JP3930880B2 - Circulation filtration aquaculture equipment - Google Patents

Description

  The present invention relates to a circulating filtration type aquaculture apparatus for culturing seafood in a breeding aquarium while purifying by circulating water between the breeding aquarium and a filtration tank.

  When cultivating fish and shellfishes in a breeding aquarium at high density or temporarily cultivating them, the breeding aquarium and filtration tank are used such that the water in the breeding aquarium is filtered and purified by a filtration tank and then returned to the breeding aquarium. A closed-circulation culture system for circulating water between them is provided.

  In such a circulating filtration type aquaculture device, the filtration tank is generally formed in a cylindrical shape or a box shape and is generally installed side by side with the breeding aquarium, but since the filtration tank has a large volume, If the filtration tanks are installed side by side, a large space is required. Therefore, it has been proposed to arrange the filtration tank along the periphery of the breeding water tank (see, for example, Patent Document 1).

If the filtration tank is arranged along the periphery of the breeding aquarium in this way, the filtration tank is formed into an elongated shape and integrated with the breeding aquarium, so the breeding tank and the filtration tank are combined into one. The installation space can be reduced, and the aquaculture device can be easily installed on land.
JP 2002-360110 A

  However, in Patent Document 1, the water purified in the filtration tank is sent to the storage tank through the connecting pipe, and then returned to the breeding tank through the supply pipe. From the filtration tank to the breeding tank The piping for returning the water to the tank becomes complicated, and despite the fact that the breeding tank and the filtration tank are combined into one, a space for the piping for returning this water is required, and the installation space is reduced. The effect of making it smaller was reduced.

  The present invention has been made in view of the above points, and an object of the present invention is to provide a circulating filtration type aquaculture apparatus that can further reduce the installation space.

The circulating filtration type aquaculture apparatus according to claim 1 of the present invention comprises a breeding aquarium 1 for rearing fish and shellfish, and a filtration tank 3 for filtering and purifying water with a filled filter medium 2, and water in the breeding aquarium 1. Is supplied to the filtration tank 3 by the circulation pump 4, and the filtration tank 3 is arranged along the periphery of the breeding tank 1 in the circulation filtration type aquaculture apparatus in which the water purified by the filtration tank 3 is returned to the breeding tank 1. The circulation pump 4 allows the water in the breeding tank 1 to flow into the upstream end of the water flow in the filtration tank 3 and the return outlet 5 provided at the downstream end of the water flow in the filtration tank 3. Are directly connected to the breeding aquarium 1, partition plates 82 are provided at a plurality of locations along the water flow direction in the filtration tank 3, and openings 83 through which water passes are provided in each partition plate 82. it is characterized in that formed by placing the opening 83 at different height positions.

  Further, the invention of claim 2 comprises the solid content removing device 6 that removes the solid content from the water in the breeding aquarium 1 and supplies the solid content removal device 6 to the filtration tank 3. It is characterized by being arranged along the periphery.

  The invention of claim 3 is characterized in that, in claim 1 or 2, the rearing tank 1 and the filtration tank 3 are formed separately, and the filtration tank 3 is arranged along the periphery of the breeding tank 1. Is.

  The invention of claim 4 is characterized in that, in any one of claims 1 to 3, the breeding water tank 1 is formed by retaining the sheet material 81 in a tank shape having an open top surface.

The invention of claim 5, returned in any one of claims 1 to 4, the filtration tank 3 is formed from a plurality of tanks units 84 along the flow direction of the water, the final tank unit 84 of the water flow direction An outlet 5 is provided, and an overflow port 85 is provided in at least one tank unit 84 other than the final one.

Further, the invention of claim 6 is that in claim 5 , the final tank unit 84 in the direction of water flow is formed as a fixed tank 86 filled with the filter medium 2 in a stationary state, and the tank units 84 other than the final are formed. The filter medium 2 is formed as a fluidized tank 87 filled with a fluidized state.

According to a seventh aspect of the present invention, in any one of the first to sixth aspects, the air diffusion pipe 8 is provided at the bottom of the filtration tank 3 and the air diffusion pipe 8 is disposed at a position closer to one side in the width direction of the filtration tank 3. 3, the bottom of at least one side in the width direction is formed on an inclined surface 80 that inclines upward toward the outside.

  According to the present invention, by disposing the filtration tank 3 along the periphery of the breeding water tank 1, it is possible to reduce the installation space by bringing the breeding water tank 1 and the filtration tank 3 together. In addition, by directly connecting the return outlet 5 of the filtration tank 3 and the breeding aquarium 1, complicated piping for returning water from the filtration tank 3 to the breeding aquarium 1 becomes unnecessary, and the installation space can be further reduced. Moreover, the filtration tank 3 can be formed as a long flow path, the purification performance in one pass is improved, and the height of the filtration tank 3 can be lowered, so that the seafood to the breeding aquarium 1 It becomes easy to take in and out and observe seafood, and manage seafood.

  Hereinafter, the best mode for carrying out the present invention will be described.

  FIG.1 and FIG.2 shows an example of embodiment of this invention, The filtration tank 3 is arrange | positioned along the outer periphery of the breeding water tank 1 with which the upper surface was open | released. The filtration tank 3 may be formed integrally with the breeding water tank 1 or may be formed separately. Moreover, when the outer periphery of the breeding water tank 1 is formed in the cylindrical shape, the filtration tank 3 is arrange | positioned so that it may become an annular | circular shape. Further, the filtration tank 3 may be formed integrally with the entire length. However, in the embodiment of FIG. 1, the filtration tank 3 is partially divided so that the filtration tank 3 is formed on a part of the outer periphery of the breeding water tank 1. A non-arranged portion 125 is formed. By forming the portion 125 where the filtration tank 3 is not disposed in this way, a part of the outer periphery of the breeding aquarium 1 directly faces the outside, and the seafood is taken into and out of the filtration tank 3 through the external exposed portion 125, It makes it easy to perform operations such as feeding and checking. In this case, if the width of the filtration tank 3 is narrow, the above operation can be performed easily through the filtration tank 3, and it is not necessary to form the externally exposed portion 125. May be provided over the entire length of the outer periphery of the rearing tank 1.

  In the embodiment of FIG. 1, the filtration tank 3 is formed by connecting a plurality of tank units 84. FIG. 3 shows a tank unit 84 formed of FRP or the like. Opening 90 is provided at both ends in the longitudinal direction (water flow direction) and the cross-sectional shape in the width direction is formed in a U shape. Joining flanges 91 extend at the inner edges of the openings 90 at both ends in the longitudinal direction, and as shown in FIG. 5 (a), partition plates are held on the inner surfaces of both side walls of the tank unit 84 at five locations in the longitudinal direction. Grooves 92a to 92e are recessed. Further, as shown in FIG. 1 (b), the tank unit 84 is formed on an inclined surface 80 that is inclined obliquely upward with the lower end portions of both side walls outward. Further, an overflow bulging portion 93 is provided on the upper end of the inner side wall of the tank unit 84 so as to bulge outward, and the upper end of the overflow bulging section 93 is as shown in FIG. 5B. It is cut out so as to be lower than the upper end of the side wall of 84, and an overflow port 85 is formed in this cutout portion. A drain valve 95 is provided at the bottom of each tank unit 84.

  In the embodiment of FIGS. 1 and 2, a plurality of tank units 84 (three in the embodiment of FIGS. 1 and 2) are joined to form a pair of tank unit groups 94a and 94b. The filtration tank 3 is formed by arranging 94a, 94b on the outer periphery of the breeding water tank 1, and the breeding water tank 1 as described above is provided between one end and the other end of the tank unit groups 94a, 94b. An externally exposed portion 125 that directly faces the outside is formed on a part of the outer periphery of the outer periphery.

  As shown in FIG. 6B (see also FIG. 3), the tank units 84 are connected by making the openings 90 of the adjacent tank units 84 face each other and joining the joining flanges 91 through the frame-shaped packing 96. This can be performed by connecting the joining flange 91 with the bolt and nut 97. And as shown to Fig.6 (a), the partition plate 82 is attached to the inner surface side of the joining flange 91 of this tank unit 84 so that the opening 90 of the tank unit 84 located in the upstream of the flow of water may be block | closed. The attachment of the partition plate 82a can be performed using a bolt and nut 97 for connecting the joining flange 91. An opening 83 with a net 98 is formed in the partition plate 82a. By attaching the partition plate 82a in this way, the opening 83 is disposed in the upper part of the filtration unit 84. Here, in the tank unit 84 located at both ends of the tank unit groups 94a and 94b, the opening 90 on the end side is not used for connection, so the opening 90 is closed with a closing plate or the like. Or each tank unit 84 may be shape | molded in the state which does not provide the opening 90, and you may make it form the opening 93 by post-processing, such as cutting, in the edge part of the side used for a connection. Moreover, the tank unit 84 located in the most downstream of the water flow of one tank unit group 94a and the tank unit 84 located in the most upstream of the water flow of the other tank unit group 94b are shown in FIG.4 (b). Thus, it connects with the connecting pipe 100 attached between the lower end parts of the tank unit 84. FIG. In FIG. 1A, reference numeral 118 denotes a drain valve provided in the connecting pipe 100.

  As described above, the filtration tank 3 can be formed by connecting a plurality of tank units 84, and the upper surface opening of each tank unit 84 is covered with two lids 101 as shown in FIG. It is designed to be attached. By forming the filtration tank 3 from a plurality of tank units 84 in this way, the constituent members of the filtration tank 3 can be reduced in size, and the construction for installing the filtration tank 3 is facilitated.

  Further, in the filtration tank 3 composed of a plurality of tank units 84 as described above, the final tank unit 84 in the water flow direction is formed as a fixed tank 86 in which the granular filter medium 2 is allowed to stand, The other tank unit 84 is formed as a fluid tank 87 containing the particulate filter medium 2 in a fluid state. Here, in the embodiment of FIGS. 1 and 2, the filtration tank 3 is formed from a pair of tank unit groups 94a and 94b, and one tank unit group 94a is formed into tank units 84a, 84b and 84c in the order of water flow. Since the other tank unit group 94b is formed by the tank units 84d, 84e, and 84f in the order of water flow, the tank units 84a to 84e are formed as the flow tank 87 and the tank unit 84f is formed as the fixed tank 86. is there.

  Here, as shown in FIG. 6, a diffuser tube 8 is arranged along the water flow direction at the bottom of each tank unit 84. The air diffuser 8 is composed of a flow diffuser 8a provided at the bottom of the tank units 84a to 84e forming the fluid tank 87, and a cleaning air diffuser 8b provided at the bottom of the tank unit 84f forming the fixed tank 86. Is. The upper ends of the connection pipe portions 103 raised at both ends of these air diffusion pipes 8 are projected from the side wall of the tank unit 84 to the outside and connected to the air supply pipes 104 arranged on the outer peripheral part of the filtration tank 3. Yes (see FIG. 3). In FIG. 3, reference numeral 119 denotes a valve provided in the connecting pipe portion 103. In each tank unit 84, the air diffuser 8 is arranged at a position closer to one side in the width direction of the tank unit 84 as shown in FIG.

  Further, each tank unit 84 (excluding the final tank unit 84f) forming the fluidized tank 87 is inserted into the partition plate holding groove 92c at the center thereof so that the partition plate 82 is as shown in FIGS. 4 and 6C. It is attached and the center part in the tank unit 84 is partitioned by the water flow direction. In the partition plate 82b attached to the central portion of the tank unit 84, an opening 83 with a net 98 is formed in the lower portion thereof as shown in FIG. 7 (a), and the partition plate 82b is attached to the filtration unit 84. By attaching, the opening 83 is arranged in the lower part of the filtration unit 84. The partition plate 82b is detachably inserted into the partition plate holding groove 92c and attached, and the diffuser tube 8 is fitted and pressed into a fitting recess 106 formed at the lower end of the partition plate 82b. The air diffuser 8 can be repaired or replaced by pulling out the partition plate 82b.

Of each tank unit 84, the partition plate holding groove 92e at the downstream end of the tank unit 84c located on the most downstream side of the water flow of the tank unit group 94a, and the most upstream of the water flow of the tank unit group 94b. The partition plate 82c is inserted and attached to the partition plate holding groove 92a at the upstream end of the tank unit 84d (see FIGS. 4B and 4C). As shown in FIG. 7 (b), the partition plate 82c is formed with an opening 83 with a net 98 stretched on the upper portion thereof. By attaching the partition plate 82c to the filtration unit 84, the opening 83 is formed into the filtration unit. 84 is arranged in the upper part. By attaching the partition plate 82c to the ends of the tank units 84c and 84d in this way, the filter medium 2 filled in the tank units 84c and 84d is prevented from flowing out of the tank through the connection pipe 100.

  Furthermore, in the tank unit 84f forming the fixed tank 86, a partition plate 82d provided with an opening 83 with a net 98 in the upper part as shown in FIG. A partition plate 82b provided with an opening 83 with a net 98 in the lower portion as shown in FIG. 7A is attached to the partition plate holding grooves 92b and 92d so as to be freely pulled out. By fitting and pressing the diffuser tube 8 into the fitting recess 106 formed at the lower ends of the partition plates 82b and 82d, it is possible to prevent the diffuser tube 8 from being lifted and to pull out the partition plates 82b and 82d. The air diffuser 8 can be repaired or replaced. The net 98 stretched on the opening 83 of the partition plate 82 is formed in a mesh size that allows water to pass through without resistance but does not allow the filter medium 2 to pass through.

  On the other hand, the breeding water tank 1 is formed of a waterproof sheet material 81. That is, the sheet material 81 is cut into a circular shape, and its peripheral end is attached to the ring-shaped frame 107 and lifted, thereby retaining the shape of the tank having a cylindrical side wall as shown in FIG. Thus, the breeding aquarium 1 can be formed. And the breeding water tank 1 is supported by the filtration tank 3 by fixing the ring-shaped frame 107 to the outer surface of the inner peripheral side of the tank unit 84 which forms the filtration tank 3 as shown in FIG. By forming the breeding aquarium 1 with the waterproof sheet material 81 as described above, the breeding aquarium 1 can be produced at a low cost, and the construction for installing the breeding aquarium 1 having a large volume is facilitated. It is.

  A discharge port 48 is provided at the center of the bottom surface 17 of the breeding water tank 1, and one end of the flow pipe 15 is connected to the lower side of the discharge port 48. The other end of the flow pipe 15 is connected to the upstream end of the water flow of the tank unit 84a located at the uppermost stream of the water flow of one tank unit group 94a. A solid content removing device 6 and a circulation pump 4 are connected to the flow pipe 15. The solid content removing device 6 is formed from a drum filter 22 and a foam separation tank 23, and is connected to the feed pipe 15 in the order of the drum filter 22, the circulation pump 4, and the foam separation tank 23 along the flow direction of water. It is. The solid content removing device 6 and the circulation pump 4 are disposed and arranged substantially in parallel along the periphery of the breeding water tank 1. Moreover, the return outlet 5 is provided in the tank unit 84f located in the most downstream of the water flow of the other tank unit group 92b, and this return outlet 5 is provided on the peripheral edge of the breeding water tank 1 as shown in FIG. It is arranged. Therefore, the water flowing out from the return outlet 5 flows directly into the breeding aquarium 1, and the return outlet 5 is directly connected to the breeding aquarium 1 without using piping or the like.

  Here, as described above, each tank unit 84 is provided with an overflow bulging portion 93 to form an overflow port 85. The overflow port 85 is located above the peripheral end of the breeding water tank 1 as shown in FIG. It is arranged in. The overflow port 85 is provided with a net 123. Only the tank unit 84f at the end of the water flow is provided with a return outlet 5 in place of the overflow port 85. The return outlet 5 is formed by cutting out the overflow bulge portion 93 and cutting it out. It is formed by attaching the discharge rod 108 to the excision opening 121 that opens as shown in FIG. By fitting and fixing the mounting portion 109 provided on the discharge rod 108 to the portion where the cut opening 121 is cut, the discharge rod 108 is attached so as to protrude from the side wall of the tank unit 84f. By providing the return outlet 5 at one side end of the tank, the return outlet 5 opens in a direction parallel to the outer surface of the tank unit 84f on the breeding water tank 1 side. The excision opening 121 is provided with a net 122. Here, as described above, each tank unit 84 is provided with a plurality of partition plate holding grooves 92a to 92e, and various partition plates 82b to 82d are selected and any one of the partition plate holding grooves 92a to 92e is selected. Since the return outlet 5 can be formed by using the overflow bulging portion 93 as described above, the tank unit 84 manufactured by FRP or the like using the same mold is used. Can be used as any of the tank units 84a to 84f, the tank unit 84 can be manufactured by sharing the mold, and the manufacturing cost of the tank unit 84 can be reduced. Is.

  Although the particulate filter medium 2 is incorporated in the filtration tank 3, among the tank units 84 a to 84 f constituting the filtration tank 3 as described above, the tank units 84 a to 84 e have the diffuser pipe 8 (flow) By constantly aerating air from the air diffuser tube 8a) and aeration, the filter medium 2 is wound up in the water in the tank units 84a to 84e, and the fluid tank 87 in which the filter medium 2 always flows in the tank units 84a to 84e is formed. It is made to do. Here, since the air diffuser 8 is arranged at a position biased to the side wall on one long side of the tank units 84a to 84e as described above, the convection in the vertical direction is generated in the water in the tank units 84a to 84e. The filter medium 2 flows up and down by this convection and is stirred. And since the inclined surface 80 is formed in the lower part of each side wall of the long side which tank unit 84a-84e opposes as mentioned above, water follows one inclined surface 80 in the bottom part of tank unit 84a-84e. It rises and convects so that it falls along the other inclined surface 80, and it convects with a smooth flow so that the part where water stays does not arise in the corner | angular part of the bottom part of tank unit 84a-84e. is there. Therefore, the water stays in the corners of the bottoms of the tank units 84 a to 84 e forming the fluid tank 87 so that the part where the filter medium 2 does not move can be prevented, and the filter medium 2 in the fluid tank 87 can be removed. It can be efficiently flowed and stirred uniformly.

  Of the tank units 84a to 84f, in the final tank unit 84f, air is not ejected from the air diffuser 8 (cleaning air diffuser 8b) provided at the bottom during normal operation. The filter medium 2 settles in water under its own weight, and is deposited on the bottom of the tank unit 84f to form a fixed tank 86 in a state where the filter medium 2 is allowed to stand. The air diffuser 8 provided in the tank unit 84f forming the fixed tank 86 is operated when the filter medium 2 in the fixed tank 86 is washed as will be described later.

  In the aquaculture apparatus formed as described above, the aquarium 1 is filled with water such as seawater, and the seafood is bred in the aquarium 1. The water in the breeding aquarium 1 is circulated and purified with the filtration tank 3, but the water in the breeding aquarium 1 is sent out from the feed pipe 15 and is first fed into the underwater feed and feces by the drum filter 22. Solids such as suspended solids (SS) are physically separated and removed. The water from which the solid content or the like has been removed by the drum filter 22 is sent to the foam separation device 23 through the feed pipe 15 by the circulation pump 4, and organic matter such as protein in the water is foamed and removed as foam. The water thus treated flows into the tank unit 84a at the start end of the filtration tank 3. Here, since the solid content removing device 6 is arranged along the periphery of the breeding aquarium 1, the solid content removing device 6 is integrated with the breeding water tank 1 together with the filtration tank 3 to reduce the installation space. It is made to be able to.

  And the water which flowed into the filtration tank 3 receives a purification | cleaning effect | action in tank unit 84a-84e which forms the fluid tank 87 first. In the fluidized tank 87, in the aerobic state aerated by the diffuser tube 8 (flow diffuser tube 8a), the nitrifying bacteria on the surface of the filter medium 2 are subjected to nitrification, and the ammonia in the water is oxidized to nitrous acid, and further nitric acid. Ammonia is converted to nitrate nitrogen with low fish toxicity. At this time, since the filter medium 2 in the fluidized tank 87 flows and is stirred, the contact efficiency between the nitrifying bacteria adhering to the filter medium 2 and water is increased, and ammonia can be removed with high nitrification ability. . Next, the water that has passed through the tank units 84a to 84e forming the fluid tank 87 is transferred to the tank unit 84f that forms the fixed tank 86, and is similarly subjected to nitrification by nitrifying bacteria attached to the filter medium 2 in the fixed tank 86. . Since the fixed tank 86 is not aerated, the filter medium 2 is settled and deposited in the fixed tank 86, and solid matter such as SS in the water is captured by the filter medium 2 when water passes between the accumulated filter media 2. To be removed. Water thus biologically filtered in the fluid tank 87 and the fixed tank 86 is returned to the breeding water tank 1 from the return outlet 5 of the final tank unit 84f.

  The return outlet 5 is provided at the downstream end of the partition plate 82b downstream of the water flow of the tank unit 84f. In the tank unit 84f, the filter medium 2 is provided in the chamber 112 at the end downstream of the partition plate 82c. Is not filled. Therefore, the filter medium 2 is prevented from flowing out from the return outlet 5. The chamber 112 may be provided with a heat exchanger so that the water temperature can be adjusted.

  In performing biological filtration by passing water through the filtration tank 3 as described above, the water flowing into the starting tank unit 84a passes through the opening 83 at the bottom of the tank provided in the partition plate 82b, and then enters the partition plate 82a. It moves to the tank unit 84b through the opening 83 at the upper part of the tank. The water transferred to the tank unit 84b passes through the opening 83 in the lower part of the tank provided in the partition plate 82b, and then flows to the tank unit 84c through the opening 83 in the upper part of the tank provided in the partition plate 82a (FIG. )reference). The water advected to the tank unit 84c passes through the opening 83 in the upper part of the tank provided in the partition plate 82c after passing through the opening 83 in the lower part of the tank provided in the partition plate 82b, and passes through the connection pipe 100 in the lower part of the tank. It moves to the tank lower part of the unit 84d. The water advected to the tank unit 84d passes through the opening 83 in the upper part of the tank provided in the partition plate 82c, then passes through the opening 83 in the lower part of the tank provided in the partition plate 82b, and passes through the opening 83 in the upper part of the tank provided in the partition plate 82a. It flows to the tank unit 84e through the opening 83 (see FIG. 4B). The water transferred to the tank unit 84e passes through the opening 83 in the lower part of the tank provided in the partition plate 82b, and then passes through the opening 83 in the upper part of the tank provided in the partition plate 82a to be transferred to the tank unit 84f. The water advected to the tank unit 84f passes through the opening 83 in the upper part of the tank provided in the partition plate 82d after passing through the opening 83 in the lower part of the tank provided in the partition plate 82b, and passes through the opening 83 in the lower part of the tank provided in the partition plate 82b. After passing through the opening 83 and flowing into the chamber 112, it is returned to the breeding aquarium 1 from the return outlet 5 (see FIG. 4C). As described above, the water flowing through the filtration tank 3 alternately passes through the opening 83 at the upper part of the tank and the opening 83 at the lower part of the tank in each tank unit 84 so as to meander the water in the vertical direction. It is. Accordingly, the water passes through the filtration tank 3 at a long meandering distance, and the contact efficiency of the water with the filter medium 2 can be increased to perform highly efficient filtration.

  Moreover, if the flow of water in each tank unit 84 becomes worse, the water level in each tank unit 84 may rise and the water may overflow. Therefore, as described above, the overflow port 85 is provided at the upper edge of the side wall of the tank unit 84a to 84e on the rearing tank 1 side at the downstream end of the water flow, and the water level in the tank units 84a to 84e rises. Water overflows from the overflow port 85 and is returned to the breeding aquarium 1 to prevent the water from overflowing from the tank units 84a to 84e. Since the return outlet 5 is provided in the final tank unit 84f, it is not necessary to provide the overflow port 85 in the tank unit 84f.

  Next, the cleaning operation of the filter medium 2 in the fixed tank 86 will be described. As shown in FIG. 1A, one end and the other end of the cleaning pipe 114 are located at the bottom of the tank unit 84f forming the fixed tank 86, the position between the discharge port 48 of the flow pipe 15 and the drum filter 22. Connected. The cleaning pipe 114 is provided with a valve 115, and the flow pipe 15 is provided with a valve 116 at a location between the cleaning pipe 114 and the discharge port 48. First, the circulation pump 4 is stopped and the valve 115 of the cleaning pipe 114 is opened. The water in the filtration tank 3 flows out from the cleaning pipe 114 to the breeding tank 1 through the feed pipe 15, and the water level in the tank unit 84 f drops below the return outlet 5. Next, when the valve 116 of the flow pipe 15 is closed and air is ejected from the air diffuser 8 (cleaning air diffuser 8b) in the tank unit 84f, the filter medium 2 in the tank unit 84f is swirled in water and stirred. Is done. In this way, by stirring the filter medium 2 in the tank unit 84f, it is possible to perform cleaning for peeling off solid substances such as SS adhering to the surface of the filter medium 2. At this time, since the tank unit 84f is formed in a structure in which the filter medium 2 is easy to flow as in the case of the tank units 84a to 84e, the stirring effect of the filter medium 2 is high, and the filter medium 2 can be washed efficiently. Is. Next, when the circulation pump 4 is operated, the water in the tank unit 84f passes through the drum pipe 22 and the foam separator 23 of the solid content removing device 6 through the flow pipe 15 from the cleaning pipe 114 and then into the tank unit 84a. Sent back. Thus, by circulating water between the filtration tank 3 and the solid content removing device 6, the solid matter peeled off from the filter medium 2 by washing can be removed by the solid content removing device 6.

Next, a reference example of the aquaculture device will be described with reference to FIG. In the reference example of FIG. 11, the filtration tank 3 is provided along the inner surface of the outer peripheral wall 16 of the breeding water tank 1, but the filtration tank 3 may be provided along the outer surface of the outer peripheral wall 16. Further, in the reference example of FIG. 11, the inner wall 18 is erected on the inner side of the outer peripheral wall 16 of the breeding aquarium 1 with a predetermined gap, and the ceiling wall 19 is stretched between the inner wall 18 and the outer peripheral wall 16. Thus, the filtration tank 3 is formed integrally with the breeding aquarium 1 by using a part of the outer peripheral wall 16 and the bottom surface 17 of the breeding aquarium 1. When the filtration tank 3 is formed integrally with the breeding water tank 1 in this way, the number of members constituting the aquaculture device can be reduced, and the assembly work of the aquaculture device is facilitated. It is. Of course, a filtration tank 3 separate from the breeding aquarium 1 may be installed along the outer periphery of the breeding aquarium 1, and in this case, an existing one can be used as it is. It will be possible.

  The filtration tank 3 is provided over the entire circumference so as to go around the breeding water tank 1, but an end plate 21 is provided at one place in the filtration tank 3 to block the inner circumference of the filtration tank 3. By doing so, the one end of the end plate 21 is on the upstream side of the flow of water in the filtration tank 3, and the other end of the end plate 21 is on the flow of water in the filtration tank 3. The filtration tank 3 is formed in an elongated shape. And the above-mentioned feed pipe 15 is connected to the starting end of the filtration tank 3, and the return outlet 5 is formed facing the inside of the breeding water tank 1 by providing an opening in the inner wall 18 at the terminal end of the filtration tank 3. It is.

  Opening and closing members 7 are arranged at a plurality of locations along the water flow direction in the filtration tank 3. The opening / closing member 7 is formed as a plate provided with a vertical rotation shaft 25 at one end, and is centered on the rotation shaft 25 between a direction parallel to the longitudinal direction of the filtration tank 3 and a direction perpendicular thereto. Thus, the opening / closing member 7 can be rotated. When the opening / closing member 7 is rotated in a direction parallel to the longitudinal direction of the filtration tank 3 as indicated by a solid line in FIG. 11A, the inside of the filtration tank 3 communicates without being blocked by the opening / closing member 7. ”State. Further, when the opening / closing member 7 is rotated in a direction perpendicular to the longitudinal direction of the filtration tank 3 as indicated by a chain line in FIG. 11A, the inside of the filtration tank 3 is closed and blocked by the opening / closing member 7 and is closed. It becomes a state and can partition the inside of the filtration tank 3 in the direction along the circumference of the breeding water tank 1 by each opening and closing member 7, and between the adjacent opening and closing members 7 or between the opening and closing member 7 and the end plate 21. Each of the partition chambers 3a, 3b, 3c,... Isolated from each other can be formed.

Furthermore, a net-like water flow sheet 26 is stretched in the filtration tank 3 at the front and rear positions of each opening / closing member 7 in the water flow direction. In the example of the figure, a water flow sheet 26 is stretched from a location where the flow pipe 15 is connected to a location downstream of the water flow. The filter tank 3 is filled with the filter medium 2, and this filter medium 2 is disposed between the water flow sheets 26 stretched in the partitions of the partition chambers 3 a, 3 b, 3 c. Since the water flow sheet 26 is formed by a net of water that allows water to freely pass through, but does not allow the filter medium 2 to pass through, the filter medium 2 remains in the partition chambers 3a, 3b, 3c. It does not move or flow out of the compartment. Here, the filter medium 2 can be of any form such as a substantially cylindrical shape or granular shape, and may be a floating filter medium.

  Further, a cleaning air diffuser 8 is arranged along the bottom of the filtration tank 3 in each partition 3a, 3b, 3c. The air diffusion pipe 8 is formed by providing a large number of air discharge ports 28 along the longitudinal direction, and is connected to the main air supply pipe 30 via an air supply pipe 29 arranged in the vicinity of each opening / closing member 7. It is. The main air supply pipe 30 is connected to the blower 31, and the air is supplied from the air discharge ports 28 of the individual air diffusion pipes 8 by opening the valves 32 provided in the respective air supply pipes 29. , 3b, 3c,...

  Further, a drain pipe 9 is connected to each partition 3a, 3b, 3c,..., And a valve 33 is provided in each drain pipe 9. As described above, the water passing sheets 26 are stretched at the front and rear positions of each opening / closing member 7 in the water flow direction, and each opening / closing member 7 is disposed between these water passing sheets 26. The drain pipes 9 are also disposed between the water flow sheets 26 in the same manner as the opening / closing member 7.

  In the aquaculture apparatus formed as described above, the aquarium 1 is filled with water such as seawater, and the seafood is bred in the aquarium 1. The water in the breeding aquarium 1 is circulated and purified with the filtration tank 3, but the water in the breeding aquarium 1 is sent out from the flow pipe 15 and is firstly removed by the solid content removing device 6 in the water. Solids such as suspended matter (SS) derived from the above are physically separated and removed. The water from which the solid content or the like has been removed by the solid content removing device 6 is sent to the starting end portion of the filtration tank 3 through the feed pipe 15 by the circulation pump 4. At this time, all the open / close members 7 are in an open state parallel to the longitudinal direction of the filtration tank 3 as indicated by the solid line in FIG. 11A, and the inside of the filter tank 3 is blocked by the open / close member 7. It is in a state of communication from the start end to the end. Accordingly, the water flowing into the filtration tank 3 flows in the filtration tank 3 along the longitudinal direction from the start end to the end of the filtration tank 3 as indicated by the arrow in FIG. It is filtered with the filter medium 2 filled in. Aerobic microorganisms are cultivated on the surface of the filter medium 2, and the action of the microorganisms can nitrify ammonia resulting from the excrement of seafood into nitric acid that is non-toxic to seafood. In addition, the inside of the filtration tank 3 is formed in a sealed structure except for the part of the sending pipe 9 at the beginning and the return outlet 5 at the end and the part of the air vent pipe 39 described later, and the inside of the filtration tank 3 is filled with water. It is made to flow. The water thus biologically filtered and purified by the filter medium 2 in the filter tank 3 is returned to the breeding water tank 1 from the return outlet 5 at the end of the filter tank 3.

  Here, since the filtration tank 3 is arranged along the periphery of the breeding water tank 1 as described above, the breeding water tank 1 and the filtration tank 3 can be combined into one, and the filtration tank is located in the vicinity of the breeding water tank 1. As in the case where the three are installed side by side, the surroundings of the breeding aquarium 1 are not uneven, and the space for installing the aquaculture device can be reduced. And in particular, it is complicated to return water from the filtration tank 3 to the breeding aquarium 1 by opening the return outlet 5 of the filtration tank 3 in the breeding aquarium 1 and directly connecting the filtration tank 3 to the breeding aquarium 1. Piping is unnecessary, and the installation space can be further reduced. In addition to the filtration tank 3, the solid content removing device 6 is arranged along the periphery of the breeding water tank 1 as described above, so that the solid content removing device 6 is also integrated with the breeding water tank 1 in the same manner as the filtration tank 3. It is possible to reduce the installation space of the aquaculture device.

  Moreover, as a result of arranging the filtration tank 3 along the circumference | surroundings of the breeding water tank 1 as mentioned above, the filtration tank 3 is formed in the elongate form in the direction along the circumference | surroundings of the breeding water tank 1, The inflowing water comes into contact with the filter medium 2 at a long distance from the start end to the end of the filtration tank 3 and is filtered and purified with high efficiency. Thus, as a result of the filtration tank 3 being formed in an elongated shape, the cross-sectional area of the filtration tank 3 is reduced, and the flow rate of water flowing through the filtration tank 3 is increased. Here, considering the clogging between the filter media 2 due to adhesion of SS or the like to the surface of the filter media 2, it is desirable to use a filter media 2 having a small surface area per unit volume. Although the contact efficiency is poor, when the flow rate of the water flowing in the filtration tank 3 is increased, the amount of water staying on the surface of the filter medium 2 is reduced, and the efficiency of water contact with the filter medium 2 is increased. However, it is possible to efficiently filter and purify water. Furthermore, as a result of being able to reduce the cross-sectional area of the filtration tank 3, it is possible to form the filtration tank 3 with a low height. Water is pumped up by the circulation pump 4 to the filtration tank 3. In supplying, the circulation pump 4 having a small pumping capacity can be used, the running cost can be reduced, and the height of the upper surface of the filtration tank 3 is made lower than the upper end of the outer peripheral wall 16 of the breeding water tank 1. Thus, operations such as removal and maintenance of seafood in the breeding aquarium 1 can be easily performed from the outside of the outer peripheral wall 16 of the breeding aquarium 1.

During the normal operation in which the water in the breeding aquarium 1 is circulated and purified with the filtration tank 3, the circulation pump 4 is “ON”, the open / close members 7 are all “open”, the blower 31 is “OFF”, and the valve 32 and 33 are all “closed”. If this normal operation is continued, dirt such as SS adheres to the surface of the filter medium 2 in the filtration tank 3, the contact efficiency of water with the surface of the filter medium 2 is deteriorated, and water passes between the filter medium 2. Since it becomes difficult and the filtration / purification effect of the water by the filter medium 2 decreases, it is necessary to perform an operation called backwashing for cleaning the filter medium 2. And the dirt of the filter medium 2 in the filter tank 3 is not uniform over the entire length of the filter tank 3, for example, it is easy to get dirty in the part near the start end and hard to get dirty in the part near the end part. The degree of dirt varies depending on the flow direction. Therefore, in the present reference example , the inside of the filtration tank 3 can be partitioned into a plurality of partition chambers 3a, 3b, 3c... In the water flow direction, and the filter medium 2 is independently provided for each partition chamber 3a, 3b, 3c. Can be efficiently cleaned.

  That is, for example, when the filter medium 2 in the partition chamber 3a at the start end is washed, first, after the operation of the circulation pump 4 is turned “OFF”, among the open / close members 7, the open / close member 7a at the rear of the partition chamber 3a is As shown in FIG. 11 (a), the partition chamber 3a is rotated to be in a “closed” state perpendicular to the longitudinal direction of the filtration tank 3, and the inside of the filtration tank 3 is blocked by an opening / closing member 7a. (Other open / close members 7b, 7c, and 7d may remain "open"). Next, the blower 31 is turned “ON” and the valve 32 of the air supply pipe 29 connected to the air diffusing pipe 8 provided in the partition 3 a is made “open” so that the air discharge port 28 of the air diffusing pipe 8 is opened. Aeration is performed in which air is discharged and the filter medium 2 in the partition chamber 3b is rolled up into water and stirred by the discharged air. Thus, the filter medium 2 can be washed (backwashed) by aeration and stirring the filter medium 2 in water.

  After cleaning the filter medium 2 in the partition chamber 3a in this way, while the air is discharged from the diffuser tube 8, the operation of the circulation pump 4 is turned "ON" and the opening / closing member 7a at the rear of the partition chamber 3a is turned on. If the valve 33 of the drain pipe 9 connected to the partition chamber 3b is opened while being closed, the water in the partition chamber 3a is discharged from the drain pipe 9 by being pushed by the water sent by the circulation pump 4. The Dirt such as SS peeled off from the filter medium 2 by washing the filter medium 2 is discharged from the drain pipe 9 together with this water. When a large amount of breeding water such as seawater can be used, such as when the aquaculture device is near the sea, the circulation pump 4 is operated by drawing this water directly into the partition chamber 3b with a pump. The dirty water in the partition 3a can be discharged without necessity. In this way, the filter medium 2 in the compartment of the partition chamber 3a in the filtration tank 3 can be washed and the dirty water can be discharged.

  When cleaning the filter medium 2 in the second partition 3b from the start end, the front and rear opening / closing members 7a and 7b of the opening / closing member 7 are rotated to be in a “closed” state. Then, the inside of the filtration tank 3 is shut off by the opening / closing members 7a and 7b to form the sealed partition chamber 3b, and the filter medium 2 in the partition chamber 3b can be washed in the same manner as described above. After the cleaning of the filter medium 2 in the partition chamber 3b, the air pump is turned on while discharging air from the diffuser tube 8 of the partition chamber 3b, and the opening / closing member at the rear of the partition chamber 3a is turned on. When the opening / closing member 7a at the front part of the partition chamber 3b is turned to "open" while the valve 7b of the drain pipe 9 connected to the partition chamber 3b is opened, the circulation pump is opened. 4, the water in the partition chamber 3 b is discharged from the drain pipe 9 by being pushed by the water sent to the filtration unit 3. In this manner, the filter medium 2 in the partition chamber 3b can be washed and the contaminated water can be discharged, and the filter medium 2 in the compartments of the other partition chambers 3c and 3d is also the same. Thus, it is possible to discharge dirty water by washing and washing.

  Here, after washing the filter medium 2 in the filtration tank 3 as described above, when the dirt such as SS peeled off from the filter medium 2 is discharged from the filtration tank 3 together with water, the filtration tank 3 is filled with water. Since the filter tank 3 is formed in a sealed structure that flows in the same manner as in the case where there is a space in the upper side of the water surface in the filtration tank 3, the dirt does not float on the surface of the water and drifts away with the water. It can be discharged from the tube 9, and dirt can be discharged efficiently from the filtration tank 3.

  FIG. 12 shows a section of each partition chamber 3 a, 3 b, 3 c, 3 d of the filtration tank 3, and a plurality of rectifications are made on the lower surface of the ceiling wall 19 of the filtration tank 3 in the direction of water flow at predetermined intervals. A plate 11 is suspended. In order to filter and wash the water with the filter medium 2 in the filtration tank 3, when water flows along the lower surface of the ceiling wall 19 in passing the water through the filter tank 3, this water has an opportunity to contact the filter medium 2. However, there is a risk that it will be returned to the breeding aquarium 1 from the return outlet 5 without being affected by filtration and washing. For this purpose, the flow straightening plate 11 is suspended from the ceiling wall 19, and the water near the lower surface of the ceiling wall 19 can be allowed to flow downward by the flow straightening plate 11. Water can be allowed to flow while being sufficiently in contact with 2, and filtration with the filter medium 2 can be performed efficiently.

  An air passage hole 42 is provided at the upper end of each rectifying plate 11, and when air accumulates in the upper part of the filtration tank 3, this air passes along the lower surface of the ceiling wall 19 through the air passage hole 42. It can be moved and discharged from the air vent tube 39. Further, the net-shaped water-permeable sheet 26 is attached so as to hang down from some of the rectifying plates 11.

  FIG. 13 shows a partition unit 10 including an opening / closing member 7, an air diffusion pipe 8, and a drain pipe 9. The partition unit 10 is provided with a side plate 37 between both side ends of the upper surface plate 35 and the lower surface plate 36 and is formed in a vertically long box shape with two opposing side surfaces opened. A net-shaped water-permeable sheet 26 is stretched on the surface. In addition, the opening / closing member 7 is attached to the inside of the water-permeable sheet 26 at one opening. The opening / closing member 7 pivotally supports the upper end and the lower end of the rotation shaft 25 provided at one end on the bearing 44 of the upper surface plate 35 and the bearing 45 of the lower surface plate 36 of the partition unit 10, and is plate-shaped around the rotation shaft 25. The opening can be opened and closed by rotating the opening / closing member 7. A lever 38 for manually rotating the opening / closing member 7 is provided at the upper end of the rotation shaft 25 that protrudes upward from the upper surface plate 35. Further, the air supply pipe 29 raised from the air diffuser pipe 8 is attached through the upper surface plate 35, and the lower end portion of the drain pipe 9 attached through the upper surface plate 35 is disposed in the lower end portion of the partition unit 10. is there. Further, an air vent tube 39 opened near the lower surface of the upper surface plate 35 is provided so as to protrude upward from the upper surface plate 35. By forming at least a part of the air vent tube 39 transparently, the air vent tube is provided. 39, the water pressure detecting means 12 is formed. Further, an oxygen supply pipe 40 for supplying oxygen to the partition chambers 3a, 3b, 3c... Of the filtration tank 3 is attached to the partition unit 10 through the upper surface plate 35 as necessary. In FIG. 13, 49 is a maintenance hole provided in the upper surface plate 35, and 50 is a lid plate that is detachably fixed by screws to seal the hole 49.

  FIG. 14 shows the return unit 52, which is formed in a vertically long box shape in which a side plate 55 is provided between two adjacent end portions of the upper surface plate 53 and the lower surface plate 54 and the two adjacent side surfaces are opened. As in the partition unit 10, a maintenance hole 49 and a cover plate 50 are provided on the upper surface plate 53. A louver 57 for setting the direction of water flow is provided in the opening 56 on one side surface of the return unit 52. The louver 57 is formed of a vertically long plate material, and a plurality of louvers 57 are arranged in parallel with the upper and lower ends fixed to the upper surface plate 53 and the lower surface plate 54. Each louver 57 is inclined sideways with respect to the opening surface of the opening 56 on one side surface of the return unit 52, and each louver 57 is connected by a connecting rod 58.

  A plurality of partition units 10 formed as described above are assembled at predetermined intervals to form a filtration tank 3, so that the inside of the filtration tank 3 is kept in the breeding tank 1 with the opening / closing member 7 of each partition unit 10 as shown in FIG. Can be divided into a plurality of partition chambers 3 a, 3 b, 3 c... In the direction along the periphery of the return space, and a return unit 52 is incorporated adjacent to the partition unit 10 at the final end. The return outlet 5 is formed by the opening 56 of 52. Therefore, by incorporating the partition unit 10 into the filtration tank 3, the open / close member 7 that divides the inside of the filtration tank 3 into the partition chambers 3a, 3b, 3c..., The diffuser pipe 8, the drain pipe 9, the air vent pipe 39, the oxygen supply The pipe 40 can be attached to each of the partition chambers 3a, 3b, 3c ... at the same time, and the filtration tank 3 can be easily assembled. The opening 56 of the return unit 52 that forms the return outlet 5 is provided with an inclined louver 57, and the direction of the water flow returned from the return outlet 5 to the breeding aquarium 1 is the direction of the breeding aquarium 1 by the louver 57. It is set in an oblique direction away from the center. Therefore, an annular flow along the circumferential direction of the breeding aquarium 1 is generated in the water in the breeding aquarium 1 by this water flow, and foreign matters such as solids in the water are collected in the center by this annular flow. The discharge port 48 is configured to discharge efficiently.

  Here, the air vent pipe 39 is for discharging the air in the filtration tank 3 so that the filtration tank 3 is filled with water and flows. Further, when dirt such as SS adheres to the surface of the filter medium 2 in the filtration tank 3, it becomes difficult for water to pass between the filter media 2 and the water pressure in the filter tank 3 becomes high, so the water pressure in the filter tank 3 is reduced. By detecting it, it is possible to know how dirty the filter medium 2 is. The air vent tube 39 also serves as the water pressure detecting means 12 for detecting the water pressure in the filtration tank 3. That is, when the water pressure in the filtration tank 3 increases, the water rises from the filtration tank 3 to the air vent pipe 39, so that the water pressure in the filter tank 3 is detected by observing the change in the water level in the air vent pipe 39. The degree of contamination of the filter medium 2 can be determined by this water pressure detection, and the cleaning time of the filter medium 2 can be accurately known. An air vent valve 60 as shown in FIG. 16 is connected to the air vent pipe 39. A ball 61 having a smaller density than water is disposed in the air vent valve 60 so as to be movable up and down. A lower valve seat 62 and an upper valve seat 63 are provided on the inner periphery of the air vent valve 60 on the lower side and upper side of the ball 61. is there. In this air vent pipe 39, the ball 61 is normally placed on the lower valve seat 62 and closes the lower valve seat 62. However, when the air pressure in the filtration tank 3 increases, the ball 61 is pushed up. Thus, the lower valve seat 62 is opened, and the air in the filtration tank 3 can be discharged. Further, when the filtration tank 3 is filled with water and the water rises through the air vent pipe 39, the ball 61 is lifted by this water and the upper valve seat 63 is closed, and the air vent valve 60 is closed, so that the water is discharged. Outflow from the air vent pipe 39 can be prevented.

FIG. 17 shows another reference example of the aquaculture device, in which each drain pipe 9 connected to each compartment 3a, 3b, 3c, 3d of the filtration tank 3 is connected to a drain pipe 65, Valves 33a, 33b, 33c, 33d are provided in the drain pipes 9 of the partition chambers 3a, 3b, 3c, 3d. The drain pipe 65 is connected to the flow pipe 15, and the flow pipe 15 is provided with a valve 66 at a position between the connection points of the discharge port 48 and the drain pipe 65. A drain pipe 67 is connected to the drain pipe 65, and a valve 68 is provided on the drain pipe 67. Further, the drain pipe 65 is provided with a valve 69 at a position between the connection point of the terminal partition 3d with the drain pipe 9 and the connection part of the discharge pipe 67 and the connection part of the flow pipe 15. . Other configurations are the same as those of the above-described reference examples .

  In the aquaculture apparatus formed as shown in FIG. 17, an operation of growing and activating nitrifying bacteria attached to the filter medium 2 of the filtration tank 3 can be performed at the time of starting to start the cultivation. In order to perform this operation, first, ammonia or the like is added to the water in the filtration tank 3 for eutrophication, and then the opening / closing members 7a, 7b provided in the partition units 10 of the partition chambers 3a, 3b, 3c, 3d. , 7c, 7d, the open / close members 7a, 7b, 7c of the partition chambers 3a, 3b, 3c are opened, the open / close member 7d of the terminal partition chamber 3d is closed, and the valve 69 of the drainage pipe 65 and the terminal partition chamber 3d are closed. The valve 33d of the drain pipe 9 is opened and the valves 33a, 33b, 33c of the other drain pipes 9, the valve 66 of the flow pipe 15 and the valve 68 of the discharge pipe 67 are closed. When the circulation pump 4 is operated in this state, the water in the filtration tank 3 flows from the partition of the partition chamber 3a at the start end to the partition of the partition chamber 3d at the end, and then drains from the partition of the partition chamber 3d at the end. The water flows into the drain pipe 65 from the pipe 9 and is discharged from the drain pipe 65 through the flow pipe 15 to the partition of the partition chamber 3a at the start end. In this way, the water in the filtration tank 3 can be circulated from the starting partition 3 a to the terminal partition 3 d, and the start-up operation for growing nitrifying bacteria adhering to the filter medium 2 can be performed. Can be performed.

  Further, after washing the filter medium 2 in the partition chambers 3a, 3b, 3c, 3d, when discharging the washed partition chambers 3a, 3b, 3c, 3d, the water is passed through the solid content removing device 6 to remove dirt. After removal, the water can be reused by returning it to the filtration tank 3. For example, the operation for discharging the water in the partition chamber 3a after washing the partition chamber 3a at the start end will be described. First, the opening / closing member 7a of the partition chamber 3a is closed, and the partition chambers 3b and 3c are closed. , 3d open / close members 7b, 7c, 7d are opened, the valve 33a of the drain pipe 9 of the partition chamber 3a and the valve 69 of the drain pipe 65 are opened, and the valves 33b, 33c, 33d of the other drain pipe 9 are The valve 66 of the pipe 15 and the valve 68 of the discharge pipe 67 are closed. When the circulation pump 4 is operated in this state, the water in the partition chamber 3a flows into the drain pipe 65 from the drain pipe 9 of the partition chamber 3a, passes through the solid content removing device 6 through the feed pipe 15, and is washed. The solid content of the water contaminated with is removed by the solid content removing device 6. Thus, the water purified by the solid content removing device 6 is returned to the partition chamber 3 a through the flow pipe 15 and can be reused in the filtration tank 3. Therefore, in this case, it is not necessary to discard the water after washing the filter medium 2 in the partition chambers 3a, 3b, 3c, 3d, and it is not necessary to make up for the insufficient amount of water by discarding.

  Moreover, after washing | cleaning the filter medium 2 of partition room 3a, 3b, 3c, 3d, the water can also be discarded as it is. For example, the operation for discarding the water in the partition chamber 3a after washing the partition chamber 3a at the start end will be described. First, the opening / closing member 7a of the partition chamber 3a is closed, and the partition chambers 3b and 3c are closed. , 3d open / close members 7b, 7c, 7d are opened, the valve 33a of the drain pipe 9 of the partition 3a, the valve 68 of the discharge pipe 67, the valve 66 of the flow pipe 15 and the valves of the other drain pipes 9 are opened. 33b, 33c, 33d and the valve 69 of the drain pipe 65 are closed. When the circulation pump 4 is operated in this state, the water in the breeding water tank 1 flows into the partition chamber 3a through the flow pipe 15 and is pushed by this water, so that the water in the partition chamber 3a flows out from the drain pipe 9. This water is discarded from the discharge pipe 67 through the drain pipe 65.

18 and 19 show another reference example of the aquaculture device . As shown in FIG. 19, a return opening 72 is formed in the side plate 37 of the partition unit 10 on the breeding water tank 1 side, and a louver 73 is provided in the return opening 72. A packing 74 is attached around the inside of the return opening 72. The other configuration of the partition unit 10 is the same as that of FIG. 13 described above. However, when the opening / closing member 7 is rotated to the “open” state of the solid line, the opening / closing member 7 is parallel to the inner surface of the side plate 37. The seal 74 is in close contact with the packing 74 so that the return opening 72 can be closed with the opening / closing member 7. Therefore, when the opening / closing member 7 is rotated to the “closed” state of the chain line, the return opening 72 can be opened. Then, the partition unit 10b of FIG. 19 is assembled at a predetermined interval, and the filtration unit 3 is formed by incorporating the partition unit 10a not provided with the return opening 72 of FIG. 13 at the final position as shown in FIG. In addition, the opening and closing member 7 of each partition unit 10b can divide the inside of the filtration tank 3 into a plurality of partition chambers 3a, 3b, 3c... In the direction along the periphery of the breeding water tank 1. Other configurations are the same as those in FIG.

In the reference example of FIG. 18, for example, when the filter medium 2 in the second partition chamber 3b from the start end is washed, as shown by the solid line in FIG. The opening / closing member 7a between the partition chambers 3b is rotated to be in the “closed” state, the space between the partition chamber 3b and the partition chamber 3a is shut off, and the other opening / closing members 7b, 7c, 7d are in the “open” state. Leave it alone. Thus, by opening and closing the opening / closing member 7a, the return opening 72 at the location of the opening / closing member 7a is opened, and the return opening 72 at the location of the other opening / closing members 7b, 7c is closed. . In this state, the filter medium 2 in the partition chamber 3b can be aerated and washed by discharging air from the diffuser tube 8 provided in the partition chamber 3b. Here, while the filter medium 2 in the partition chamber 3b is washed in this way, the circulation pump 4 can continue to operate, and the water in the breeding aquarium 1 is supplied to the filtration tank 3 by the operation of the circulation pump 4. It is sent back to the breeding aquarium 1 from the return opening 72 opened in the partition chamber 3a. As described above, in the reference example of FIG. 18, the partition chambers 3a and 3b in front of the partition medium 3b, 3c, and 3d while the filter medium 2 of the partition chambers 3b, 3c, and 3d is being cleaned except for the partition chamber 3a at the start end. 3c, the water in the breeding aquarium 1 can be circulated between the filtration tank 3 through the return opening 72 and the filtration and washing of the breeding aquarium 1 can be continued. After finishing the cleaning of the filter medium 2 in the partition chamber 3b as described above, the partition member 7a is set to the “open” state as shown by a broken line in FIG. 18, and the opening / closing member 7d of the final partition chamber 3d is set to the “closed” state. When the valve 33 of the drain pipe 9 connected to each of the partition chambers 3a, 3b, 3c, 3d is opened, the water in the partition chamber 3b is pushed by the water sent to the filtration unit 3 by the circulation pump 4. Can be discharged from the drainage pipe 9, and water contaminated by washing can be discharged from the filtration tank 3.

BRIEF DESCRIPTION OF THE DRAWINGS An example of embodiment of this invention is shown, (a) is a top view of schematic structure, (b) is sectional drawing of a part of schematic structure. (A) is a plan view and (b) is a cross-sectional view. It is a disassembled perspective view of the part of a tank unit same as the above. The filter tank same as the above is shown, (a), (b), (c) is a schematic sectional drawing, respectively. The tank unit same as the above is shown, (a) is a plan view, and (b) is a sectional view taken along line BB of (a). It shows the same tank unit, (a) is a cross-sectional view of the tank unit cut in the width direction, (b) is a cross-sectional view of the connection part of the tank units cut in the longitudinal direction, (c) is the tank unit It is sectional drawing which cut | disconnected in width direction. The same partition plate is shown, (a), (b), (c) is a front view, respectively. It is sectional drawing of the part of the last tank unit same as the above. The tank unit same as the above is shown, (a) is a partial front view, and (b) is a partial cross-sectional view. The same tank unit is shown, (a) is a partial front view, and (b) is a partial plan view. It shows a reference example , (a) is a plan view, (b) is a cross-sectional view. It is a one part schematic perspective view same as the above. The partition unit same as the above is shown, (a) is a front sectional view, (b) is a plan view, and (c) is a plan sectional view. The return unit same as the above is shown, (a) is a front view, and (b) is a partially broken plan view. It is a schematic plan view of the reference example incorporating the partition unit and return unit same as the above. It is the partially broken front view which shows an air bleeding valve same as the above. It is a schematic plan view of the other reference example same as the above. It is a schematic plan view of still another reference example . The partition unit same as the above is shown, (a) is a front sectional view, (b) is a plan view, and (c) is a plan sectional view.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Breeding tank 2 Filter medium 3 Filtration tank 3a, 3b, 3c, 3d Partition chamber 4 Circulation pump 5 Return outlet 6 Solid content removal device 7 Opening and closing member 8 Air piping 9 Drain pipe 10 Partition unit 11 Current plate 12 Water pressure detection means 80 Inclined surface 81 Sheet material 82 Partition plate 83 Opening 84 Tank unit 85 Overflow port 86 Fixed tank 87 Fluid tank

Claims (7)

It has a rearing tank for rearing seafood and a filtration tank for filtering and purifying water with a filled filter medium, supplying water from the rearing tank to the filtration tank with a circulation pump and rearing the water purified in the filtration tank In the circulating filtration aquaculture device that is to be returned to the aquarium, a filtration tank is provided along the periphery of the breeding aquarium, and the water in the breeding aquarium is caused to flow into the upstream end of the water flow in the filtration tank by a circulation pump. In addition, the return outlet provided at the downstream end of the water flow in the filtration tank is directly connected to the breeding water tank, and partition plates are provided at a plurality of locations along the water flow direction in the filtration tank and water is supplied to each partition plate. A circulating filtration type aquaculture apparatus, characterized in that an opening is provided for passing through and openings of adjacent partition plates are arranged at different height positions .   The solid content removal apparatus which removes solid content from the water of a breeding aquarium and supplies it to a filtration tank is provided, The solid content removal apparatus is arrange | positioned along the circumference | surroundings of a breeding aquarium. Circulation filtration type aquaculture equipment.   The circulating filtration type aquaculture apparatus according to claim 1 or 2, wherein the breeding water tank and the filtration tank are formed separately, and the filtration tank is arranged along the periphery of the breeding water tank.   The circulating filtration type aquaculture apparatus according to any one of claims 1 to 3, wherein the breeding water tank is formed by holding the sheet material in a tank shape having an upper surface opened. The filtration tank is formed from a plurality of tank units along the water flow direction, and a return outlet is provided in the final tank unit in the water flow direction, and an overflow port is provided in at least one tank unit other than the final one. The circulating filtration type aquaculture device according to any one of claims 1 to 4 . The final tank unit in the water flow direction is formed as a fixed tank containing the filter medium in a stationary state, and the tank units other than the final tank are formed as a flow tank containing the filter medium in a fluid state. The circulating filtration type aquaculture device according to claim 5 , wherein An inclined surface in which a diffuser pipe is provided at the bottom of the filtration tank and the diffuser pipe is disposed at a position closer to one side in the width direction of the filtration tank and the bottom of at least one side in the width direction of the filter tank is inclined upward toward the outside. The circulating filtration type aquaculture device according to any one of claims 1 to 6 , wherein the circulating filtration type aquaculture device is formed.

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