KR20220041380A - sea water supply system for aquaculture farm of land base - Google Patents

Abstract

The present invention relates to a seawater supply system for a land-based aquaculture farm, and more particularly, to a seawater supply system which removes foreign substances in seawater supplied to a land-based aquaculture farm and at the same time, generates fine oxygen bubbles or ozone bubbles in seawater, to increase the amount of dissolved oxygen in seawater and kill harmful bacteria.

Description

Sea water supply system for aquaculture farm of land base

The present invention relates to a seawater supply system for onshore aquaculture, and more particularly, removes foreign substances in seawater supplied to onshore farms and at the same time generates fine oxygen bubbles or ozone bubbles in seawater to increase the dissolved oxygen content of seawater and kill harmful bacteria It relates to a seawater supply system that can make

In recent years, with the spread and development of aquaculture technology for the stable securing of aquatic resources, land aquaculture farms for cultivating fish and shellfish on land by drawing in seawater have been widely distributed.

These farms artificially culture fish and shellfish while supplying feed after storing seawater inside the aquaculture tank. For onshore aquaculture, a seawater supply system that installs an intake pipe in the sea and supplies seawater to the onshore farm through the intake pipe is essential.

In order to stably supply clean seawater, it is necessary to remove foreign substances such as mud and harmful bacteria in the seawater taken in. Various harmful organisms such as pathogens and pathogens exist in natural seawater in Korea, and these harmful organisms can have a fatal effect on farmed fish. Moreover, when humans reproduce fish and shellfish exposed to harmful bacteria, it can cause serious harm to the human body.

Korean Utility Model Registration No. 20-0383104 discloses a filtration system for aquaculture.

The filtration system for aquaculture is supplied to a filtration tank filled with a filter medium to supply seawater to filter the seawater and then supplied to the aquaculture tank. Such a filtration system has the advantage of removing foreign substances in seawater, but has a problem in that it cannot remove harmful bacteria in seawater. In addition, when the amount of dissolved oxygen in seawater is low, the amount of dissolved oxygen cannot be increased.

In addition, since the filtration system uses seawater taken in during backwashing as backwashing water, there is a problem in that the effect of backwashing is greatly reduced by foreign substances contained in the seawater.

Republic of Korea Registered Utility Model No. 20-0383104: Filtration system for aquaculture

The present invention was created to improve the above problems, and at the same time remove foreign substances in seawater supplied to land aquaculture farms, and at the same time generate fine oxygen bubbles or ozone bubbles in seawater to increase the dissolved oxygen content of seawater and kill harmful bacteria. Its purpose is to provide a supply system.

In addition, an object of the present invention is to provide a seawater supply system excellent in backwashing effect because backwashing of a filter medium is performed using filtered seawater as washing water.

The seawater supply system for onshore aquaculture of the present invention for achieving the above object includes: a filtration tank having a seawater inlet pipe connected thereto; a perforated plate installed inside the filtration tank to be spaced apart from the bottom of the filtration tank and having a plurality of through-holes formed therein; a filter unit formed by laminating a filter material on the upper portion of the perforated plate and configured to remove foreign substances in seawater flowing into the filtration tank through the seawater inlet pipe; fine bubble generating means for generating oxygen bubbles or ozone bubbles in the filtered water discharged through the filtered water discharge pipe connected to the lower part of the filtering tank; backwashing means for washing the filter unit by introducing washing water into the filtration tank through a washing water inlet pipe connected to the lower part of the filtration tank; and a washing water dispersing part installed at the bottom of the filtration tank to collide with the washing water flowing into the filtration tank through the washing water inlet pipe to disperse the flow of the washing water in all directions.

A pressure sensor installed in the filtration tank to sense the pressure inside the filtration tank, and the supply of seawater through the seawater inlet pipe is stopped by the pressure value sensed by the pressure sensor, and the backwashing means is operated It further includes a control unit for doing so.

The backwash means is connected to a branch pipe branching from the filtered water outlet pipe, and is installed in a washing water storage tank in which filtered water is introduced and stored through the branch pipe, and the washing water inlet pipe connecting the washing water storage tank and the lower part of the filtration tank a washing water supply pump, which is connected to the upper side of the filtration tank, and a washing water discharge pipe through which the washing water that has passed through the filter unit is discharged; and a three-way valve for introducing it to any one of the bubble generating means.

The microbubble generating means includes a pump connected to the filtered water discharge pipe, a gas injection pipe connected to the filtered water discharge pipe to inject oxygen or ozone into the filtered water flowing into the pump, an oxygen generator connected to the gas injection pipe, and An ozone generator is provided.

The microbubble generating means further includes a gas-liquid mixing module connected to the end of the gas injection pipe and installed inside the filtered water discharge pipe, wherein the gas-liquid mixing module is connected to the gas injection pipe and has a gas outlet on the side up and down An elongated rectangular cylinder-shaped gas ejection box, an elastic film attached to the inner surface of the gas ejection box, a cutting slit formed in the elastic film to be located at the center of the gas outlet, and one side of the gas ejection box outside A first vortex induction panel coupled to the side and the other side is formed to extend a certain length in the outward direction of the gas ejection box and twisted in one direction, and the first vortex inducing panel with the gas outlet interposed therebetween is arranged in parallel with One side is coupled to the outer surface of the gas outlet box, the other side is formed to extend a predetermined length in the outward direction of the gas outlet box, and a second vortex inducing panel formed by twisting in the opposite direction to the first vortex inducing panel.

As described above, the present invention removes foreign substances in seawater and at the same time generates fine oxygen bubbles or ozone bubbles in seawater to increase the dissolved oxygen amount in seawater and kill harmful bacteria, so safe and clean seawater can be supplied to land aquaculture farms.

In addition, according to the present invention, a portion of the filtered seawater is stored and used as washing water during backwashing of the filter unit, so that the cleaning effect of the filter unit is excellent.

1 is a block diagram of a seawater supply system for onshore aquaculture according to an example of the present invention;
Figure 2 is a cross-sectional view showing the inside of the filtration tank applied to Figure 1,
Figure 3 is a cut-away perspective view showing the main part of the filtration tank applied to Figure 1,
4 is a cross-sectional view taken from the main part of a seawater supply system for onshore aquaculture according to another example of the present invention;
Figure 5 is a cut-away perspective view of the main part shown in Figure 4,
Fig. 6 is a cross-sectional view of a main part shown in Fig. 4;

Hereinafter, a seawater supply system for onshore aquaculture according to a preferred embodiment of the present invention will be described in detail.

1 to 3, the seawater supply system for onshore farms of the present invention includes a filtration tank 10 to which a seawater inlet pipe is connected to the upper portion, and the filtration tank 10 so as to be spaced apart from the bottom of the filtration tank 10. A perforated plate 20 installed in the slab and formed with a plurality of through-holes, a filter unit 30 formed by laminating a filter material on the upper part of the perforated plate 20, and a filtered water discharge pipe 13 connected to the lower part of the filtration tank 10 ) to the inside of the filtration tank 10 through the fine bubble generating means 40 for generating oxygen bubbles or ozone bubbles in the filtered water discharged through the Backwashing means 50 for washing the filter unit 30 by introducing washing water, and washing water installed at the bottom of the filtration tank 10 and flowing into the filtration tank 10 through the washing water inlet pipe 15 and A washing water distribution unit 60 for dispersing the flow of washing water in all directions by collision is provided.

The filtration tank 10 has a cylindrical structure. The upper surface of the filtration tank 10 is formed to be convex upward, and the bottom surface has a structure formed to be convex downward. A support leg 19 is installed in the lower part of the filtration tank 10 and is installed to be spaced apart from the ground.

A seawater inlet pipe 11 is connected to the upper surface of the filtration tank 10 . Seawater taken from the sea through the seawater inlet pipe 11 is introduced into the filtration tank 10 . A seawater supply pump 1 for transferring seawater is installed in the seawater inlet pipe 11 . In addition, the seawater inlet pipe 11 is provided with a valve 3 for opening and closing the flow path.

A filtered water outlet pipe 13 and a washing water inlet pipe 15 are connected to the bottom of the filtration tank 10, respectively. The washing water inlet pipe 15 is located at the center of the bottom, and the filtered water outlet pipe 13 is positioned to be spaced apart from the washing water inlet pipe 15 . The filtered seawater, that is, filtered water is discharged through the filtered water discharge pipe 13 .

A perforated plate 20 and a filter unit 30 are installed inside the filtration tank 10 .

The perforated plate 20 is installed horizontally to cross the inner space of the filtration tank 10 . The perforated plate 20 is installed at a position spaced upward a predetermined distance from the bottom of the filtration tank 10 .

A plurality of through-holes 21 are formed in the perforated plate 20 . A strainer 23 is mounted in each through hole 21 .

The illustrated strainer 23 includes a hollow screw portion 24 inserted into the through hole 21 , and a locking jaw 25 formed on the upper portion of the screw portion 24 and having a larger diameter than the through hole 21 , and , is formed on the upper portion of the locking protrusion 25 and consists of a head 26 having a plurality of through slits 27 formed therein, and a fastening ring 28 screwed to the screw portion 24 .

After inserting the screw part 24 into the through hole 21 in the upper part of the perforated plate 20 and fastening the fastening ring 28 to the threaded part 24 at the lower part of the perforated plate 20, the strainer 23 is the perforated plate (20) is fixed.

The filter unit 30 serves to remove various foreign substances such as mud in the seawater flowing into the filtration tank 10 through the seawater inlet pipe 11 . The filter unit 30 is formed by laminating a filter material on the perforated plate 20 .

Examples of the media include sand, gravel, and activated carbon. For example, the filter unit 30 includes a gravel layer 31 formed by laminating gravel on the perforated plate 20 , a lower sand layer 33 formed by laminating sand on the gravel layer 31 , and a lower sand layer The activated carbon layer 35 formed by laminating activated carbon on the upper portion of (33), and an upper sand layer 37 formed by laminating sand on the activated carbon layer 35 may be formed.

The seawater flowing into the filtration tank 10 through the seawater inlet pipe 11 sequentially passes through the upper sand layer 37, the activated carbon layer 35, the lower sand layer 33, and the gravel layer 31, and various foreign substances are removed. is removed The seawater that has passed through the gravel layer 31 moves to the lower part of the perforated plate 20 through the through slit 27 of the strainer 23 and then is discharged to the outside of the filtration tank 10 through the filtered water discharge pipe 13 .

The fine bubble generating means 40 serves to generate oxygen bubbles or ozone bubbles in the filtered water discharged through the filtered water discharge pipe 13 connected to the lower portion of the filtering tank 10 . The amount of dissolved oxygen in the filtered water is increased by the microbubble generating means 40 and harmful bacteria in the filtered water are killed.

The microbubble generating means 40 includes a pump 41 connected to the filtered water discharge pipe 13, and a gas injection pipe for injecting oxygen or ozone into the filtered water flowing into the pump 41 connected to the filtered water discharge pipe 13 ( 43) and an oxygen generator 44 and an ozone generator 47 connected to the gas injection pipe 43.

The filtered water discharge pipe 13 is connected to the suction side of the pump 41 . And a gas injection pipe 43 is connected to the filtered water discharge pipe 13 . The gas injection pipe 43 is positioned between the branch pipe 51 of the backwashing means to be described later and the pump 41 . The gas supplied through the gas injection pipe 43 is injected into the filtered water discharged through the filtered water discharge pipe 13 . The filtered water into which the gas is injected is introduced into the pump 41 .

The oxygen generator 44 and the ozone generator 47 are connected to the gas injection pipe 43 by the oxygen supply pipe 45 and the ozone supply pipe 48, respectively. Valves 46 and 49 for opening and closing flow paths are installed in the oxygen supply pipe 45 and the ozone supply pipe 48, respectively. The valve 46 of the oxygen supply pipe 45 and the valve 49 of the ozone supply pipe 48 may be selectively opened, either one of them, both of them being opened, or both of them being closed.

The filtered water mixed with gas is discharged through the discharge side of the pump 41 while passing through the impeller of the pump 41 , bubbles are finely broken. As the filtered water mixed with gas passes through the pump 41 as described above, fine oxygen bubbles or fine ozone bubbles are generated in the filtered water. The filtered water from which oxygen bubbles or ozone bubbles are generated is supplied to the onshore farms.

When the valve 46 installed in the oxygen supply pipe 45 is opened, oxygen is introduced into the filtered water, and fine oxygen bubbles are generated while passing through the pump 41 . Therefore, it is possible to increase the concentration of dissolved oxygen in the filtered water supplied to the onshore farm.

And when the valve 49 installed in the ozone supply pipe 45 is opened, ozone flows into the filtered water and passes through the pump 41 to generate fine ozone bubbles. In this filtered water, various harmful bacteria and harmful organisms are killed by ozone, which has a strong oxidizing power.

On the other hand, when the filtration function of the filter unit 30 is deteriorated due to clogging of the pores between the filter media, a backwash means 50 for washing the filter unit 30 by introducing washing water into the filtration tank 10 is provided.

The backwashing means 50 is connected to a branch pipe 51 branching from the filtered water discharge pipe 13 and includes a washing water storage tank 53 in which filtered water is introduced and stored through the branch pipe 51, and a washing water storage tank 53 and The washing water supply pump 55 installed in the washing water inlet pipe 15 connecting the lower part of the filtration tank 10 and the washing water passing through the filter unit 30 connected to the upper side of the filtration tank 10 are discharged A three-way valve ( 59) is provided.

The branch pipe 51 is branched from the filtered water discharge pipe 13 . A three-way valve 59 is installed at the connection portion between the branch pipe 51 and the filtered water discharge pipe 13 . The three-way valve 59 serves to switch the flow path to introduce the filtered water into the branch pipe 51 or to the pump 41 .

When seawater is filtered, filtered water initially discharged is introduced into the branch pipe 51 and supplied to the washing water storage tank 53 . And when a certain amount of filtered water is filled in the washing water storage tank 53, the three-way valve 59 operates to switch the flow path. Accordingly, the filtered water does not flow into the branch pipe 51, but flows into the pump 41 and is supplied to the land aquaculture farm.

The washing water storage tank 53 is connected to the branch pipe 51 . Although not shown, a water level sensor may be installed in the washing water storage tank 53 . Whether the filtered water flows into the branch pipe 51 may be controlled by the water level value of the washing water storage tank 53 measured by the water level sensor. For example, when the water level in the washing water storage tank 53 reaches a set value, the three-way valve 59 closes the flow path of the branch pipe 51 and opens the flow path on the pump 41 side. And when the water level in the washing water storage tank 50 is less than the set value, the three-way valve 59 opens the flow path of the branch pipe 51 and closes the flow path on the pump 41 side.

The operation of the water level sensor and the three-way valve described above may be controlled by a controller to be described later.

The filtered water stored in the washing water storage tank 53 is used as washing water for washing the filter unit 30 . As described above, in the present invention, since the filtered water from which foreign substances are removed is used as washing water, backwashing efficiency can be increased.

The washing water storage tank 53 is connected to the filtration tank 10 by the washing water inlet pipe 15 . A washing water supply pump 55 is installed in the washing water inlet pipe 15 . And a valve 57 for opening and closing the flow path of the washing water inlet pipe 15 is installed. When the valve 57 is opened during backwashing of the filter unit 30 and the washing water supply pump 55 is operated, the washing water stored in the washing water storage tank 53 flows into the lower part of the filtration tank 10 . The washing water flowing into the lower part of the filtration tank 10 passes through the perforated plate 20 and the filter unit 30 while forming an upward flow, and at this time, as foreign substances attached to the surface of the filter media or caught in the pores of the filter media are detached, the washing water It is discharged to the outside through the washing water discharge pipe 17 together with.

As such, it is possible to prevent the filtration efficiency of the filter unit from being lowered due to backwashing of the filter unit 30 .

The pressure of the washing water flowing into the filter tank 10 through the washing water inlet pipe 15 during backwashing is very non-uniform. That is, the washing water flow is formed with a strong pressure in the inner center of the filtration tank 10 in which the washing water inlet pipe 15 is located, but the pressure of the washing water is greatly reduced in the edge region deviating from the center. In this case, the central side of the filter unit 30 is washed well, but the edge side of the filter unit 30 is not washed well.

Accordingly, the present invention is provided with a washing water dispersing unit (60) to evenly distribute the pressure of the washing water flowing into the filtration tank (10).

The washing water distribution unit 60 is installed at the bottom of the filtration tank 10 and collides with the washing water flowing into the filtration tank 10 through the washing water inlet pipe 15 to distribute the flow of the washing water in all directions. .

The washing water distribution unit 60 includes supports 61 installed at regular intervals around the washing water inlet 16, and a collision plate coupled to the supports 61 on the upper part and installed to face the washing water inlet 16 ( 63) is provided.

The supports 61 are formed at a constant height at the bottom of the filtration tank 10 . The collision plate 63 has a disk shape having a larger diameter than the diameter of the washing water inlet 16 .

The washing water flowing in through the washing water inlet 16 collides with the facing collision plate 63 and the flow is dispersed in front, back, left, and right directions. Therefore, since the flow of the washing water introduced into the filter tank 10 passes through the filter unit 30 in a widely diffused state, the pressure deviation of the washing water passing through the filter unit 30 can be greatly reduced.

Meanwhile, a pressure sensor (not shown) and a control unit (not shown) may be further provided to automatically operate the backwashing means 50 according to the pressure inside the filtration tank 10 .

The pressure sensor is installed in the filtration tank 10 to sense the pressure inside the filtration tank 10 . And the control unit stops the supply of seawater through the seawater inlet pipe 11 by the pressure value sensed by the pressure sensor and operates the backwashing means 50 .

When the pores of the filter medium are gradually clogged, the internal pressure of the filtration tank 10 rises. When the internal pressure of the filtration tank 10 exceeds a set value, the control unit operates the backwashing means.

On the other hand, as another embodiment of the present invention, the microbubble generating means may further include a gas-liquid mixing module.

4 to 6 , the gas-liquid mixing module 70 is connected to the end of the gas injection pipe 51 and installed inside the filtered water discharge pipe 13 .

The gas-liquid mixing module 70 is connected to the gas injection pipe 43 and has a gas discharge box 71 in the shape of a rectangular cylinder having a gas discharge port 73 on the side surface formed to be elongated vertically, and on the inner surface of the gas discharge box 71 . The attached elastic membrane 75, the cutting slit 77 formed in the elastic membrane 75 to be located in the center of the gas outlet 73, one side is coupled to the outer surface of the gas discharge box 71, and the other side is gas A first vortex inducing panel 81 formed to extend a certain length in the outward direction of the ejection box and twisted in one direction, and the first vortex inducing panel 81 with the gas outlet 73 interposed therebetween. is coupled to the outer surface of the gas ejection box 71 and the other side includes a second vortex induction panel 83 formed to extend a predetermined length in the outward direction of the gas ejection box 73 .

The gas injection pipe 43 passes through the filtered water discharge pipe 13 and extends inside.

The gas ejection box 71 has a hexahedral shape, and has a box structure with an empty interior. The end of the gas injection pipe 43 is coupled to the upper portion of the gas outlet box 71 . Oxygen or ozone is introduced into the gas ejection box 71 through the gas injection pipe 43 .

A gas outlet 73 is formed on the side of the gas outlet box 71 . The gas outlet 73 is formed on each of the four sides of the gas outlet box 71, one each. The gas outlet 73 is formed in the form of a long hole in the vertical direction.

An elastic film 75 is attached to the inner surface of the gas ejection box 71 . The elastic film 75 may be formed of a rubber material having excellent elasticity. A cutting slit 77 is formed in the elastic film 75 . The cutting slit 77 is elongated vertically. The cutting slit 77 may be formed by cutting the elastic film 75 with a knife. The cutting slit 77 is provided at a position corresponding to the gas outlet 73 . The vertical length of the cutting slit 77 is shorter than the vertical length of the gas outlet 73 . The position of the cutting slit 77 is formed in the elastic film so as to be located in the center of the gas outlet 73 .

When gas is introduced into the gas outlet box 71, the pressure inside the gas outlet box 71 rises, and accordingly, the cutting slit 77 is opened, and the gas passes through the gas outlet 73 to the outside of the gas outlet box 71. is ejected with And when the gas does not flow into the gas ejection box 71, the cutting slit 77 is closed by the elastic force of the elastic film.

The first vortex induction panel 81 and the second vortex induction panel 83 are arranged side by side in the left and right direction. The gas outlet 73 is positioned between the first vortex inducing panel 81 and the second vortex inducing panel 83 . The first vortex inducing panel 81 and the second vortex inducing panel 83 have a shape made by twisting a square plate by 180°. The first vortex inducing panel 81 and the second vortex inducing panel 83 are twisted in opposite directions.

The first vortex inducing panel 81 and the second vortex inducing panel 83 are arranged to form a pair on each side of the gas outlet box 71 . Accordingly, a total of four pairs of the first vortex inducing panel 81 and the second vortex inducing panel 83 are installed.

The gas discharged between the first vortex inducing panel 81 and the second vortex inducing panel 83 through the gas outlet 73 is opposite to each other by the first vortex inducing panel 81 and the second vortex inducing panel 83. As vortices in the direction are formed and collided, they diffuse around the gas ejection box 71 and are mixed with the filtered water, so that the gas-liquid mixing efficiency can be greatly improved.

Through the above-described gas-liquid mixing module 70, it is possible to mix the gas while effectively diffusing the gas in the filtered water.

As mentioned above, although the present invention has been described with reference to one embodiment, it will be understood that this is merely an example, and that those skilled in the art may make various modifications and equivalent embodiments therefrom. Accordingly, the true protection scope of the present invention should be defined only by the appended claims.

10: filtration tank 20: perforated plate
23: strainer 30: filter unit
40: micro bubble generating means 50: back washing means
60: washing water dispersing unit

Claims (5)

a filtration tank having a seawater inlet pipe connected thereto;
a perforated plate installed inside the filtration tank to be spaced apart from the bottom of the filtration tank and having a plurality of through-holes formed therein;
a filter unit formed by laminating a filter material on the perforated plate and removing foreign substances in seawater flowing into the filtration tank through the seawater inlet pipe;
fine bubble generating means for generating oxygen bubbles or ozone bubbles in the filtered water discharged through the filtered water discharge pipe connected to the lower part of the filtering tank;
backwashing means for washing the filter unit by introducing washing water into the filtration tank through a washing water inlet pipe connected to the lower part of the filtration tank;
Seawater for land aquaculture comprising a; a washing water distribution unit installed at the bottom of the filtration tank to collide with the washing water flowing into the filter tank through the washing water inlet pipe to disperse the flow of washing water in all directions; supply system. According to claim 1, wherein the supply of seawater through the seawater inlet pipe is stopped by a pressure sensor installed in the filtration tank to sense the pressure inside the filtration tank, and a pressure value sensed by the pressure sensor and a control unit for operating the backwashing means. The method of claim 1, wherein the backwash means is connected to a branch pipe branching from the filtered water discharge pipe to a washing water storage tank in which filtered water is introduced and stored through the branch pipe, and the washing water storage tank and the lower part of the filtration tank are connected A washing water supply pump installed in the washing water inlet pipe, a washing water discharge pipe connected to the upper side of the filtration tank through which the washing water that has passed through the filter unit is discharged, and the filtered water installed in the filtered water discharge pipe and discharged through the filtered water discharge pipe Seawater supply system for land aquaculture, characterized in that it comprises a three-way valve for introducing into any one of the branch pipe or the microbubble generating means. The method according to claim 1, wherein the microbubble generating means comprises: a pump connected to the filtered water discharge pipe; a gas injection pipe connected to the filtered water discharge pipe to inject oxygen or ozone into the filtered water flowing into the pump; and the gas injection pipe Seawater supply system for land aquaculture, characterized in that it has an oxygen generator and an ozone generator connected to. 5. The method of claim 4, wherein the microbubble generating means further comprises a gas-liquid mixing module connected to the end of the gas injection pipe and installed inside the filtered water discharge pipe,
The gas-liquid mixing module is connected to the gas inlet pipe and has a rectangular cylinder-shaped gas outlet box in which a gas outlet is formed in a vertical direction on a side surface, an elastic membrane attached to an inner surface of the gas outlet box, and at the center of the gas outlet A first vortex inducing panel formed by a cutting slit formed on the elastic film to position, one side coupled to the outer surface of the gas discharge box, and the other side extending a predetermined length in the outward direction of the gas discharge box and twisted in one direction; , disposed in parallel with the first vortex induction panel with the gas outlet interposed therebetween, one side is coupled to the outer surface of the gas outlet box, and the other end is formed to extend a certain length in the outward direction of the gas outlet box, and the first A seawater supply system for land aquaculture, characterized in that it comprises a second vortex inducing panel twisted in the opposite direction to the vortex inducing panel.

Images