KR20190113620A - Granular material spraying apparatus - Google Patents

Abstract

(Problem) Provide a granular material spreading device which can spray granular material evenly around the rotating plate.
(Solution means) The granular matter spreading apparatus 10 which concerns on this invention is provided below the tank 12 and the tank 12, and the rotating plate 31 and the rotating plate which were rotatably centered around the rotating shaft 30 are provided. The blade body 32 which has a plurality of blade bodies 32 provided in the upper surface of 31, and scatters the granular material which flows out on the rotating plate 31 which rotates from the tank 12 in which granular objects were accommodated outwardly by the blade body 32 In the granular matter spreading apparatus 10 provided with the rotating blade mechanism 28, it is moved outward from the adjacent area in the area divided | segmented into the several area in the circumferential direction by the blade body 32 of the rotating plate 31. At least one of the shape of the rotating plate 31 and the shape of the blade body 32 is different in an adjacent area in order to make at least one of the angles of jumping out of the initial velocity and the horizontal direction of the protruding granular material different from each other. .

Description

Granular material spraying device {GRANULAR MATERIAL SPRAYING APPARATUS}

The present invention relates to a granular material spreading apparatus which enables uniform spraying of granular material.

Various apparatuses exist in the granular material spraying apparatus which sprays the granular material, such as chemicals, such as pesticides, and fertilizer. For example, Patent Document 1 (Japanese Patent Laid-Open No. 2012-157273) discloses a tank, a rotating plate installed below the tank and rotatably centered on a rotating shaft, and a plurality of blade bodies provided in a radial shape on an upper surface of the rotating plate. And a rotating blade mechanism for dispersing outwardly the granular material flowing down from the tank in which the granular material is stored onto the rotating plate that rotates from the inlet hole at a position biased from the rotary shaft to the outside by the blade body. A particulate spreading device is described. This granular material spreading device is adapted to press and rotate the granular material falling on the rotating plate by the rotating blade body in the rotational direction of the rotating plate, and to fly to the outside of the rotating plate.

Japanese Patent Publication No. 2012-157273

By the way, there is a rotating shaft for rotating the rotating plate in the center of the rotating plate. Therefore, since the rotating shaft becomes a spatial obstacle in the inlet and outflow of the granular material from a tank, it cannot be installed in the rotation center of a rotating plate, and must be arrange | positioned in the position which shifted away from the rotating shaft.

In this way, when the inlet and outlet of the granular material are provided at a position deviated from the rotating shaft which is the center of the rotating plate, a bias occurs in the direction in which the granular object pops out, and it is difficult to spread the granular object evenly around the rotating plate.

This invention is made | formed in order to solve the said subject, Comprising: It aims at providing the granular material spreading apparatus which can spray the granular material uniformly around the rotating plate, while being a simple structure.

In order to achieve the above object, the present invention has the following configuration.

That is, the granular matter spreading apparatus according to the present invention has a tank, a rotating plate provided below the tank and rotatably centered on a rotating shaft, and a blade body provided on a plurality of upper surfaces of the rotating plate, wherein the granular material is accommodated. A granular matter spreading device having a rotating blade mechanism for dispersing granular matter flowing down from a tank onto the rotating plate rotating outwardly by the blade body, wherein the blade body of the rotating plate is disposed in a plurality of areas in a circumferential direction. At least one of the shape of the rotating plate and the shape of the blade body is adjacent to each other so that at least one of the initial velocity of the granular material protruding outward from the adjacent area in the divided area and the angle of projection to the horizontal direction are different from each other. Characterized by different in the area.

The length in the radial direction from the center of the rotating plate of the blade body in the adjacent area can be varied.

 Alternatively, the inclination angle of the bottom surface of the rotating plate facing outward from the center of the rotating plate in the adjacent area can be varied. In this case, the inclination angle of the bottom surface of the rotating plate that faces outward from the center of the rotating plate in the adjacent area is the angle from the horizontal upward to the circumferential direction of the rotating plate, horizontal, horizontal downward to horizontal angle, horizontal, horizontal It can be set to repeat in the order of upward angle.

Alternatively, the length of the bottom surface of the rotating plate facing outward from the center of the rotating plate in the adjacent area can be varied.

Alternatively, furthermore, the angle toward the central axis direction of the blade body in the adjacent area can be varied.

Moreover, the planar shape of the said blade body in the said adjacent area can be formed with the curved blades from which a curved form differs from each other.

According to the present invention, it is possible to provide a granular material spreading device which can spread the granular material evenly around the rotating plate while having a simple structure.

1 is a cross-sectional view of a particulate spreader.
2 is a plan view and a cross-sectional view showing a conventional rotating plate and a blade body.
It is a top view and sectional drawing which shows 1st Embodiment of the rotating plate and blade body in this invention.
It is a top view and sectional drawing which shows 2nd Embodiment of the rotating plate and blade body in this invention.
It is a top view and sectional drawing which shows 3rd Embodiment of the rotating plate and blade body in this invention.
It is a top view and sectional drawing which shows 4th Embodiment of the rotating plate and blade body in this invention.
It is a top view and sectional drawing which shows 5th Embodiment of the rotating plate and blade body in this invention.
It is a top view and sectional drawing which shows 6th Embodiment of the rotating plate and blade body in this invention.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described in detail based on attached drawing.

1 is a cross-sectional view of a particulate matter spraying device 10 according to the present embodiment.

The granular material spreading device 10 is used by being attached to a mobile device (not shown) such as an unmanned aerial vehicle or a spreading truck.

Reference numeral 12 denotes a tank, and the required amount of granular material can be stored in the tank 12 from the storage port 14. The lid 16 is attached to the storage port 14 in a detachable manner.

The tank 12 is attached to the base 13.

A lot hopper 18 is attached below the tank 12. Between the tank 12 and the hopper 18, the shutter plate 20 is rotatably provided by the rotating shaft 22 provided through the tank 12. As shown in FIG.

The shutter plate 20 is rotated to an arbitrary position by rotating the rotating shaft 22 manually or by electric motor. In the present embodiment, the shutter plate 20 is rotated by manually operating the handle 23 to rotate the rotation shaft 22.

Perforations 24 are formed in the shutter plate 20. In addition, perforations (not shown) are formed in the bottom surface of the tank 12.

If the shutter plate 20 prevents the perforation of the bottom surface of the tank 12, the granular material stored in the tank 12 will not fall. In addition, when the shutter plate 20 rotates so that the perforation 24 of the shutter plate 20 and the perforation of the bottom surface of the tank 12 coincide, the granular material stored in the tank 12 flows into the hopper 18. It is supposed to be. By adjusting the degree of overlap of the two perforations, the flow rate of the granular material can be adjusted.

The lower part of the hopper 18 becomes the flow port 26 of a granular material.

The rotary blade mechanism 28 is provided below the tank 12.

The rotary blade mechanism 28 has a rotary plate 31 rotatably installed about the rotary shaft 30. On the upper surface of the rotating plate 31, a plurality of blade bodies 32 are formed radially.

The rotating shaft 30 is rotatably supported by the bearing 33 fixed to the base 13. An upper portion of the rotating shaft 30 is formed in the screw gear 34, and the helical gear 35 is engaged with the screw gear 34. As the helical gear 35 is rotated by a motor or manual which is not shown, the rotating plate 31 is rotated. Moreover, you may make it rotate the rotation shaft 30 directly by a motor (not shown).

As mentioned above, the granular material accommodated in the tank 12 flows down on the rotating plate 31 from the inlet port 26 of the hopper 18.

The inlet hole 26 of the hopper 18 is provided inclined downward obliquely toward the rotating shaft 30 direction, as shown in FIG.

In addition, in this embodiment, the distribution lot 37 is rotatably provided centering on the bearing 33. As shown in FIG. The distribution lot 37 is provided in the shape of a long saucer in the circumferential direction, the distribution port 38 is formed at one end, receives the granular material falling from the inlet port 26, and the granular material is rotated by 30) It can distribute to the surrounding place, and can flow down on the rotating plate 31. FIG.

In addition, the distribution lot 37 does not necessarily need to be provided, and the granular material may be made to flow down on the rotating plate 31 directly from the flow port 26.

Reference numeral 40 is a cover, which is provided to cover the upper side of the rotating plate 31, and prevents the granular object from protruding upward. In addition, a shielding wall (not shown) extending downward may be provided at the tip of the cover 40 to restrict the scattering of the granular material outward by a predetermined distance or more.

In the present embodiment, as described above, in the initial velocity and the horizontal direction of the granular material protruding outward from an adjacent area in an area divided into a plurality of areas in the circumferential direction by the blade body 32 of the rotating plate 31. At least one of the shape of the rotating plate 31 and the shape of the blade body 32 is different in an adjacent area in order to make at least one of the outward angles with respect to each other different.

For comparison, a conventional example is shown in FIG.

2 is a view showing a conventional rotating plate 31 and a blade body (32). A is its plan view and B is a sectional view. The rotating plate 31 is provided in disk shape, and the blade body 32 is formed radially in the same length and the same shape. In this conventional rotary blade mechanism, as described above, since the inlet and outlet of the granular material from the tank are not installed at the position deviated from the center of the rotary plate 31, a bias occurs in the direction in which the granular object pops out and the rotary plate ( It was difficult to spray the granular objects evenly around 31).

3 shows an example of the first embodiment of the rotary blade mechanism 28 in the present invention, where A is its plan view and B is a sectional view.

In this embodiment, the length in the radial direction from the center of the rotating plate 31 of the blade body 32 in the adjacent area of the area divided into the plurality of areas in the circumferential direction by the blade body 32 is different. have.

More specifically, in this embodiment, the length of the blade body 32 is the blade body 32a of the largest length, the blade body 32b of the intermediate length, and the blade body of the minimum length in the circumferential direction of the rotating plate 31 ( 32c), it is set to repeat in order of the blade body 32b of intermediate length, and the blade body 32a of maximum length. In addition, the rotating plate 31 and the blade body 32 are provided so that they may become 180 degree point symmetry in plan view. As a result, the rotational balance of the rotation of the rotating plate 31 around the central axis 30 is obtained.

In this first embodiment, the granular material flowing down from the inlet port 26 onto the rotating plate 31 is pressed against the blade body 32 to rotate, and protrudes outward from the position away from the blade body 32, but the blade Since the sieve 32 has a different length, the speed (second speed) when jumping outward is large in the case of the long blade body 32 and becomes smaller in the case of the short blade body 32, so The distance at which the prized objects stick out will be different.

Thus, in this embodiment, since the distance which a granular object from an adjacent area sticks out differs and scatters, the granular object is sprayed evenly around the rotating plate 31 by this.

4 shows an example of the second embodiment of the rotary blade mechanism 28 according to the present invention, where A is a plan view, B is an A-A cross sectional view, C is a B-B cross sectional view, and D is a C-C cross sectional view.

In this embodiment, the inclination angle of the bottom surface of the rotating plate 31 toward the outside from the center of the rotating plate 31 in the adjacent area of the area divided into the plurality of areas in the circumferential direction by the blade body 32 is different. have.

More specifically, in this embodiment, the inclination angle of the bottom surface of the rotating plate 31 facing outward from the center of the rotating plate 31 in the adjacent area is an angle (AA cross section) upward from horizontal in the circumferential direction of the rotating plate, It is set to repeat in order of horizontal (BB cross section), horizontally downward angle (CC cross section), horizontal (BB cross section), and horizontal to upward angle (AA cross section). In addition, the rotating plate 31 and the blade body 32 are provided so that they may become 180 degree point symmetry in plan view. As a result, the rotational balance of the rotation of the rotating plate 31 around the central axis 30 is obtained.

In this 2nd Embodiment, since the inclination angle of the bottom face of the rotating plate 31 toward the outer side is made different from the center of the rotating plate 31 in the said adjacent area, it jumps to the upper and lower sides of the granular material from an adjacent area. Since the exit angles are different, and thus the scattering distance of the granular materials is different, scattering of the granular materials is scattered, so that the granular materials are evenly spread around the rotating plate 31.

5 shows an example of a third embodiment of the rotary blade mechanism 28 in the present invention, where A is its plan view and B is its sectional view.

In this embodiment, the length of the bottom surface of the rotating plate 31 which faces outward from the center of the rotating plate 31 in the adjacent area of the area divided | segmented into the several area in the circumferential direction by the blade body 32 is changed. .

More specifically, the length of the bottom face toward the outside from the center of the rotating plate 31 in the adjacent area is in the order of the base 31a, the small 3lb, and the base 31a in the circumferential direction of the rotary plate 31. It is set to repeat. In addition, the rotating plate 31 and the blade body 32 are provided so that they may become 180 degree point symmetry in plan view. As a result, the rotational balance of the rotation of the rotating plate 31 around the central axis 30 is obtained.

In this 3rd Embodiment, since the length of the bottom face of the rotating plate 31 which faces outward from the center part of the rotating plate 31 in the said adjacent area is different, the granular object is hold | maintained for a long time in the long bottom surface area, The circumference is large, and the speed (seconds) when jumping outward is large, and the granular material flies far. On the other hand, in the short bottom area, the time for which the granular material is held is short, the circumferential speed thereof is small, and the speed at which the granular material flies outward is small, and the distance at which the granular material flies is small.

Thus, in this embodiment, since the distance which a granular object from an adjacent area sticks out differs and scatters, the granular object is sprayed evenly around the rotating plate 31 by this.

6 shows an example of a fourth embodiment of the rotary blade mechanism 28 in the present invention, where A is its plan view and B is its sectional view.

In this embodiment, the angle toward the center axis | shaft 30 direction of the blade body 32 in the said adjacent area is changed. That is, in the blade body 32 which is provided in multiple numbers on the upper surface of the rotating plate 31, the blade body which faces the center axis 30 direction of the rotating plate 31 (faces the center axis 30 in front), and the central axis It is provided so that the blade body which does not face the (30) direction may be mixed.

In FIG. 6, the blade body 32a is a blade body which faces the center axis | shaft 30 direction, and the blade bodies 32b, 32c, and 32e do not face the center axis | shaft 30 direction, but the rotation direction of the rotating plate 31 is shown. It is provided inclined so that the front end side may face the rotation back with respect to (X). Moreover, the blade body 32d is provided inclined so that the front end side may face the rotation front with respect to the rotation direction X of the rotating plate 31. As shown in FIG.

Although two sets of blade bodies 32a to 32e are provided, these two sets of blade bodies are provided so as to be 180 ° point symmetrical in plan view. As a result, the rotational balance of the rotation of the rotating plate 31 around the central axis 30 is obtained.

In the fourth embodiment, since the angles toward the central axis 30 of the blade body 32 are different in the adjoining area, the residence time of the granular material in each area is different and the residence time becomes longer. It can be said that the more the circumferential speed increases, the larger the speed (second speed) when jumping outwards and the granular material flies far. On the other hand, the shorter the residence time, the shorter the time for which the granular material is held (falls quickly from the rotary plate 31), the smaller the peripheral speed thereof is, and the smaller the speed (second velocity) at the time of protruding outwards is, so that the distance that the granular material flies is smaller. .

Thus, in this embodiment, since the distance which a granular object from an adjacent area sticks out differs and scatters, the granular object is spread | distributed evenly around the rotating plate 31 by this.

FIG. 7: shows the example of 5th Embodiment of the rotating blade mechanism 28 in this invention, A is its top view, B is its sectional drawing.

In this embodiment, the planar shape of the blade body 32 in the said adjacent area is formed with the curved blades from which a curved form differs from each other. For example, after the blade body 32a extends linearly toward the outer side, the front end side is curved in an arc shape in the rotational rearward direction with respect to the rotation direction X of the rotating plate 31, and is provided. The blade body 32b adjacent to the blade body 32a is a curved blade that curves in an arc shape in a rotational direction with respect to the rotation direction X as a whole.

The blade body 32c has a circular arc shape with a large curvature on the base side, a straight line in the middle portion, and an arc shape with a large curvature on the front end side, thereby forming a shape in which the linear part and the circular arc part are mixed. Similar to the blade body 32b, the blade body d is a curved blade that is curved in an arc shape in the rotational direction with respect to the rotation direction X as a whole.

Each of the blade bodies 32a to 32d is provided so that the front end side thereof faces the rotational direction X of the rotating plate 31 as a whole.

In some cases, the blade body 32 may be formed of a curved blade that curves forward in the rotational direction with respect to the rotational direction of the rotary plate 31.

And in this embodiment, two sets of blade bodies 32a-32d are provided, and these two sets of blade bodies are provided so that it may become 180 degree point symmetry in plan view. As a result, the rotational balance of the rotation of the rotating plate 31 around the central axis 30 is obtained.

In the fifth embodiment, since the planar shapes of the blade bodies 32 in the adjacent areas are formed by curved blades having different curved shapes, the residence time of the granular material in each area is different and the longer the residence time is, the longer the residence time is. It can be said that the circumferential speed becomes large, and the speed (second speed) when jumping outward is large, and the granular material flies far. On the other hand, the shorter the residence time, the shorter the time that the granular material is held (falls quickly from the rotating plate 31), the smaller the peripheral speed thereof is, and the smaller the speed (second speed) at the time of protruding outwards is, so the distance that the granular material flies is smaller. .

Thus, in this embodiment, since the distance which a granular object from an adjacent area sticks out differs and scatters, the granular object is spread | distributed evenly around the rotating plate 31 by this.

In addition, the shape of the rotating plate 31 and the shape of the blade body 32 may use together the shape shown to the said, 1st-5th embodiment.

For example, FIG. 8A and 8B alternately provide the blade body 32a which is a curved blade, and the linear blade body 32b of short length alternately (6th Embodiment).

What is necessary is just to select the shape of the rotating plate 31 and the shape of the blade body 32 in an adjacent area according to the kind, shape, size, etc. of the granular material, and also according to the spraying degree of the granular material at that time.

In addition, in this invention, an adjoining area does not necessarily need to be an all successive adjoining area.

Claims (8)

Tanks,
A granular material provided below the tank, having a rotary plate rotatably installed around the rotary shaft, and a plurality of blade bodies provided on the upper surface of the rotary plate, and flowing down on the rotary plate rotating from the tank in which the granular material is accommodated. In the granular matter spreading apparatus provided with the rotating blade mechanism which scatters outward by the said blade body,
In order to make at least one of the initial velocity of the said granular object protruding outward from the adjacent area in the area divided | segmented into the several area in the circumferential direction by the said blade body of the said rotating plate, and the jumping angle with respect to a horizontal direction different from each other, At least one of the shape of the said rotating plate and the shape of the said blade body was changed in the adjoining area, The granular material spreading apparatus characterized by the above-mentioned. The method of claim 1,
The granular matter spreading apparatus characterized by varying the length in the radial direction from the center of the rotating plate of the blade body in the adjacent area. The method according to claim 1 or 2,
The inclined angle of the bottom surface of the said rotating plate toward the outer side from the center of the said rotating plate in the said adjacent area was changed, The granular material spreading apparatus characterized by the above-mentioned. The method of claim 3, wherein
The angle of inclination of the bottom surface of the rotating plate facing outward from the center of the rotating plate in the adjacent area is an angle upward from horizontal in the circumferential direction of the rotary plate, horizontal, angle downward from horizontal, horizontal, horizontal upward A granular matter spreading device, characterized by being set to repeat in order of angle. The method according to any one of claims 1 to 4,
The granular matter spreading apparatus characterized by changing the length of the bottom face of the said rotating plate toward the outer side from the center part of the said rotating plate in the said adjacent area. The method according to any one of claims 1 to 5,
A granular matter spreading device, characterized in that an angle toward the central axis direction of the blade body in the adjacent area is different. The method according to any one of claims 1 to 6,
The planar shape of the said blade body in the adjoining area is formed with the curved blades from which a curved form differs from each other, The granular material spreading apparatus characterized by the above-mentioned. The method according to any one of claims 1 to 7,
A particulate matter spraying device, characterized in that the spraying device is attached to a moving device.

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