JP2015112066A - Apparatus and method for producing bivalve seed - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an apparatus and method for producing bivalve seeds in which the bivalve seeds can efficiently be produced while simplifying the feeding work.SOLUTION: Bivalve seeds S are received in an aquarium 2, and seawater W is supplied to the aquarium 2 via a feed-water filter 3 through a water supply pipe 5. Also, the seawater W accumulated in the aquarium 2 is discharged outside the aquarium 2 through a drain pipe 7 via a drainage filter 4. In the feed-water filter 3, the seawater W is supplied to the aquarium 2 without passing zooplankton B, while passing phytoplankton A contained in the supplied seawater W. In the drainage filter 4, the seawater W is discharged outside the aquarium 2 without passing the bivalve seeds S received in the aquarium 2.

Description

  The present invention relates to a bivalve seedling production apparatus and method, and more particularly to a production apparatus and method that can efficiently produce bivalve seedling seedling while simplifying the feeding operation.

  Several methods for growing shellfish in an aquarium have been proposed (see, for example, Patent Documents 1 and 2). In the conventional shellfish breeding method, seawater and bait are appropriately supplied to the aquarium, and the seawater in the aquarium is appropriately discharged or circulated in order to prevent contamination of the seawater in the aquarium. In the feeding operation, food suitable for growing shellfish must be prepared and an appropriate amount of food must be supplied to the aquarium at an appropriate time. Therefore, there are a lot of parts that depend on work by humans, and it is work that requires a lot of labor (time).

  Therefore, the inventors conducted various studies to simplify feeding work and lighten labor when producing bivalve seedlings such as clams. As a result, it was found that appropriate and sufficient food is contained in normal natural seawater. However, simply using natural seawater for feeding work does not improve seedling production efficiency. By investigating the cause and taking countermeasures, it is possible to efficiently use bivalve seedlings using natural seawater. Has developed a new device and method.

JP 2009-273405 A JP 2007-159507 A

  An object of the present invention is to provide a bivalve seedling production apparatus and method that can efficiently produce bivalve seedlings while simplifying the feeding operation.

  In order to achieve the above object, a bivalve seedling production apparatus according to the present invention includes a water tank for storing bivalve seedlings, a water supply means for supplying seawater to the water tank, and seawater supplied by the water supply means to the water tank. A water supply filter that filters before being drained, drainage means for draining seawater stored in the aquarium out of the aquarium, and drainage filter for filtering the seawater drained by the drainage means before draining out of the aquarium The water supply filter has a specification that allows phytoplankton contained in the supplied seawater to pass therethrough and does not allow zooplankton to pass through, and the drainage filter is a bivalve shell contained in the water tank. It is a specification that does not allow seeds to pass through.

  The method for producing bivalve seedlings according to the present invention includes accommodating bivalve seedlings in a water tank, supplying seawater to the water tank through a water supply filter, and supplying seawater stored in the water tank through a drainage filter. Discharge outside the aquarium, pass the phytoplankton contained in the supplied seawater with the feed water filter, supply seawater to the aquarium without passing the zooplankton, and with the drainage filter, Seawater is discharged out of the water tank without passing through the bivalve seedlings contained in the water tank.

  According to the present invention, phytoplankton contained in seawater can be supplied as feed for seedlings by supplying normal natural seawater to a water tank in which bivalve seedlings are accommodated. Therefore, the work by manpower becomes very small, and the feeding work can be remarkably simplified. In addition, the feedwater filter is used to pass phytoplankton contained in the seawater, while supplying the seawater to the tank without passing zooplankton, thus preventing zooplankton from entering the seawater in the tank. it can. Thereby, the risk that the phytoplankton used as seed and seedlings will be eaten by the zooplankton is reduced. Furthermore, since the seawater is discharged out of the water tank without passing through the bivalve seedlings contained in the water tank using the drainage filter, the seawater is appropriately purified while preventing the seedlings in the water tank from being washed away. . Therefore, it is possible to grow a large number of bivalve seedlings in a certain period.

It is explanatory drawing which illustrates the production apparatus of the bivalve seedlings of this invention. It is explanatory drawing which illustrates the maintenance method of a water supply filter and a drainage filter.

  Hereinafter, the bivalve seedling production apparatus and method of the present invention will be described based on the embodiments shown in the drawings.

  A bivalve seedling production apparatus 1 (hereinafter referred to as production apparatus 1) of the present invention illustrated in FIG. 1 includes a water tank 2, a water supply pipe 5, a water supply pump 6, a water supply filter 3, a drain pipe 7, and a drain. And a filter 4. In this embodiment, an aeration 8 for continuously supplying air into the water tank 2 and a control unit 9 are further provided. A large number of bivalve seedlings S are accommodated in the water tank 2. Examples of clams stored in the aquarium 2 include clams, swordfish, clams and the like.

  The water supply pipe 5 and the water supply pump 6 are water supply means for supplying natural water W collected from the sea to the water tank 2. Operation and stoppage of the water supply pump 6 are controlled by the control unit 9.

  The water supply filter 3 filters the seawater W supplied by the water supply means before being injected into the water tank 2. The water supply filter 3 of this embodiment is composed of a bowl-shaped mesh frame 3a and a sheet-shaped filter 3b that is detachably attached along the mesh frame 3a. The mesh size of the mesh frame 3a is larger than that of the filter 3b. As the filter 3b, known materials of various materials such as nonwoven fabric and resin can be used. The feed water filter 3 is arranged above the sea water W surface stored in the water tank 2, and the sea water W supplied by the water supply means is injected into the inside of the mesh frame 3a.

  When the seawater W is injected into the water tank 2, the feed water filter 3 allows the phytoplankton A contained in the seawater W to pass therethrough and prevents the zooplankton B from passing therethrough. The size of phytoplankton A such as diatom is about 40 μm or less, and the size of zooplankton B that feeds on phytoplankton A is about 200 μm or more. Therefore, the size of the eyes of the filter 3b is set to 100 μm (about 80 μm to 150 μm).

  The drain pipe 7 is a drain means for discharging the seawater W stored in the water tank 2 to the outside of the water tank 2. In this embodiment, the drain pipe 7 is provided with an on-off valve 7a. The opening and closing of the on-off valve 7a is controlled by the control unit 9. For the drainage means, for example, it is preferable to use the principle of siphon that does not require a power source and has a relatively slow drainage speed.

  The drainage filter 4 filters the seawater W discharged from the water tank 2 by the drainage means before discharging it out of the water tank 2. The drainage filter 4 of this embodiment includes a bowl-shaped mesh frame 4a and a sheet-shaped filter 4b that is detachably attached along the mesh frame 4a. The mesh size of the mesh frame 4a is larger than that of the filter 4b. As the filter 4b, known materials of various materials such as nonwoven fabric and resin can be used. The drainage filter 4 is immersed in the seawater W stored in the water tank 2 and arranged. One end of the drain pipe 7 is disposed below the sea water W surface inside the mesh frame 4a.

  When discharging the seawater W to the outside of the water tank 2, the drainage filter 4 prevents the bivalve seedlings S contained in the water tank 2 from passing therethrough. Since the size of the seedling S contained in the water tank 2 varies depending on the type of bivalve and the growth process, an appropriate eye size filter 4b is used according to the size. For example, when the seedling S is a clam larva, the size of the seedling S is approximately 60 μm or more, so the eye size of the filter 3 b is set to 50 μm.

  Next, the procedure of the bivalve seedling production method of the present invention will be described.

  First, the bivalve seedling S is stored in the water tank 2 at the stage of larvae. Next, the seawater W supplied through the water supply pipe 5 by operating the water supply pump 6 is injected into the water tank 2 through the water supply filter 3, and a prescribed amount of seawater W is stored in the water tank 2. Before accommodating the seedling S in the water tank 2, a predetermined amount of seawater W may be stored in the water tank 2 in advance.

  Thereafter, under the control of the control unit 9, a predetermined amount of seawater W is supplied to the water tank 2 by a water supply means at a predetermined time. The aeration 8 is continuously operated. The supplied seawater W includes phytoplankton A and zooplankton B. The phytoplankton A passes through the mesh frame 3a and the filter 3b and is injected into the water tank 2 together with the seawater W. On the other hand, zooplankton B is captured by the filter 3 b and is not injected into the water tank 2.

  Therefore, in the seawater W stored in the aquarium 2, there is almost no zooplankton B that feeds on the phytoplankton A, and there is an appropriate amount of the seedlings S and phytoplankton A that feeds the seedlings S. It becomes a state. Therefore, the seedling S can be grown from the larva to the mother shell through the juvenile by feeding an appropriate bait (phytoplankton A) in the water tank 2.

  When natural seedling W is simply supplied to the aquarium S at the stage where the seedling S is equal to or less than the size of the zooplankton B, many phytoplankton A contained in the seawater W becomes zooplankton. B eats. That is, the seedling S contained in the water tank S is disturbed by the zooplankton B and cannot sufficiently eat the phytoplankton A, resulting in a problem that the seedling S is killed or the growth condition becomes extremely poor. Therefore, in the present invention, at the stage where the seedlings S cannot win the bait with the zooplankton B, this problem is solved by supplying the seawater W to the water tank 2 via the feed water filter 3.

  By simply supplying seawater W to the aquarium 2, the seawater W overflows from the aquarium 2, and the seawater W is also contaminated by the excrement of the seedlings S and the like. Therefore, the seawater W stored in the water tank 2 is discharged to the outside of the water tank 2 via the drainage filter 4, and the seawater W stored in the water tank 2 is maintained as much as possible. A predetermined amount of seawater W is discharged outside the aquarium 2 at a predetermined time by the control of the control unit 9.

  When the seawater W is discharged, the seedling S cannot pass through the filter 4b, and therefore is not discharged out of the water tank 2. Further, dirt C smaller than the eyes of the filter 4b passes through the mesh frame 4a and the filter 4b and is discharged out of the water tank 2 together with the seawater W. Dirt C larger than the eyes of the filter 4b is captured by the filter 4b.

  When the zooplankton B captured by the filter 3b of the feed water filter 3 becomes conspicuous at every elapse of a predetermined period, it is attached along the inside of the mesh frame 3a as illustrated in FIG. The filter 3b is removed and replaced with a new filter 3b. Alternatively, the zooplankton B trapped by the filter 3b is removed and washed, and then attached to the mesh frame 3a again for use. The mesh frame 3a is also washed appropriately.

  Similarly, the filter 4b of the drainage filter 4 is arranged along the outside of the mesh frame 4a as illustrated in FIG. 2 when a predetermined period has elapsed or when the dirt C captured by the filter 4b becomes noticeable. The filter 4b that has been attached is removed and replaced with a new filter 4b. Alternatively, the dirt C trapped by the filter 4b is removed and washed, and then attached to the mesh frame 4a again for use. The mesh frame 4a is also washed appropriately.

  If the drainage speed is too fast, the phytoplankton A may be discharged out of the aquarium 2 together with the seawater W. Therefore, it is preferable to use a drainage means that uses the principle of siphon, which has a relatively slow drainage speed. If the siphon principle is used, no special power source can be required for the drainage itself. In order to smooth the flow of the seawater W in the aquarium 2 and prevent stagnation, the position where the seawater W is supplied to the aquarium 2 and the position where the seawater W is discharged from the aquarium 2 are respectively positioned opposite to the aquarium 2. It is preferable to do.

  After the seedlings S become juveniles and grow larger than the zooplankton B contained in the seawater W, the seedlings S and the animals can be used even if the zooplankton B is contained in the seawater W of the aquarium 2. There is no risk that the seed plan S will not be able to feed the phytoplankton A due to competition with the sex plankton B. Therefore, after that, the water supply filter 3 can be removed and the seawater W can be directly supplied to the water tank 2 from a water supply means.

  As the seedling S grows, the amount of phytoplankton A required increases, so the amount of seawater W per period supplied to the aquarium 2 is also increased. Along with this, the amount of seawater W discharged to the outside of the water tank 2 per certain period is also increased.

  According to the present invention, the phytoplankton A contained in the seawater W is supplied to the aquarium S in which the bivalve seedlings S are accommodated as described above. Can be supplied as bait. Therefore, it is possible to remarkably simplify the feeding work that has conventionally been mostly manual work.

  In addition, since the zooplankton B is prevented from entering the seawater W of the aquarium 2 using the feed water filter 3, the phytoplankton A is competed by the seedling S and the zooplankton B in the aquarium 2. You can avoid eating. Thereby, many seedlings S can be grown greatly in a fixed period. That is, it is advantageous for efficiently producing the seedling S. The drainage filter 4 is used to discharge the seawater W out of the water tank 2 without passing through the seedling S contained in the water tank 2, so that the risk of the seedling S being washed away is reduced, and the seawater W in the water tank 2 is also reduced. Is moderately purified. Therefore, it is more and more advantageous to efficiently produce the bivalve seedling S.

DESCRIPTION OF SYMBOLS 1 Production apparatus 2 Water tank 3 Water supply filter 3a Mesh frame 3b Filter 4 Drainage filter 4a Mesh frame 4b Filter 5 Water supply pipe 6 Water supply pump 7 Drainage pipe 7a Open / close valve 8 Aeration 9 Control part A Plant plankton B Animal plankton C Dirt S Bivalve seedlings W Seawater

Claims (8)

  A water tank containing bivalve seedlings, a water supply means for supplying seawater to the water tank, a water supply filter for filtering the seawater supplied by the water supply means before being injected into the water tank, and stored in the water tank And a drainage filter for filtering the seawater discharged by the drainage means before discharging it to the outside of the water tank. The water supply filter is included in the supplied seawater. Production of bivalve seedlings characterized in that it passes through phytoplankton and does not pass through zooplankton, and the drainage filter does not allow passage of bivalve seedlings contained in the aquarium apparatus.   2. The bivalve seedling production apparatus according to claim 1, wherein the drainage means is a drainage means utilizing the principle of siphon.   The water supply filter is composed of a bowl-shaped mesh frame and a sheet-like filter that is detachably attached along the mesh frame, and is disposed above the seawater level stored in the water tank, The apparatus for producing bivalve seedlings according to claim 1 or 2, wherein seawater supplied by the water supply means is injected into the inside of the mesh frame.   The drainage filter is composed of a bowl-shaped mesh frame and a sheet-like filter that is detachably attached along the mesh frame, and is disposed by being immersed in seawater stored in the water tank, The apparatus for producing a bivalve seedling seedling according to any one of claims 1 to 3, wherein one end of a drain pipe serving as a drain means is disposed below a sea level inside the mesh frame.   The bivalve seedlings are stored in a water tank, and seawater is supplied to the water tank via a water supply filter, and the seawater stored in the water tank is discharged to the outside of the water tank via a drainage filter. , While passing phytoplankton contained in the supplied seawater, supplying seawater to the aquarium without passing zooplankton, and passing the seedlings of bivalves contained in the aquarium by the drainage filter A method for producing bivalve seedlings, characterized in that seawater is discharged outside the aquarium without causing it to escape.   6. The method for producing bivalve seedlings according to claim 5, wherein the seawater stored in the aquarium is discharged out of the aquarium using the principle of siphon.   The water supply filter is composed of a bowl-shaped mesh frame and a sheet-like filter that is detachably attached along the mesh frame, and is disposed above the seawater surface stored in the water tank. The method for producing bivalve seedlings according to claim 5 or 6, wherein seawater is injected into the inside of the mesh frame to supply seawater to the aquarium.   The drainage filter is composed of a bowl-shaped mesh frame and a sheet-like filter that is detachably attached along the mesh frame, and is disposed by being immersed in seawater stored in the water tank. The bivalve seedling production method according to any one of claims 5 to 7, wherein one end of the clam is disposed below the seawater surface inside the mesh frame, and seawater is discharged out of the water tank through the drainage pipe.

Images