KR102006480B1 - A fish farm with easy water level control and water quality management - Google Patents

Abstract

The present invention relates to a fish farm for easy water level control and water quality management. More specifically, the present invention relates to the fish farm comprising: a fish tank with water; an inner drainage hole through which water of the fish tank is drained in a state formed on a bottom surface of the fish tank: an inner drainage pipe mounted in communication with the inner drainage hole and formed at a predetermined height on the bottom surface of the fish tank; an external discharge hole which is discharged to the outside by flowing water drained to the inner drainage hole in a state located outside the fish tank, and positioned lower than a height of the bottom surface of the fish tank; and a water level control tube mounted in communication with the external discharge hole and formed at a predetermined height from the external discharge hole, wherein the inner drainage pipe has a plurality of flow holes formed therein and water of the fish tank is drained to the inner drainage hole through the plurality of flow holes.

Description

[0001] The present invention relates to a fish farm with easy water level control and water quality management,

The present invention relates to a fish farm where water level control and water quality management are easy, and in a fish farm where water is continuously exchanged, a water level control pipe is attached to an external discharge hole lower than the bottom surface of a fish tank, The water level control tube can be easily cleaned by cleaning and dismounting the water level control pipe during the cleaning of the both tones. Further, in the process of draining the water in the both tone tanks, the fish is prevented from being swept out of the water and discharged to the outside, The present invention relates to a fish farm which can minimize the damage of a fish.

Fish farms are places where fish are raised and breed artificially with certain facilities.

In fish farms, solid matter is continuously generated by fish feces, secretions, and residual feed, and these solid matter immediately harms fish gills or is converted into toxic substances such as ammonia and nitrous acid by coexisting microorganisms, Not only does it harm health, it consumes dissolved oxygen quickly, and it causes the growth of harmful pathogens and green algae. They all interfere with the growth of the fish and can lead to the death of fish if severe.

In order to minimize the problems caused by the solid substances generated in the fish farms, various means such as treatment of water in the bilingual tank have been proposed, and a method of continuously replacing the water has been widely known. That is, water is constantly introduced into the both tones, and the water in both tones is continuously discharged through the drainage means of the aquarium, thereby minimizing the accumulation of the generated solid matter.

For this continuous water change, fish farms should be installed near the beach.

In the fishery where water is continuously replaced, seawater continuously flows into the fish tank, and after staying in the fish tank for a period of time, it is discharged to the outside through the drainage means of the fish tank and discharged to the sea again.

However, during the process of constant water exchange, water level control in both tones is required depending on the amount of fish or the temperature of the water. Furthermore, it is necessary to periodically clean the bottom surface of the fish tank in order to remove the sediment that has settled on the bottom of the fish tank during the water exchange.

In addition, during the process of discharging the water introduced into the fish tank through the drain port, the fish may be swept away by the flow of the water and may be discharged to the outside. Furthermore, the fish may be hit by the water flow, Problems arise.

Therefore, in order to solve problems caused by continuous water replacement, technological features for water level control and water quality management are urgently needed.

(Patent Document 1) KR10-2016-0026536 A

In order to solve the problem of the conventional technology described above, the water level in the two tone tones can be easily adjusted during the continuous replacement of the water in the both tone tones for water quality management, and further, We propose a fish farm.

Also, we propose a fish farm which can minimize the damage of fish that can occur during the continuous water exchange.

In order to solve the above problem, the fish farm according to the present invention comprises: a bilingual fish tank 100 in which water is contained; An inner drain hole 220 through which the water of the both tone tanks 100 is drained in a state of being formed on the bottom surface of the both tone tones 100; An internal drain pipe 240 formed at a predetermined height on a bottom surface of the drain pipe 100; The water drained to the inner drain hole 220 is discharged to the outside while the water discharged from the inner drain hole 220 is positioned outside the both tone holes 100, (320); And a water level control pipe 340 mounted in a state of being connected to the external discharge hole 320 and formed at a predetermined height from the external discharge hole 320. The internal drain pipe 240 is provided with a plurality of flow holes And the water in both the tone holes 100 is drained to the inner drain hole 220 through the plurality of flow holes 242.

Preferably, the level control tube 340 includes a side flow closing portion 342 formed at a predetermined height at a lower end in a state where the lower end communicates with the external discharge hole 320 and the side surface is closed; A side flow opening (344) connected to an upper end of the side flow closing part (342) and formed at a predetermined height upward from the side flow closing part (342) with one side of the side open; And a water level adjusting portion (348) vertically movable inside the side flow closing portion (342) and the side flow opening portion (344), and the upper end of the side flow closing portion (342) 100), and a gap 348a continuous from the lower end to the upper end in the vertical direction is formed on the side surface of the water level adjusting part 348, so that the diameter of the water level adjusting part 348 can be adjusted Do.

Preferably, the level control pipe 340 further includes a support 346 connecting the one end edge and the other end edge of the open side of the side flow opening part 344 in the horizontal direction, The support base 346 has a shape corresponding to the shape of the outer surface of the water level adjusting part 348 so that the water level adjusting part 348 can move up and down inside the side flow opening part 344, The maximum height of the upper end of the water level adjusting portion 348 which can start from the top of the side flow closing portion 342 and climb up while closing the side surface of the side flow opening portion 344, Is lower than the height of the wall.

Preferably, a plurality of blocks 400 are spaced apart from the inner drain pipe 240 at predetermined intervals, and are disposed in the form of surrounding the inner drain pipe 240.

The buoyancy member 500 is moved along the outer surface of the inner drain pipe 240 while being in contact with the outer surface of the inner drain pipe 240 while being floated on the water contained in the both tone pipes 100, Wherein the diameter of the buoyancy member (500) is larger than the diameter of the flow hole (242), and the brush is mounted on the buoyancy member (500).

Due to the above-mentioned problem, the level of the water level control pipe can be moved up and down in a normal situation, so that the water level in the both sound levels can be easily adjusted. Furthermore, the bottom surface of the aquarium is always maintained at a constant level by the side flow closed pipe, so that the risk of the water being completely discharged even if the amount of water discharged is larger than the inflow amount.

In addition, when it is desired to remove solid matter or water deposits accumulated on the bottom surface of the tank, the water level control pipe is detached from the external discharge hole, so that the water in both the tank can be discharged to the outside by gravity. At this time, as the water is discharged naturally to the outside by gravity, the solid matter accumulated on the bottom surface of the water tank can be swept away by water and can be easily discharged.

Further, by disposing a plurality of blocks around the inner drain pipe, water can be drained to the inner drain pipe, which can weaken the rotating flow of water generated in the direction of the drain pipe. Fish sweeps can be minimized.

In addition, the water bump attached to the outer surface of the water pipe can be automatically removed by the buoyancy member continuously moving along the outer surface of the water pipe while contacting the outer surface of the water pipe.

1 is a view schematically showing a fish farm in accordance with the present invention.
FIG. 2 is an exploded view of a fish farm according to the present invention. FIG.
3 is a view showing a state in which the water level control pipe is engaged and a state in which it is disassembled.
4 is a view schematically showing a process of adjusting the water level of a fish tank by a water level adjusting pipe.
FIG. 5 is a view showing a state in which the rotated flow of water generated as the water is drained to the internal drain pipe is minimized by a plurality of blocks.
6 is a view showing a buoyancy member which moves along the outer surface of the inner drain pipe and removes the water stuck to the outer surface of the inner drain pipe.

Hereinafter, preferred embodiments of the method according to the present invention will be described with reference to the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user or operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

Will be described with reference to Figs. 1 to 6. Fig.

The fish farm according to the present invention includes the fish tank 100, the inner drain hole 220, the inner drain pipe 240, the outer drain hole 320, the level control pipe 340, the block 400 and the buoyancy member 500 .

The water is continuously introduced into the both-tone sound source 100 through the inlet pipe 10. The fish is placed in the water in the bilingual tone 100. The positive tone (100) is formed as a wall having a constant height.

An inner drain hole 220 through which the water is drained is formed on the bottom surface of the both-tone sound source 100. And is continuously drained to the inner drain hole (220).

The inner drain pipe 240 is connected to the inner drain hole 220 to form a drain pipe 240 at a predetermined height on the bottom surface of the both tone pipes 100. When the water is directly drained to the inner drain hole 220, the water leaks to the inner drain hole 220, so that the fish is swept toward the inner drain hole 220 in the flow of water. The fish may be discharged to the outside through the inner drain hole 220.

Even if the screen is installed in the inner drain hole 220, the water still leaks out and the fish will be swallowed by the flow of the water and be damaged in the state where it is caught in the inner drain hole 220. Further, So that the water can not be drained smoothly.

Therefore, it is preferable that an internal drain pipe 240 formed at a predetermined height is installed in the internal drain hole 220 in order to smooth drainage of water and to minimize the tilting of water. Water is drained through the plurality of flow holes 242 formed in the inner drain pipe 240. The flow of water can be dispersed through the plurality of flow holes 242 formed in the inner drain pipe 240 formed at a predetermined height, thereby minimizing the deflection of the water.

It goes without saying that the inner drain pipe 240 can be mounted to or detached from the inner drain hole 220.

It is a matter of course that the plurality of flow holes 242 formed in the inner drain pipe 240 can be changed according to the size of the fish. It is a matter of course that the size of the flow hole 242 should be smaller than the size of the fish. It is prevented that the fish is swept away by the flow of the water and flows out to the internal drain pipe 240.

The outer surface of the inner drain pipe 240 is preferably in the form of a gentle curve without protruding portions. So as to minimize damage to the fish when the fish is brought into contact with the inner drain pipe 240.

The outer discharge hole 320 is communicated with the inner discharge hole 220. The water drained into the inner drain hole 220 is discharged to the outside through the outer drain hole 320.

The external discharge hole 320 is positioned lower than the bottom surface of the both tone grooves 100. [ In order to clean the bottom surface of both the tone pipes 100, water is naturally discharged to the external discharge hole 320 through the inner drain hole 220 by gravity. The water in the both tone tanks 100 is discharged to the external discharge hole 320 and the solid matter or water gaps accumulated on the bottom surface of the both tone tanks 100 are swept by the water and discharged to the outside together with the water. The inner drain pipe 240 can be detached from the inner drain hole 220 at the time of cleaning.

Will be described with reference to Figs. 3 and 4. Fig.

And the water level control pipe 340 is connected to the external discharge hole 320 in a communicated state. The water level control pipe 340 is formed at a predetermined height from the external discharge hole 320. The water discharged to the external discharge hole 320 flows into the water level control pipe 340.

The height of the water level control pipe 340 at which the water is discharged to the outside is equal to the water level at the both tone levels. Accordingly, the water level of both the tone levels can be adjusted by adjusting the height of the water level control pipe 340 to discharge the water to the outside. In the state where the water level control tube 340 is not mounted, since the external discharge hole 320 is lower than the sea surface of both the tone holes 100, the entire water in both the tone holes 100 is discharged to the outside (FIG. Reference).

The water level control pipe 340 includes a side flow closing portion 342 constituting the lower portion, a side flow opening portion 344 constituting the upper portion, and a water level adjusting portion 348 capable of moving up and down.

The lower end of the side flow closing portion 342 communicates with the outer discharge hole 320, the side surface is closed, and the upper end is connected to the side flow opening portion 344. [ The lateral flow closing portion 342 is formed at a predetermined height at the lower end.

The upper end of the side flow closing portion 342 is higher than the height of the bottom surface of both the tone holes 100. Accordingly, when the water is discharged through the upper end of the side flow closing part 342, the water tank 100 maintains the water level corresponding to the height of the upper end of the side flow closing part 342. That is, in the state where the water level control tube 340 is mounted on the external discharge hole 320, the water level of both the tone pressure chambers 100 is maintained at a higher level than the bottom surface due to the side flow closing portion 342. The water is completely discharged from both the tone holes 100 in any case in the state where the water level control pipe 340 is attached to the external discharge hole 320 so that an accident that the fish is killed does not occur (see (c) of FIG. 4) .

The side flow opening portion 344 is connected to the upper end of the side flow closing portion 342 so that one side of the side opening portion is open. And is formed at a constant height in the upward direction from the side flow closing portion 342. The water flowing into the side flow closing portion 342 through the external discharge hole 320 is discharged from the side flow opening portion 344 as long as the side flow opening portion 344 is not closed by the water level regulating portion 348 And flows out to the outside. The lower end of the side flow opening 344 is the upper end of the side flow closing portion 342 (see Fig. 4 (c)).

The water level regulating portion 348 is moved up and down inside the side flow closing portion 342 and the side flow opening portion 344. It is a matter of course that the water flows into the water level adjusting part 348.

The water flows into the water level control pipe 340 while the water level control pipe 340 is attached to the external discharge hole 320. The water is discharged to the upper end of the side flow closing portion 342 if the water level adjusting portion 348 does not close the upper end of the side flow closing portion 342 while the water flows upward through the side flow closing portion 342 (See Fig. 4 (c)). When the water level adjusting portion 348 closes the upper end of the side flow closing portion 342, the water flows upward to the upper end of the water level adjusting portion 348 and is discharged to the outside.

The vertical length of the water level regulating portion 348 is longer than the vertical length of the lateral flow closing portion 342. Therefore, even when the lower end of the level regulating portion 348 is positioned at the lower end of the side flow closing portion 342, the upper end of the level regulating portion 348 is positioned above the upper end of the lateral flow closing portion 342.

However, if the upper end of the side flow closing portion 342 is open with the water level regulating portion 348 being moved to the inside of the side flow opening portion 344 through the inside of the side flow closing portion 342, Regardless of the position of the portion 348, the water flows to the upper end of the side flow closing portion 342 and is discharged to the outside.

Therefore, when it is desired to keep the water level of the both tone sets 100 to a minimum, it is possible to open the upper end of the side flow closing portion 342 with the water level adjusting portion 348 raised. When the water level of the bilingual tone 100 is increased by a predetermined height or more, the upper end of the side flow closing portion 342 is closed by the water level adjusting portion 348 and the water level adjusting portion 348 is moved up and down So that the water level of both the tone signals 100 can be adjusted (see FIG. 4 (b)).

On the side surface of the water level adjusting portion 348, a continuous gap 348a is formed in the vertical direction from the lower end to the upper end. Thus, the diameter of the water level adjusting portion 348 can be adjusted.

The water level adjusting portion 348 is moved upward and downward inside the side surface flow closing portion 342 and the side surface flow opening portion 344 and is moved only when a constant force is applied and when the force is not applied, It is preferable to keep it in a stopped state.

The gap 348a is narrowed so that the diameter of the water level regulating portion 348 becomes small so that the side flow closing portion 342 and the side flow opening portion 344 As shown in Fig.

The frictional force is increased inside the side flow closing portion 342 and the side flow opening portion 344 as the gap 348a of the water level adjusting portion 348 made of a material having a constant elasticity is held in the state where the force is not applied The vertical movement is limited.

The water level control pipe 340 further includes a support 346 connecting the one end edge and the other end edge of the open side of the side flow opening part 344 in the horizontal direction. The support stand 346 has a shape corresponding to the shape of the outer surface of the water level adjusting portion 348 so that the water level adjusting portion 348 can move up and down inside the side flow opening portion 344.

The water is discharged to the outside through the upper end of the water level adjusting part 348 in a state where the water level adjusting part 348 is located at a certain position. A force due to the flow of the water is applied to the water level adjusting portion 348. [ The support member 346 supports the force receiving portion 348 which receives this force so as not to come off from the inside of the side flow closing portion 342 and the side flow opening portion 344. The shape of the supporter 346 corresponds to the shape of the outer surface of the water level adjusting portion 348 so that a constant force is applied and the water level adjusting portion 348 can be moved up and down.

The maximum height of the upper end of the level adjusting portion 348 which can rise from the top of the side flow closing portion 342 to the side surface of the side flow opening portion 344 while closing the side surface of the side flow opening portion 344, Lt; RTI ID = 0.0 > a < / RTI > When the height of the water level control unit 348 is higher than the height of the wall, the water level in the both tone sets 100 corresponds to the height of the upper end of the water level control unit 348, causing water to be discharged to the outside through the wall.

A plurality of blocks 400 are positioned at a predetermined distance from the inner drain pipe 240 at a predetermined distance from the inner tone pipe 100 and are disposed in the form of surrounding the inner drain pipe 240. The water flows toward the inner drain pipe 240, and a rotated flow of water is generated. Increase water flow rate. As a result, the fish can be swept into the water flow, and the fish can hit the internal drain pipe 240, so that damage to the fish may occur.

A plurality of blocks 400 are positioned a certain distance from the inner drain pipe 240 to minimize the flow rate of water caused by the rotated flow of water. As the rotated flow of water reaches the inner drain pipe 240 and is blocked by the block 400, the flow rate of water is mitigated. To minimize the swelling of the fish by mitigating the flow rate of water as the water is rotated.

It is preferable that the block 400 is located in the form of surrounding the internal drain pipe 240. So as to mitigate the overall flow of water around the entire circumference of the inner drain pipe 240. And in a state in which it is not arranged on the other side, the water leaks to the other side largely.

The buoyancy member 500 is moved along the outer surface of the inner drain pipe 240 while being in contact with the outer surface of the inner drain pipe 240 while being floated on the water contained in the both tone pipes 100, Is larger than the diameter of the flow hole (242). Accordingly, the buoyancy member 500 is not allowed to flow into the flow hole 242 and is moved along the outer surface of the inner drain pipe 240. A brush is mounted on the buoyancy member (500).

The water in both the tone holes 100 is drained through the inner drain pipe 240. As time goes on, the outer surface of the inner drain pipe (240) is attached with a water stream which flows while water flows. The water in the positive tone (100) becomes turbid by such a water course, and eventually hinders the growth of the fish. These scales should be removed periodically.

Most internal drain pipes 240 are located at the center of both tone pipes 100. There arises a problem that a human being must enter into both the tone pipes 100 in order to remove water marks adhering to the outer surface of the inner drain pipe 240.

To solve this problem, a brush is mounted on the buoyancy member 500 floating on the water. When the water in both the tone holes 100 is drained through the inner drain pipe 240, water flows in the direction of the inner drain pipe 240 so that a rotated flow of water is naturally generated.

The buoyancy member 500 floating in the water naturally moves on the rotated flow of this water. The buoyancy member 500 does not flow into the flow hole 242 and is continuously moved along the outer surface of the inner drain pipe 240 in accordance with the rotated flow of the water in contact with the outer surface of the inner drain pipe 240.

As the buoyancy member 500 moves in contact with the outer surface of the inner drain pipe 240, the brush mounted on the buoyancy member 500 rubs against the outer surface of the inner drain pipe 240, A certain amount of force is exerted on the water surface attached to the outer surface of the tube. A physical force is applied to the outer surface of the inner drain pipe 240 so that the attached water pipe is removed from the outer surface of the inner drain pipe 240 and then flows into the flow hole 242 together with the water and is discharged to the outside.

While the present invention has been described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims. It will be appreciated that embodiments are possible. Accordingly, the scope of protection of the present invention should be determined by the claims.

10: inlet pipe
100: positive tone
220: Internal drain hole
240: Internal drain pipe
320: External discharge hole
340: Level control tube
342: side flow closing portion
344: side flow opening
346: Support
348:
400: Block
500: Buoyancy member

Claims (5)

A bilingual tone 100 in which water is contained;
An inner drain hole 220 through which the water in both the tone holes 100 is drained in a state of being formed on the bottom surface of the both tone holes 100;
An internal drain pipe (240) mounted in communication with the internal drain hole (220) and formed at a predetermined height on the bottom surface of the both tone pipes (100);
The water drained to the inner drain hole 220 is discharged to the outside while the water discharged from the inner drain hole 220 is positioned outside the both tone holes 100, (320); And
And a water level control pipe (340) mounted in a state of being connected to the external discharge hole (320) and formed at a predetermined height from the external discharge hole (320)
A plurality of flow holes 242 are formed in the inner drain pipe 240,
The water in both the tone holes 100 is drained to the inner drain hole 220 through the plurality of flow holes 242,
The water level control pipe (340)
A side flow closing portion 342 formed at a predetermined height at a lower end in a state where the lower end communicates with the external discharge hole 320 and the side is closed;
A side flow opening portion 344 connected to the upper end of the side flow closing portion 342 and formed at a predetermined height upward from the upper end of the side flow closing portion 342 with one side of the side opened; And
And a water level adjusting part (348) movable up and down inside the side flow closing part (342) and the side flow opening part (344)
The upper end of the side flow closing portion 342 is higher than the height of the bottom surface of the both tone holes 100,
A continuous gap 348a is formed in the side surface of the water level adjusting part 348 from the bottom to the top in the vertical direction so that the diameter of the water level adjusting part 348 can be adjusted.
delete The method according to claim 1,
The water level control pipe 340 further includes a support 346 connecting the one end edge and the other end edge of the open side of the side flow opening part 344 in the horizontal direction,
The support base 346 has a shape corresponding to the shape of the outer surface of the water level adjusting part 348 so that the water level adjusting part 348 can move up and down inside the side flow opening part 344,
The maximum height of the upper end of the level regulating portion 348, which can rise from the upper end of the side flow opening portion 342 to the level regulating portion 348 while closing the side surface of the side flow opening portion 344, Lower than the height of the wall forming the positive tone (100).
The method according to claim 1,
A plurality of blocks 400 are spaced apart from the inner drain pipe 240 at predetermined intervals and are positioned in the form of surrounding the inner drain pipe 240.
5. The method of claim 4,
And a buoyancy member (500) moving along the outer surface of the inner drain pipe (240) in contact with the outer surface of the inner drain pipe (240) in a floating state on the water contained in the both tone pipes (100)
The diameter of the buoyancy member (500) is larger than the diameter of the flow hole (242)
And a brush attached to the buoyancy member (500).

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