KR20190097491A - Growing Apparatus for Macrobrachium Rosenbergii seeds - Google Patents

Abstract

Disclosed is an apparatus for farming seeds of giant river prawns. For the purpose of the present invention, the apparatus comprises: a plurality of water bath housings (100) arranged in a row and having seawater and freshwater, which are supplied from the outside, mixed therein; a cage (200) disposed inside each of the water bath housings (100) so that larvae can be introduced and prey for the larvae is included, having an upper part opened, and provided with a plurality of meshes along the circumference thereof, which are smaller than the size of the larvae and the prey; a seawater tank (300) and a freshwater tank (400) arranged at one side of each of the water bath housings (100) to supply seawater and freshwater through a seawater supply pipe (310) and a freshwater supply pipe (410) into the water bath housings (100), respectively; a sensor unit installed inside the water bath housings (100) to sense water quality environment inside the water bath; and a control unit (600) receiving information on water quality environment inside the water bath sensed by the sensor unit to control a heater disposed inside the water bath housing and opening/closing of the seawater supply pipe (310) and the freshwater supply pipe (410) in order to keep the temperature and salinity of water stored in the water bath housings at the set temperature and salinity. According to the present invention, a large quantity of larvae of giant river prawns can be made.

Description

Growing Apparatus for Macrobrachium Rosenbergii seeds}

The present invention relates to a seedling growth device of large spider shrimp. More specifically, the present invention relates to a device capable of solving stable problems of breeding water, temperature, larval escape and water quality problems, etc. of the conventional growth apparatus, and enabling stable mass production of larvae.

Shrimp is known to have about 2,500 species belonging to the shellfish, and the flavor is known to vary depending on the species. Seafood is commonly traded internationally, with shrimp being a significant resource for fisheries and aquaculture, accounting for over 17% of global seafood consumption (De Grave, Cai & Anker, 2008).

Among them, the Giant river prawn is a freshwater prawn from the genus Shrimp. It grows in subtropical areas such as Thailand and Taiwan, and is the world's largest freshwater shrimp that grows up to about 40cm and 400g in length.

It is popular as a high quality ingredient and is a major source of income for fisheries. Large-sized Shrimp is capable of growing up to 300-400g in 6-9 months and is priced at 4-60,000 won per kilogram, and has high added value. It is being actively promoted.

On the other hand, there are no patents for the production of large-sized spider shrimp seedlings in Korea.

In particular, this species requires a brackish environment, that is, a salt in the range of 5 ~ 12psu needs a special breeding device that can control this.

In addition, since high temperatures are required due to the characteristics of subtropical organisms, an apparatus capable of maintaining a range of 28 to 30 ° C. was required.

In addition, it is necessary for breeding tanks to prevent live food from exiting larval breeding tanks, and a large amount of living organisms must feed on the food and discharge the secretions and debris that occur during the larval period. Because death occurred, we needed a way to induce food to feed.

KR 10-1443851 (registered September 17, 2014)

The present invention maintains the temperature range and the salinity range of the appropriate range of water as described above, and prevents the escape of larvae by conventional water flow, as well as solves various problems such as reduced food intake due to the lack of adequate illuminance It is an object of the present invention to provide a seedling growing apparatus of a large structured shrimp.

Seedling growth device of large-sized spider shrimp is introduced.

To this end, the present invention is disposed in a plurality in a row and the water tank housing 100 is mixed with fresh water supplied from the outside; Cages 200 made of a plurality of meshes are placed in each of the plurality of the water tank housing 100 so that the larvae are stocked and the food organisms of the larvae and the upper side is open and smaller than the size of the larvae and the food organisms along the circumference. ; The seawater tank 300 provided on one side of the plurality of water tank housing 100 to be supplied to the sea water and fresh water through the sea water supply pipe 310 and the fresh water supply pipe 410 into the plurality of water tank housing 100, respectively. Fresh water tank 400; A sensor unit installed inside the plurality of tank housings 100 to sense a water quality environment in the tank; And a heater located inside the tank housing, the sea water supply pipe 310, and the fresh water so as to receive water environment information in the tank sensed by the sensor unit and maintain the temperature and salinity of water in the tank housing at a set temperature and salt. It includes a control unit 600 for controlling the opening and closing of the supply pipe 410.

The overflow pipe 110 is connected to one side of the plurality of tank housings so that drainage by natural pressure is achieved, and the drain pipe 120 is connected to the overflow pipe 110.

An aeration that can inject air into the water in the cage 200 is installed, the upper edge of the plurality of tank housings is characterized in that the LED lamp which can use the daylight of the larvae and feed organisms is installed.

The size of the mesh formed in the cage 200 is characterized in that more than 140㎛ 160㎛.

The control unit 600 controls the heater so that the temperature of the water inside the water tank housing is maintained at 28 ° C or more and 30 ° C or less, and the salinity of the seawater supply pipe 310 so that the salinity of the water in the water tank housing is 5 psu or more and 12 psu or less. And controlling the opening and closing of the fresh water supply pipe 410 and controlling the illumination of the pair of LED lamps to be 3000 lux or more.

According to the seedling growth apparatus of the large jingle shrimp of the present invention having the above configuration, various effects as follows are realized.

First, there is an advantage that can be mass-produced large larvae larvae.

Second, there is an advantage to provide a way for other shrimp and livestock to breed similar larvae (especially lobster).

Third, there is an advantage of providing a variety of seafood to domestic consumers through the development of new varieties.

Fourth, there is an advantage that can be utilized as a basic technology for RAS form.

Fifth, there is an advantage that a large amount of organisms can feed and discharge the secretions and debris generated smoothly.

Sixth, solves the problem of breeding water and maintaining the proper temperature of water, solves the problem of escape of larvae, which has been a problem in the past, solved the feeding problem through cage and feeding guide, and the hygiene through the easily replaceable cage Various effects are realized, such as increasing the castle.

1 is an overall perspective view of the seedling growth apparatus of the present inventors large large shrimp;
Figure 2 (a) shows a water tank housing which is one component of the present invention, Figure 2 (b) shows a cage which is one component of the present invention,
3 is a view showing the position of the sea water supply pipe and fresh water supply pipe,
4 is a view showing a probe and a titanium heater which is an embodiment of a sensor unit that is one component of the present invention;
5 is a view showing an overflow pipe and a drain pipe connected thereto as one component of the present invention;
6 is a view showing the inside of the tank housing which is one component of the present invention,
Figure 7 is a real photo showing the late larvae larvae produced through the present invention,
8 is a view showing an interlocking relationship between a control unit and a sensor unit which are one component of the present invention.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the seedling growth apparatus of the present invention large spider.

In describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted. Therefore, the shape of the components shown in the drawings and the like are exaggerated to emphasize a more clear description.

1 is an overall perspective view of the seedling growth apparatus of the large-sized spider shrimp of the present invention, Figure 2 (a) shows a water tank housing 100 is a component of the present invention, Figure 2 (b) is one component of the present invention Figure 7 shows the cage 200, Figure 7 shows the large larvae late larvae produced through the present invention, Figure 8 shows the interlocking relationship between the control unit 600 and the sensor unit 500, which is one component of the present invention .

As shown, the present invention includes a water tank housing 100, a cage 200, a seawater tank 300 and a fresh water tank 400, a sensor unit 500 and a control unit 600.

The water tank housing 100 is arranged in a plurality in a row and mixed with sea water and fresh water supplied from the outside.

5 are implemented in the drawings, but are not necessarily limited thereto and may be differently applied according to the facility environment or the work environment.

As shown in Fig. 1 and 2 (a), the tank housing 100 is a space for accommodating a large number of larvae to accommodate the larvae.

The water tank housing 100 is preferably made of PP (polypropylene) or ABS resin, PVC, concrete, but is not necessarily limited thereto, and may be implemented in various materials as long as the components are durable and not harmful to larvae.

Although the width of the tank housing 100 may vary according to the amount of larvae, the standard for breeding 20,000 animals may be realized as 60 cm, 90 cm, and 40 cm in height, but is not limited thereto. It is not.

Although it will be described in detail below, the water tank housing 100 is mixed with sea water and fresh water, more preferably is composed of brackish water (5 ~ 14 psu).

Referring back to Figures 1 and 2 (b) discloses a cage 200, which is one component of the present invention.

The cage 200 is formed to correspond to the shape of the tank housing 100 described above. Although generally implemented in the shape of an open rectangular parallelepiped, it is obvious that the present invention is not limited thereto and may be variously changed according to a working environment.

The cage 200 is located in the plurality of the water tank housing 100 so that the larvae are stocked and the food organisms of the larvae are opened, the upper side is open, and consists of a plurality of meshes smaller than the size of the larvae and the food organisms along the circumference.

The size of the larvae is about 400 μm at the beginning of development and Artemia, a food organism, is about 250 μm.

The mesh size formed along the circumference of the cage 200 should also be smaller than the size of these larvae and food organisms. Applicant is most efficient when the size of the mesh formed in the cage 200 is 140㎛ 160㎛ less through a number of experiments larvae and food organisms do not escape, the residue of the secretion and the remaining feed that occurs after the feeding activity of the larvae Was confirmed to fall smoothly.

Thus, in one embodiment of the present invention is characterized in that the size of the mesh formed in the cage 200 is more than 140㎛ 160㎛.

In addition, when the cage 200 is contaminated, it can be easily replaced, so that the hygienic maintenance effect can be realized.

And, the size of the late larvae grown by the present invention can be raised up to 1cm, if more than the size should be carried out in the breeding density and conditions, because the cage 200 is easy to replace labor and time Saving effect is realized.

On the other hand, the frame is formed along the upper and lower circumference of the cage 200 to support the portion consisting of a plurality of mesh. The material of the frame is preferably made of plastic, PP (polypropylene), stainless, PVC, ABS resin, acrylic, but is not necessarily limited thereto.

Referring back to FIG. 1, a seawater tank provided on one side of the plurality of tank housings 100 to be supplied with seawater and fresh water through the seawater supply pipe 310 and the freshwater supply pipe 410 into the plurality of tank housings 100, respectively. 300 and a fresh water tank 400 is disclosed.

In addition, seawater and fresh water are introduced into the water tank housing 100 by the seawater supply pipe 310 and the freshwater supply pipe 410, respectively, as shown in FIG. 3. The end is installed in the cage 200 so that clean water flows directly into the cage 200.

4 illustrates a probe 510 and a titanium heater 520, which is an embodiment of a sensor unit 500 that is one component of the present invention.

The sensor unit 500 for sensing a water quality environment in the tank is installed in the plurality of tank housings 100.

The sensor unit 500 measures the temperature of the water in the water tank, PH, dissolved oxygen, salt, and the like according to its use. Sensors for each application are of general construction and are omitted here.

At this time, the controller 600 receives the water quality environment information in the tank sensed by the sensor unit 500.

The control unit 600 controls the opening and closing of the heater, the sea water supply pipe 310 and the fresh water supply pipe 410 located inside the water tank housing to maintain the temperature and salinity of water in the water tank housing at the set temperature and salt.

However, although the heater inside the tank housing is not shown in the drawing, but is not shown as a general configuration, an underwater heater (200W or more) whose temperature can be varied according to the signal of the controller 600 is possible.

The controller 600 may check the temperature through a sensor installed for each tank housing and maintain the temperature.

As large-sized spider shrimp should be maintained at a high temperature of 28 ° C. or more and 30 ° C. or less as a subtropical shrimp, its temperature is controlled by the controller 600 through ON / OFF of the titanium heater 520.

5 is a view illustrating the overflow pipe 110 and the drain pipe 120 connected thereto as one component of the present invention.

As shown, the overflow pipe 110 is connected to one side of the plurality of water tank housing 100 so that drainage by natural pressure is achieved, and the overflow pipe 110 is connected to the drain pipe 120. It is done.

In one embodiment of the present invention, the overflow pipe 110 is installed at the front and rear of the water tank housing 100, but is not necessarily limited to the quantity.

The water in the water tank housing 100 is filled up to the position where the overflow pipe 110 is connected to the water tank housing 100, and when more water is supplied, the water is discharged to the outside by the natural pressure, the overflow pipe 110 The level is determined by the position of).

A drain pipe 120 extending to both sides is connected to a lower portion of the overflow pipe 110, and the drain pipe 120 is a pipe for draining the entire amount of water in the water tank housing 100 or purifying fresh water (purified to clean water). .

However, although not shown in the drawing, the overflow pipe 110 may be connected to seawater and freshwater tanks to recover breeding water according to the purpose, and may be implemented as a kind of circulation system.

If a particular salinity is required, the tank housing can be utilized individually, or switched to a circulating bath to raise larvae under certain salinity conditions.

6 is a view showing the interior of the water tank housing 100 which is one component of the present invention.

As shown, an aeration is installed to inject air into the water in the cage 200.

Air is supplied to the water in the cage 200 through the aeration 130 using the air stone.

On the other hand, the upper edge of the plurality of tank housing 100 is characterized in that the LED lamp 140 that can use the daylight of the larvae and feed organisms is installed.

It is desirable to use an LED lamp (daylight) to maintain the illuminance of 3,000 Lux.

Although shown in the figure installed in the front portion of the water tank housing 100, it is not necessarily limited to this position.

Through the LED lamp 140, the direction of light is biased to only one side, so that the main larvae floating larvae and prey organisms gather toward the light, thereby increasing the chance of contact between the larvae and the prey organisms. Increase your food intake.

In particular, it is possible to induce a lot of food in the larvae to promote high growth and survival rate.

More preferably, the LED lamp 140 is interlocked with the control unit 600 and adjusted at 12 hours intervals of contrast conditions.

The controller 600 controls the heater so that the temperature of the water in the water tank housing 100 is maintained at 28 ° C or more and 30 ° C or less, and the seawater supply pipe 310 so that the salinity of the water in the water tank housing 100 is 5 psu or more and 12 psu or less. And the opening and closing of the fresh water supply pipe 410.

Opening and closing of the seawater supply pipe 310 and the fresh water supply pipe 410 through the control unit 600 can be mixed and supplied to the desired ratio by the operator.

As such, the present invention solves the problem of breeding water and maintaining the proper temperature of water through the control unit 600, and solves the problem of escape of larvae, which has been a conventional problem.

In addition, the problem has been solved through the cage 200 and the food induction, etc., various effects are realized such that the hygiene is also increased through the cage 200 that can be easily replaced.

In the above description, but limited to the preferred embodiments of the present invention, but this is only an example, the present invention is not limited to this may be modified and carried out in various ways, and further technical features based on the technical spirit disclosed It will be apparent that it can be implemented in addition.

100: tank housing 200: cage
300: seawater tank 400: freshwater tank
500: sensor unit 600: control unit

Claims (5)

A water tank housing in which a plurality of water tanks are arranged in a row and mixed with fresh water supplied from the outside;
A cage made of a plurality of meshes each positioned inside the plurality of tank housings so that the larvae are stocked and include the larvae of feed organisms, the upper side of which is open and smaller than the size of the larvae and the feed organisms along a circumference;
A seawater tank and a freshwater tank provided at one side of the plurality of tank housings to be supplied with seawater and fresh water through the seawater supply pipe and the freshwater supply pipe into the plurality of water tank housings, respectively;
A sensor unit installed inside the plurality of tank housings to sense a water environment in the tank; And
Opening and closing the heater, the sea water supply pipe, and the fresh water supply pipe located inside the water tank housing to receive the water quality information in the water tank sensed by the sensor unit to maintain the temperature and salinity of the water in the water tank housing at the set temperature and salt. Seedling growth apparatus of large-sized spider shrimp which includes a control part to control. The method according to claim 1,
An overflow pipe is connected to one side of the plurality of tank housings so that drainage by natural pressure can be made, and the overflow pipe is connected to a drain pipe. The method according to claim 1 or 2,
An aeration is provided for injecting air into the water in the cage, and the upper edge of the plurality of tank housings is provided with an LED lamp for utilizing the daylight of the larvae and the feed organisms. Device. The method according to claim 3,
The size of the mesh formed in the cage is 140㎛ 160㎛ less seedling growing device of large spider prawns. The method according to claim 3,
The control unit,
The heater is controlled such that the temperature of the water inside the tank housing is maintained at 28 ° C. or higher and 30 ° C. or lower,
Controlling the opening and closing of the sea water supply pipe and the fresh water supply pipe so that the salinity of water in the tank housing is 5 psu or more and 12 psu or less,
The seedling growing apparatus of the large spider shrimp, characterized in that the illumination of the pair of LED lamps is controlled to be 3000 lux or more.

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