KR102075634B1 - Smart farming device - Google Patents

Abstract

The present invention relates to a smart farming device and, more specifically, to a smart farming device which is configured to quickly and effectively discharge foreign matters to the outside while continuously supplying water to fish and shellfish so that the fish and shellfish can be farmed in the clean environment. According to the present invention, the smart farming device comprises: a water tank main body formed in a hollow shape and including an opening formed upward; a farming portion arranged inside the water tank main body, configured to accommodate fish and shellfish therein, and including a plurality of through holes connected to the inside of the water tank main body; a first separation portion formed as one side of the farming portion and one side of the water tank main body are separated from each other; a second separation portion formed as the other side of the farming portion and the other side of the water tank main body are separated from each other; a third separation portion formed as a lower surface of the farming portion and a lower surface of the water tank main body are separated from each other; a water feeding portion installed on the first separation portion and configured to feed water to the inside of the water tank main body; and a drainage portion installed on the second separation portion and configured to discharge water in the water tank main body to the outside, wherein the water fed from the water feeding portion is discharged to the outside through the drainage portion after passing through the third separation portion and the second separation portion.

Description

Smart Former {SMART FARMING DEVICE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a smart farming machine, and more particularly, to a smart farming machine which allows fish and shellfish to be farmed in a clean environment by quickly and effectively discharging foreign substances to the outside while continuously supplying water to the fish and shellfish.

Conventional sea farming is a method of trapping seawater and raising fish on the coast, and at this time, because the seawater is periodically changed to maintain water quality, the coastal environment may be contaminated.

Farms grown in tanks, or farms, also need to be changed every day with sea water, fed with antibiotics to keep fish from getting sick and sprayed with fungicides to kill germs.

Here, the farm means a place for breeding various useful organisms in the artificially produced tank, and in general, aquaculture farms are used to produce tanks in various forms according to the growth characteristics of the organisms so as to raise various organisms. Doing.

Unlike onshore farms, land farms are limited in breeding volume and tank space, so that contaminants such as excreta, feed debris, and dead bodies of farmed organisms continue to accumulate.

In particular, aquaculture organisms decompose proteins to obtain energy, and only 20-30% of the protein components contained in these aquaculture feeds are actually consumed by aquaculture organisms. It turns into pollutants such as nitrous acid.

When ammonia and nitrite increase in concentration, they act as toxic substances and cause aquaculture.

In addition, when the water quality is deteriorated, ammonia or hydrogen sulfide is generated in the summer when the water temperature is high, as well as a bad odor, the virus and pathogenic microorganisms are proliferated to increase the lethality of aquaculture organisms, and in some cases, aquaculture organisms may die.

Therefore, it is necessary to keep the inside of the farm where fish and shellfish are housed in clean and clean environmental conditions at all times. In the related art, it is difficult to require expensive equipment to maintain such clean environmental conditions or to maintain clean environmental conditions.

Patent Registration 10-1302657 Patent Registration 10-1642663 Patent Publication 10-2017-0030682

The present invention is to solve the above-mentioned problems, while continuously supplying water to the shellfish, a smart fish farm that can culture fish and shellfish in a clean environment by quickly and effectively draining foreign substances (feces, etc.) generated from the shellfish to the outside The purpose is to provide.

In order to achieve the above object, the smart farming machine of the present invention comprises a tank body formed in a hollow shape and having an open hole in an upward direction; A culture portion disposed inside the tank body, in which fish and shellfish are accommodated, and having a plurality of through holes communicating with the inside of the tank body; A first spacing part formed on one side of the aquaculture part and on one side of the tank body; A second spacing part formed with the other side of the aquaculture part and the other side of the tank main body spaced apart from each other; A third spacing portion formed with the lower surface of the aquaculture portion and the lower surface of the tank main body spaced apart from each other; A water supply unit mounted to the first separation unit to supply water to the inside of the tank main body; A drainage part mounted on the second spacing part to discharge water from the tank body to the outside; the water supplied from the water supply part passes through the third spacing part and the second spacing part, and then the drainage part Characterized in that discharged to the outside through.

The culture unit, the lower perforated plate is installed in the horizontal direction in the tank body, a plurality of the through-holes are formed in the vertical direction, and forming the third spacing portion between the lower surface of the tank body; A first blocking plate coupled to one side of the lower perforated plate to form the first spacing part between one side of the tank body; And a second blocking plate coupled to the other side of the lower perforated plate to form the second separation part between the other side of the tank body.

The lower perforated plate arranged in a horizontal direction is coupled to the inner surface of the tank body to receive the fish and shellfish in a space formed between the inner surface of the tank body and the upper portion of the lower perforated plate, foreign matter present in the culture portion is penetrated through the The ball is dropped into the third spaced portion through the ball, and the water supplied through the water supply portion is discharged by moving the foreign matter to the drain portion while passing through the third spaced portion.

A locking jaw is formed in the tank body, and the lower perforated plate is seated on and supported by an upper portion of the locking jaw.

At the bottom of the lower perforated plate, the water tank body is formed such that its width is gradually narrowed downward.

The drain portion, the outer housing is formed in a hollow shape, the lower portion is spaced apart from the lower surface of the tank body to form a drain inlet therebetween; An inner housing formed in a hollow shape and spaced apart from the inside of the outer housing, and having a lower end protruding downward longer than the outer housing to be coupled through the lower portion of the tank body; Spacer spaced apart from each other the outer housing and the inner housing to form a ring-shaped drain passage therebetween, wherein the inner housing is formed with a drain communication port for communicating the interior and the drain passage, the drain inlet Is communicated with the inside of the inner housing through the drain passage and the drain communication port, the water transferred through the third separation portion passes through the drain inlet, drain passage and drain communication port to the outside through the interior of the inner housing. Discharged.

The drain communication port is at the same position as the water surface of the culture section.

The drain communication port is formed as a hole penetrating the inside and the outside on the outer peripheral surface of the inner housing.

The drain inlet, the drain passage, and the drain communication port are formed to be larger than the diameter of the through hole formed in the culture portion and the height of the third separation portion.

And a partition plate mounted inside the culture unit to divide the culture unit into a plurality.

It further comprises a water supply pipe that is installed in the aquaculture unit long along the longitudinal direction of the water tank body, the water supply pipe is one end is connected to the water supply portion, the water supplied from the water supply portion It is supplied to the inside, the partition plate is formed with a seating groove for mounting the water supply pipe is supported.

A bubble removing tube installed in an upper portion of the aquaculture unit along the longitudinal direction of the tank body; The air supply pipe is installed long in the lower portion of the culture unit along the longitudinal direction of the water tank body; further comprising, the partition plate is formed with a seating groove is supported by the foam removal pipe and the air supply pipe.

According to the smart farming machine of the present invention as described above has the following effects.

As described above, in the present invention, when foreign matters generated in fishery products fall to the third spaced portion, the third spaced portion rapidly moves in the direction of the second spaced portion by water flowing rapidly, and the foreign materials thus moved are drained inlets and drains. The rapid velocity of water that occurs in the narrow gap of the passage allows it to be sucked into the drain along with the water and quickly discharged to the outside.

This has the effect of keeping the aquaculture unit clean at all times while continuously supplying the aquaculture unit.

1 is a perspective view of a smart flatware according to a first embodiment of the present invention,
FIG. 2 is a front sectional view taken along line AA of FIG. 1;
3 is a side cross-sectional view taken along line BB of FIG.
Figure 4 is a side cross-sectional view showing the flow of water and foreign matter in FIG.
5 is a front cross-sectional view of the smart flatware according to the second embodiment of the present invention,
Figure 6 is a side cross-sectional view of the smart flatware according to a second embodiment of the present invention.

First embodiment

1 is a perspective view of a smart flatware according to a first embodiment of the present invention, Figure 2 is a front sectional view taken on line AA of Figure 1, Figure 3 is a side sectional view taken on line BB of Figure 1, Figure 4 3 is a side cross-sectional view showing the flow of water and foreign matter in FIG.

Smart culture machine of the present invention, the tank body 10, the culture unit 20, the first separation unit 31, the second separation unit 32, the third separation unit 33, the water supply unit 40 and a drain 50.

The tank body 10 is formed in a hollow shape and the opening is formed in the upward direction.

In the present embodiment, the water tank body 10 is made of a substantially circular cross-section, the water tank body 10 forms a hollow circular pipe shape as a whole.

The tank body 10 may be formed in a variety of shapes in addition to the cross-section, but preferably made as circular as shown in the drawings of the present embodiment.

One side and the other side of the tank body 10 is blocked.

The culture portion 20 is disposed inside the tank body 10, the shellfish and shellfish are accommodated therein, a plurality of through holes (21a) in communication with the interior of the tank body (10) Is formed.

The first separation unit 31 is formed with one side of the culture unit 20 and one side of the tank body 10 spaced apart from each other.

The second spacing part 32 is formed so that the other side of the culture portion 20 and the other side of the tank body 10 are spaced apart from each other.

The third spacing part 33 is formed by spaced apart from the bottom of the culture unit 20 and the bottom of the tank body 10.

The form portion 20 includes a lower perforated plate 21, a first blocking plate 22, and a second blocking plate 23.

The lower perforated plate 21 is installed in the horizontal direction in the water tank body 10, and a plurality of through holes 21a are formed in the vertical direction.

The lower perforated plate 21 is spaced apart from the lower surface of the water tank body 10 to form the third spaced portion 33 therebetween.

The lower perforated plate 21 disposed in the horizontal direction is coupled to the inner surface of the tank body 10 to accommodate the fish and shellfish in a space formed between the inner surface of the tank body 10 and the upper portion of the lower perforated plate 21. .

In addition, foreign substances existing in the culture portion 20, such as excreta and food generated from the shellfish, are dropped into the third spaced portion 33 through the through holes 21a and accommodated therein.

The size of the through hole 21a is such that the fish and shellfish cannot move.

A catching jaw 11 is formed inside the tank body 10, and the lower perforated plate 21 is seated and supported on an upper portion of the catching jaw 11.

In the lower portion of the lower perforated plate 21, the water tank body 10 is formed such that its width is gradually narrowed downward.

In the present embodiment, since the tank body 10 has a circular cross section, in the state where the lower perforated plate 21 is mounted below the center of the tank body 10, the tank body 10 is the The width of the lower perforated plate 21 toward the downward direction is gradually formed narrower.

Even when the cross section of the water tank body 10 is not circular, the lower portion of the water tank body 10 is formed such that its width is gradually narrowed downward.

Due to the shape of the water tank body 10, foreign matter dropped and accommodated in the third spaced apart portion 33 accumulates on one side, and moves more quickly and effectively by water passing through the third spaced space 33. Done.

The first blocking plate 22 is coupled to one side of the lower perforated plate 21 to form the first spaced portion 31 between one side of the tank body 10.

The second blocking plate 23 is coupled to the other side of the lower perforated plate 21 to form the second separation portion 32 between the other side of the tank body 10.

The first blocking plate 22 and the second blocking plate 23 may be blocked differently from the lower perforated plate 21.
As described above, the first blocking plate 22 and the second blocking plate 23 are blocked, and the inside of the first separation unit 31 and the form unit 20 and the second separation unit 32 are separated from each other. The interior of the form portion 20 is blocked without being in communication with each other.

The culture portion 20 may be formed in one space, but is preferably divided into a plurality of spaces by a plurality of partition plates 25 mounted in the culture portion 20.

As a result, it is possible to accommodate a variety of fish and shellfish, it is possible to prevent the fish and shellfish from being oriented in either direction.

The water supply part 40 is mounted to the first spaced part 31 to supply water to the inside of the water tank body 10.

Water supplied through the water supply part 40 passes through the first separation part 31 and the third separation part 33, and then moves to the culture part 20 through the through hole 21a to fill. do.

The drainage portion 50 is mounted to the second separation portion 32 to discharge the water of the tank body 10 to the outside.

The water supplied from the water supply part 40 passes through the third separation part 33 and the second separation part 32 and is discharged to the outside through the drainage part 50.

Therefore, the water supplied through the water supply part 40 passes the third spaced part 33 while moving the foreign matter accumulated in the third spaced part 33 to the drainage part 50 to be discharged to the outside. Let's do it.

In the present invention, since the water supplied through the water supply part 40 quickly moves along the narrow third spaced portion 33 without passing through the culture portion 20, it accumulates in the third spaced portion 33. The foreign matter can be moved to the drain portion 50 more quickly and effectively to be discharged to the outside.
In addition, since the second separation portion 32 is blocked by the second blocking plate 23 being blocked without being in communication with the inside of the form portion 20, the second separation portion 32 moves to the second separation portion 32. One foreign matter is discharged through the drain 50 while being blocked by the second blocking plate 23 without being moved into the culture unit 20.

The drain 50 includes an outer housing 51, an inner housing 52, and a spacer 53.

The outer housing 51 is formed in a hollow shape, the lower portion is spaced apart from the lower surface of the tank body 10 to form a drain inlet 54 therebetween.

The inner housing 52 has a hollow shape and is spaced apart from an inner circumferential surface of the outer housing 51 in the outer housing 51.

The inner housing 52 has a lower end protruding downwardly longer than the outer housing 51 and is coupled through the lower portion of the water tank body 10.

The spacer 53 spaces apart the outer housing 51 and the inner housing 52 to form a ring-shaped drain passage 55 therebetween.

The spacer 53 may include a plurality of spacers, and the outer housing 51 and the inner housing 52 may be discontinuously integrally connected to each other, and the outer housing 51 and the inner housing 52 may be spaced apart from each other by bolts or the like. You can also combine while.

The inner housing 52 is formed with a drain communication port 56 for communicating the inside and the outside.

The drain communication port 56 communicates the drain passage 55 and the inside of the inner housing 52 formed between the inside of the outer housing 51 and the outside of the inner housing 52.

The drain communication port 56 is at the same position as the water surface of the culture unit 20.

The drain communication port 56 is formed as a hole penetrating the inside and the outside on the outer peripheral surface of the inner housing (52).

In some cases, the drain communication port 56 may be formed as an upper cross section of the inner housing 52.

The drain inlet 54 communicates with the inside of the inner housing 52 through the drain passage 55 and the drain communication port 56.

Accordingly, the water transferred through the third spacing part 33 passes through the drain inlet 54, the drain passage 55, and the drain communication port 56, and then is discharged to the outside through the interior of the inner housing 52. do.

The drain inlet 54, the drain passage 55, and the drain communication port 56 are larger than the diameter of the through hole 21 a formed in the culture part 20 and the height of the third spacing part 33. Is formed.

Therefore, foreign matter dropped through the through hole 21a can be easily discharged to the outside through the drainage portion 50.

In addition, the inner housing 52 has a lower end coupled to the lower portion of the water tank body 10, and an upper end thereof protrudes to an upper portion of the outer housing 51 so that an operator grasps an upper end of the inner housing 52. Make it easy to install.

More specifically, the operator may hold the upper end of the inner housing 52 and insert the lower end of the inner housing 52 into the second spacing part 32 to be coupled to the lower portion of the tank body 10. When the drainage portion 50 is to be replaced or cleaned, the drainage portion 50 may be separated from the water tank body 10 so as to be easily replaced or cleaned.

Hereinafter, an operation process of the present invention having the above-described configuration will be described.

The water supplied through the water supply part 40 moves to the first separation part 31, the third separation part 33, and the second separation part 32 to be filled.

Part of the water moved to the third spacing part 33 is filled in the culture portion 20 in which a portion of the water is moved upward through the through hole 21a to accommodate fish and shellfish.

In addition, since the water filled in the tank body 10 is discharged to the outside through the drain communication port 56, the height of the water filled in the culture portion 20 is the same as the position where the drain communication port 56 is formed. .

When excretion and the like occurs in the fish and shellfish accommodated in the culture portion 20 is accumulated in the third spaced portion 33 through the through-hole (21a).

Then, foreign matter present in the third separation unit 33 is swept away by the water continuously supplied through the water supply unit 40 to move to the second separation unit 32.

The water present in the second separation portion 32 is discharged to the outside through the interior of the inner housing 52 after passing through the drain inlet 54, drain passage 55 and drain communication port 56, At this time, because the gap between the drain inlet 54 and the drain passage 55 is narrow, water moves quickly to the drain inlet 54 and the drain passage 55.

Accordingly, the foreign matter present in the water is quickly sucked into the drain inlet 54 and the drain passage 55 which moves rapidly, passes through the drain communication port 56 and is discharged to the outside through the interior of the inner housing 52. Will be.

As described above, according to the present invention, the foreign matter generated in the shellfish is quickly moved in the direction of the second spaced portion 32 by the water flowing rapidly through the third spaced portion 33, and the foreign matter thus moved is the drainage inlet ( By the rapid speed of the water generated in the narrow gap between the 54 and the drain passage 55 is sucked into the drain 50 with the water is quickly discharged to the outside.

Through this, there is an effect that can always clean the culture portion 20 while continuously supplying water to the culture portion 20.

Second embodiment

5 is a front sectional view of a smart fish farm according to a second embodiment of the present invention, Figure 6 is a side sectional view of a smart fish farm according to a second embodiment of the present invention.

Compared to the first embodiment, the second embodiment has a difference in that the water supply pipe 61, the bubble removing pipe 62, and the air supply pipe 63 are installed.

The water supply pipe 61 is installed long in the aquaculture unit 20 along the longitudinal direction of the tank body (10).

One end of the water supply pipe 61 is branched to the water supply part 40, and supplies water supplied from the water supply part 40 to the inside of the aquaculture part 20.

The bubble removing tube 62 is installed long in the upper portion of the culture unit 20 along the longitudinal direction of the tank body (10).

The bubble removing tube 62 is open at the top, and accommodates the bubbles formed on the water surface of the aquaculture unit 20 with water and discharges them to the outside.

The air supply pipe 63 is installed long in the lower portion of the culture unit 20 along the longitudinal direction of the water tank body (10).

The air supply pipe 63 is connected to an external pump to continuously supply air below the surface of the aquaculture unit 20.

In addition, the partition plate 25 is provided with a seating groove 26 in which the water supply pipe 61, the bubble removing pipe 62, and the air supply pipe 63 are seated and supported.

The water supply pipe 61, the bubble removing pipe 62 and the air supply pipe 63 may change the presence and number thereof as necessary.

Since other matters are the same as in the first embodiment, detailed description thereof will be omitted.

The present invention smart farming machine is not limited to the above-described embodiment, it can be carried out in various modifications within the scope of the technical idea of the present invention.

10: tank body, 11: jaw,
20: aquaculture part, 21: lower perforated plate, 21a: through hole, 22: first blocking plate, 23: second blocking plate, 25: partition plate, 26: seating groove,
31: first spaced portion, 32: second spaced portion, 33; Third Spacer,
40: water supply,
50: drainage portion, 51: outer housing, 52: inner housing, 53: spacer, 54: drainage inlet, 55: drainage passage, 56: drainage communication port,
61: water supply pipe, 62: bubble removing pipe, 63: air supply pipe.

Claims (12)

A water tank body having a hollow shape and having an open hole in an upward direction;
A culture portion disposed inside the tank body, in which fish and shellfish are accommodated, and having a plurality of through holes communicating with the inside of the tank body;
A first spacing part formed on one side of the aquaculture part and on one side of the tank body;
A second spacing part formed with the other side of the aquaculture part and the other side of the tank main body spaced apart from each other;
A third spacing portion formed with the lower surface of the aquaculture portion and the lower surface of the tank main body spaced apart from each other;
A water supply unit mounted to the first separation unit to supply water to the inside of the tank main body;
A drain part mounted on the second spacing part to discharge water from the tank main body to the outside;
A partition plate mounted inside the culture unit to divide the culture unit into a plurality;
A water supply pipe installed in the culture section along the longitudinal direction of the tank body;
A bubble removing tube installed in an upper portion of the aquaculture unit along the longitudinal direction of the tank body;
It is made, including; the air supply pipe is installed long in the lower portion of the culture unit along the longitudinal direction of the tank body,
The aquaculture unit,
A lower perforated plate installed in the horizontal direction in the tank body, and having a plurality of through holes formed in the vertical direction, and forming the third spacing portion between the bottom surface of the tank body;
A first blocking plate coupled to one side of the lower perforated plate to form the first spacing part between one side of the tank body;
And a second blocking plate coupled to the other side of the lower perforated plate to form the second separation part between the other side of the tank body.
The first blocking plate and the second blocking plate are blocked so that the inside of the first spaced portion and the form portion and the inside of the second spaced portion and the form portion are blocked without being in communication with each other,
The lower perforated plate arranged in a horizontal direction is coupled to the inner surface of the tank body is the fish and shellfish is accommodated in the space formed between the inner surface of the tank body and the upper portion of the lower perforated plate,
Foreign matter present in the culture portion is dropped into the third spaced through the through hole is accommodated,
The water supplied from the water supply part passes through the third separation part and passes through the second separation part together with the foreign matter, and then is discharged to the outside through the drainage part.
The foreign matter moved to the second separation portion is blocked from being moved into the form portion by the second blocking plate,
A locking jaw protrudes from the inside of the tank body, and the lower perforated plate is seated on and supported by an upper portion of the locking jaw.
In the lower portion of the lower perforated plate, the water tank body is formed such that its width becomes narrower as it goes downward.
The drain portion,
An outer housing formed in a hollow shape and having a lower portion spaced apart from a lower surface of the tank body to form a drainage inlet therebetween;
An inner housing formed in a hollow shape and spaced apart from the inside of the outer housing, and having a lower end protruding downward longer than the outer housing to be coupled through the lower portion of the tank body;
It comprises a spacer; spaced apart from the outer housing and the inner housing to form a ring-shaped drainage passage therebetween,
The outer housing is fixedly coupled to the inner housing through the spacer,
The inner housing has an upper end protruding to the upper portion of the outer housing,
The inner housing is formed with a drain communication port for communicating the interior and the drain passage,
The drain inlet is in communication with the inside of the inner housing through the drain passage and the drain communication port,
The water transferred through the third spacing portion is discharged to the outside through the interior of the inner housing after passing through the drain inlet, drain passage and drain communication port,
The splitter plate is a smart flatware, characterized in that the water supply pipe, the bubble removing pipe and the air supply pipe is formed in the seating groove is supported. delete delete delete delete delete The method according to claim 1,
Smart drainage characterized in that the drain communication port is in the same position as the water surface of the aquaculture unit. The method according to claim 7,
The drain communication port is a smart flatware, characterized in that formed in the outer circumferential surface of the inner housing through a hole penetrating the inside and the outside. The method according to claim 8,
The drainage inlet, the drainage passage and the drainage communication port is a smart farming machine, characterized in that formed larger than the diameter of the through hole formed in the culture portion and the height of the third separation portion. delete delete delete

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