotation. It can be housed wholly or partially inside the wheel 3 forming with the housing 22 a compact module that can be easily mounted on sowing elements.
    According to a particular embodiment of the invention, it rotates at relatively low speeds, for example between 10 and 100 revolutions per minute. This speed can be controlled by the dose of seeds distributed by the dispenser so that the cups are always filled. For example, the seed level in the buffer pool may be about 4 to 8 times the number of buckets.
    In another embodiment, several (or all) regulating devices may be driven by a single motor. In this case, the wheel axes of the various devices are advantageously aligned.
    For corn, the reserve contains, for example, an average of one hundred seeds. However, the control device, even if it is designed to distribute the seeds one by one regularly, can accept situations of duplicate (seeds grouped by two or more) or lacks (seed absent) if necessary. It is thus very tolerant to load variations, and does not lock up in the event of overloading or underloading of the reserve. Tests show that such a regulating device can accept strong overdoses of 1.5 or 2 times the expected dose. In such a situation, a large number of duplicates will be issued, but the device will not lock.
    Furthermore, the drive of the wheel 23 can be linked to the progress of the drill, proportionally. This gives the farmer the possibility to modulate or cut the distribution automatically and instantly if necessary (this can be the case in the ends of parcels, or in bends, etc.). The residual seeds transported in the transfer channel are then locked in the buffer pool and are selected only when the seeder (and thus the wheel) starts up again.
    This is an advantage compared to current systems, especially pneumatic seed drills, which always have a quantity of seeds in transit in the ducts, continuing to flow until complete emptying, and despite stopping the seeder. In this case, the seeds fall to the ground where they gather.
    It may happen that seeds 100 are driven by the wheel 23 without being placed in one of the bucket teeth. For example, in the embodiment of Figure 2, a seed can be housed and driven between the two rows of teeth 31, 32 at the hub 33). In order to remedy this eventuality, it is possible to provide a central ejector 26, called a "scraper", taking for example the shape of a plane blade, extending above the hub 33. In contact with or near this hub, between the two rows of teeth 31, 32, it allows to return to the buffer pool the seeds not to be distributed.
    In a second embodiment, shown in Figure 5, a second brush 57 substantially horizontal, flexible, and in contact with the hub 33 and the series of teeth 31, 32 of the wheel. This broom 57 has the advantage of limiting the risk of blockage of the system, due to potential seed debris jamming under a more rigid element, as is the case of the scraper. At the passage of the wheel 3, the long bristles of the broom 57 oscillate without lifting, and maintain the seeds upstream of the latter. In this embodiment, the scraper of the first embodiment may be deleted.
    The blade 27 (as well as the blade 57 in the second embodiment) is relatively flexible, but has a sufficient stiffness allowing it to keep the portion of its bristles in contact with the wheel substantially vertically, or more precisely substantially radial to the wheel, for example by a pre-stress applied at the attachment of the brush to the housing of the device. Thus, the seed 100 is held in place on the toboggan portion of the tooth despite the rotation of the wheel 23, at least until this seed exceeds a horizontal axis AH passing through the axis of rotation of the wheel. Thus, the seed is released only after having exceeded this horizontal axis AH, and falls vertically, being subjected to the effect of the gravity.
    The flexibility of the brushes 27, 57 can be adapted to all types of wheels and / or seeds.
    These brushes 27, 57 could possibly be replaced by one or more flexible blades, for example plastic or rubber.
    This regulating device can be arranged close to the ground, for example on the seed element itself. Thus, the transfer conduit 24b of the seeds to the ground, illustrated in Figure 8, has a moderate length (for example 30 to 40 cm) to accompany the seeds without disturbing the regular spacing between them. It can have a smooth surface without asperity not disturbing the gravitational descent of the seeds.
    A regulating device according to the invention makes it possible to control the dose of seeds sown for each row. In some cases, control devices may be present only in certain rows (eg 1 in 5), the other rows being closed (without seed). This can in particular make it possible to adopt a spacing between rank identical to that of a precision seeder. Classically, conventional seed drills deliver a seed every 12.5 cm, while a precision seeder deliver one seed every 75 cm. The invention makes it possible to approach the precision of a precision seed drill effectively, it may be desirable to use the same spacing between the seeds.
    As illustrated in Figure 8, the seeds 100 are finally deposited at regular intervals on the ground, the moderate length (of the order of 30 cm for example) of the transfer channel 24b does not disrupt their transport.
    Of course, the specific features or variants described in correspondence with one of the embodiments may be adapted and / or implemented in another embodiment. 5.3 operation
    The operation of the regulating device according to the invention is described below with reference to FIGS. 6A to 7D.
    Figures 6A to 6C illustrate a first portion of the path of a seed 6, gripping in a set of 66 seed present in the buffer zone to the top of the housing. Figs. 7B-7D are sectional views, as defined in Fig. 7A, illustrating a second portion of the path of seed 6 until it is released. In these figures, for the purposes of the explanation, a single seed 6 is presented, in different successive positions. Of course, in practice, each tooth carries a seed.
    The seeds 100 present in the hopper are thus dosed and distributed by a metering device (not shown). They arrive more or less irregularly at the zone 22a of the housing 22 of the regulating device by the upstream portion of the conduit 24a (Figure 2). Seeds 100 are continuously collected at the buffer pool where they accumulate (66).
    The teeth 31, 32 forming buckets of the wheel 23 (in rotation) come in turn to draw a seed in the buffer pool).
    The tooth 61, when in the lower part of the housing 22, passes through the seed set 66 and selects (or catches) a seed 6, as shown in FIG. 6A.
    In this embodiment, a first brush, called a "horizontal" brush 57, which is flexible, positioned in the upper part of the housing 22, is thus used. Its base is directed towards the wheel (for example substantially radially) while the bristles are directed towards the wheel, and are placed substantially horizontally against the wheel 23 (as shown in Figure 5).
    After about 1/4 to 2/3 of rotation of the wheel 23, the seed 6, taken from the reserve, thus comes into contact with the bristles of the "horizontal" brush 57, as can be seen in FIG. 6B. For another 1/6 to 1/4 turn, it is held in a "tunnel" (or cavity) formed by the inner radius of the tooth 61 in which it is placed, the back of the tooth 64 preceding the tooth 61 , and the bristles of the broom 57.
    Then, still held from above and to the sides by bristles 57, the seed 6 slides on the toboggan surface of the foregoing tooth 64 as shown in FIG. This slide thus forms a "relaxation zone", which allows an exit as soon as possible of the housing of the tooth, whose shape is adapted accordingly. This prevents seed blockages in this housing, especially when several seeds have been seized at the same time.
    The seed 6 continues to slide on the toboggan, until it comes into contact with the second broom, called "vertical" broom 27, which may be identical or similar to the first broom 57. It will be recalled that this second broom (more generally mobile restraint) is an essential element of the invention, while in some embodiments it is possible to dispense with the first brush. The essential aspect of the invention is indeed the retardation of the drop of the seeds, so as to improve the regularity and timing of the distribution, and the accuracy thereof, ensuring a fall under the sole effect of the gravity.
    The broom 27 is arranged and constrained so that its long hairs exert a force against the wheel to maintain a seed 6 against the surface of a tooth. Thus, the blade 27 makes it possible to maintain the seed 6 at least up to a point of rotation of the wheel where the force of gravity allows the seed to escape vertically into the downstream transfer line 24b (the seed having thus crossed the horizontal axis AH passing through the axis of rotation of the wheel).
    For this, the bristles 27 of the bristles may cover at least the total width of the wheel 23, including the two rows of teeth 31, 32 forming buckets, and the hub 33. The bristles of the brush 27 can also extend over the sides of the wheel and in the central part defined by the hub, to prevent the seed 6 from escaping or moving laterally, forming a kind of flexible tunnel for the seed, defined by the hollow and the back of the tooth, and broom bristles, above and to the sides of the tooth.
    Thus, some bristle bristles 27 (located on either side of the rows of teeth 31, 32) can form substantially two lateral guiding walls of the seed 100, while other bristles (located at the height of the rows of teeth 31, 32) form a third wall to be repelled by the passage of the tooth and the seed.
    Unlike a "solid" tunnel (for example formed by a rigid wall), this "flexible" tunnel (or evolutionary, or mobile) does not pose the risk, for example, that a peel of seed is detached and gets stuck in the tunnel, blocking the mechanism.
    This operation is more specifically illustrated in FIGS. 7A to 7D. Figure 7A shows a sectional view of a wheel, showing the sections discussed below: section A: at a row of teeth 31; section B: at the hub 33.
    FIGS. 7B and 7C illustrate section A at two successive instants t0 and t1, respectively corresponding to the retaining position and the release position.
    The seed 6, which, in the position of Figure 6C, has slid on the flat portion 36 of the back of the previous tooth 64. In the absence of the blade 27, or a functionally similar retaining means, it is understood that at time t0 (FIG. 7B), the seed 6 would have already left the tooth, and would fall in a poorly controlled manner, under the effect of the gravity on the one hand and the centrifugal force due to the rotation of the wheel and to the direction of the back of the tooth. The fall would not be purely vertical, and the time of fall and the final position would not be precisely controlled.
    The brush 27, which is subjected to a prestressing F tending to press the bristles against the wheel, keeps the seed 6 on the back 36 of the tooth, delaying its fall. This corresponds to the holding position. On the illustrations, for reasons of readability, only a few hairs are illustrated. In practice, the number of hairs is higher.
    The release of the seed is therefore delayed, or delayed, at time t1, in the release position (FIG. 7C). In this position, the blade 27, and in particular its free portion, has shifted slightly to the right (deflection Δ1), while the tooth has gradually shifted to the left. Then, the seed 6 is subject only to its own weight and to the effect of the force of gravity: it continues its course vertically in the transfer conduit 24b.
    The offset of the bristles can be ensured, at least in part, by the action of the next tooth 61, whose tip bears on the bristles, and pushes them (to the right in FIG. 7C), facilitating the fall of the seed 6. This mechanism controls the timing of seed release, each release being actuated by a tooth (by the next tooth, and more precisely by the tip forming the upper part of the housing of the seed considered, in the embodiment illustrated). In the case where several rows of teeth are provided, the bristles are sufficiently flexible and independent to ensure a differentiated treatment of each row (a part of the bristles being associated with a given row).
    In this embodiment, it is therefore the teeth that control the gradual transition from the retaining position to the release position, and the return to the retaining position. In variants, other displacement actuation means are possible, preferably controlled by the rotation of the wheel, to ensure synchronization.
    Figure 7D further illustrates the situation at the hub 33 (section B). Here, some bristles 72 come into permanent contact with the hub. Referring to the section of Figure 7A, it is understood that these bristles 72 therefore extend on the side of the teeth, forming a side wall, maintaining the seeds laterally in the tooth. Some bristles may provide lateral support on the other side of the tooth, thereby forming the aforementioned "soft" tunnel.
    This broom 27 thus makes it possible to delay the release of each seed and thus to control the regularity of depositing seeds 6 on the ground. Indeed, the seed, thus accompanied in its movement, is not released before reaching the entrance of the transfer conduit 24b, in which it can be released vertically, only subject to its own weight. Unlike existing solutions in which the seeds are often ejected from the wheel in the conduit, subjected to centrifugal force, the solution proposed by the invention allows a synchronized release of seeds and a regular distribution, the deposition of seeds on the ground. 'being more influenced by the speed of the wheel.
    权利要求:
    Claims (13)
    [1" id="c-fr-0001]
    1. Seed drill comprising a plurality of sowing elements (12), each sowing element (12) comprising dosing and transport means, controlling the flow of seeds at the outlet of a hopper (13) and delivering said seeds in a transfer duct (151a, 151b, 5) for feeding means for planting said seeds, each sowing element (12) also comprising a regulating device (18a, 18b, 22) mounted between said dosing and transport means and said earthing means, close to the latter, said regulating device (18a, 18b, 22) comprising a seed-fed reserve area (22a) (100) via a supply inlet connected to said dosing means and transporting by an upstream portion (24a) of said transfer conduit, characterized in that said regulating device (18a, 18b, 22) comprises a wheel (23) adapted to take seeds (100) into said reserve space ( 22a), by means of at least one a row of teeth forming buckets, each ensuring the removal of a seed in said reserve zone (22a) and the release of said seed in a downstream portion (24b) of said transfer conduit, and in that it comprises means retainer delaying said release of each seed, movable between two positions: a holding position of a seed; and a seed release position, said holding means being temporarily moved away from said wheel (23).
    [2" id="c-fr-0002]
    2. Seeder according to claim 1, characterized in that said retaining means provide said release of a seed that after said seed has passed under a horizontal axis (AH) passing through axis of rotation of said wheel (23).
    [3" id="c-fr-0003]
    3. Seeder according to claim 1, characterized in that said retaining means comprise at least one movable element and prestressed towards the wheel (23) so that a portion of said movable element extends along a portion of the periphery of said wheel (23), according to the direction of rotation of said wheel (23).
    [4" id="c-fr-0004]
    4. Seeder according to claim 3, characterized in that, at a time and / or a location before that where said seeds are only subjected to the force of gravity, said movable element forms with at least one of said teeth forming buckets said wheel, a corridor for maintaining said seeds.
    [5" id="c-fr-0005]
    5. Seeder according to claim 3, characterized in that a displacement of said movable member from said retaining position to said release position, is controlled and / or provided by said teeth (31, 32).
    [6" id="c-fr-0006]
    6. Seeder according to claims 3 to 5, characterized in that said movable member comprises at least one blade (27) comprising a pile assembly of which at least the free portion extends substantially tangentially to the wheel (23) and substantially vertically .
    [7" id="c-fr-0007]
    7. Seeder according to claim 1, characterized in that said wheel (23) comprises at least two rows of teeth (31,32) forming buckets.
    [8" id="c-fr-0008]
    8. Seeder according to claim 1, characterized in that said regulating device (18a, 18b, 22) comprises at least one blade (57) comprising a pile assembly of which at least the free portion extends substantially tangentially to the wheel and substantially horizontally above said wheel.
    [9" id="c-fr-0009]
    9. Seeder according to claim 1, characterized in that said teeth have a housing (35) adapted to maintain a seed, during the rise thereof, and a flat portion (36) on which said seed moves gradually during of the descent.
    [10" id="c-fr-0010]
    10. Seeder according to claim 1, characterized in that said teeth have at least one side wall (37, 38).
    [11" id="c-fr-0011]
    Seed drill according to claim 1, characterized in that said feed inlet has a grid (56) allowing the air to escape.
    [12" id="c-fr-0012]
    Seed drill according to claim 1, characterized in that said feed inlet comprises an inclined plane (52), directing the seeds to a step (53) formed substantially at mid-height of said regulating device (18a, 18b, 22). ), so as to slow the seeds arriving in said reserve zone (22a).
    [13" id="c-fr-0013]
    13. Control device (18a, 18b, 22) for a drill according to any one of claims 1 to 12, intended to be mounted between the dosing and transport means and the means for grounding said seed drill, close to said grounding means, said regulating device (18a, 18b, 22) comprising a seed-fed reserve area (22a) (100) via a feed inlet connected to said dosing and transport means by a part upstream (24a) of said transfer duct (151a, 151b, 5), characterized in that it comprises a wheel (23) adapted to collect seeds in said reserve space (22a), by means of at least one row teeth forming buckets, each ensuring the removal of a seed in said reserve zone (22a) and the release of said seed in a downstream portion (24b) of said transfer conduit (151a, 151b, 5), and in that 'it comprises retaining means delaying said release of each seed, mobile two positions: a holding position of a seed; and a seed release position, said holding means being temporarily moved away from said wheel (23).
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    同族专利:
    公开号 | 公开日
    FR3050607B1|2018-11-30|
    EP3238518A1|2017-11-01|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    DE254520C|1911-10-03|1912-12-09|Erhardt Ludwig|ADJUSTABLE SIZE CELLS FOR SOWING MACHINES|
    DE1051047B|1956-08-10|1959-02-19|Martin Schmidt|Precision seeder with a seed wheel arranged on the bottom outlet of the seed box|
    DE1064276B|1957-06-29|1959-08-27|Saat & Erntetechnik Gmbh|Separation device, especially for a precision seed drill|
    CA2814221A1|2013-04-26|2014-10-26|Straw Track Manufacturing Inc.|Apparatus for metering seeds|
    FR2658380B1|1990-02-20|1992-06-19|Sulky Burel Sa|SEED GUIDING SHOE, ADAPTABLE ON A SEEDER SHOE.|
    FR2691040B1|1992-05-12|1999-03-05|Sulky Burel|SEED DISPENSING DEVICE FOR SEEDER.|
    US5549060A|1995-08-02|1996-08-27|Deere & Company|Mechanical seed meter|
    FR2817447B1|2000-12-05|2003-08-29|Sulky Burel Sa|DRILL|
    FR2923675B1|2007-11-16|2012-10-26|Sulky Burel|SEMOLINATING THE SIMULTANEOUS DISTRIBUTION OF GRANULAR SEEDS AND ELEMENTS, IN PARTICULAR FERTILIZERS|FR3072855B1|2017-10-27|2019-12-20|Sulky Burel|DEVICE FOR REGULATING THE SEED DISTRIBUTION FOR A SEEDER, AND CORRESPONDING SEEDER.|
    US10736264B1|2019-02-01|2020-08-11|Cnh Industrial Canada, Ltd.|Modular meter roller shaft system|
    US10750665B1|2019-02-01|2020-08-25|Cnh Industrial Canada, Ltd.|Meter roller system|
    US10757857B2|2019-02-01|2020-09-01|Cnh Industrial Canada, Ltd.|Meter roller insert system|
    法律状态:
    2017-04-27| PLFP| Fee payment|Year of fee payment: 2 |
    2017-11-03| PLSC| Search report ready|Effective date: 20171103 |
    2018-04-25| PLFP| Fee payment|Year of fee payment: 3 |
    2019-04-25| PLFP| Fee payment|Year of fee payment: 4 |
    2020-04-21| PLFP| Fee payment|Year of fee payment: 5 |
    2021-04-27| PLFP| Fee payment|Year of fee payment: 6 |
    2021-06-18| CD| Change of name or company name|Owner name: BUREL PRODUCTION, FR Effective date: 20210510 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1653845A|FR3050607B1|2016-04-28|2016-04-28|SEEDER EQUIPPED WITH A DEVICE FOR REGULATING THE DISTRIBUTION OF SEEDS, AND CORRESPONDING REGULATION DEVICE|
    FR1653845|2016-04-28|FR1653845A| FR3050607B1|2016-04-28|2016-04-28|SEEDER EQUIPPED WITH A DEVICE FOR REGULATING THE DISTRIBUTION OF SEEDS, AND CORRESPONDING REGULATION DEVICE|
    EP17168786.6A| EP3238518A1|2016-04-28|2017-04-28|Seeder provided with a device for controlling the distribution of seeds, and corresponding control device|
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