KR100665196B1 - The shrimp farm not to exchange water - Google Patents

Abstract

The present invention relates to a farm for shrimp farming, and in particular, by culturing nitrifying bacteria inside the tank, the bacteria do not need to separate the shrimp by eating the suspended matter discharged from the shrimp, ammonia, nitrite, etc. It provides a good environment for shrimp farming by arranging habitats and shrimp feeding grounds. It supplies air through the air circulation system and promotes the purification function by moving the water in the tank. It's about a shrimp farm that doesn't need to change.

The present invention is useful for farming farms that can cultivate healthy shrimp without breaking the conventional cumbersome farming methods that had to be changed after a certain period of time in farming shrimp.

In addition, the present invention is a high availability invention that can be used in other fish farms because it can supply fresh air to the tank with a simple and convenient structure.

In addition, the present invention does not need to change the water, but can be equipped with a more stable farm since it is provided with a separate water exchange device that can prevent in advance the problems that occur in advance.

Farm, shrimp, water exchange system, ammonia, nitrite, etc.

Description

The shrimp farm not to exchange water}

1 is a plan view showing an arrangement of the tank heat of the present invention,

2 is a perspective view showing a state in which an air circulation device and a water exchange device are installed in a tank heat of the present invention;

Figure 3 is an exploded perspective view showing a state in which the tank is produced in the tank heat of the present invention,

4 is a plan view showing a state in which the air circulation of the present invention disposed in the tank heat,

5 is a plan view showing a state in which an air circulation device is disposed in the water tank of the present invention, and a shrimp nest, a shrimp neck, etc. are arranged;

Figure 6 is a plan view showing a state in which the water exchange apparatus of the present invention is disposed in the tank heat,

7 is a perspective view illustrating main parts of the bubble tube of the bubble supply unit of the present invention;

8 is a principal view showing a shrimp habitat of the present invention in a perspective view,

9 is a perspective view showing a shrimp feed cage of the present invention,

10 is a perspective view showing a state of an intake and exhaust field of the present invention.

<Brief description of the symbols in the drawings shown>

One; Cultured shrimp 10; water tank

11; Countertop frame 12; Horizontal chord

13; Vertical lattice 14; Synthetic Resin Panel

15; Tent basin 20; Counter Heat

40; Air circulation system 41; Air pump

41 '; Motor 42; Air outlet

43; Switching valve 44; Main air pipe

45; Open valve 46; Wave generator

47; Connector 48; Air outlet

50; Bubble supply unit 51; Bubble Seal Valve

52; Bubble supply pipe 53; Bubble ball

54; Stopper 55; Bubble tube

56; Ozone generator 60; Water exchange system

61; Water exchange motor 62; Purified Water Supply Pump

63; Acquisition pipe 64; Drain pipe

65; Joint pipe 66; Drain Joint Pipe

67; Main inlet pipe 68 '; Inlet / outlet valve

69; Suction tube 70; Shrimp Farm

71; Shrimp market connecting rod 72; Elbow House

73; Formative frame 74; "T" Zaelbow

75; Cultured sticks 76; Shrimp Grower

77; Ties 80; Shrimp Feeding Ground

81; Feeding station connecting rod 82; Feeding elbow tube

83; Feeding frame 85; Feeding bag

86; Ties 87; Storage

The present invention relates to a farm for shrimp farming, and in particular, by culturing nitrifying bacteria inside the tank, the bacteria do not need to separate the shrimp by eating the suspended matter discharged from the shrimp, ammonia, nitrite, etc. It provides a good environment for shrimp farming by arranging habitats and shrimp feeding grounds. It supplies air through the air circulation system and promotes the purification function by moving the water in the tank. It's about a shrimp farm that doesn't need to change.

In general, aquaculture farms are a breeding ground of fish for breeding and breeding fish in an artificial tank.

However, these farms are produced in various forms to suit the growth characteristics of the fish to grow a variety of fish, of which the farms for raising shrimp need to be more careful than other fish farms.

In other words, shrimp is a type of crustacean, which is difficult to survive if its habitat changes.

Therefore, to grow these shrimp must always be supplied with purified water in the tank, the task is difficult.

That is, the shrimp is drained of the tank in which the shrimp is being raised, the water is purified through a purification facility, and the water is filled in the drained tank again.

Therefore, the process of purifying and draining the water in the tank is quite cumbersome and expensive.

And shrimp that are growing in the process of draining and purifying water often cause a loss of life without overcoming some environmental changes.

In other words, when the water is drained and a small amount of water is left at the bottom of the tank, the shrimp that lived during the water purification time do not survive the environmental change and lose their lives.

This is a huge cost loss for operators operating shrimp farms.

Therefore, it is best for shrimp tanks to grow shrimp without draining the water to purify the water.

However, in growing shrimp, it is a dangerous idea to raise shrimp in a tank where the flow of water is controlled.

Due to the nature that decay water decays, shrimp that grow once they are filled in the tank will release their excrement, so over time, the water in the tank will not maintain an environment where shrimp can grow. will be.

As a result, these shrimp farms have been installed and operated with various problems exposed, and many methods have been used to solve them, but it is true that the best alternative has not been devised.

The present invention solves the above problems by culturing nitrifying bacteria inside the tank, the bacteria eat the suspended matter discharged from the shrimp, ammonia, nitrite, etc., no need to separate the shrimp, shrimp pond and shrimp feed inside the tank It provides a good environment for shrimp farming by arranging the intestines, supplies air through the air circulation system, moves the water in the tank to enhance the purification function, and supports water exchange by installing a water exchange device. Wants to provide shrimp farms that don't need it.

Therefore, the present invention is a tank row having a plurality of tanks arranged in a multi-line fortunate, and an air circulation device and a water exchange device disposed at the side ends of the tank row to exchange air and water, each of the interior of the plurality of tanks in the form of a cube A shrimp farm formed of a long frame and a shrimp breeding membrane arranged in multiple rows, and a shrimp feeder provided in the plurality of tanks, are connected to an air pump and an air circulation pipe of an air circulation device to each of the tank rows. In addition to the automatic supply, and each of the tank heat to the purified water supply pump and the purified water supply pipes of the water exchange device to provide a supplementary exchange of the purified water and to provide a shrimp farm without the need to change the shrimp.

In another aspect, the present invention, the air circulation device, an air pump composed of a motor provided on the side end of the tank row, a switching valve fixed to the air discharge portion of the air pump, coupled to the switching valve and arranged up to the plurality of tanks A main air pipe, a wave generating tube having a bleed valve connected to each tank from the main air pipe, and a connecting pipe connected to the four left and right corners of the water tank at the end of the wave generating tube and connected to the air; Consists of a discharge port, and a bubble supply portion in communication with each tank in the main air pipe, the air discharged through the air pump and the switching valve through the wave generating pipe opened through the main air pipe to the air outlet of the connection pipe It is discharged to form a wave from the corner of the tank, also supplied to the bubble supply through the main air pipe The air is intended to provide a shrimp farm without a water change to continuously supply the air through a bubble in the interior of the water tank is required.

In addition, between the air discharge portion and the switching valve of the air pump of the present invention, to configure a ozone generator to provide a shrimp farm that does not need to change the fresh water at all times.

In another aspect, the present invention, the bubble supply unit of the air circulation unit, the bubble supply valve is composed of a bubble closure valve communicated to each tank in the main air pipe, and the connection pipe is separated and arranged in a plurality of strands at the end of the bubble supply pipe And a bubble tube having a plurality of bubble balls coupled to elbows at the end of the connecting pipe, and an ozone generator formed inside the bubble supply pipe, and a bubble seal valve in which air passing through the main air pipe is opened. It is intended to provide a shrimp farm without blowing the air to the bubble supply pipe, and through the bubble pipe to supply a small amount of air in the form of bubbles through the bubble ball.

In another aspect, the present invention, the water exchange device, the purified water supply pump is provided on the side end of the tank heat, the inlet pipe and the drain pipe fixed to the side end of the air pump respectively, the inlet is fixed to the other end of the inlet pipe and the drain pipe, respectively A bottom surface of each tank having a water inlet and outlet valve formed at one side in communication with a drain joint pipe and a cylindrical main inlet pipe connected to the inlet pipe inlet pipe and arranged in a respective tank row; The suction pipe connected to the main body, the discharge pipe connected to the bottom of each tank in communication with the main drain pipe, and the quadrilateral suction pipe fixed to the ends of the suction pipe and the discharge pipe are opened when the purified water supply pump is operated by the operation of the motor. The main inlet pipe and inlet joint pipe are drawn by suctioning the water in the tank through the inlet and outlet valve. After passing through the purified water supply pump, the purified water supply pump passes through the drain pipe and the drain joint pipe and is stored in the empty tank A of the empty space where the drain valve is opened. It is intended to provide a shrimp farm that does not require water to supply purified water by operation.

In another aspect, the present invention is a shrimp farm, a habitat frame having a skeleton in the shape of a cuboid through each of the habitat connecting rod and the form elbow tube, and the form of the bar, which is vertically coupled to the middle of the habitat frame, and The shrimp propagation membrane which hangs in the habitat frame according to the spacing of the habitats is combined with the binding line which couples the side edge of the shrimp propagation membrane which is inserted by the spacing between the habitats, and a plurality of habitats. They are attached to the shrimp breeding membrane to provide a shrimp farm that does not need to change the food to eat.

In addition, the shrimp feeding ground, the feeding cage frame having a skeleton in the shape of a cuboid through each feeding cage connecting rod and the feeding cage elbow tube, the feeding cage rods arranged in the longitudinal direction of the feeding cage frame, and the upper surface of the feeding cage frame The receiving members tied in a concave shape through the tie line are organically coupled to each other and put in each tank, so that there is no need to change the shrimp farm to pile up the food of the shrimp on the upper surface of the concave receiving member. .

The present invention is similar to the conventional farm in that the shrimp farm for farming.

However, using the aquaculture system of the present invention, it is not necessary to multiply nitrifying bacteria and grind the water in the tank. The shrimp farm and the shrimp feeding center in the tank are always arranged to supply air and generate waves to purify the water. It will be described together with the drawings shown in that there is a difficulty between the water exchange in the water tank and the configuration therefor through a water exchange device that is a separate auxiliary means.

As shown in Figs. 1 to 10 of the drawings, the present invention is arranged in multiple rows, and has a plurality of tanks 10 which are rectangular and have proliferated nitrifying bacteria therein, and one of the tanks 10 is an empty space. A plurality of tank rows 20 having A tank 21 and one B tank 22 in which purified water is built is provided.

In addition, there is an air circulation device 40 and a water exchange device 60 disposed at the side ends of the water tank row 20 to exchange air and water, and each of the plurality of water tanks 10 has a cube-shaped habitat. There is a shrimp farm 70 formed of a frame 71 and a shrimp breeding film 76 arranged in multiple rows therein.

In addition, each of the plurality of tanks (10) is provided with a shrimp feed cage (80) formed of a hexahedral feeding cage frame (83) and a receiving member (87) fixedly concave on the upper portion thereof.

Therefore, the air pump 41 and the air circulation pipes of the air circulation device 40 are connected to each of the water tanks 20 so as to automatically supply air, and the water exchange device 60 to each of the water tanks 20. The purified water supply pump 61 and the purified water supply pipes of the purified water supplementary exchange, the tank (10) is provided with a number of shrimp farms 70 and shrimp feeding grounds (80) to form shrimp (1) It is.

That is, as shown in Fig. 1 and 2, the tank 10 for the shrimp farming is provided in the tank row () consisting of a plurality of rows, one of the tank 10 of the one side of the tank A to maintain the empty space (21) ), And there is a B tank 22 for storing purified water.

The A tank 21 and the B tank 22 is to be used only in an aquaculture farm of the present invention, in particular, only when there is a water tank () to grind water among the plurality of tanks 10 described above. will be.

Therefore, the A tank 21 and the B tank 22 are not determined at a specific position, and two of the tank rows 20 may be selected and randomly arranged as necessary.

On the other hand, as shown in Figures 1 to 3, the tank row 20 is composed of a long rectangular parallelepiped tank frame 11 composed of a plurality of compartments with a square pipe 18, the tank frame 11 Between the cross-section is horizontally coupled between the horizontal cross section of the "c" -shaped cross-section 12 and the vertical cross-section of the "c" -shaped vertical cross section 13 is formed.

In addition, a synthetic resin panel 14 in which the kankan is installed for the partition is installed inside the tank frame 11 and the splitting bar 13, and the tent tank in which the upper part is sealed and fused in the state of the synthetic resin panel 14 is opened. The barrel 15 is formed.

Therefore, the panel 14 and the tent water tank 15 are built into each compartment of the tank frame 11 to form a plurality of tanks 10.

Here, the size of the water tank 10 can be manufactured in various forms, but the applicant of the present invention intends to perform a water tank having a width of 10-20 m and a length of 5-12 m.

On the other hand, the air circulation device 40, as shown in Figure 4, there is an air pump 41 composed of a motor 41 'is provided on the side end of the tank heat 20, the air pump 41 of A switching valve 43 is fixed to the air exhaust 42.

In addition, there is a main air pipe 44 coupled to the switching valve 43 and arranged up to a plurality of tanks 10 formed in the plurality of tank rows 20, each of the tanks in the main air pipe 44 ( There is a wave generating tube 46 in which the open and close valves 45 are communicated with each other.

In addition, from the end of the wave generating tube 46, the connecting pipe 47 connected to the left and right four corners of the water tank 10, and from the bottom of the water tank 10 at the end of the connecting pipe 47 There is an air outlet 48 for discharging air, and the bubble supply unit 50 is configured to communicate with each water tank 10 in the main air pipe 44.

Accordingly, the air discharged through the air pump 41 and the switching valve 43 passes through the wave generating pipe 46 opened through the main air pipe 44 to the air outlet 48 of the connecting pipe 47. It is discharged to form a wave from the corner portion of the water tank 10, and the air supplied to the bubble supply unit 49 through the main air pipe 44 is continuously air through the bubble in the water tank 10 To supply.

That is, when the air pump 41 shown in FIG. 4 is operated, air is blown into the main air pipe 44. One of the three rows of the main air pipes 44 is provided through the switching valve 43. It is possible to blow air into the main air pipe (44).

However, the switching valve 43 does not necessarily need to be installed.

The reason is that the wave generating pipe 46 extending from each of the main air pipes 44 has a separate open valve 45, so that only the water tank 10 in which the open valve 45 is opened can be introduced into the air. will be.

Therefore, the clean air discharged to the wave generating pipe 46 enters the bottom of the water tank 10 to blow out the air.

At this time, the strong air is discharged to the air discharge port 48 of the wave generating tube 46 installed at the four corners of the water tank 10, so that the water in the water tank 10 rises to generate water flow.

Of course, when the water rotates and moves, it is possible to prevent phenomena such as decay of the decayed water beforehand and keep the water fresh.

In addition, the tank 10 of the present invention is an important feature of the present invention, since the nitrifying bacteria are multiplying, the nitrifying bacteria always eat the excretion discharged from the shrimp (1) of aquaculture, and always eat ammonia or nitrite generated from water. You can keep clean water.

This point is not seen in the conventional cultured shrimp (1) farm, the conventional phenomenon that the water must always be changed after a certain period through the nitrification bacteria and air circulation device 40 is solved.

In addition, the present invention is to supply air to the shrimp (1) to smoothly multiply in the water contained in the water tank 10, the configuration of the bubble supply unit 50 shown in the drawings shown in 4, 5, 7 )to be.

Therefore, the bubble supply unit 50 will be described in detail below.

In any case, in the present invention, in order to blow fresher air into the water tank 10, a separate ozone generator K may be installed at the introduction portion.

That is, as shown in Figure 4, to configure the ozone generator (K) between the air discharge portion 42 and the switching valve 43 of the air pump (41).

When the ozone generator (K) is operated, all the air supplied to the main air pipe 44 can be supplied in a fresher state, this configuration is the bubble supply pipe 52 of the bubble supply unit 50 to be described later It is possible to perform the same purpose in connection with the ozone generator 56 provided in.

Then, the non-bubble supply unit 50 will be described by deferring the above description.

As shown in FIGS. 4, 5 and 7, the bubble supply unit 50 of the air circulation device 40 has a bubble seal valve 51 communicated with each of the water tanks 10 in the main air pipe 44. There is a bubble supply pipe 52 is configured, separated by a plurality of strands at the end of the bubble supply pipe 52 is composed of a connection pipe 131 evenly arranged at regular intervals on the bottom of the water tank (10).

In addition, the end of the connecting pipe 131 is coupled to the elbow 132, there is a bubble hole 53 formed of a plurality of circumference of the outer peripheral surface, and a bubble tube 55 formed of a stopper 54 formed at each end thereof, An ozone generator 56 formed inside the bubble supply pipe 52 is provided.

Accordingly, the air passing through the main air pipe 44 blows air into the bubble supply pipe 52 of the water tank 10 having the bubble open valve 51 opened, and passes through the bubble pipe 55 to bubble air. Through (53) a small amount of air is supplied in the form of bubbles.

That is, the air flows into the main air pipe 44 from the above-described air pump 41, but in the bubble supply pipe 52 arranged in the aquaculture farm of the present invention because a separate bubble seal valve 51 is disposed Bubble is supplied only from the water tank 10 of the site where the bubble pad valve 51 is opened.

If only the bubble pad valve 51 arranged in the water tank 10 on one side is opened, air is supplied only to the water tank 10, and the air is ozone generator 56 formed inside the bubble supply pipe 52. Pass through the) and is changed to fresh air is split at the end of the bubble supply pipe 52 and passes through the connecting pipe 131 arranged on the bottom of the tank.

And a small amount of air is discharged through the bubble hole 53 of the bubble tube 55 coupled through the connecting pipe 131 and the elbow 132 to always supply air in the water tank (10).

On the other hand, the present invention does not need to exchange water by the action of the nitrifying bacteria and the air circulation device 40 described above.

However, it has a water exchange device 60 that can be supplemented with a separate water in preparation for a problem that occurs in the secondary.

This water exchange device 60, as shown in Figure 6, there is a purified water supply pump 62 composed of a water exchange motor 61 is provided on the side end of the tank heat 20, the purified water supply pump ( An inlet pipe 63 and a drain pipe 64 fixed to the side ends of 62 are provided.

In addition, there are inlet and drain joint pipes 65 and 66 fixed to the ends of the inlet pipe 63 and the drain pipe 64, respectively, and connected to the inlet pipe 63 inlet joint pipe 65 to each tank. The cylindrical main inlet pipe 67 arranged in the row 20 is configured.

In addition, a cylindrical main drain pipe 68 connected to the drain pipe 64 to the drain joint pipe 66 and disposed in each tank row 20 is installed, and is in communication with the main inlet pipe 67. A suction pipe 69 is provided which extends to the bottom of each tank in which an inlet and outlet valve 68 'is formed.

In addition, there is a discharge tube 92 which communicates with the main drain pipe 68 and extends to the bottom surface of each of the tanks 10 in which the drainage valve 91 is formed on one side thereof, and the suction tube 69 and the discharge tube 92 are separated from each other. A quadrilateral intake and exhaust field 100 fixed to the end is formed.

Therefore, as shown in FIG. 4, when the purified water supply pump 62 is operated by the operation of the motor 61, the water tank (limited to C of the illustrated figure) is provided through a suction pipe 69 configured with an open inlet / outer valve 68 ′; 10) sucks the water in and passes through the main inlet pipe (67) and the inlet joint tube (65), passes through the purified water supply pump (62), and again through the purified water supply pump (62) drain pipe (64) and drain joint pipe The purified water of the B tank 22, which is stored in the empty tank of the empty space in which the drainage valve 91 is opened after passing through 66, is supplied with the purified water in a reverse operation to the above. .

To explain this action in more detail,

The illustrated purified water pump 62 operates to extract water in the tank, and the intake and exhaust fields 100 of FIG. 10 to be described later are formed at ends of the suction pipe 69 and the discharge pipe 92.

The intake and exhaust field 100 is locked to all the water tanks 10, and the intake and exhaust field 100 is coupled to the suction pipe 69 and the discharge pipe 92, and again, the main inlet pipe 67 and the main drain pipe ( 68) is coupled.

Accordingly, when the purified water supply pump 62 is opened and the suction pipe 69 including the inlet / outer valve 68 'arranged in the water tank (C; 10) to which the water is to be ground is opened, the water is The suction pipe 69 and the main inlet pipe 67 are taken into the purified water supply pump 62 by the inlet pipe 63 connected to the inlet joint tube 65.

In addition, the water entering the purification water supply pump 62 passes through the drain pipe 64 to the main drain pipe 68 through the drain pipe 64 again.

Of course, the old water passing through the main drain pipe 68 is to discharge the water through the discharge pipe 92 to the water tank 10, that is, the A water tank 21 of the empty space in which the drain valve valve 91 is opened. .

After removing the stored water of the water tank 10 to be watered into the A water tank 21, the water of the B water tank 22, which has been purified and stored as clean water, is obtained through the same method as described above. It can be supplied to (C; 10) again.

And the intake and exhaust field 100 described above can be manufactured in the form of a wide variety of embodiments, it is preferable to manufacture as shown in FIG.

That is, the frame 104 having the intake and exhaust field 100 fixed at the ends of the suction pipe 69 and the discharge pipe 92, and has upper and lower panels 101 and 102, and constitutes the support pillar 103 at four corners. There is.

In addition, a cylindrical suction pipe connector 105 and a discharge pipe connector 106 are formed through the upper surface of the upper panel 101 to connect the suction pipe 69 and the discharge pipe 92 to each other, and the frame 104 is formed. The sieve 107 is coupled to the four sides of the configuration.

Therefore, the aquaculture shrimp 1 is prevented from rising through the strainer 107 when the water in the water tank 10 is inhaled, and when the water is discharged through the discharge pipe 92, the purified water is supplied into the water tank 10. It is.

However, the excretion, ammonia, nitrite discharged by the shrimp generated in the tank by removing the nitrifying bacteria in the tank is neatly removed, but in the case of nitrate, only a small amount is removed and the majority of the nitrate is present in the water.

Therefore, there is a need to remove such nitrate, which is to be performed in the process of purifying the water discharged from the tank and stored in the tank (A).

This process is usually microorganisms of the genus Achromobactor, Bacillus, Microccus, Pseudomonas, etc. reported to perform denitrification.

Therefore, the water of the tank (A) passes through a path in which microorganisms of each chromium such as Achromobactor, Bacillus, Microccus, Pseudomonas, etc. passes through a denitrification process to discharge nitrogen, and then passes through a purifying means such as an ozone generator. desirable.

In the present invention, the shrimp cage 70 and the shrimp feed cage 80 provided in the tank 10 also become main parts.

That is, as shown in Figure 8, the shrimp habitat 70 has a habitat frame 73 having a skeleton in the shape of a cuboid through each of the habitat connecting rod 71 and the habitat elbow pipe 72, In addition, the form of the cutting rod 75 is coupled to the "T" Zaelbow 74 arranged at a predetermined interval in the horizontal direction of the formative frame 73.

In addition, the shrimp propagation membrane 76 is formed in the habitat frame 73 in accordance with the interval between the habitation rod (75).

Therefore, the side end of the shrimp growth membrane 76 sandwiched by the spawning rod 75, and the coupling line 77 to couple the spawning rod 75 in a plurality, the shrimp in the tank (1) (1) ) Is attached to the shrimp breeding membrane (76) to eat food.

That is, the shrimp (1) in the interior of the water tank (10) grabs the shrimp feed (P) poured into the shrimp feeding ground 80 to be described later, the shrimp breeding arranged in a plurality in the shrimp habitat 70 Take it to the membrane (76) and eat food while clinging.

Therefore, it can be farmed as a healthy shrimp (1) to move around and eat and grow food.

On the other hand, the above-mentioned shrimp feeding cage 80, as shown in Figure 9, through the feeding cage connecting rod 81 and the feeding cage elbow pipe 82 through the food box frame 83 having a skeleton in the shape of a cuboid There, there is a feeding rod bar (85) coupled to the "T" Zaelbow 84 arranged at a predetermined interval in the transverse direction of the feeding cage frame (83).

In addition, the shrimp feeding cage is manufactured by the combination of the receiving member 87 tied to the concave shape through the binding line 86 on the upper surface of the feeding cage frame 83.

Therefore, the shrimp feeding ground is put in a plurality of spaces in each tank 10, to stack the food of the cultured shrimp (1) on the upper surface of the concave receiving member 87 to make the shrimp to eat the food.

Of course, the amount of food left in the shrimp feeding cage 80 can be observed by looking at the upper portion of the tank 10, that is, the upper portion of the shrimp feeding cage 80 on the surface of the shrimp feed cage 80. Shrimp farming (1) is easier.

As described above, the present invention is a useful invention regarding a farm that can cultivate healthy shrimp without breaking the conventional method of cumbersome farming, which had to change water after a certain period in farming shrimp. .

In addition, the present invention is a high availability invention that can be used in other fish farms because it can supply fresh air to the tank with a simple and convenient structure.

In addition, the present invention does not need to change the water, but can be equipped with a more stable farm since it is provided with a separate water exchange device that can prevent in advance the problems that occur in advance.

Claims (9)

In a farm for farming shrimp, Arranged in a multi-line gladness, a plurality of tanks (10) that are rectangular and proliferate nitrifying bacteria therein, one of the tanks (10) is provided with an empty space, and one is purified water A plurality of tank rows 20 having a B tank 22 having a built-in; An air circulation device (40) and a water exchange device (60) disposed at side ends of the tank heat (20) to exchange air and water; A shrimp farm 70 formed with a hexahedral habitat frame 71 in each of the plurality of tanks 10, and a shrimp breeding membrane 76 arranged in a row in the interior thereof; Shrimp feed cabinet (80) formed in each of the plurality of tanks (10) formed of a hexahedral feeding cage frame (83) and a receiving member (87) fixed concave on the upper portion thereof; The air pump 41 and the air circulation pipes of the air circulation device 40 are connected to each of the water tanks 20 to automatically supply air, and the water exchange device 60 of each of the water tanks 20 is also provided. The purified water supply pump 61 and the purified water supply pipes exchange the purified water auxiliaryly, and the water tanks 10 are provided with a plurality of shrimp farms 70 and a shrimp feed farm 80 for farming the shrimps 1. Shrimp farms that do not require water. The method of claim 1, The tank row 20, A long rectangular parallelepiped tank frame 11 formed of a plurality of compartments with a square pipe 18; A vertical cross section having a cross section horizontally coupled between the tank frame 11 and a vertical cross section having a cross section vertically coupled with a horizontal cross section 12 having a “c” shape and a vertical cross section having a “c” shape;  A synthetic resin panel 14 in which the compartment is coupled to the compartment inside the countertop frame 11 and the separator 13; A tent container 15 sealed and fused in a state in which the upper part of the synthetic resin panel 14 is blown out; Each panel of the tank frame 11, each panel of the panel 14 and the tent canister 15 to form a plurality of tanks (10), characterized in that it does not need to change the shrimp farm. The method of claim 1, The air circulation device 40, An air pump 41 composed of a motor 41 'provided at a side end of the tank row 20; A switching valve 43 fixed to the air discharge part 42 of the air pump 41; A main air pipe 44 coupled to the switching valve 43 and arranged up to a plurality of tanks 10 formed in the plurality of tank rows 20; A wave-generating tube 46 having a bleeding valve 45 communicating with the respective water tanks 10 in the main air pipe 44; The connecting pipe 47 is separated from the end of the wave generating pipe 46 and connected to the left and right four corners of the water tank 10, and the air from the bottom of the water tank 10 at the end of the connecting pipe 47 An air outlet 48 for discharging the air; Bubble supply unit 50 in communication with each of the water tank 10 in the main air pipe 44; the air discharged through the air pump 41 and the switching valve 43 is the main air pipe 44 Through the wave generating pipe 46 is opened through the discharge to the air outlet 48 of the connecting pipe 47 to form a wave from the corner of the water tank 10, and also the main air pipe 44 The air supplied to the bubble supply unit 49 through the shrimp tank, characterized in that the continuous supply of air through the bubble to the inside of the tank (10). The method of claim 3, wherein Between the air discharge part 42 and the switching valve 43 of the air pump 41, Shrimp farms do not need to change, characterized in that the ozone generator (K) is configured The method of claim 3, wherein Bubble supply unit 50 of the air circulation device 40, A bubble supply pipe (52) configured with a bubble closure valve (51) communicating with each of the water tanks (10) in the main air pipe (44); A connection pipe 131 separated into a plurality of strands at an end of the bubble supply pipe 52 and evenly arranged at regular intervals on a bottom surface of the water tank 10; An elbow 132 coupled to the end of the connecting tube 131, a bubble tube 55 formed of a plurality of bubble holes 53 formed around the outer circumference thereof, and a stopper 54 formed at each end thereof; An ozone generator (56) formed in the bubble supply pipe (52); The air passing through the main air pipe 44 blows air into the bubble supply pipe 52 of the water tank 10 having the bubble open valve 51 opened, and passes through the bubble pipe 55 to form a bubble hole ( 53) A shrimp farm without a change, characterized in that the supply of a small amount of air in the form of bubbles through. The method of claim 1, The water exchange device 60, A purified water supply pump 62 composed of a water exchange motor 61 provided at a side end of the tank heat 20; An inlet pipe 63 and a drain pipe 64 fixed to side ends of the air pump 62; Inlet and drain joint pipes (65,66) fixed to ends of the inlet pipe (63) and the drain pipe (64), respectively; A cylindrical main inlet pipe (67) connected to the inlet pipe (63) inlet joint tube (65) and disposed in each tank row (20); A cylindrical main drain pipe (68) connected to the drain pipe (64) drain joint pipe (66) and disposed in each tank row (20); A suction pipe 69 communicating with the main inlet pipe 67 and extending to the bottom of each tank having an inlet and outlet valve 68 'formed at one side thereof; A discharge pipe (92) communicating with the main drain pipe (68) and extending to the bottom of each of the water tanks (10) having a drain valve (91) formed at one side thereof; A quadrilateral intake and exhaust field 100 fixed to the ends of the suction pipe 69 and the discharge pipe 92; When the purified water supply pump 62 is operated by the operation of the motor 61, the water in the water tank 10 is sucked through the suction pipe 69 configured with the open inlet and outlet valve 68 ′, and the inlet water can be obtained from the main inlet pipe 67. An empty space through the joint pipe 65, passing through the purified water supply pump 62, and again through the purified water supply pump 62, passing through the drain pipe 64 and the drain joint pipe 66. It is stored in the tank A of the tank 21, the purified water of the tank B (22) in which the purified water is stored in the shrimp farm that does not need to change, characterized in that to supply the purified water in the reverse operation. The method of claim 6, The intake and exhaust field 100 fixed to the ends of the suction pipe 69 and the discharge pipe 92, A frame 104 having upper and lower panels 101 and 102 and constituting support pillars 103 at four corners; A cylindrical suction pipe connector 105 and a discharge pipe connector 106 which are fastened through the upper surface of the upper panel 101 to communicate the suction pipe 69 and the discharge pipe 92 with each other; A strainer 107 coupled to the sides of the frame 104; When the intake of water in the water tank (10) prevents the cultured shrimp (1) to follow up through the strainer 107, and to supply the purified water in the water tank (10) when discharging the purified water through the discharge pipe (92) A shrimp farm that doesn't need to change. The method of claim 1, The shrimp farm 70, Formatting frame 73 having a skeleton in the shape of a cuboid through each shrimp cage connecting rod 71 and shrimp cage elbow tube 72; A habitation rod 75 coupled to the "T" jaelbow 74 arranged at a predetermined interval in the horizontal direction of the habitation frame 73; Shrimp growth membrane 76 hanged inside the habitat frame 73 according to the spacing of the habitat bar (75); Shrimp (1) in the tank (10) by combining the side end of the shrimp growth membrane (76) sandwiched between the habitation rods (75) and the binding line (77) for coupling a plurality of habitation rods (75) Shrimp farms that do not need to change, characterized in that they eat food stuck to the shrimp growth membrane (76). The method of claim 1, The shrimp feeding ground (80), Feeding frame frame 83 having a skeleton in the shape of a cuboid through each feeder connecting rod 81 and the feeder elbow pipe 82; Feeding place bar (85) coupled to the "T" Jaelbow 84 arranged at a predetermined interval in the transverse direction of the feeding place frame 83; A receiving member 87 tied to the upper surface of the feeding frame 83 in a concave shape through the binding line 86; Organically coupled to each other is put in each tank (10), the shrimp-free shrimp farm, characterized in that the food of the cultured shrimp (1) is stacked on the upper surface of the concave receiving member (87).

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