BR102015016527B1 - seed distributor for an agricultural machine - Google Patents

Abstract

SEED DISTRIBUTOR FOR AN AGRICULTURAL MACHINE A distributor (100) applicable to an agricultural machine is described, the distributor (100) being associated with a reservoir (300) containing seeds (S) to be distributed in the soil, the distributor (100) comprising a seed inlet (110) connected to the reservoir (300) and also connected to at least one chamber (200), the chamber (200) being provided with an air inlet (210) and an air and seed outlet (220 ), the air inlet (210) being connected to a pneumatic system, the chamber (200) comprising a deflector (230) provided between the seed inlet (110) and the air and seed outlet (220), the deflector ( 230) configuring a free volume (400) between themselves and the air and seed outlet (220) that remains without the presence of seeds (S) prior to the activation of the pneumatic system, the air inlet (210) and the air outlet and seeds (220) being arranged at different elevations inside the chamber (200) and configuring a rising angle (500) of the air flow, the distributor (100) promoting a stable and continuous air and seed flow through a simple and easy to maintain constructive configuration

Description

[001] The present invention relates to a seed distributor applicable to an agricultural machine, having a configuration of internal elements that allows constant flow and ideal air / seed ratio to the distribution process through a simple and easy maintenance configuration, giving more efficiency and reliability to the production process at a lower production cost.

DESCRIPTION OF THE STATE OF THE TECHNIQUE

[002] The growing need to plant crops in larger areas of land has demanded larger implements and greater operational efficiency, especially those dedicated to the deposition of seeds on agricultural fields.

[003] The application of pneumatic systems pressurized by an air pump has been preferred for its flexibility and speed in the conduction of seeds from a central reservoir to the ground, or even the dosing mechanisms, which carry out the selection and individual deposition at intervals regular intervals along the planting furrows.

[004] Numerous prior technology documents report several constructive ways in an attempt to improve the conduction of seeds, among which, initially, the US patent document US 4514114 - SEED AND / OR FERTILIZER DISTRIBUTOR, which describes a distributor of pneumatic seeds / fertilizers equipped with a sealed loading hopper containing the input to be distributed. The input is poured into a pneumatic transmission duct by means of a metering shaft, and the distributor is equipped with a series of chambers that transfer their pressures to the loading hopper, equalizing the pressures of the entire equipment and allowing a better distribution of the equipment. input.

[005] The use of dosing shafts to force the deposition of inputs and equalizing the pressures implies the use of additional elements for the composition of the distributor itself, such as the dosing shaft itself (in this case, more than one) and additional pressure chambers , which represents extra costs to the machine manufacturing process.

[006] A second document that presents a seed distribution system is the US patent US 6267067 - NURSE RECEIVER AND HEADER FOR AIR SEEDERS, which describes a distribution head and an input doser that allows passive control of the feed of the planting units by counting input particles present in the feeder. In this way, the planting flow remains constant and uniform.

[007] It can be seen that this document describes a relatively complex system, which uses a distribution system itself adapted to an individual head and doser to allow a desirable flow. In addition to the large number of components used to assemble the assembly (which requires more assembly time for the process), the geometric complexity of each element inevitably makes its production more expensive.

[008] The document US 8800458 - AIR ENTRAINMENT DEVICE FOR SEED DELIVERY is another that describes a seed distribution device, this one equipped with a series of sections with sub-chambers for receiving air, receiving the seeds, mixing the air with the seeds and air feedback (to allow homogeneous mixing and to prevent clogging).

[009] In short, the device uses a multiplicity of sub-chambers in the same main chamber to separate the stages of seed distribution, thus allowing a superior performance of the distribution process. However, again, the use of a complex construction geometry is noticed, formed by several associable elements that make the distributor's assembly difficult and make the manufacture of agricultural equipment more expensive.

[0010] Finally, the document US 2008/0163807 - VARIABLE DISPLACEMENT METER ROLLER presents a configuration of a distributor in which, once again, it is noted the use of dosing axes to transfer seeds in a homogeneous way. As already mentioned, the dosing axis represents an additional element in the construction set of agricultural equipment. Furthermore, it requires adaptation of a large number of components for its association and makes corrective maintenance difficult due to the fact that it is necessary to dismantle the whole set if the shaft needs to be changed or repaired.

[0011] After analyzing the documents above, which summarize what is understood by the current technique, it is understood that all known solutions are of complex manufacturing, application and maintenance, and / or have additional components of large dimension and / or complexity for the realization of the effective distribution, which is reflected in a distributor machine with high manufacturing cost and difficult maintenance.

OBJECTIVES OF THE INVENTION

[0012] In view of the problems presented by the state of the art in the field of agricultural seed distribution machines, the present invention aims to present a distributor for application in an agricultural machine that allows an efficient distribution process without the use of complex components such as agitators, dosing shafts, multiplicities of sub-chambers in a single chamber, among others, and consequently allowing a low cost in the manufacture of the machine and ease in its maintenance.

[0013] It is also the aim of the invention to present a distributor for an agricultural machine that allows an uninterrupted and fluid flow of air and seed mixture, avoiding clogging and obstruction of seeds both at the time of startup and in operation.

BRIEF DESCRIPTION OF THE INVENTION

[0014] The present invention discloses a distributor applicable to an agricultural machine associated with a reservoir containing seeds to be distributed in the soil. The distributor has a rectangular and hollow profile, and a seed inlet connected to the reservoir and also connected to at least one chamber, the latter being provided with an air inlet and an air and seed outlet.

[0015] The air inlet is connected to a pneumatic system, and the chamber comprises a deflector provided between the inlet of seeds and the outlet of air and seeds. The deflector configures a free volume, between itself and the outlet of air and seeds, which remains without the presence of seeds before the activation of the pneumatic system.

[0016] The air inlet and the air and seed outlet are arranged at different elevations inside the chamber, configuring an angle of ascension of the air flow.

[0017] The seed inlet is arranged on the upper side of the distributor, and the air inlet and the air and seed outlet are arranged on opposite sides of the distributor. In addition, the deflector is angled in relation to the air inlet and the air and seed outlet.

[0018] Additionally, the air inlet is provided with a filtering grid, and is arranged at a lower elevation than the air and seed outlet. The chamber is equipped with at least one plate for eliminating sharp edges.

BRIEF DESCRIPTION OF THE DRAWINGS

[0019] The present invention will be described in more detail below based on an example of execution shown in the drawings. The figures show:

[0020] Figure 1 - a front perspective view of the dispenser of the present invention associated with a reservoir;

[0021] Figure 2 - a rear perspective view of the dispenser of the present invention associated with a reservoir;

[0022] Figure 3 - a rear view of the distributor of the present invention associated with a reservoir;

[0023] Figure 4 - a front perspective view of the dispenser of the present invention;

[0024] Figure 5 - a rear perspective view of the dispenser of the present invention;

[0025] Figure 6 - a side sectional view of the chamber of the distributor of the present invention;

[0026] Figure 7 - a side sectional view of the chamber of the distributor of the present invention detailing the free volume before the beginning of the distribution operations; and

[0027] Figure 8 - a side sectional view of the chamber of the distributor of the present invention detailing the path of the air flow and seeds.

DETAILED DESCRIPTION OF THE FIGURES

[0028] Figures 1, 2 and 3 show different views of the distributor 100 of the present invention associated with a reservoir 300. The reservoir 300 contains the seeds that will be distributed in the planting process, and can have different construction configurations according to the maximum desired capacity. , the available means of association with the distributor 100, the space available for assembly, etc.

[0029] Reservoir 300 transfers the seeds contained within it to the distributor 100 by means of gravity, and then the distributor 100 is fed with compressed air, causing the seeds to mix with this air. Subsequently, the compressed air transports the seeds through a pipe 150 to one or more planting units (not shown), which are in charge of depositing the seeds in the soil.

[0030] Starting now to detail the elements that form the distribution system, the reservoir 300 has geometry such as that illustrated in figures 1, 2 and 3, more specifically equipped with a lower region 310 in a conical shape to allow its association with the preferred configuration of the distributor 100, which will be described in more detail later. The reservoir 300 is also provided with an upper region 320 provided with a lid for opening and closing the reservoir. The reservoir is fed with seeds by this upper region 320, and such seeds are deposited naturally, by gravity, in the lower region 310.

[0031] As previously stated, the lower region 310 is provided with a conical shape for its association with the distributor 100. The seeds that are deposited in the lower region 310 are subsequently deposited, also by gravity, inside the distributor 100.

[0032] The dispenser 100 is illustrated separately in figures 4, 5 and 6, being preferably provided with a substantially rectangular profile, elongated geometry and provided with a hollow interior. The chosen geometry and profile may vary depending on design and usage preferences. One side of the distributor 100 is open for association with the reservoir 300, preferably an upper side 110, for better use of gravity for depositing the seeds in the distributor 100. This upper side 110, hereinafter called the seed inlet 110, is open and equipped of a set of angled flaps 120, configured to receive said reservoir 300. The fixation between the distributor 100 and the reservoir 300 is made through holes 121 present in the flaps 120 of the distributor 100, using fixing elements such as projections of fitting provided in reservoir 300, rivets or sets of screw and nut.

[0033] As can be seen in figures 4 and 5, the hollow interior of the distributor 100 is divided into several chambers 200 by means of partition walls 130. Each partition wall 130 has a lower opening 131 that allows homogeneous pressurization throughout the distributor 100. Each chamber 200 is connected to the seed inlet 110 of the distributor 100, thus providing a connection between said chamber 200 and the reservoir 300. Each chamber 200 is also provided with an air inlet 210 and an air outlet and seeds 220, both more fully illustrated in figure 6. The air inlet 210 is connected to a pneumatic system (not shown) that supplies the chamber 200 with a flow of compressed air when the start of operations and distribution. The air and seed outlet 220 is provided opposite the air inlet 210, and adjacent to the seed inlet 110. The air inlet 210 is provided with a filter grid 211 to prevent impurities that accompany the compressed air from being mixed and transported. together with the seeds. Each outlet of air and seeds 220 is connected by tubes to a planting unit (not shown) that later deposits the seeds received in the soil. The distributor 100 is preferably also provided with a series of fitting projections 140 for associating it with the hydraulic piping 150.

[0034] The dimension of the chambers 200, and consequently the total number of chambers 200 inside the distributor 100, can vary significantly according to the desired capacity for the agricultural machine. Preferably, the number of chambers 200 must accompany the number of planting units to be used.

[0035] From figure 6, it can be seen that each chamber 200 is equipped with a series of elements that allow an efficient mixing of the seeds and the air that transports these seeds, as well as their proper deposition in the distributor 100. First, the The chamber is provided with a deflector 230, of substantially rectangular and elongated geometry, associated adjacent to the seed inlet 110 and provided with an angle in relation to this, partially separating said seed inlet 110 from the air and seed outlet 220. This configuration prevents seeds from being deposited directly in chamber 200 when filling reservoir 300 and before the start of distribution operations, that is, before the activation of the pneumatic system to supply the distributor 100 with compressed air. Thus, the region close to the air and seed outlet 220 is provided with a free volume 400, more fully illustrated in figure 7, without the presence of seeds and prior to the beginning of the air supply, preventing an eventual initial clogging of this outlet. The free volume 400 is bounded by both the baffle 230 and the seeds (represented by the letter S in figure 7) deposited in chamber 200.

[0036] The angle between the baffle 230 and the seed inlet 110, or even the angle between the baffle 230 and the air and seed outlet 220, is defined from the desired free volume 400 inside the chamber 200. Preferably, the The relation between the angles must be such that a sufficient free volume 400 is obtained so that the seeds deposited in the chamber 200 can move freely towards exit 220 without being able to concentrate on a point in the path, and at the same time avoid getting an unnecessarily high free volume 400 so that there is no turbulence near outlet 220 due to a sharp difference between the sections of chamber 200 and said outlet 220. The ideal free volume 400 to be reached varies depending on several factors, including the dimensions of the chamber 200, the area of the air outlet and seeds 220 and the air pressure applied in the process.

[0037] Chamber 200 is also provided with at least one plate 240, of substantially rectangular and elongated geometry, for the elimination of sharp edges, preventing the accumulation of seeds in these regions, and consequently preventing the generation of turbulence by these accumulations. In this preferred configuration, three plates 240 are used, two for the sharp corners of the lower region of the chamber 200 and one for the sharp corner generated by the deflector 230 in relation to the vertical wall of the outlet 220.

[0038] As previously explained, the air inlet 210 is provided as opposed to the air and seed outlet 220. Additionally, both are arranged with a height difference between them, more specifically the air and seed outlet 220 being arranged in a greater height in relation to the air inlet 210. Thus, an air flow rise angle 500 is configured between the air inlet 210 and the air and seed outlet 220.

[0039] This ascension angle 500 causes the air to suspend the seeds before reaching exit 220, eliminating the possibility of a portion of seeds being physically dragged by the others, and consequently stabilizing the transport flow. Additionally, by forcing the seeds to join the air stream, the mixture of air and seeds is homogenized, maintaining an optimum ratio between the two elements. The ideal ascension angle depends on the pressure applied and the type of seed to be distributed, and varies between 5 ° and 45 °.

[0040] To better clarify the beneficial effect resulting from the use of the ascension angle 500 combined with the elimination of the sharp edges by the plates 240, figure 8 illustrates the chamber 200 and represents, by means of an arrow, the T path taken by the mixture of air and seeds between the air inlet 210 and the air and seed outlet 220. It can be clearly seen that the flow of the mixture is forced to rise slightly between the inlet 210 and the outlet 220. Again, this effect prevents the seeds suffer unnecessary friction with each other and are forcibly dragged by their adjacent portions. Under this effect, the seeds are easily joined to the air stream, homogenizing the mixture of air and seeds with minimum effort required.

[0041] From the above, it is noticed that the distributor 100 of the present invention allows a continuous and stable flow in the process, decreases the occurrence of turbulence inside the chambers, decreases the chances of clogging in the sharp corners and at the outlet of air and seeds, and allows a safe and reliable start-up, increasing the efficiency of the entire process.

[0042] As a result of the increase in efficiency, the power required for the pneumatic system to move seeds is reduced, reducing the cost of related components (turbines, pumps, drive motors) and also of the agricultural machine itself. In addition, it promotes all the aforementioned advantages through the efficient arrangement of elements with simple geometry, easily manufactured and assembled, and viable maintenance.

[0043] As an example of simple components used in the construction of the distributor 100, the deflector 230 and the plates 240 are mentioned, which have, as already described, rectangular and elongated geometry, which are known to be easy to manufacture, without the need for machines. or specific processes. One can also mention the geometry of the dispenser 100, which is rectangular, angled and hollow, which is also easily obtainable. And as an example of efficient arrangement, we can mention the arrangement of the air inlet 210 in relation to the air and seed outlet 220, which promotes the ascension angle 500 of the air and seed flow and all its advantages already mentioned.

[0044] Having described a preferred embodiment example, it should be understood that the scope of the present invention covers other possible variations, being limited only by the content of the appended claims, including the possible equivalents therein.

Claims (8)

1. Seed distributor (100) for an agricultural machine, the distributor (100) being associated with a reservoir (300) containing seeds (S) to be distributed in the soil, the distributor (100) comprising an inlet seeds (110) connected to the reservoir (300) and also connected to at least one chamber (200), the chamber (200) being provided with an air inlet (210) and an air outlet and seeds (220), the air inlet (210) being connected to a pneumatic system, the distributor (100) characterized by the fact that the chamber (200) comprises a deflector (230) provided between the seed inlet (110) and the air outlet and seeds (220), the deflector (230) configuring a free volume (400) between themselves and the air and seeds outlet (220), the air inlet (210) and the air and seeds outlet (220) being arranged in different elevations inside the chamber (200) and configuring an airflow rise angle (500), the rise angle (500) being between 5 degrees and 45 degrees. 2. Distributor (100) according to claim 1, characterized by the fact that it has a rectangular and hollow profile. 3. Distributor (100) according to claim 2, characterized by the fact that the seed inlet (110) is arranged on the upper side of the distributor (100). 4. Distributor (100) according to claim 1, characterized by the fact that the air inlet (210) and the air and seed outlet (220) are arranged on opposite sides of the distributor (100). 5. Distributor (100) according to claims 3 and 4, characterized in that the deflector (230) is angled in relation to the air inlet (210) and the air and seed outlet (220). 6. Distributor (100) according to claim 1, characterized by the fact that the air inlet (210) is provided with a filter grid (211). 7. Dispenser (100) according to claim 1, characterized by the fact that the air inlet (210) is arranged at a lower elevation than the air and seed outlet (220). 8. Dispenser (100) according to claim 1, characterized by the fact that the chamber (200) is provided with at least one plate (240) for eliminating sharp edges.

Images