KR102597245B1 - Intermediate breeding device for giant river prown - Google Patents

Abstract

The present invention is a formula ( This is about an intermediate rearing device for giant shrimp postlarvae that minimizes the phenomenon of co-eating.
The present invention for achieving the above object is a growing device for intermediate rearing of large gnat shrimp postlarvae, comprising: a water tank (10) containing water for intermediate rearing of large gnat shrimp postlarvae; A plurality of vertical supports (11) installed standing upright within the water tank (10) while maintaining a distance from each other; An inclined supporter (12) installed at an angle on both sides of the vertical supporter (11) to support the vertical supporter (11) and used as a movement passage for postlarvae that are about to molt. A vegetation plate (30) is installed long in the horizontal direction between the vertical and inclined supports (11) (12) and is formed in multiple stages to provide a safe habitat for a large number of large shrimp postlarvae and enable smooth feeding activities; ; An upper screen (31) located at the top of the vegetation plate (30) and used as a molting place and refuge where large spider shrimp postlarvae that are about to molt can safely escape; It is formed on the upper part of the vertical support 11 and consists of a passage 20 for movement of workers and dropping of feed.

Description

Intermediate breeding device for giant river prawn}

The present invention relates to an intermediate growing device for shrimp postlarvae, and more specifically, for the cultivation of giant shrimp postlarvae, the size of shrimp placed in the intermediate growing device is 1 cm in length, and can be raised up to 10 cm in length. This is about an intermediate rearing device for postlarvae shrimp that, due to the nature of crustaceans, minimizes the phenomenon of being eaten by strong shrimp that have not molted when they are stuck due to lack of strength for 3 minutes immediately after molting due to the nature of crustaceans. .

Shrimp is a creature belonging to the crustacean family, and approximately 2,500 species are known to exist. Among them, giant river prawn is a freshwater shrimp of the river prawn family. It grows in tropical areas such as Thailand and Taiwan, and is a popular product sold at a high price in Southeast Asia. In particular, many tourists enjoy indoor fishing as one of the leisure activities, and it is so popular that it has been designated as a national sport in Taiwan.

These giant spider shrimp are the largest species of freshwater shrimp. Males grow to about 40 cm in length and 400 g, and females grow to about 25 cm and 200 g. They grow very quickly, reproduce prolifically, and are delicious. It is popular as a high-quality food ingredient sold at high prices, making it a major source of income for the fishing industry.

Giant snail shrimp can grow up to a maximum of 300-400g in 6-9 months, are omnivorous, require low feed costs, are resistant to diseases, and have high added value, so they are attracting attention as the next-generation aquaculture species in inland waters.

Meanwhile, giant spider shrimp grow through four stages: eggs, larvae, postlarvae, and adults. In other words, the mother shrimp spawns eggs and holds them outside the mother's abdomen, and after a certain period of time, the eggs hatch and go through a free-swimming larval stage. This stage is called the zoea stage.

When the zoea stage undergoes about 11 molts and is transformed into a post-larva, from then on it is not called a larva, but rather a seedling or postlarva, and from this point on, it can be cultured.

At this time, both the larval stage and the postlarva stage, which metamorphoses into postlarvae and finally begin farming, are completely separated from the adult stage.

In order to cultivate such large spider shrimp and grow them into commercial-size adults, an intermediate training process is required at the postlarva stage.

To this end, a lot of effort has been made to achieve seed production and industrialization of aquaculture, and many fish farmers have participated in aquaculture and have secured a certain level of technology for producing PL, but the process of raising PL from PL to adult is despite the efforts of many public research institutes as well as private fish farmers. Despite this, industrialization has not yet been achieved, and if this cause is not resolved in the future, industrialization will not be possible.

The main reason for this impossibility is the phenomenon of co-eating, in which shrimp with weakened shells are eaten by strong shrimp that have not molted immediately after molting during the molting process, which is an ecological characteristic of crustaceans. All crustaceans, including shrimp, crabs, and crayfish, undergo a certain degree of erosion as they go through the molting process. Although the giant spider shrimp is classified as a shrimp, its ecological characteristics are similar to those of crayfish, so it is most aggressive towards each other and is the most aggressive in narrow spaces. This is the entity with the most severe formal phenomenon due to active territorial fights.

In addition, the problem of water pollution caused by organic matter such as secretions and waste generated by large amounts of postlarvae eating food during the farming process also occurred.

Accordingly, there is a need for an intermediate postlarva rearing device that can minimize the pitting phenomenon of giant gnat shrimp, which made industrialization impossible, to near zero and recycle water in the tank.

Republic of Korea Patent No. 10-2297174 (registered on September 27, 2021)

Accordingly, the present invention was created to solve the above-mentioned problems, and its main purpose is to enable shrimp postlarvae with a length of 1 cm to be raised up to 10 cm in length, which are stocked in an intermediate growing farm for the cultivation of giant gnat shrimp postlarvae. At the same time, the goal is to provide an intermediate rearing device for postlarval shrimp that can minimize the phenomenon of them being eaten by other shrimp during the molting process.

Another object of the present invention is to provide an intermediate growing device for giant shrimp postlarvae, which allows a large amount of shrimp larvae to inhabit by forming a multi-stage vegetation plate inhabited by giant shrimp postlarvae.

Another object of the present invention is to darken the vegetation plate inhabited by giant spider shrimp postlarvae in accordance with their nocturnal characteristics, and to provide a light shielding film with gaps to allow water to pass through the upper and lower sections of the vegetation plate formed in multiple stages. By forming it, the purpose is to provide an intermediate breeding device for giant shrimp postlarvae that can provide a safe habitat environment for a large amount of shrimp shrimp postlarvae.

Another object of the present invention is to form a multi-stage vegetation plate so that the left and right widths become wider toward the bottom, so that the feed dropped from the passage at the top of the vegetation plate is evenly distributed on the multi-stage vegetation plate to ensure smooth feeding. The purpose is to provide an intermediate rearing device for large shrimp postlarvae that can be grown.

Another object of the present invention is to form an upper screen formed at the top of a multi-stage vegetation plate sloping downward from the center of the width to both sides, and install it so that part of the upper screen at the sloping top is submerged in water and part is exposed out of the water. The purpose is to provide an intermediate rearing device for giant shrimp postlarvae that is about to molt, which can provide a refuge for them to safely molt.

Lastly, the present invention installs a purification facility on the outside of the water tank that precipitates the organic matter contained in the discharged water, removes the organic matter, purifies it through microorganisms (biofloc), and recycles it, thereby eliminating harmful substances such as organic matter and ammonia and nitrite in the water tank. The goal is to solve the problem of water pollution caused by substances and provide an intermediate rearing device for giant shrimp postlarvae that allows recycling of water in the tank.

In order to solve the above object, the present invention, in the growing device for intermediate growing of large gnat shrimp postlarvae,

A tank filled with water for the cultivation of postlarvae; A plurality of vertical supports installed standing upright within the water tank while maintaining a distance from each other; Inclined supports are installed at an angle on both sides of the vertical support to support the vertical support, and are used as a movement path for large shrimp postlarvae that are about to molt; A plurality of vegetation plates are installed longitudinally in the horizontal direction between the vertical and inclined supports for vegetation of shrimp postlarvae; An upper screen located at the top of the vegetation plate and used as a molting area and refuge for larvae that are about to molt, where they can safely molt; It is formed on the upper part of the vertical support and consists of a passage for movement of workers and dropping of feed.

At this time, the vegetation plate installed inside the tank can cultivate a large amount of shrimp postlarvae and is formed in multiple stages to enable smooth feeding activities, but is formed at a height of 5 levels considering the water depth and the density of shrimp reared in the vegetation plate. It is desirable to do so.

In addition, the vegetation plate is formed as a light shield to provide a safe and comfortable habitat for nocturnal giant shrimp postlarvae through a dark environment.

In addition, the vegetation plate, which is installed in multiple stages, ensures smooth feed supply and visual observation of whether feed is consumed by dropping the feed downward evenly on the multi-stage vegetation plate when dropping feed downward from the passage at the top of the vertical support for worker movement and feed dropping. Make sure that the width on the left and right becomes wider toward the bottom so that you can check it. In other words, in a vegetation plate formed in multiple stages, the width at the top is narrowed, and as it moves towards the bottom, the width on both sides increases by about 30cm compared to the stage immediately above, so that it is formed like a step when viewed from the side.

In addition, the upper screen is formed to slope downward on both sides from the center of the width of the upper screen so as to provide an environment in which postlarva shrimp, which are about to molt, can safely molt, and a portion of the upper screen at the top of the slope is submerged in water. Install it so that part of it is exposed to the water.

At this time, the inclination angle, which is formed sloping downward from the center of the width of the upper screen to both sides, creates a shallow and dark environment for a large number of larval shrimp larvae during the molting process and maintains an inclination angle of 30° to provide a safe refuge.

Furthermore, on the outside of the water tank, a purification facility is installed consisting of a water channel through which the discharged water flows, a sedimentation tank to precipitate organic matter contained in the water discharged through the water channel, and a pump to purify the water from which the organic matter has been removed and supply it back into the water tank. Thus, the organic matter contained in the water discharged after use in the water tank is precipitated, the organic matter is removed, and purified with microorganisms (biofloc) so that it can be recycled.

Applying the present invention as described above has the following effects.

First, the advantage is that shrimp postlarvae of 1 cm in length, which are stocked in a medium-sized growing farm for the cultivation of giant gnat shrimp postlarvae, can be raised up to 10 cm in length, while also minimizing the phenomenon of shrimp being eaten by other shrimp during the molting process. There is.

Second, there is the advantage of providing an environment in which a large number of shrimp larvae can inhabit by forming a multi-tiered vegetation plate where large gnat shrimp larvae live.

Third, the vegetation plate where the larvae larvae live is darkened to suit their nocturnal characteristics, and it is formed with a shading film with gaps to allow water to pass through the upper and lower parts of the multi-stage vegetation plate, allowing a large amount of larvae larvae to grow. It has the advantage of providing a safe habitat environment.

Fourth, the width of the left and right sides of the multi-stage vegetation plate is widened toward the bottom, so that the feed dropped from the passage at the top of the vegetation plate can be evenly distributed to the multi-stage vegetation plate, thereby facilitating feed supply. .

Fifth, the upper screen, which is formed slanted at the top of the multi-stage vegetation plate, is formed to slope downward from the center of the width to both sides, and the upper screen at the top of the slope is installed so that part of the top screen is submerged in water and part is exposed to the outside of the water, so that large areas that are about to shed are installed. It can provide a refuge for postlarval shrimp to escape safely.

Sixth, by installing a purification facility on the outside of the water tank that precipitates the organic matter contained in the discharged water, removes the organic matter, purifies it through microorganisms (biofloc), and recycles it, thereby eliminating the harmful substances such as organic matter and ammonia and nitrite in the water tank. It can solve the problem of water pollution and recycle water in the tank.

Figure 1 is a perspective view showing an intermediate growing device for large gnat shrimp postlarvae according to the present invention.
Figure 2 is a front view showing the medium growing device for large gnat shrimp postlarvae according to the present invention.
Figure 3 is a side view showing the medium growing device for large gnat shrimp postlarvae according to the present invention.
Figure 4 is a state diagram showing the use of the large gnat shrimp postlarva intermediate growth device according to the present invention from the side.

A preferred embodiment of the present invention will be described in detail with the accompanying drawings as follows.

In the process of growing spider shrimp, an intermediate training process is necessary to grow postlarvae that have passed the larval stage into commercial-sized adults.

For this purpose, as shown in Figures 1 and 2, the intermediate rearing device for giant shrimp postlarvae according to the present invention is first equipped with a water tank 10 for cultivating giant shrimp shrimp postlarvae.

At this time, since giant shrimp generally grow and develop normally at a temperature of 28 to 32 ℃, it is most appropriate to maintain the temperature of the water filled inside the water tank 10 within the appropriate temperature range of 28 to 32 ℃.

Next, inside the water tank 10, a plurality of vertical supports 11 of a certain height are installed in the horizontal direction while maintaining a certain distance from each other.

In addition, inclined supports 12 are installed at an angle on both left and right sides of the plurality of vertical supports 11, which are installed at regular intervals, to make the vertical supports 11 supporting the multi-stage vegetation plate 30 more sturdy. It is designed to provide support and can be used as a passageway for the migration of giant shrimp larvae that are about to molt.

Next, between the vertical support (11) and the inclined support (12), a vegetation plate (30) on which large spider shrimp postlarvae can grow is installed in the horizontal direction, and both sides of the vegetation plate (30) are provided with vertical supports (11). It is tied through inclined supports (12) installed on both left and right sides to maintain a taut state without sagging.

At this time, the vegetation plate (30) on which large gnat shrimp larvae can grow is formed in multiple stages so that a large amount of larvae larvae can be cultivated, and to provide a safe habitat for the larvae and enable smooth feeding activities. Considering the density of shrimp reared on the vegetation plate 30, it is preferable to form it into 5 tiers.

In addition, the vegetation plate (30) where the larval shrimp larvae live can be darkened to suit the nocturnal larvae, and water can freely pass between the upper and lower parts of the vegetation plate (30), which is formed in multiple stages. It is formed with a shading screen with gaps to provide a safe and comfortable habitat for large numbers of postlarvae.

In addition, the vegetation plate 30 is installed in multiple stages so that when the feed is dropped downward from the passage 20 formed at the top of the vertical support 11, the dropped feed can be evenly dropped on the multi-stage vegetation plate 30. The left and right widths become wider toward the bottom. That is, in the vegetation plate 30 formed in multiple stages, the width at the top is narrowed and the width on both sides increases by about 30 cm compared to the stage immediately above as it moves toward the bottom, so that it is formed in a staircase shape when viewed from the side. .

Next, an upper screen (31) is installed at the top of the multi-tiered vegetation board (30) so that it can be used as a molting place and refuge where larval shrimp larvae that are about to molt can safely molt.

At this time, the upper screen (31) is formed to slope downward from the center of the width to both sides, and the upper screen (31) at the top of the slope is installed so that part of it is submerged in water and part is exposed out of the water, so that the postlarvae that are about to molt are safely installed. Provide a refuge from which to escape.

Next, a passage 20 is formed on the upper part of the vertical support 11 for workers to move or drop feed.

In addition, on the outside of the water tank 10, there is a water channel 41 through which the discharged water flows, a sedimentation tank 42 for precipitating organic matter contained in the water discharged through the water channel 41, and water from which the organic matter has been removed is supplied with microorganisms (bioflakes). ) is installed to purify the water and supply it back into the water tank 10. A purification device 40 consisting of a pump 43 is installed to precipitate organic substances contained in the water discharged after use in the water tank 10, thereby removing the organic substances. , purified with microorganisms (biofloc) so that it can be recycled.

A plurality of such intermediate postlarva rearing devices (1) are installed inside the aquarium (10) to enable breeding of large quantities of postlarvae.

Although it has been described above that all the components constituting the embodiments of the present invention are combined or operated in combination, the present invention is not necessarily limited to these embodiments. That is, within the scope of the purpose of the present invention, all of the components may be selectively combined into one or more to operate.

The mid-term rearing device for large shrimp postlarvae according to the present invention with such a configuration is a device for the intermediate rearing of large shrimp postlarvae that is farmed. Shrimp postlarvae with a length of 1 cm, which are stocked in an intermediate growth farm, are grown until they grow into adults with a length of 10 cm. During the stripping process, pitting phenomenon should be minimized.

According to the large spider shrimp postlarvae intermediate growing device (1) for this purpose, a plurality of multi-stage vegetation plates (30) are installed at regular intervals inside the water tank (10), and vertical supports (11) are installed on the left and right sides. It is installed so that it can be maintained in a sturdy, tight state without sagging through inclined supports (12) installed at an angle on both sides.

Once the installation of the multi-stage vegetation plate 30 inside the water tank 10 is completed through the above work, the water tank 10 is filled with water. At this time, the temperature of the water is set to 28 degrees Celsius, taking into account the optimal habitat environment for giant shrimp postlarvae. Maintain an appropriate temperature of ~32℃.

Next, a large amount of giant gnat shrimp are stocked inside the postlarva tank (10) and allowed to grow on the upper part of the multi-stage vegetation plate (30).

At this time, the vegetation plate 30 can create a dark environment through a light shield having a gap for the nocturnal giant spider shrimp postlarvae, thereby creating a safe and comfortable environment.

When the larvae are placed on the multi-stage vegetation plate 30 installed inside the aquarium 10 through the above operation, the operator creates a passage ( Drop the feed downward from 20).

When feed is dropped on the multi-stage vegetation plate 30 through the above operation, the width of the multi-stage vegetation plate 30 is formed to be wider by 30 cm on the left and right than the stage immediately above as it moves toward the lower stage, forming a staircase shape. Since it is formed, the feed dropped from the top is evenly dropped to the lower vegetation plate 30 through the edges of the multi-stage vegetation plate 30.

When feed is dropped on the edge of the multi-stage vegetation plate (30) through the above operation, the feed is concentrated in the portion formed in a step shape on the multi-stage vegetation plate (30), and large plants living between the multi-stage vegetation plates (30) are added. As the shrimp postlarvae are nocturnal and actively feed in dark places, the large spider shrimp postlarvae carry the food concentrated in the step-shaped part with their claws and enter the vegetation plate 30 to eat the food, and this is repeated. Through this process, postlarvae growing on the multi-stage vegetation plate 30 can smoothly feed.

In addition, when all the feed dropped on the step-shaped part is eaten, the operator can visually check whether the feed has been used up in the step portion, so when the feed is used up, the feed can be added again. In other words, giant spider shrimp have a habit of eating feed quietly when there is an abundance of feed, but when the feed is exhausted, they move in all directions in search of food and attack each other, which worsens the attack. It is possible to easily check with the naked eye whether feed is used up, so feed can be supplied uninterrupted, minimizing the phenomenon of overeating due to feed shortage.

On the other hand, postlarynx shrimp are unable to move for about 3 minutes immediately after molting, and at this time, they are attacked the most, causing a pitfall phenomenon. Giant shrimp shrimp instinctively know that they are in danger right after molting, so when molting is imminent, they become immobile. Instead of going deep into the water, they find a safe place as shallow as possible and move to molt. That is, the upper screen 31 at the top of the multi-stage vegetation plate 30 is formed to slope downward from the center of the width on both sides, so that part of it is submerged in water and part of it is exposed out of the water, forming a shallow and safe place to escape. The imminent giant shrimp postlarvae use the inclined supports (12) that bind both sides of the vegetation plate (30) on both left and right sides of the vertical support (11) as a passage to move through the shallow but upper screen at the top of the vegetation plate (30). Through (31), you can move to a dark place and molt safely.

In addition, most of the PL that has not molted because it is not the molting season stays deep in the water, and there are no PL that have not molted in the shallow area formed on the upper screen (31) at the top of the vegetation plate (30), so they can molt safely. After molting, the postlarvae's shells become hard after about 3 minutes, and from this point on, they are free from the pitting phenomenon. In other words, the pitting phenomenon occurs only immediately after molting, so postlarvae whose shells become hard after a certain period of time after molting never develop the pitting phenomenon.

Meanwhile, there is a risk that the water inside the tank (10) will be contaminated due to the continued supply of feed and large amounts of organic matter such as excrement from postlarvae and ammonia, nitrite, etc., and the water discharged from inside the tank (10) must be purified. After being purified through the device 40, it is supplied back into the water tank 10. That is, the water inside the water tank 10 is discharged to the water channel 41 outside the water tank 10, and the organic matter contained in the water is precipitated through the sedimentation process of the organic matter in the sedimentation tank 42, thereby removing the organic matter and forming microorganisms (bioflocs). By installing a purification facility that purifies and recycles water, it is possible to solve the problem of water pollution caused by harmful substances such as organic matter and ammonia and nitrite in the water tank, and the organic matter removed through sedimentation can be used as compost after drying.

The above description is merely an illustrative explanation of the technical idea of the present invention, and various modifications and/or variations will be possible to those skilled in the art without departing from the essential characteristics of the present invention. .

Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but rather to explain it, and the scope of the technical idea of the present invention is not limited by these examples. The scope of protection of the present invention should be interpreted solely in accordance with the claims below, and all technical ideas within the equivalent scope should be construed as being included in the scope of rights of the present invention.

1: Growth device 10: Water tank
11: vertical support 12: inclined support
20: Passage 30: Vegetation board
31: upper screen 40: purification device
41: Waterway 42: Sedimentation tank
43: pump

Claims (5)

In the rearing device for intermediate rearing of large gnat shrimp postlarvae,
A tank (10) containing water for the cultivation of postlarva shrimp;
A plurality of vertical supports (11) installed standing upright within the water tank (10) while maintaining a distance from each other;
An inclined supporter (12) installed at an angle on both sides of the vertical supporter (11) to support the vertical supporter (11) and used as a movement passage for postlarvae that are about to molt.
A vegetation plate (30) is installed long in the horizontal direction between the vertical and inclined supports (11) (12) and is formed in multiple stages to provide a safe habitat for a large number of large shrimp postlarvae and enable smooth feeding activities; ;
An upper screen (31) located at the top of the vegetation plate (30) and used as a molting place and refuge where large spider shrimp postlarvae that are about to molt can safely escape;
It is formed on the upper part of the vertical support (11) and consists of a passage (20) for movement of workers and dropping of feed.
According to paragraph 1,
The vegetation plate 30 is widened left and right toward the bottom so that the feed dropped from the passage 20 at the top of the vertical support 11 is evenly dropped on the multi-stage vegetation plate 30 to ensure smooth feed supply. It is formed to be vertical, but the width increases as it moves toward the lower stage, so that each side is 30 cm wider than the upper stage.
According to claim 1 or 2,
The vegetation plate (30) provides a dark environment for nocturnal giant spider shrimp postlarvae, and is a light shield having a gap so that water can pass between the upper and lower parts of the vegetation plate (30), which is formed in multiple stages. An intermediate rearing device for large shrimp postlarvae, characterized in that it is formed.
According to paragraph 1,
The upper screen 31 is formed to slope downward from the center of the width to both sides, and the vegetation plate 30 at the top of the slope is partially submerged in water and partially exposed to the outside of the water. Device.
According to paragraph 1,
Outside the water tank 10, there is a water channel 41 through which the discharged water flows, a sedimentation tank 42 for settling organic matter contained in the water discharged through the water channel 41, and the organic matter is removed and converted to microorganisms (biofloc). A purification device (40) consisting of a pump (43) for supplying the purified water back into the water tank (10) is installed to precipitate, purify, and recycle organic substances contained in the water discharged after use in the water tank (10). An intermediate rearing device for large gnat shrimp postlarvae, characterized in that it allows

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