JP3224225U - Vacuum seeder - Google Patents

Abstract

The present invention provides a vacuum sowing machine that allows a plurality of seeds to be concentrated and dropped at one place in a field. A suction plate 120 is configured such that a disc portion 120x and a disc portion 120y are bonded together with an annular metal mesh 123 interposed therebetween. The opening of the wire mesh 123 is smaller than the diameter of the suction hole 121. The suction plate 120 is formed with suction holes 121 having a size through which seeds can pass. The seed supplied from the hopper is adsorbed in the adsorption hole 121 of the adsorption plate 120. A plurality of seeds are adsorbed in one adsorption hole 121. The wire mesh 123 restricts seeds from passing through the adsorption holes 121. When the suction plate 120 rotates with the seeds adsorbed to the suction holes 121, the seed adsorption is released when the suction holes 121 reach a predetermined position. Thereby, a plurality of seeds are separated from the suction hole 121 and fall to the ground below. [Selection] Figure 3

Description

  The present invention relates to a vacuum seeder.

  Conventionally, as in Patent Document 1, after rotating the adsorption member in a state where one seed is adsorbed in one hole formed in the adsorption member, the adsorption of the seed in the hole is released and the seed is dropped. Vacuum seeders are known. In Patent Document 1, in order to drop a plurality of seeds together, the adsorption member is formed so that the same number of holes as the number of seeds to be dropped together are close to each other.

JP 2002-171805 A

  There are cases where it is desirable to drop a plurality of seeds as concentratedly as possible in one place of the field. According to the adsorbing member of Patent Document 1, one seed is adsorbed in one hole. For this reason, in order to concentrate and drop a plurality of seeds, it is necessary to make the formation positions of the suction holes as close as possible on the suction member. However, there is a limit to making the hole formation positions close to each other. Therefore, there is a natural limit in concentrating and dropping a plurality of seeds in one place in the field.

  An object of the present invention is to provide a vacuum sowing machine that allows a plurality of seeds to be concentrated and dropped at one place in a field.

  The vacuum seeder of the present invention comprises a supply means for supplying seeds, an adsorption member formed with a plurality of adsorption holes for adsorbing seeds supplied from the supply means, a rotation drive means for rotating the adsorption member, The adsorbing hole has a size through which the seed can pass, and a regulating member that restricts the seed from passing through the adsorbing hole by being in contact with the seed is provided in the adsorbing hole. And a plurality of the seeds are adsorbed to each of the adsorption holes in the first position with respect to the rotation direction of the adsorption member by the rotation driving means, and at a second position different from the first position. The adsorption is released at the adsorption hole, and the plurality of seeds are dropped from the adsorption hole.

  According to the vacuum seeder of the present invention, an adsorption hole having a size that allows seeds to pass through is formed in the adsorption member, and a regulation member that restricts seeds from passing through the adsorption hole is provided. Thereby, it is comprised so that a several seed may adsorb | suck to each adsorption hole. As the regulating member, for example, a net or a string-like member can be used. Thereby, the passage of seeds is regulated without greatly impairing the function of adsorption by the adsorption holes. Moreover, since a plurality of seeds are adsorbed in one adsorption hole, the seeds can be adsorbed concentrated in a narrow area. By these, compared with the structure which forms a some adsorption | suction hole in the position which adjoined in the adsorption | suction member, the structure which concentrates and drops a several seed to one place of a field is easy to implement | achieve.

  Moreover, in this invention, it is preferable that the said limitation member is a net | network member stretched by the said suction hole which has a mesh opening smaller than the diameter of the said suction hole. According to this, the regulating member can be realized with a simple configuration.

  Moreover, in this invention, the said adsorption member has the 1st and 2nd board component which each formed the partial hole which comprises the said adsorption hole, and pinched | interposed the said regulating member between each other Is preferred. According to this, in each adsorption hole, the structure which a control member controls passage of seed between partial holes is realized.

1 is a side view of a vacuum seeder according to an embodiment of the present invention, partially showing an internal structure. It is a disassembled perspective view of the seeding part provided in the vacuum seeder of FIG. It is a disassembled perspective view of the adsorption | suction board provided in the sowing part of FIG.

  Hereinafter, a vacuum seeder 1 (hereinafter referred to as a seeder 1) according to an embodiment of the present invention will be described with reference to FIGS. The seeder 1 is a device that moves forward by being pulled by a tractor or the like. As shown in FIG. 1, the seeder 1 includes a main body frame 2, a hopper 3 (supplying means in the present invention) supported by the main body frame 2, a main wheel 4, a groove forming gauge 5, a stone removing plate 6, and a soil covering plate 7. And a seeding unit 100. The main body frame 2 is composed of a plurality of metal frame members. The hopper 3 is a resin container and is supported on the upper part of the main body frame 2. Seeds S are accommodated in the hopper 3. A seed S supply port 3a is formed in the lower portion of the hopper 3 so as to face downward. The seed S in the hopper 3 is supplied to the lower sowing unit 100 through the supply port 3a. The sowing unit 100 collects a plurality of seeds S from the hopper 3 and drops them downward. A chute 130 is provided below the seeding unit 100. The seed S that has fallen from the sowing unit 100 falls to the ground while being guided by the chute 130. Details of the sowing unit 100 will be described later.

  The main wheel 4, the groove forming gauge 5, the stone removing plate 6 and the earth covering plate 7 are supported on the lower part of the main body frame 2. The main wheel 4 is a wheel which contacts the ground and supports the entire seeder 1 on the ground. The groove forming gauge 5 is a member that contacts the ground and forms a groove on the ground along the traveling direction at a position where the seed S falls. The seed S guided by the chute 130 falls into the groove. The stone removing plate 6 is disposed in front of the groove forming gauge 5 and has a V shape with the tip facing forward in plan view. The stone removing plate 6 comes into contact with an obstacle such as a stone on the ground as it moves forward, and draws the obstacle to both sides of the aircraft. The earth covering plate 7 is disposed behind the groove forming gauge 5. As the soil covering plate 7 moves forward, the soil covering plate 7 covers the groove after the seed S has fallen.

  Hereinafter, the sowing unit 100 will be described in detail. As shown in FIG. 2, the seeding unit 100 includes a casing 101, a drive plate 104 (rotation drive means in the present invention), a seed selection plate 106, a lid portion 110, and an adsorption plate 120 (an adsorption member in the present invention). ing. The housing 101 is a synthetic resin container having a cylindrical box-like schematic shape. The casing 101 is formed with an internal space 103 that opens toward the side of the machine body. A suction part 102 is formed on the top of the housing 101. A suction channel 102 a is formed in the suction unit 102. The flow path 102 a communicates with the internal space 103 of the housing 101. A pump 9 is connected to the suction unit 102 through the tube 10. The pump 9 sucks air in the internal space 103 through the suction unit 102 and keeps the internal space 103 in a vacuum. A cover plate 105 is fixed to the opening of the housing 101. The covering plate 105 partially covers the opening of the internal space 103.

  The drive plate 104 is a wheel-shaped member disposed near the opening of the internal space 103. The drive plate 104 has a shaft portion 104a, a rim portion 104b, and a plurality of arm portions 104c extending radially from the shaft portion 104a toward the rim portion 104b. A plurality of protrusions 104d are formed on the rim portion 104b at equal intervals in the extending direction of the rim portion 104b. The shaft portion 104a is connected to the axle of the main wheel 4 through a transmission mechanism (not shown). The transmission mechanism transmits the rotational movement of the axle of the main wheel 4 that occurs as the seeding machine 1 moves forward to the shaft portion 104a. Thereby, the drive plate 104 rotates in the direction R of FIG. Regardless of the forward speed of the seeder 1, the transmission mechanism can rotate the axle of the main wheel 4 so that the ratio between the number of rotations of the main wheel 4 and the number of rotations of the drive plate 104 becomes a preset value. Transmitted to the unit 104a. For example, the rotational movement of the axle of the main wheel 4 is transmitted to the shaft portion 104a so that the drive plate 103 rotates twice while the main wheel 4 rotates once.

  The suction plate 120 is fixed to the drive plate 104 and rotates in conjunction with the rotation of the drive plate 104. As shown in FIG. 3, the suction plate 120 has disk portions 120x and 120y (first and second plate parts in the present invention) and a wire mesh 123 (regulation member in the present invention) stretched between them. doing. The disk parts 120x and 120y are both disk-shaped members. In the vicinity of the outer edge of the disc portion 120x, a plurality of circular through holes 121x (partial holes in the present invention) are formed at equal intervals along the circumferential direction of the disc portion 120x. The through hole 121x has a size through which one seed S can pass. A plurality of circular through holes 122x are formed at equal intervals along the circumferential direction at a position slightly closer to the center of the disc portion 120x than the through holes 121x. The through hole 122x is formed at a position corresponding to the protrusion 104a of the drive plate 104. A through hole 124x is formed at the center of the disc portion 120x. The disk part 120y has the same size as the disk part 120x, and is arranged so as to overlap the disk part 120x. In the disk portion 120y, circular through holes 121y (partial holes in the present invention) and 122y having the same size as the through holes 121x and 122x are formed at positions corresponding to the through holes 121x and 122x of the disk portion 120x. ing. A through hole 124y is formed at the center of the disc portion 120y. The disc part 120x and the disc part 120y are bonded together so as to sandwich the wire mesh 123. Thereby, the through-hole 121x and the through-hole 121y are connected via the wire mesh 123, and the adsorption hole 121 for the seed S is formed. Further, the through hole 122x and the through hole 122y are connected to form an insertion hole 122 into which the protrusion 104d of the drive plate 104 is inserted. The shaft portion 104a of the drive plate 104 is inserted into the through holes 124x and 124y.

  The metal mesh 123 is an annular metal member. The wire mesh 123 is disposed at a position indicated by a one-dot chain line A in FIG. Thereby, the wire mesh 123 is located between the through hole 121x and the through hole 121y. The opening of the wire mesh 123 is smaller than the diameter of the adsorption hole 121 and is adjusted to a size that prevents one seed S from passing through the mesh. The wire mesh 123 restricts the seed S from passing through the adsorption hole 121 by contacting the seed S adsorbed in the adsorption hole 121.

  From the suction hole 121, air outside the housing 101 is sucked into the internal space 103 due to a difference in atmospheric pressure between the internal space 103 and the outside of the housing 101. Thereby, the seed S in the seed pool 115 formed in the lid 110 described later is adsorbed in the adsorption hole 121 as shown in FIG. FIG. 1 shows a state where the seed S is adsorbed only for some of the adsorption holes 121. The adsorption hole 121 has a size through which one seed S can pass as described above. For this reason, a relatively large suction force can be applied to the seed S through one suction hole 121. Thus, a plurality of seeds S are adsorbed to the adsorption holes 121 per one adsorption hole 121. On the other hand, the seed S adsorbed in the adsorption hole 121 is restricted from passing through the adsorption hole 121 by the mesh of the metal mesh 123 provided between the through hole 121x and the through hole 121y. As a result, the state where the seed S is adsorbed in the adsorption hole 121 is maintained.

  As shown in FIG. 2, the seed selection plate 106 is a flat plate member on which a plurality of blades 106a are formed. The seed selection plate 106 is supported by the housing 101 so that the blade 106 a is caught by the seed S adsorbed in the adsorption hole 121 of the adsorption plate 120. The seed selection plate 106 scrapes off the plurality of seeds S adsorbed in the adsorption holes 121 by the blade 106a when the adsorption plate 120 rotates. Thereby, the number of seeds S adsorbed to one adsorbing hole 121 is adjusted to a predetermined range.

  As shown in FIG. 2, the lid portion 110 is a synthetic resin member having a cylindrical box-like schematic shape that opens toward the housing 101. In addition, in FIG. 1, illustration of the cover part 110 in the seeding part 100 is abbreviate | omitted. The lid 110 is fixed to face the casing 101 as indicated by the dashed-dotted arrow in FIG. The internal space of the lid 101 is defined by the outer wall 110a and the side wall 110b. A seed passage 111 through which the seed S supplied from the hopper 3 passes is formed in the lid 101. The seed passage 111 has a substantially U-shaped horizontal cross section, and opens upward and downward. The seed passage 111 protrudes from the side wall 110b toward the housing 101. In addition, a partition wall 112 having a V-shaped schematic shape is formed in the lid portion 101. The partition wall 112 protrudes toward the housing 101 from the side wall 110b. A seed pool 115 partitioned by a partition wall 112 is formed below the seed passage 111.

  The seed S that has passed through the seed passage 111 along the curved arrow in FIG. As described above, the seed S is once accumulated in the seed pool 115 and then adsorbed in the adsorption holes 121 of the adsorption plate 120. The position where the seed S is adsorbed in the adsorption hole 121 corresponds to the first position in the present invention. The seed S adsorbed in the adsorption hole 121 moves in the R direction as the adsorption plate 120 rotates. During the movement, as described above, a part of the seeds S adsorbed to the adsorption holes 121 by the seed selection plate 106 are scraped off. As a result, in a state where an appropriate number of seeds S are adsorbed per one adsorption hole 121, these seeds S reach the position of the covering plate 104 (the second position in the present invention) in the R direction. At this position, the suction action through the suction holes 121 is temporarily weakened by the cover plate 104 that partially covers the internal space 103 of the housing 101. Thereby, the adsorption of the seed S in the adsorption hole 121 is released. That is, every time the suction hole 121 reaches the position of the cover plate 104, the plurality of seeds S adsorbed by the single suction hole 121 are detached from the suction hole 121 at the same time. The plurality of seeds S separated from the suction holes 121 are guided to the lower chute 130 and fall together on the ground.

  According to the present embodiment described above, the suction hole 121 having a size through which the seed S can pass is formed in the suction plate 120, and the wire mesh 123 that restricts the passage of the seed S through the suction hole 121 is the suction plate. 120. Thereby, a plurality of seeds S are adsorbed in each adsorption hole 121. The wire mesh 123 is formed with a mesh that allows air to flow easily. For this reason, the passage of the seeds S is regulated by the wire mesh 123 without greatly impairing the function of adsorption by the adsorption holes 121. In addition, since a plurality of seeds S are adsorbed in one adsorption hole 121, the seeds S can be adsorbed in a concentrated manner in a narrow area. Therefore, it is easy to realize a configuration in which a plurality of seeds S are concentrated and dropped at one place in the field.

  As described above, the rotational movement of the axle of the main wheel 4 is transmitted to the shaft portion 104a so that the ratio between the number of rotations of the main wheel 4 and the number of rotations of the drive plate 104 becomes a preset value. The number of rotations of the drive plate 104 matches the number of rotations of the suction plate 120. Further, when the main wheel 4 makes one rotation, the seeder 1 moves forward by a distance corresponding to the rotation. Therefore, regardless of the forward speed of the seeder 1, the forward distance of the seeder 1 and the number of rotations of the adsorption plate 121 correspond to each other. Suction holes 121 are formed in the suction plate 120 at regular intervals with respect to the rotation direction R. For this reason, each time the sowing machine 1 moves forward by a predetermined distance according to the ratio between the number of rotations of the main wheel 4 and the number of rotations of the drive plate 104, a plurality of seeds S are gathered from the sowing unit 120 to the ground. Will fall. That is, the interval between the sowing positions in the field is a size corresponding to the ratio between the number of rotations of the main wheel 4 and the number of rotations of the drive plate 104. Therefore, the interval between the seeding positions can be adjusted by changing the ratio between the number of rotations of the main wheel 4 and the number of rotations of the drive plate 104. Moreover, it can also be adjusted by changing the interval between the suction holes 121 in the R direction.

<Modification>
The above is a description of a preferred embodiment of the present invention, but the present invention is not limited to the above-described embodiment, and various modifications can be made within the scope described in the means for solving the problem. It is possible.

  For example, in the above-described embodiment, the wire mesh 123 is provided as a member that restricts the passage of the seed S in the adsorption hole 121. However, a member other than the wire mesh 123 may be provided as such a member. For example, instead of a metal mesh, a resin mesh may be provided instead of the metal mesh 123. One or a plurality of thin resin strings or wires may be provided instead of the wire mesh 123.

  In the above-described embodiment, the wire mesh 123 as a member for restricting the passage of the seed S is provided by being sandwiched between the disc portion 120x and the disc portion 120y. That is, such a member is provided in the middle of the suction hole 121. However, such a member may be provided at the opening of the suction hole 121.

S Seed 1 Vacuum seeder (seeder)
3 Hopper 100 Seeding part 120 Suction plate 120x, 120y Disc part 121 Suction hole 121x, 121y Through hole 123 Wire mesh

Claims (3)

Supply means for supplying seeds;
An adsorbing member formed with a plurality of adsorbing holes for adsorbing seeds supplied from the supply means;
Rotation drive means for rotating the adsorption member,
The adsorption hole has a size through which seeds can pass;
A regulating member for regulating the passage of the seed through the adsorption hole by contacting the seed is provided in the adsorption hole,
A plurality of the seeds are adsorbed to each of the adsorption holes in the first position with respect to the rotation direction of the adsorption member by the rotation driving means, and the adsorption holes are in a second position different from the first position. The vacuum seeder is characterized in that the adsorption is released and the plurality of seeds are dropped from the adsorption hole.   2. The vacuum seeder according to claim 1, wherein the regulating member is a net member stretched on the suction hole and having an opening smaller than the diameter of the suction hole. The adsorption member is
The partial hole which comprises the said adsorption | suction hole is formed in each, It has the 1st and 2nd board component which pinched | interposed the said regulating member between each other, The 1 or 2 characterized by the above-mentioned. Vacuum seeder.

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