KR102136934B1 - Feed distributor for fish using high-speed air - Google Patents

Abstract

The present invention provides a configuration capable of minimizing the amount of feed that is supplied in the form of granules is broken by an internal device and supplied in powder form in a feed spreader for feeding fish to a fish farm or the like. The present invention, the discharge passage extending in the horizontal direction from the bottom of the body and open toward the front, and the falling passage formed in the vertical direction to communicate with the discharge passage, the upper portion of the falling passage and formed to open the top An impeller capable of supplying a uniform amount of feed by including a feed supply port, wherein the drop passage is partitioned by a plurality of wings in a radial direction around the rotation axis to form a predetermined size of the feed receiving space around the rotation axis. And, a drive for rotating the impeller, a high-speed air blower is installed in the discharge passage to blow the feed falling from the impeller to the front of the body, the side wall of the feed port, the elastic member is attached to the inclined surface .

Description

FEED DISTRIBUTOR FOR FISH USING HIGH-SPEED AIR

The present invention relates to a feeder for fish using high-speed air, and more specifically, to be used in aquaculture, etc., by discharging the feed in a uniform amount by an impeller, by high-speed air (air jetted at high speed, such as compressed air). It relates to a feeder for fish of a configuration that can be sprayed and sprayed.

In the case of fish farms, it is important to continuously supply the proper amount of fish ingested, because if the amount of feed is too large, it can be washed out or settled, causing waste and water pollution.

To this end, in a method in which the worker carries the feed container and scatters the supply, it takes a lot of time and effort to supply the feed, and it is difficult to efficiently and effectively manage the difference in the amount and time of the feed.

In order to solve this problem, a feeding device has been developed that can automatically feed the fish.

1 to 3 show an example of such a fish feed device, and are described in Korean Patent Publication No. 10-1677010.

Referring to FIG. 1, a storage bin 1 in which a certain amount of feed is stored is installed, and a feed discharge pipe 1a is connected to the bottom of the funnel-type discharge hopper below the storage bin 1, and the feed discharge pipe 1a is connected to the upper cover ( It is connected to the outer side of 3a), and a drop pipe 4 is connected to the outer side of the lower cover 3b, and a branch blow pipe 2a of the air blow pipe 2 is installed at the lower outlet of the drop pipe 4 And, the feed pipe 5 is installed in the branch ventilation pipe 2a.

2 and 3 show a configuration for distributing the feed quantitatively in FIG. 1.

The distribution rotor 6 is installed inside the upper cover 3a and the lower cover 3b, and a plurality of feed input spaces 6a are installed at regular intervals in the distribution rotor 6, and the distribution rotor 6 is rotated. The driving motor 8 and the driving shaft 8a are installed.

Accordingly, when the feed is supplied through the inlet 7a of the upper cover 3a to which the feed discharge pipe 1a is connected and the distribution rotor 6 rotates, a certain amount of feed is fed into the feed input space 6a and rotated and transported. When the feed input space (6a) meets the outlet (7b) of the lower cover (3b), it can be dropped through the lower drop pipe (4).

Thereafter, the feed is transferred to the feed transfer pipe 5 by the blowing air of the branch blow pipe 2a, and can be sprayed by being ejected to the outside.

Looking at the above-described conventional feeder, when the distribution rotor 6 rotates, the feed is supplied to the feed inlet space 6a and the action of sequentially being discharged to the dropping pipe 4 occurs continuously, so that a certain amount of feed is Although it can be continuously sprayed, a problem occurs in that the grains of some feeds between the distribution rotor 6 and the upper cover 3a are broken, so that the grains of a plurality of feeds are discharged into a crushed powder form and fed to the farm. There is a problem to be supplied.

That is, due to the rotational operation of the distribution rotor 6, some feed grains are caught between the lower edge of the upper cover 3a and the upper edge of the distribution rotor 6, which is broken and shredded by the rotational force. .

In the case of such crushed feed, there is a problem in that it becomes powdery and is easily blown out of the air, so that it is difficult to be sprayed at a desired location on the farm. .

Accordingly, it is a cause of waste of feed and lowering the efficiency of the overall operation.

The present invention has been derived in view of the above, the object of the present invention is a feed spreader for supplying feed to fish in aquaculture farms, the amount of feed supplied in the form of granules is broken by an internal device and supplied in powder form. It is to provide a configuration that can be minimized.

Another object of the present invention is a situation in which the air supplied at a high speed acts on a device dispensing the feed from the upper side while preventing the amount of feed to be supplied while being crushed so that the amount supplied in the crushed state is minimized. It is to provide a feed spreader for fish configured so as not to occur.

In addition, another object of the present invention is to provide a feeder for fish that can be easily produced by having a relatively simple configuration while achieving the above object.

The feeder for fish of the present invention for achieving the above object, the body, and a discharge passage extending in the horizontal direction from the bottom of the body and open toward the front, so that the lower portion in the body communicates with the discharge passage It includes a drop passage formed in the vertical direction and a feed supply port formed such that a lower portion at the upper portion of the body communicates with an upper portion of the drop passage and an upper end is opened, and is installed in the drop passage, and installed in the drop passage. As, the feed receiving space partitioned by a plurality of blades formed in the radial direction around the rotating shaft is formed along the circumference of the rotating shaft, and an impeller capable of supplying feed to a lower side in a set amount, and the impeller installed on the body A rotating driver and a high-speed air blower which is installed in the discharge passage and blows feed falling from the impeller toward the front of the body, further includes a side wall of the feed port, wherein the wing of the impeller rotates and proceeds The side wall of the side is formed as an inclined surface so that the feed hole becomes narrow while going to the lower side, and an elastic member is attached to the inclined surface, wherein the elastic member has a lower end positioned in front of the lower end of the side wall where the inclined surface is formed, so that the It is characterized in that the grains of the feed pushed by the tip of the wing first contact the lower end of the elastic member before the inclined surface.

In addition, the present invention is characterized in that the elastic member is installed with a plate-shaped pad and its lower end is installed at the front side and further below the lower end of the sidewall on which the inclined surface is formed.

In addition, according to the present invention, an impeller installation hole in which the impeller is installed is formed in the drop passage, and the impeller installation hole has an inner circumferential surface formed at an interval of 0.5 to 2 mm from the outer circumferential surface of the impeller, thereby ejecting it from the high-speed air ejector Another feature is that the impeller blocks the rise of air.

In addition, the present invention, the high-speed air ejector, the ejection passage includes an ejection pipe body protruding toward the front and the ejection opening is formed in the front end, the ejection pipe body is inclined toward the bottom by being inclined toward the lower surface from the upper surface of the tip end Another feature is that by having a structure in which a cutting surface is formed, high-speed air is deflected toward the floor and blown forward.

In addition, the present invention is coupled to the rotating shaft of the impeller or the drive shaft of the driver, and a count disc having a predetermined interval of grooves or protrusions formed on an outer circumferential surface, and the number of passages of the grooves or protrusions facing the outer circumference of the count disk in the body A sensing sensor installed to detect, and a controller for receiving the signal about the number of passes of the groove or protrusion from the sensing sensor to calculate the number of revolutions of the impeller and stop the operation of the driver when the set number of revolutions is reached Another feature is to include.

Feed spreader for fish according to the present invention, by attaching an elastic member to the inclined surface of the side wall of the feed supply port, and configured so that the lower end of the elastic member is located in front of the lower end of the side wall where the inclined surface is formed, the end and elasticity of the impeller wing Even if the feed grains are caught between the lower ends of the members, the elastic member is slightly compressed and provides a flow margin through which the feed grains can escape. Accordingly, since the amount of feed supplied in the form of granules can be broken by the internal device and supplied in the form of a powder, it is possible to improve the supply of feed, such as a farm.

In addition, the feeder for fish according to the present invention, the impeller is installed in the impeller installation hole installed in the drop passage can supply the feed uniformly to the lower side while blocking the inflow of high-speed air through the drop passage to the upper side, the jet tube By installing the inclined cutting surface in the front end of the high-speed air is double-blocked from entering the upper side.

Accordingly, the present invention is a high-speed air-type feed spreader that can accurately control the supply and uniform supply of feed, while the high-speed air flows upward and the feed does not fall smoothly. Can be prevented.

1 to 3 is a configuration diagram of a feeder for supplying feed for fish, such as a conventional farm
Figure 4 is a perspective configuration diagram showing the external configuration of a fish feeder for fish according to an embodiment of the present invention
5 is a configuration explanatory diagram for explaining the overall configuration of a fish feeder for fish according to an embodiment of the present invention
Figure 6 is a cross-sectional configuration diagram showing a cross-sectional configuration in a fish feeder for fish according to an embodiment of the present invention
Figure 7 is a perspective configuration diagram showing the configuration of a fish feeder for fish according to an embodiment of the present invention
8(a) and 8(b) are explanatory diagrams for comparing and explaining the interaction of the elastic member installed on the side wall of the impeller and the feeder in the feeder for fish according to an embodiment of the present invention.
9 is a configuration and action explanatory diagram for explaining the configuration and operation of the feed supplied to the discharge passage in the feed distribution device for fish according to an embodiment of the present invention is ejected by the high-speed air of the high-speed air ejector

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

4 and 5, the feeder for fish according to an embodiment of the present invention, the body 10 and the discharge passage 20 extending in the horizontal direction from the bottom of the body 10 and open toward the front ), the drop passage 30 formed in the vertical direction so that the lower portion in the body 10 communicates with the discharge passage 20, and the lower portion from the upper portion of the body 10 and the upper portion of the drop passage 30 It includes a feed port 40 formed to be in communication with the upper end.

The body 10 is formed in a block shape, and the upper discharge passage 20 and the falling passage 30 and the feed supply port 40 are installed inside, and the impeller 50 and the actuator 61 are installed and supported. do.

The body 10 is made of synthetic resin or metal.

The discharge passage 20 extends in the horizontal direction from the bottom of the body 10 and opens toward the front, so that the feed is discharged forward and sprayed by high-speed high-speed air.

It is preferable that the discharge passage 20 is formed as a circular passage, and a high-speed air blower 70 is installed at the rear end of the discharge passage 20 so that compressed high-speed air can be blown forward.

As the discharge passage 20 is formed as a circular passage, the bottom 23 of the discharge passage 20 forms a concave curved surface as shown in FIG. 6, and the food falling from the falling passage 30 meets the center due to the concave curved surface, thereby providing high-speed air. It is easy to be discharged forward by the high-speed air blown from the blower (70).

The drop passage 30 is formed in the vertical direction so that the lower portion in the body 10 communicates with the discharge passage 20.

The falling passage 30 is a part for supplying feed from the feed supply port 40 to the impeller 50 to uniformly supply the discharge passage 20 by a predetermined amount, the feed supply port 40 and the discharge passage 20 It is formed in the vertical direction between the can be reached to the discharge passage 20 while the feed falls downward.

The dropping passage 30 is provided with an impeller 50 so that feed is supplied by the impeller 50, thereby preventing the feed from falling directly from the feed supply port 40 to the discharge passage 20, and high-speed air falling Ascent through the passage 30 is also blocked.

The impeller 50 is divided by a plurality of blades 51 in the radial direction around the rotating shaft 55 as shown in FIG. 7, so that the feed receiving space 52 of a predetermined size is formed around the rotating shaft 55 to feed the feed. It can be supplied in a uniform amount.

The drop passage 30 has an impeller installation hole 35 in which an impeller 50 is installed, and an inner circumferential surface of the impeller installation hole 35 is formed at an interval of 0.5 to 2 mm from the outer circumferential surface of the impeller 50, thereby providing an impeller ( 50) is closely assembled, and due to the close assembly, most of the high-speed air ejected from the high-speed air ejector (70) riding on the falling passage (30) and rising to the feed port (40) is blocked.

6 and 7, the impeller 50 is provided with a plurality of blades 51 that extend radially around the rotational shaft 55, and the blades 51 rotate around the rotational shaft 55. Accordingly, by being installed at uniform intervals, the feed receiving space 52 formed between the wings 51 may be formed to have a constant size and may have uniform intervals from each other.

The front end disc 53 and the rear end disc 54 of the impeller 50 can be formed by blocking the front and rear ends of the wing 51 with the wing 51 therebetween.

The impeller 50 is installed in the horizontal direction so as to block the falling passage 30 from the vertical direction and is connected to the driver 61 so that the rotation shaft 55 coincides with the driving shaft 62 of the driver 61 to increase rotational force. I receive it.

The driver 61 is fixedly installed on the rear surface of the body 10, the drive shaft 62 of the driver 61 is inserted into the rotation shaft 55 of the impeller 50 and pinned to rotate integrally, and the controller ( 80), the driving and stopping operation can be controlled.

The driver 61 may be a conventional motor or a structure in which a motor and a reducer are combined, or a count disk 63 and a detection sensor 64 may be installed to detect the rotation speed. Allows the controller 80 to receive the signal from the sensor 64.

The count disc 63 is coupled to the rotation shaft 55 of the impeller 50 or the drive shaft 62 of the driver 61, and a groove or protrusion of a certain interval is formed on the outer circumferential surface so that the detection sensor 64 detects the rotation amount Make it possible.

The detection sensor 64 is installed to be fixed to the body 10 and is preferably installed to surround the outer circumference of the count disk 63 in a U-shape.

Accordingly, the detection sensor 64 can detect the number of passages of the grooves or protrusions of the count disk 63 and transmit a signal regarding the number of passages of the grooves or protrusions to the controller 80.

The controller 80 calculates the number of revolutions of the impeller 50 by using the signal about the number of passes received from the detection sensor 64, and when the set number of revolutions is reached, stops the operation of the driver 61, and the high speed The operation of the on-off valve (solenoid valve) 75 installed in the air blower 70 can also be stopped.

The input amount of the feed to be sprayed to the controller 80 can be set using the input device 81, and the feed amount of the feed can be calculated according to the number of revolutions of the impeller 50.

The feed supply port 40 is a portion where the feed hopper 91 is mounted to feed the feed to the impeller 50 installed on the lower drop passage 30 in which the feed is stacked.

As shown in FIG. 6, the feed supply port 40 is formed with an inclined inclined surface 41 so that the sidewalls of both sides gather together while going downward, and the feed supply port 40 is narrowed.

Referring to FIG. 6, of the side walls of both sides, the side wall of the side where the blade 51 of the impeller 50 rotates and proceeds is formed by the inclined surface 41, and the elastic member 45 is attached.

The elastic member 45 is installed to prevent the blades 51 of the impeller 50 from crushing the grain 93 of the feed by the rotational operation of the impeller 50.

The elastic member 45 attached to the inclined surface 41, the lower end (45a) is positioned in front of the lower end (41a) of the side wall on which the inclined surface (41) is formed, the blade (51) according to the rotation of the impeller (50) ) When the grains 93 of the feed are caught between the end 51a and the inclined surface 41, the grains 93 of the feed are placed on the lower end 45a of the elastic member 45 before the inclined surface 41. It is arranged to contact first.

That is, referring to (a) of FIG. 8, the lower end 45a of the elastic member 45 is located in front of the lower end 41a of the side wall on which the inclined surface 41 is formed, so that the impeller 50 wing 51 Between the end (51a) of the end and the lower end (45a) of the elastic member 45, the feed grain (93) is sandwiched, and in this state, the feed grain (93) is impeller (50) by the strength of the wing (51) ) During the movement of the elastic member 45, while having a slight compression, it has a flow margin that can escape to the upper side or the lower side.

When the grains 93 of the feed are compressed to the inclined surface 41 side by the end 51a of the impeller 50, the wing 51, the contact portion of the elastic member 45 is slightly compressed, so that the grains of the feed 93 are Since it is possible to form a margin that can be pushed, it is possible to have a spatial margin in which the grains 93 of the feed will escape upward.

If, as shown in Figure 8 (b), the elastic member 45 is not present, between the end (51a) of the impeller (50) blade (51) and the lower end (41a) of the side wall on which the slope 41 is installed The grains 93 of the trapped feed are formed of a rigid body with both the wing 51 and the inclined surface 41, so that when they are compressed, they are immediately broken, and when a large number of feed grains 93 are crushed and sprayed in a powder form, they are fished in aquaculture. Becomes difficult to consume.

The elastic member 45 is installed in the form of a plate-shaped pad and its lower end 45a is more preferably installed to be installed at the lower side of the front and lower side of the lower end 41a of the side wall on which the inclined surface 41 is formed, and the elastic member ( It is more preferable to install the lower end 45a of the impeller 50 to match the outer circumferential surface of the impeller 50 where the end 51a of the wing 51 is located.

Accordingly, the lower end 45a of the elastic member 45 is located on the outer circumferential surface of the impeller 50 so that the food filled in the feed receiving space 52 moves with the rotation of the impeller 50 and the elastic member 45 The lower end (45a) of the impeller (50) can be removed over the outer circumferential surface of the feed so that a uniform amount of feed can be supplied to the discharge passage (20).

In addition, such a configuration can make the grain 93 of the feed being pushed to the end 51a of the wing 51 of the impeller 50 more reliably contact the lower end 45a of the elastic member 45.

The grains 93 of the feed contact the tip 51a of the wing 51 of the impeller 50 and the elastic member 45 so that the grains 93 of the feed come out upward when the impeller 50 rotates. In order to make the action to be performed more reliably, it is more preferable to form an inclined surface or a vertical surface 41b that is steeper than the inclined surface 41 at the lower end of the side wall where the inclined surface 41 is formed.

The inclined surface or the vertical surface 41b forms a free space for the lower end 45a of the elastic member 45 to move from the rear of the elastic member 45 so that the grain 93 of the feed is the rotational force of the impeller 50. By creating a free space to escape to the upper side in the pinched state and the lower end (45a) of the elastic member 45 is deformed to the rear, a space to exert the elastic force to push the grains (93) of the feed upwards It works.

Accordingly, the inclined surface or the vertical surface (41b), the rotation of the impeller 50 of the impeller (50) of the feed pinched between the end (51a) of the blade (51) and the lower end (45a) of the elastic member (45) The grain 93 serves to provide both a spatial margin and a temporal margin that can move upward.

On the other hand, referring to Figures 5 and 9, the fish feeder of the present embodiment, the high-speed air ejector (70) protruding toward the front from the discharge passage 20 and the ejection pipe 71b is formed in the front end (71).

The jet tube body 71 has a structure in which the front end portion is inclined toward the bottom surface from the upper surface of the end, and the inclined cutting surface 72 facing the floor is formed.

As shown in FIG. 9, the spout 71b is formed on the inclined cutting surface 72 at the front end of the spout tube 71 so that the spout 71b faces the front and opens downward.

Accordingly, the high-speed air discharged from the blow-out port (71b) of the blow-out tube body (71) is discharged toward the front, but is deflected toward the floor (23) to blow it out, thereby facilitating the discharge of the collected food on the floor and discharging it. .

Since the discharge passage 20 of this embodiment is formed as a circular passage, it is formed to form a concave bottom 23 as shown in FIG. 6 so that the feed is collected at the middle of the bottom, so that the discharge pipe is deflected toward the bottom. When the high-speed air is blown forward, the high-speed air can be easily swept forward and discharged.

In addition, by forming the inclined cutting surface 72 toward the bottom of the front end portion of the jet tube body 71, the high-speed air discharged from the jet port 71b of the jet tube body 71 is blown out toward the bottom 23 It is a structure in which upward ascent is limited.

Accordingly, since the high-speed air ejected from the ejection tube 71 does not rise through the falling passage 30, the feed supplied to the feed supply port 40 is fed to the impeller 50 of the falling passage 30 by gravity. It can be minimized that the smoothly supplied action is interrupted by high-speed air.

According to the configuration of the present embodiment described above, the impeller 50 is installed in the impeller installation hole 35 installed in the drop passage 30, while supplying the feed uniformly to the lower side while moving the feed passage upwards through the drop passage 30. The inflow of the air can be blocked, and the situation in which high-speed air flows upward due to the installation of the inclined cutting surface 72 of the jet tube 71 can be blocked.

Accordingly, while the embodiment of the present invention can constitute a high-speed air-type feed spreader that can accurately control feed and uniformly supply the feed, the high-speed air flows upward and feeds the feed supply 40 It also solves the problem that it cannot be supplied by dropping smoothly by disturbing or blowing by the high-speed air introduced.

Although the preferred embodiments of the present invention have been described above, the above embodiments are only one embodiment within the scope of the technical spirit of the present invention, and those skilled in the art within the technical spirit of the present invention. Of course, other modified implementations are possible.

10; Body 20; Outlet
23; Bottom 30; Fall passage
35; Impeller installation hole 40; Feed
41; Slope 41a; Bottom of side wall
41b; 45 if vertical; Elastic member
45a; Bottom 50 of the elastic member; Impeller
51; Wing 52; Feed receiving space
55; Axis of rotation 61; Driver
62; Drive shaft 63; Count disk
64; Detection sensor 70; High Speed Air Blower
71; Jet tube 71b; vent
72; Inclined cutting surface 75; Open/close valve
80; Controller 91; Feed hopper
93; Grains of feed

Claims (5)

Body (10),
And the discharge passage 20 extending in the horizontal direction from the bottom of the body 10 and open toward the front,
A drop passage 30 formed in the vertical direction so that the lower portion in the body 10 communicates with the discharge passage 20,
In the upper portion of the body 10, the lower portion includes a feed supply port 40 formed to communicate with the upper portion of the drop passage 30 and to open the upper end.
As being installed in the drop passage 30, the feed receiving space 52 partitioned by a plurality of blades 51 formed in the radial direction around the rotation shaft 55 is formed along the circumference of the rotation shaft 55 An impeller (50) capable of supplying feed at a set amount to the lower side,
A driver 61 installed on the body 10 to rotate the impeller 50,
A high-speed air blower (70) is installed in the discharge passage (20) to blow the feed falling from the impeller (50) toward the front of the body (10),
The side wall of the feed port 40 is formed by an inclined surface 41 so that the side wall of the side where the wing 51 of the impeller 50 rotates and progresses toward the lower side, thereby narrowing the feed port 40. And
An elastic member 45 is attached to the inclined surface 41, and the elastic member 45 has the lower end 45a at which the end 51a of the wing 51 of the impeller 50 is located. ) Is a plate-shaped pad installed to coincide with the outer circumferential surface, and the lower end 45a is positioned in front of the lower end 41a of the side wall on which the inclined surface 41 is formed, so that the end 51a of the wing 51 is pushed. The grain 93 is brought into contact with the lower end 45a of the elastic member 45 prior to the inclined surface 41,
A vertical lower surface 41b of a steeper slope than the inclined surface 41 is formed at a lower end of the side wall where the inclined surface 41 is formed, so that the end 51a of the wing 51 and the lower end of the elastic member 45 A space is provided at the rear of the lower end (45a) of the elastic member (45a) so that the movement of the grains of the sandwiched food can escape upward,
The drop passage 30 is formed with an impeller installation hole 35 in which the impeller 50 is installed, wherein the impeller installation hole 35 has an inner circumferential surface formed at an interval of 0.5 to 2 mm from the outer circumferential surface of the impeller 50. , The impeller 50 blocks the rise of the high-speed air ejected from the high-speed air ejector 70,
The high-speed air blower 70,
The discharge passage 20 includes an ejection tube 71 protruding toward the front and having an ejection opening 71b at the front end,
The jet tube 71 has a structure in which the front end portion is inclined toward the bottom from the upper surface of the end portion and has a structure in which the inclined cutting surface 72 is directed toward the floor, and the high-speed air is deflected toward the floor through the jet port 71b to the front. Feed spreader for fish characterized in that it is ejected by delete delete delete According to claim 1,
A count disk 63 coupled to the rotation shaft 55 of the impeller 50 or the drive shaft 62 of the driver 61 and having a groove or protrusion at a predetermined interval on the outer circumferential surface,
A detection sensor (64) installed to detect the number of passages of the groove or protrusion facing the outer circumference of the count disk (63) in the body (10),
A controller that receives a signal regarding the number of passes of the groove or protrusion from the detection sensor 64 to calculate the number of revolutions of the impeller 50 and stops the operation of the driver 61 when the set number of revolutions is reached ( 80),
The detection sensor 64 is fixed to the body 10 and facing the outer circumference of the count disk 63, the feeder for fish characterized in that it is installed to wrap the outer circumference in a U-shape.

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