JP3887330B2 - Seafood farming equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an aquaculture apparatus that cultivates or temporarily stores seafood in a breeding aquarium while recirculating and reusing water in a breeding aquarium in a closed system.
[0002]
[Prior art]
Various types of closed-circulation aquaculture equipment for culturing seafood on land have been studied. In this closed circulation type aquaculture apparatus, it is necessary to remove the seafood excrement and residual food in the closed circulation system and to remove ammonia generated from the seafood excrement. For this purpose, a circulation channel is connected to the breeding aquarium, and water excrement and residual food are removed and purified while removing water from the breeding tank through the circulation channel. (For example, see Patent Document 1 and Patent Document 2).
[0003]
FIG. 7 shows an example of a closed circulation type aquaculture apparatus. A sedimentation tank 17, an SS removal tank 18, a nitrification tank 19, and a circulation pump 20 are connected in this order to a circulation channel 16 connected to the breeding aquarium 1. It is. The water flowing into the circulation channel 16 from the breeding aquarium 1 is first physically separated and removed from the sedimentation tank 17 and the SS removal tank 18 and further metabolized by microorganisms such as nitrifying bacteria in the nitrification tank 19. Nitrogen components such as ammonia dissolved in water are removed by decomposition, and the purified water is returned to the breeding aquarium 1 by the action of the circulation pump 20.
[0004]
[Patent Document 1]
JP 2000-31542 A [Patent Document 2]
Republished Patent WO 98/04124 Publication
[Problems to be solved by the invention]
While the water in the breeding aquarium 1 is circulated in the circulation channel 16 as described above, solids such as excrement in the water, residual food, and SS can be removed and ammonia can be removed. The removal of the solid content by the solid matter removal tank 4 including the precipitation tank 17 and the SS removal tank 18 is performed by physical means such as precipitation separation and filtration. Therefore, the slower the flow rate of water, that is, the residence time of water. The longer it is, the higher the efficiency. On the other hand, since ammonia is toxic to fish, it is necessary to discharge the water in the breeding tank 1 to the nitrification tank 19 as soon as possible. For this purpose, it is preferable that the flow rate of water to the nitrification tank 19 is large. .
[0006]
Therefore, if the flow rate of circulating the water in the breeding aquarium 1 through the circulation channel 16 is small, the solids removal efficiency is high, but ammonia is not sufficiently discharged from the breeding aquarium 1, and conversely the water in the breeding aquarium 1 When the flow rate of circulating the water in the circulation channel 16 is large, ammonia discharge from the breeding aquarium 1 becomes good, but the efficiency of removing solid matter is low.
[0007]
The present invention has been made in view of the above points, and an object of the present invention is to provide a seafood aquaculture device that excels in ammonia discharge from a breeding aquarium and has high efficiency in removing solids. It is.
[0008]
[Means for Solving the Problems]
A seafood aquaculture device according to claim 1 of the present invention includes a breeding aquarium 1 for breeding seafood, a first circulation channel 3 for circulating water in the breeding aquarium 1 through an ammonia removal tank 2, and a breeding aquarium 1. And a second circulation channel 5 that circulates the water through the solid matter removal tank 4, and the flow rate of the second circulation channel 5 is set smaller than the flow rate of the first circulation channel 3. It is characterized by comprising.
[0009]
The invention of claim 1 forms a water outlet 6 connected to the second circulation channel 5 to the center of the bottom of the rearing water tank 1, waste water so as to surround the water outlet 6 at the opening of the lower end The cylinder 7 is erected, a solid material inlet 8 is formed at the lower end of the drain cylinder 7, and a water intake 9 connected to the first circulation channel 3 is provided in the drain cylinder 7. To do.
[0010]
The invention of claim 2 is the water intake port according to claim 1, wherein a return piece 10 is provided overhanging the inner periphery of the drain tube 7 at a position directly above the solid material inlet 8, and is connected to the first circulation channel 3. 9 is disposed above the return piece 10 and is provided.
[0011]
The invention of claim 3 is characterized in that in claim 1 , the first circulation path 3 is led out from the intake tank 9 to the lower side of the breeding tank 1 through the bottom of the breeding tank 1. It is.
[0012]
According to a fourth aspect of the present invention, in any one of the first to third aspects, the return port 11 of the first circulation channel 3 to the breeding aquarium 1 and the return of the second circulation channel 5 to the breeding aquarium 1 are provided. In the diagonal position of the breeding water tank 1, the mouths 12 are arranged so as to be opened in opposite directions, respectively.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below.
[0014]
FIGS. 1 to 3 show an example of an embodiment of the present invention. A first circulating channel 3 and a second circulating channel 5 are independently connected to the breeding water tank 1. A circulation pump 22 and an ammonia removal tank 2 are connected to the first circulation channel 3 in order from the upstream to the downstream of the water flow. In addition, a settling tank 17, an SS removal tank 18, and a circulation pump 23 are connected to the second circulation channel 5 in order from the upstream to the downstream of the water flow. In addition to the above, a foam separation device, a temperature adjustment device, a pH adjustment device, an oxygen supply device and the like can be connected to the first circulation channel 3 and the second circulation channel 5.
[0015]
As said ammonia removal tank 2, the nitrification tank 19 can be used, for example. The nitrification tank 19 oxidizes ammonia in water to nitrous acid and further nitric acid by the action of nitrifying bacteria, and nitrifies the highly toxic ammonia into nitric acid with low fish toxicity. Is reduced to nitrogen and released as nitrogen gas. As the ammonia removal tank 2, in addition to the nitrification tank 19 for performing such biological treatment, an electrolysis tank for removing ammonia by electrochemical treatment may be used.
[0016]
Further, the solid removal tank 4 of the second circulation channel 5 is formed by the precipitation tank 17 and the SS removal tank 18 described above. The sedimentation tank 17 is separated from the water by allowing solids to settle, and the SS removal tank 18 is separated by floating a floating substance such as SS by ejecting fine bubbles into the water. It is what you do.
[0017]
In the aquaculture device formed as described above, when the water in the breeding aquarium 1 is circulated through the first circulation channel 3, ammonia in the water can be removed in the ammonia removal tank 2, and When the water in the breeding aquarium 1 is circulated through the second circulation channel 5, the solid matter in the water can be physically separated and removed in the solid matter removal tank 4 including the precipitation tank 17 and the SS removal tank 18. is there.
[0018]
At this time, the circulation pump 22 and the circulation pump 23 are set so that the flow rate flowing through the second circulation channel 5 is smaller than the flow rate of water flowing through the first circulation channel 3. is there. Therefore, by keeping the flow rate of water in the first circulation channel 3 large, ammonia can be discharged from the breeding water tank 1 to the first circulation channel 3 and treated in the ammonia removal tank 2 at the same time. By reducing the flow rate of the water in the second circulation channel 5, the solids in the water can be efficiently removed in the solids removal tank 4.
[0019]
Here, the flow rate of the water in the first circulation channel 3 and the flow rate of the water in the second circulation channel 5 are the sum of the flow rates of the single circulation channel as in the conventional example of FIG. In general, the flow rate can be set to 12 to 24 rotations / day (flow rate set so that the water in the breeding tank 1 is replaced 12 to 24 times a day). . For example, when the total amount of water in the breeding tank 1 is 20 m ³ and 24 rotations / day, the sum of the flow rate of the first circulation channel 3 and the flow rate of the second circulation channel 5 is 20 m ³ × 24 times / 24 h = 20 m ^3. / H. The ratio of the flow rate of the first circulation channel 3 to the flow rate of the second circulation channel 5 is determined according to the processing capacity of the ammonia removal tank 2 and the solid matter removal tank 4, but the flow rate of the first circulation path 3. Is set to 1, the flow rate of the second circulation channel 5 is preferably set in the range of 1/2 to 1/10.
[0020]
FIG. 2 shows a configuration of a connection portion between the breeding water tank 1 and the first circulation channel 3 or the second circulation channel 5. The breeding aquarium 1 has a circular planar shape, and its bottom surface is formed in a funnel-shaped inclined surface that goes down toward the center. One end of the second circulation channel 5 is connected to the lower surface of the central portion of the breeding water tank 1, and one end of the second circulation channel 5 is opened as a water outlet 6 at the central portion of the bottom surface of the breeding water tank 1. . In addition, a cylindrical drain tube 7 having an open top and bottom is erected at the center of the bottom surface of the breeding water tank 1, and the water outlet 6 is surrounded by the lower end of the drain tube 7. A solid material inlet 8 is provided at a plurality of locations in the circumferential direction at the lower end of the drain tube 7, and the solid material inlet 8 is formed to reach the lower end of the drain tube 7. Further, at the upper edge position of the solid material inlet 8, a return piece 10 is provided over the entire inner periphery of the drain tube 7 over the entire periphery. The return piece 10 is formed so as to incline downward toward the inside of the drain tube 7. A filter 24 is provided at one end of the first circulation path 3 to form a water intake 9, and the water intake 9 is disposed in the drain tube 7 above the return piece 10.
[0021]
The water in the breeding tank 1 flows into the inner periphery of the drain tube 7 through the solid material inlet 8, and the water in the drain tube 7 passes through the filter 24 to the first through the intake port 9 by the action of the circulation pump 22. Water is sucked into the circulation channel 3 and taken in. This water is circulated so as to be returned from the return port 11 to the breeding water tank 1 after being treated to remove ammonia in the ammonia removing tank 2. On the other hand, water in the drain cylinder 7 is taken into the second circulation channel 5 from the water outlet 6. This water is circulated so as to be returned to the breeding aquarium 1 from the return port 12 by the action of the circulation pump 23 after being treated for removing the solid matter in the solid matter removing tank 4. When water flows into the first circulation channel 3 from the water intake 9 or when water flows into the second circulation channel 5 from the water outlet 6, seafood is sucked into the water intake 9 or the water outlet 6. This can be prevented by the drain tube 7. When the water in the drain tube 7 is taken into the first circulation channel 3 and the second circulation channel 5 from the water intake 9 and the water outlet 6 in this way, the water in the breeding aquarium 1 is turned into the solid material introduction port 8. Through this, the water flows into the drain tube 7, and accordingly, the flow of water to the center portion where the drain tube 7 is provided is generated at the bottom of the breeding water tank 1. For this reason, the solid matter 25 that has settled at the bottom of the breeding aquarium 1 moves to the center of the breeding aquarium 1 along with the flow of water, and enters the drain tube 7 from the solid matter inlet 8. The solid material 25 that has entered the drain tube 7 is sucked into the second circulation path 5 from the outlet 6 surrounded by the drain tube 7 and is removed by the solid material removal tank 4.
[0022]
In this way, the solid matter 25 at the bottom of the breeding aquarium 1 is collected in the drain cylinder 7 at the center of the breeding aquarium 1 and efficiently sent out from the water outlet 6 to the second circulation path 5, It can be removed efficiently. Further, as described above, since the return piece 10 is provided so as to protrude above the solid material inlet 8, the solid material 25 that has entered the solid tube 8 from the solid material inlet 8 rises in the drain tube 7. Can be prevented by the return piece 10, and the solid material 25 can be prevented from flowing into the first circulation path 3 from the water intake 9, and water with less solid material 25 is supplied to the ammonia removal tank 2. Can be processed.
[0023]
Further, as described above, water circulating in the first circulation channel 3 is discharged from the return port 11, and water circulating in the second circulation channel 5 is discharged from the return port 12 and returned to the breeding aquarium 1. As shown in FIG. 3, the return port 11 of the first circulation channel 3 and the return port 12 of the second circulation channel 5 are on the diagonal line of the breeding water tank 1, that is, on the opposite side across the center of the breeding water tank 1. The direction of the opening of the return port 11 of the first circulation channel 3 and the return port 12 of the second circulation channel 5 is parallel to the outer peripheral wall of the breeding aquarium 1 and in the opposite direction. It is set as follows. Therefore, when water is spouted into the breeding aquarium 1 from the return port 11 of the first circulation channel 3 and the return port 12 of the second circulation channel 5, a swirling flow is formed in the breeding aquarium 1 as shown by the arrows in FIG. In this swirl flow, the solids 25 in the water can be collected in the center of the breeding aquarium 1, and the solids 25 can be efficiently collected in the drain tube 7.
[0024]
4 to 6 show an example of another embodiment of the present invention. In the embodiment shown in FIGS. 1 to 3, the first circulation channel 3 is led out above the breeding aquarium 1. However, in the present embodiment, the first circulation channel 3 is led out below the breeding aquarium 1. That is, as shown in FIG. 5, one end of the first circulation channel 3 is connected to the center of the breeding water tank 1 from below. The outer diameter of the front end of the first circulation path 3 is smaller than the inner diameter of the water outlet 6 of the second circulation path 5, and the front end of the first circulation path 3 is inserted into the center of the water outlet 6. The water intake 9 is formed above the water outlet 6 at the central position of the water outlet 6. Other configurations are the same as those in FIGS.
[0025]
In this case, when the solid matter 25 in the breeding aquarium 1 is collected in the central part of the breeding aquarium 1 as described above and enters the drain tube 7 through the solid matter inlet 8, the solid matter 25. Flows into the second circulation flow path 5 from the water outlet 6 arranged on the outer periphery of the water intake 9, and is sent to the solid matter removal tank 4 to be removed from the water. Moreover, since the water intake 9 is located inside the water outlet 6 and above the water outlet 6, the solid material 25 does not flow into the first circulation channel 3 from the water intake 9, and the solid material 25. Water with a small amount can be supplied to the ammonia removal tank 2.
[0026]
In this embodiment, since the first circulation channel 3 is led out below the breeding aquarium 1, the water in the drain tube 7 is naturally discharged from the water intake 9 to the first circulation channel 3. Into the ammonia removal tank 2. Accordingly, as in the case of the embodiment of FIGS. 1 to 3 in which the first circulation channel 3 is led out above the breeding aquarium 1, the circulation pump 22 is used to pump water into the first circulation path 3. For example, as shown in FIGS. 4 and 6, it is possible to provide a circulation pump 22 on the downstream side of the ammonia removal tank 2. The restriction on the position where the 22 is provided is reduced, and the degree of freedom in system design is increased.
[0027]
【The invention's effect】
As described above, the fish culture apparatus according to claim 1 of the present invention includes a breeding aquarium for breeding seafood, a first circulation channel for circulating water in the breeding aquarium through the ammonia removal tank, and a breeding aquarium A second circulation channel for circulating water through the solids removal tank, and the flow rate of the second circulation channel is set smaller than the flow rate of the first circulation channel. And solids can be removed independently in the first circulation channel and the second circulation channel, and kept in the ammonia removal tank of the first circulation channel that maintains a large water flow rate. Ammonia can be discharged and treated well from the water tank, and at the same time, the solids in the water can be efficiently removed in the solids removal tank of the second circulation channel with a reduced flow rate of water.
[0028]
The invention of claim 1 forms a water outlet connected to the second circulation passage in the central portion of the bottom of the rearing water tank, erected drainage tube so as to surround the water outlet at the opening of the lower end In addition, a solid material introduction port is formed at the lower end of the drain tube, and a water intake port connected to the first circulation channel is provided in the drain tube. When the water is taken into the first circulation channel or the second circulation channel, the water in the breeding aquarium flows into the drainage pipe through the solid material inlet, and the water flows toward the drainage cylinder at the bottom of the breeding tank. The solid matter that has settled at the bottom of the breeding tank along with this flow of water can be collected by the flow of water and efficiently flowed into the drainage pipe from the solid matter introduction port. The solid material can be efficiently sent to the circulation path and removed by the solid material removal tank.
[0029]
Further, the invention of claim 2 is the invention according to claim 1, wherein the return piece overhangs the inner periphery of the drainage tube at a position directly above the solid material introduction port, and the intake port connected to the first circulation channel is formed from the return piece. Since it is arranged to be provided on the upper side, it is possible to prevent the solid matter that has entered the drain tube from the solid material inlet from rising in the drain tube with a return piece. It can prevent flowing into the circulation path, and can supply water with less solid matter to the ammonia removal tank for treatment.
[0030]
Moreover, since invention of Claim 3 penetrated the bottom part of the breeding aquarium from the water intake in Claim 1 , and led out the 1st circulation path to the lower side of a breeding aquarium, water was taken in by the natural outflow. From the first to the first circulation flow path and sent to the ammonia removal tank, and there is no need to provide a circulation pump upstream from the ammonia removal tank, and the position of the circulation pump is less restricted. This increases the degree of freedom in system design.
[0031]
According to a fourth aspect of the present invention, in any one of the first to third aspects, the return port of the first circulation channel to the breeding water tank and the return port of the second circulation channel to the breeding water tank are provided as the breeding water tank. In the diagonal position, the openings are arranged in opposite directions, so that when the water is returned to the breeding tank from the return port of the first circulation channel and the return port of the second circulation channel, respectively, A swirling flow of water is formed inside, and solid matter can be efficiently collected in the drain tube disposed in the center of the breeding aquarium with this swirling flow.
[Brief description of the drawings]
FIG. 1 is a schematic front view of an example of an embodiment of the present invention.
FIG. 2 is an enlarged cross-sectional view of a part of the above.
FIG. 3 is a schematic plan view of a part of the above.
FIG. 4 is a schematic front view of an example of another embodiment of the present invention.
FIG. 5 is an enlarged sectional view of a part of the above.
FIG. 6 is a schematic plan view of a part of the above.
FIG. 7 is a schematic diagram showing a conventional example.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Breeding tank 2 Ammonia removal tank 3 First circulation flow path 4 Solid matter removal tank 5 Second circulation flow path 6 Drain port 7 Drain tube 8 Solid material introduction port 9 Intake port 10 Return piece 11 Return port 12 Return port

Claims (4)

A breeding aquarium for breeding seafood, a first circulation channel for circulating the water in the breeding tank through the ammonia removal tank, and a second circulation channel for circulating the water in the breeding tank through the solid matter removal tank The flow rate of the second circulation channel is set smaller than the flow rate of the first circulation channel, and a water outlet connected to the second circulation channel is formed at the center of the bottom of the breeding water tank. The water intake is connected to the first circulation channel in the drainage cylinder by standing the drainage pipe so as to surround the outlet with the opening at the lower end and forming a solid material inlet at the lower end of the drainage cylinder. aquaculture apparatus seafood, characterized by comprising providing a. A return piece is provided overhanging the inner periphery of the drainage pipe at a position directly above the solid material introduction port, and a water intake port connected to the first circulation channel is provided above the return piece. The fish culture apparatus according to claim 1. 2. The fish and shellfish cultivation apparatus according to claim 1 , wherein the first circulation path is led out to the lower side of the breeding tank through the bottom of the breeding tank from the water intake . The return port to the rearing tank of the first circulation channel and the return port to the rearing tank of the second circulation channel are arranged so as to open in opposite directions at diagonal positions of the rearing tank. The seafood aquaculture apparatus according to any one of claims 1 to 3 .

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