KR20210026624A - Aquaculture tank for seahorse fry - Google Patents

Abstract

The present invention relates to a seahorse fry aquaculture tank. The present invention comprises: an aquaculture tank with an open-top, in which seahorse fry are cultured in the interior space; and a purification tank installed to be spaced apart from the aquaculture tank and purifying breeding water discharged from the aquaculture tank, wherein the aquaculture tank comprises: a breeding chamber for breeding the seahorse fry; a drainage chamber having a drainage unit for discharging the breeding water to the purification tank and storing the breeding water in the breeding chamber; and a separation unit separating the breeding chamber and the drainage chamber.

Description

Aquaculture tank for seahorse fry

The present invention relates to an apparatus, and more particularly, to a culture tank for rearing hippocampus fry.

Since long ago, the sea horse has been of interest to people for its peculiar life history, such as a peculiar body shape to be viewed as a fish, and a male giving birth to an ovoid. Seahorses are bony fish belonging to the Syngnathidae family along with seadragon and pipefish, and are known to inhabit 36 species worldwide. Five species are known in Korea, including Hippocampus kuda, H. hiatrix, H. coronatus, H. mohnikei, and H. trimaculatus. It lives in seaweed and seaweed communities.

The seahorse is sensitive to the environment and has a very high mortality rate that easily causes mass mortality even with small environmental changes, and has been regarded as a difficult fish species. The most difficult and important part of hippocampal farming is to increase the survival rate of hippocampus and fry. Therefore, the present inventors have completed the present invention after research and efforts to increase the initial survival rate of fish and fry, which are important in the hippocampus culture process.

Embodiments of the present invention are intended to provide a seahorse fry culture tank capable of stably cultivating seahorses by stably purifying breeding water.

One aspect of the present invention includes a culture tank in which an upper part is open and hippocampus fry is cultured in an inner space, and a purification tank installed to be spaced apart from the culture tank, and to purify the breeding water discharged from the culture tank, the The culture tank is a breeding chamber in which the hippocampus fry is bred, a drainage chamber having a drainage unit that stores the breeding water in the breeding chamber and discharges the breeding water to the purification tank, and separates the breeding chamber and the drainage chamber. It provides a hippocampal fry aquaculture tank, which has a separating unit.

In addition, the separating unit may include a mesh plate disposed on one side of the breeding chamber and having a mesh having a predetermined size, and a blocking plate disposed to face the mesh plate and having a discharge opening.

In addition, the discharge opening may be formed at an upper end of the blocking plate and overlap at least a portion of the mesh, but may be disposed higher than the drainage unit.

In addition, the purification tank includes an inlet chamber through which the breeding water is introduced from the drainage chamber through a drain pipe, a first filtration chamber disposed adjacent to the inlet chamber, and filtering the breeding water through a plurality of filtration nets, and the first filtration A skimmer chamber disposed adjacent to the chamber, and a skimmer chamber installed adjacent to the skimmer chamber, a second filtration chamber disposed adjacent to the skimmer chamber, and connected to the second filtration chamber, and the second filtration chamber, and a return pump supplies the breeding water to the culture tank. It may be provided with a return chamber to deliver.

In addition, the second filtration chamber may have a first limit height capable of storing the breeding water, and the return chamber may have a second limit height lower than the first limit height.

The hippocampus fry culture tank according to the present invention includes a culture tank and a purification tank, respectively, and by stably maintaining and managing the level of breeding water in the culture tank and the purification tank, it is possible to stably farm the hippocampus fry.

The seahorse fry farming tank according to the present invention allows the separation unit of the farming tank to maintain a constant level in the breeding chamber and eliminates sudden changes in the level of the water level. Particularly, the separation unit includes a mesh plate and a blocking plate having an opening, so that the amount of flow and the flow direction can be set so that the breeding water can move only to the upper end of the separation unit.

In the hippocampus fry culture tank according to the present invention, the purification tank can move the breeding water without additional driving force, thereby forming a flow of the breeding water. Each plate partitioning the purification tank has a different height, and in particular, it is formed such that the height of the plate decreases according to the movement of the breeding water, so that the rearing water can be prevented from flowing backward. In addition, the purification tank has an opening for moving each chamber, and by forming a different height limit, the breeding water can stably flow.

1 is a perspective view showing a hippocampus poultry culture tank according to an embodiment of the present invention.
FIG. 2 is an exploded perspective view showing the separating unit of FIG. 1.
3 is a cross-sectional view showing the culture tank of FIG. 1.
4 is a plan view showing the purification tank of FIG. 2.
5 is a cross-sectional view showing the purification tank of FIG. 2.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will become apparent with reference to the embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various forms different from each other, and only these embodiments make the disclosure of the present invention complete, and common knowledge in the technical field to which the present invention pertains. It is provided to completely inform the scope of the invention to the possessor, and the invention is only defined by the scope of the claims. Meanwhile, terms used in the present specification are for explaining embodiments and are not intended to limit the present invention. In this specification, the singular form also includes the plural form unless specifically stated in the phrase. As used herein, "comprises" and/or "comprising" refers to the presence of one or more other components, steps, actions and/or elements in which the recited component, step, operation and/or element is Or does not preclude additions. Terms such as first and second may be used to describe various components, but the components should not be limited by terms. The terms are used only for the purpose of distinguishing one component from other components.

FIG. 1 is a perspective view showing a hippocampal cheering tank 1 according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view showing the aquaculture tank 100 of FIG. 1.

Referring to FIGS. 1 and 2, the hippocampus fry culture tank 1 may include a culture tank 100 for farming hippocampus fry and a purification tank 200 for purifying breeding water. In the hippocampus fry culture tank 1, a supporter supports the aquaculture tank 100, and a purification tank 200 may be disposed under the supporter.

The culture tank 100 has an open top, and a hippocampal fry can be cultured in an inner space. The farming tank 100 may be extended to a certain length according to the farming size of the hippocampus fry, and the breeding water may be stored therein to a certain level, and the breeding water may circulate to the purification tank 200.

The culture tank 100 may include a breeding chamber 110, a drainage chamber 120, a separation unit 130, and a drainage unit 140.

In the breeding chamber 110, hippocampal fry may be bred in an inner space. In the breeding chamber 110, purified breeding water is introduced through the inlet valve 10. A plurality of inlet valves 10 may be provided to correspond to the number of breeding chambers 110.

The number of breeding chambers 110 is not limited to a specific number, and may be set according to the size of the hippocampal fry tank 1. For example, in FIG. 1, the breeding chamber 110 is shown as having a first breeding chamber 111 and a second breeding chamber 112, that is, two, but is not limited thereto, but may be set to a single number or a plurality of three or more. .

The breeding chamber 110 has an open top. Each inlet valve 10 is installed in the first breeding chamber 111 and the second breeding chamber 112 so that breeding water may be injected through the inlet valve 10.

The drainage chamber 120 is disposed adjacent to the breeding chamber 110 and may store a preset amount of breeding water for drainage. The drainage chamber 120 may include a drainage unit 140 for storing the breeding water introduced from the breeding chamber 110 and discharging the breeding water to the purification tank 200.

The drainage chamber 120 is spatially separated from the breeding chamber 110 by the separation unit 130. When the breeding water stored in the breeding chamber 110 exceeds a certain level, it may pass through the separation unit 130 and move to the breeding chamber 110.

The drainage unit 140 is disposed inside the drainage chamber 120 and may deliver the breeding water introduced into the drainage chamber 120 to the purification tank 200. Since the drainage unit 140 is provided with a screen net 141, it is possible to primarily screen foreign substances generated during aquaculture.

3 is an exploded perspective view showing the separation unit 130 of FIG. 1.

2 and 3, the separation unit 130 spatially separates the breeding chamber 110 and the drainage chamber 120. The separation unit 130 may include a mesh plate 121 and a blocking plate 122. The mesh plate 121 and the blocking plate 122 are disposed to face each other. In one embodiment, the mesh plate 121 and the blocking plate 122 may be substantially attached to each other.

The mesh plate 121 is disposed on one side of the breeding chamber 110. The mesh plate 121 may include a mesh 121b having a mesh having a predetermined size. In addition, it may include a frame (121a) disposed at the edge of the net (121b) to support the net (121b). The net (121b) is a hippocampus fry

The blocking plate 122 is disposed to face the mesh plate 121. The blocking plate 122 has a discharge opening 122a partially cut away. The discharge opening 122a is formed at the upper end of the blocking plate 122 and is disposed to overlap at least a portion of the mesh 121b. The discharge opening 122a has a height of h and is disposed higher than the drainage unit 140.

The discharge opening 122a spatially connects the breeding chamber 110 and the drainage chamber 120, and breeding water may move from the breeding chamber 110 to the drainage chamber 120. In detail, when the water level of the breeding chamber 110 exceeds w, the breeding water may move to the drainage chamber 120. The breeding water may move to the drainage chamber 120 through the overlapping region OR of the discharge opening 122a and the mesh 121b.

Since the discharge opening 122a has a height of w from the blocking plate 122, it is possible to control sudden changes in the water level of the breeding chamber 110 and the drainage chamber 120. Since the discharge opening 122a is disposed above the blocking plate 122, the breeding chamber 110 can maintain the water level w. Even if the breeding water flowing from the breeding chamber 110 is stopped, the breeding chamber 110 maintains the water level of w, so that the water level of the breeding chamber 110 is prevented from changing abruptly, so that the hippocampal fry can be stably reared. have.

In addition, since the discharge opening 122a is disposed above the blocking plate 122, the drainage chamber 120 can store a certain level of breeding water. The drainage unit 140 may be disposed lower than the discharge opening 122a. If only the drainage unit 140 is operated while the inflow of breeding water is suddenly stopped, the culture tank 100 cannot be stably operated. Even if the breeding water flowing from the breeding chamber 110 is stopped, the breeding water has a water level of w in the drainage chamber 120 and the drainage unit 140 is at a lower position than the discharge opening 122a, so the drainage unit 140 And it is possible to secure a spare time in which the return pump 260 can operate. That is, even if the breeding water flowing into the breeding chamber 110 is stopped, the user does not need to urgently stop the drainage unit 140 or the return pump 260 because breeding water above a certain level is stored in the drainage chamber 120. , It is possible to prevent a sudden change in water level by stopping the driving of the drainage unit 140 or the return pump 260 with ease.

FIG. 4 is a plan view showing the purification tank 200 of FIG. 2, and FIG. 5 is a cross-sectional view showing the purification tank 200 of FIG. 2.

Referring to FIGS. 4 and 5, the purification tank 200 may purify the breeding water introduced from the aquaculture tank 100, and then return the breeding water to the farming tank 100 again.

The purification tank 200 may include an inlet chamber 210, a first filtration chamber 220, a skimmer chamber 230, a second filtration chamber 240, and a return chamber 250.

The inlet chamber 210 may flow breeding water from the drain chamber 120 into the drain pipe 20. The inlet chamber 210 has a cover 211 disposed thereon, and the broth water may be introduced through the drain pipe 20 inserted into the insertion hole 212 disposed in the cover 211. The inflow chamber 210 extends to the bottom of the purification tank 200 and may be separated from the first filtration chamber 220 by a first plate 213. The first plate 213 has a height of t1 and is bent toward the first filtration chamber 220. Accordingly, breeding water can be stored up to the water level t1, and when it exceeds t1, it can be moved to the first filtration chamber 220.

The first filtration chamber 220 is disposed adjacent to the inlet chamber 210 and may include a plurality of filtration nets 220a. A plurality of filtering nets 220a are disposed on one side of the first plate 213, and breeding water passing through the filtering net 220a may move downward.

In the first filtration chamber 220, a storage space is formed by the first plate 213 and the second plate 222. The second plate 222 is formed to protrude from the first plate 213 to a height t2. Since the second plate 222 forms a protruding portion of t2, it is possible to prevent the breeding water from passing directly from the inflow chamber 210 to the skimmer chamber 230. That is, the portion of the second plate 222 protruding to the height t2 may guide the movement of the breeding water to the first filtration chamber 220.

The second plate 222 extends downward and is installed to be spaced apart from the bottom of the purification tank 200 to a height of O1. That is, the second plate 222 forms an opening through which the breeding water having a height of O1 can move. Accordingly, the breeding water that has passed through the filtering net 220a may move downward and then pass through an opening having an O1 size to be introduced into the skimmer chamber 230.

The skimmer chamber 230 is disposed adjacent to the first filtration chamber 220, and a skimmer 230a may be installed. The skimmer 230a may be a skimmer typically used in a water tank. The skimmer chamber 230 may remove proteins remaining in the breeding water.

The second filtration chamber 240 is disposed adjacent to the skimmer chamber 230, and a filtration medium 240a may be installed. The filter medium 240a may be a filter medium commonly used in a water tank. The filter medium may finally filter and purify the breeding water that has passed through the skimmer chamber 230.

The return chamber 250 is connected to the second filtration chamber 240, and the return pump 260 may deliver the breeding water to the aquaculture tank 100. The return chamber 250 stores the breeding water that has passed through the second filtration chamber 240, and the breeding water flowing from the return pump 260 is delivered to the aquaculture tank 100 through the discharge pipe 261. The return pump 260 may be used as a conventional pump used in a water tank.

A third plate 235 and a fourth plate 236 are provided between the skimmer chamber 230 and the second filtration chamber 240 to form a flow path through which breeding water moves. That is, the breeding water may move to the spaced space between the third plate 235 and the fourth plate 236. In particular, the capillary phenomenon formed between the third plate 235 and the fourth plate 236 allows the breeding water to move easily and quickly.

The third plate 235 is installed to be spaced apart by O2 from the bottom of the purification tank 200, so that the breeding water that has passed through the skimmer chamber 230 passes through the opening at the height of O2, and the third plate 235 and the fourth plate After ascending to the space between 236, it can be moved to the second filtration chamber 240.

The size of O2 may be formed to be smaller than the size of O1. Since the size of O2 is smaller than O1, a high pressure is applied to O2, so that the breeding water can quickly move from the skimmer chamber 230 to the second filtration chamber 240 at a strong flow rate.

Since the third plate 235 has a height of t3, a limit flow rate of the skimmer chamber 230 may be set. Since t3 is formed smaller than t2, it is possible to prevent backflow of breeding water from the skimmer chamber 230 to the inflow chamber 210. In addition, since t3 is formed larger than t4 of the fourth plate 236, it is possible to prevent the rearing water from flowing backward from the second filtration chamber 240 to the skimmer chamber 230.

Since the fourth plate 236 has a height of t4, a limit flow rate of the second filtration chamber 240 may be set. That is, the second filtration chamber 240 may have a first limit height capable of storing breeding water.

A fifth plate 245 and a sixth plate 246 may be installed between the second filtration chamber 240 and the return chamber 250 to form a flow path through which the breeding water moves. That is, the breeding water may move to a space spaced apart between the fifth plate 245 and the sixth plate 246. In particular, the capillary phenomenon formed between the fifth plate 245 and the sixth plate 246 allows the breeding water to move easily and quickly.

The fifth plate 245 is installed to be spaced apart by O3 from the bottom of the purification tank 200, and the breeding water that has passed through the second filtration chamber 240 passes through an opening having a height of O3. Thereafter, after the breeding water rises into the space between the fifth plate 245 and the sixth plate, it may move to the return chamber 250. The size of O2 may be formed substantially the same as the size of O3.

Since the fifth plate 245 has a height of t3, a limit flow rate of the second filtration chamber 240 may be set. Since t3 is set higher than t5 of the sixth plate 246, it is possible to prevent the rearing water from flowing backward from the return chamber 250 to the second filtration chamber 240.

Since the sixth plate 246 has a height of t5, a limit flow rate of the return chamber 250 may be set. That is, the return chamber 250 may have a second limit height capable of storing breeding water.

The second limit height t5 may be set lower than the first limit height t4. Due to the difference in height between the first limit height t4 and the second limit height t5, the breeding water may naturally move from the second filtration chamber 240 to the return chamber 250. That is, since the second limit height t5 is lower than the first limit height t4, the breeding water can move from the second filtration chamber 240 to the return chamber 250 without an additional driving source.

The hippocampus fry culture tank 1 according to the present invention includes a culture tank 100 and a purification tank 200, respectively, and stably maintains and manages the level of breeding water in the culture tank 100 and the purification tank 200. Seahorse fry can be cultivated stably.

The hippocampus fry culture tank 1 according to the present invention allows the separation unit 130 of the culture tank 100 to maintain a constant water level in the breeding chamber 110 and eliminates sudden water level changes. In particular, the separation unit 130 includes a mesh plate 121 and a blocking plate 122 having an opening, so that the amount of flow and the flow direction may be set so that the breeding water can move only to the upper end of the separation unit 130.

In the hippocampus fry culture tank 1 according to the present invention, the purification tank 200 moves the breeding water without an additional driving force, thereby forming a flow of the breeding water. Each plate partitioning the purification tank 200 has a different height, and in particular, it is formed such that the height of the plate decreases according to the movement of the breeding water, so that the breeding water can be prevented from flowing backward. In addition, the purification tank 200 has an opening for moving each chamber, and forms different heights of limits so that breeding water can stably flow.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it is possible to make various modifications or variations without departing from the spirit and scope of the invention. Therefore, the scope of the appended claims will include such modifications or variations as long as they fall within the gist of the present invention.

1: seahorse fry fish tank
100: aquaculture tank
110: breeding chamber
120: drainage chamber
130: separation unit
140: drain unit
200: purification tank

Claims (5)

Aquaculture tank in which the upper part is open and hippocampal fry is cultured in the inner space; And
It is installed to be spaced apart from the aquaculture tank, a purification tank for purifying the breeding water discharged from the aquaculture tank; includes,
The aquaculture tank is
A breeding chamber in which the hippocampus fry is bred;
A drainage chamber having a drainage unit for storing the breeding water in the breeding chamber and discharging the breeding water to the purification tank; And
A separation unit for separating the breeding chamber and the drainage chamber; comprising, a hippocampus poultry tank. The method of claim 1,
The separation unit
A mesh plate disposed on one side of the breeding chamber and having a mesh having a predetermined size; And
A blocking plate disposed to face the mash plate and having a discharge opening; including, a hippocampal cheering tank. The method of claim 2,
The discharge opening is formed on the upper end of the blocking plate, overlapped with at least a portion of the net, and disposed higher than the drainage unit, the hippocampus cheering tank. The method of claim 1,
The purification tank
An inlet chamber through which the breeding water is introduced from the drain chamber through a drain pipe;
A first filtration chamber disposed adjacent to the inflow chamber and filtering the breeding water through a plurality of filtration nets;
A skimmer chamber disposed adjacent to the first filtration chamber and installed with a skimmer;
A second filtration chamber disposed adjacent to the skimmer chamber and installed with a filter medium; And
A return chamber connected to the second filtration chamber and configured to deliver the breeding water to the culture tank by a return pump. The method of claim 4,
The second filtration chamber has a first limit height capable of storing the breeding water,
The return chamber has a second limit height lower than the first limit height, hippocampal cheering tank.

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