JP2003144003A - Oxygen feeder for fishery - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an oxygen feeder for fisheries capable of simply increasing the amount of dissolved oxygen in water by producing relatively small bubbles in the water without using a power source in a feeding means for air fed into the water. SOLUTION: This oxygen feeder 1 is composed of a constricted part 15, a connecting part 16, an air introduction part 17, and a discharge part 18. The connecting part 16 is connected to a water feed port 8 of a water pipe 9b for feeding the water into a water tank 2. The air introduction part 17 introduces air (oxygen) in an atmospheric pressure state into the constricted part 15 from an air pipe 23. Furthermore, the constricted part 15 communicates with the air introduction part 17 and a constriction pipe 33 is provided in the constricted part 15. The air introduced from the air introduction part 17 is mixed with a water stream fed from the water pipe 9b in the constriction pipe 33 and discharged from the discharge part 18. In the process, since the air in a state of fine bubbles is mixed in the water stream, a large amount of dissolved oxygen is contained in the water discharged from the discharge part 18.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fisheries oxygen supply device for supplying oxygen into water in a water tank or a fishing ground in order to feed (raise) seafood in the water tank or the fishing ground.
In particular, when temporarily storing the landed fish and shellfish in the aquarium of the fishing boat, when cultivating the fish and shellfish in the aquarium or in the fishing ground, or when cultivating the seafood in the aquarium or in the fishing ground for a long period of time The present invention relates to a fisheries oxygen supply device for supplying oxygen into water in a water tank or a fishing ground.

[0002]

2. Description of the Related Art Recently, aquaculture of seafood for appreciation and foodstuffs,
Along with demand for livestock and transportation of raw fish, an oxygen supply device for marine products that supplements oxygen in water is used in order to promote respiration of raw seafood. An oxygen supply device for marine products (hereinafter referred to as "oxygen supply device") is used, for example, when temporarily culturing seafood landed in the ocean or seafood cultivated in the sea at a fishing ground, or when cultivating seafood at the fishing ground. It is indispensable for maintaining the growth and freshness and quality of fish and shellfish when they are cultured on the sea surface. Here, a conventional oxygen supply device will be briefly described with reference to FIG. FIG. 8 is a partial sectional view,
It is a schematic block diagram which shows the schematic flow which an oxygen supply apparatus supplies oxygen to a water tank, in the state which circulates while filtering the water in a water tank. In the water tank 102, dirty water (seawater) in the water tank 102 is drained from the water intake 105 of the water tank 102, and the water filtered by the filtering device 103 is pumped by the pump 104.
A circulation channel 109 is provided for returning from the water supply port 108 of No. 02 to the water tank 102. The oxygen supply device 101 is used with such a water tank 102. The oxygen supply device 101 includes a compressor 110, a hose 111, and an air dispersion nozzle 112. Oxygen supply device 10
1, the compressor 110 is used as an air supply source. A blower may be used as the air supply source. The oxygen supply device 101 includes a compressor 11
This is a device for discharging the air compressed to an air pressure of about ² to 3 kgf / cm ² by 0 from a plurality of small diameter holes provided in the air dispersion nozzle 112 via the hose 111. The air dispersion nozzle 112 is arranged at the bottom of the water tank 102, and the oxygen supply device 101 is provided with water stored in the water tank 102.
Releases air into the water in the aquarium 102. For this reason, the air discharged from the air dispersion nozzle 112 becomes bubbles and floats toward the water surface, and oxygen in the air dissolves in the water until the bubbles float on the water surface. Therefore, when such an oxygen supply device 101 is provided in the water tank 102, the water tank 10
The amount of dissolved oxygen dissolved in the water (seawater) in 2 increases compared to when air is not supplied into the water.

[0003]

When air is supplied into water using a compressor, the amount of air released in water increases if the air supply pressure is set high. However, when air is supplied into water at high pressure, a large amount of oil and dirt in the compressor flow out together with the air, and the air dispersion nozzle is clogged in a short period of time. For this reason, when air is supplied into water using a compressor, the air pressure is reduced to 2 to 3 without making the air dispersion nozzle diameter extremely small.
Air was supplied by setting it to about kgf / cm ² .
In addition, in order to sufficiently supply air into the water, it is necessary to frequently replace the air dispersion nozzle, which increases the cost. When air is supplied into the water by the compressor, the air released into the water becomes relatively large bubbles and floats toward the water surface. Large bubbles reach the water surface shortly after being released in water. When a large bubble reaches the water surface, the oxygen component in the bubble is released into the atmosphere at a high rate, and the oxygen component in the air is not sufficiently dissolved in water. Therefore, even if the raw fish and shellfish are bred in a water tank or a fishing ground provided with a conventional oxygen supply device, oxygen is not sufficiently supplied to the water, so that the death or illness of the raw fish and shellfish due to oxygen deficiency or oxygen deficiency may occur. There were problems such as growth delay of raw seafood. The present invention was devised to solve such a problem, and the problem to be solved by the present invention is to use a power source as a means for supplying air to be supplied to water, and to provide a relatively small size. An object of the present invention is to provide an oxygen supply device for marine products that easily increases the amount of dissolved oxygen in water by generating bubbles in water.

[0004]

A first invention of the present invention for achieving the above object is an oxygen supply device for fisheries as set forth in claim 1. The aquatic oxygen supply device according to claim 1, wherein the aquatic oxygen supply device supplies oxygen into the water in the aquarium or the fishing ground, and the water pipe serves as a water channel for supplying water into the aquarium or the fishing ground. And an air pipe that allows oxygen in the atmosphere to be introduced from one end and is connected to the water pipe at the other end. In the water pipe, by providing throttling means for changing the speed of the water flow in the pipe immediately before the water pipe and the air pipe are connected, the water that has passed through the throttling means is supplied from the air pipe and is rectified by the throttling means. Mix the oxygen inside. By forming the throttling means, the cross-sectional area of the water channel is narrowed, and the speed of the water flowing through this narrowed water channel is temporarily reduced.However, when the water flow passes through the water channel at the throttling point, the speed of the water flow immediately after passing is suddenly increased. Be accelerated to. At this time, the water pressure becomes negative. In such a state, the air introduced from the air pipe and rectified by the throttling means becomes fine (small) bubbles, and is easily sucked into the water flow, and oxygen in the air dissolves in the water. It will be easier. In general, when the same amount of air is released into water, the surface area of bubbles becomes larger when they float toward the water surface in the state of small bubbles than when they float toward the water surface in the state of large bubbles. Air easily melts into the. Also,
In the state of small bubbles, the buoyancy of one bubble is smaller than that in the state of large bubbles, so that it takes longer for the bubbles to float on the water surface, and the air is more likely to dissolve in the water. Further, the oxygen supply device for marine products does not use a power source such as a compressor or a blower when supplying air into water, so that the cost is reduced. Note that the concept of "water" below includes not only fresh water but also an aqueous solution containing a solute such as salt, and seawater is also included in the concept of "water". A second invention of the present invention is an oxygen supply device for marine products as described in claim 2. In the oxygen supply device for fisheries according to a second aspect of the present invention, the water pipe and the air pipe are each formed of a corrosion resistant pipe. As a result, when oxygen is supplied into water in a water tank storing seawater or in a fishing ground, the water pipe and the air pipe are less likely to be corroded by salt and the like. Therefore, stable supply of oxygen is possible even in seawater. The third invention of the present invention is the oxygen supply device for marine products as described in claim 3. Claim 3
In the marine product oxygen supply apparatus described in paragraph 1,
With the ratio of (minimum cross-sectional area of water pipe) and (maximum cross-sectional area of water pipe) set at a predetermined ratio, the plate member is inclined so that the cross-sectional area of the water pipe becomes smaller along the direction of the water flow. It is formed by The ratio of (minimum cross-sectional area of the water channel in the throttle) / (maximum cross-sectional area of the water channel in the throttle) is 0.4 ≦ (minimum cross-sectional area of the water channel in the throttle)
It is preferable to set within the range of / (maximum cross-sectional area of the water channel in the throttle) ≤ 0.7. Accordingly, when the inclined plate-shaped member is arranged at the connecting portion between the water pipe and the air pipe, the flow of air introduced from the air pipe hits the plate-shaped member and is rectified in the direction of the water flow. Then, when the rectified air flow and the water flow come together in the water pipe, the air is efficiently mixed into the water. A fourth invention of the present invention is an oxygen supply device for marine products as described in claim 4. In the oxygen supply device for fisheries according to a fourth aspect of the present invention, the air pipe is provided with a valve capable of variably adjusting the supply amount of air. Thereby, the generation of bubbles in water can be controlled by adjusting the opening degree of the valve. Therefore, for example, by temporarily closing the valve of the air pipe,
When the generation of bubbles is stopped by shutting off the air in the atmosphere supplied to the water, the state of seafood in the water in the aquarium or the fishing ground can be observed. A fifth aspect of the present invention is an oxygen supply device for marine products as set forth in claim 5. In the aquatic oxygen supply device according to claim 5, the water pipe is formed by a circulation system that takes out dirty water in the water tank, filters the water, and returns the filtered water to the water tank again. Mix with oxygen.
Therefore, oxygen can be dissolved in the purified and cleaned water while saving water in the water tank.

[0005]

BEST MODE FOR CARRYING OUT THE INVENTION A first embodiment of the present invention will be described below with reference to the drawings. In this embodiment, a case where a fish tank oxygen supply device (hereinafter referred to as “oxygen supply device”) is provided will be described with reference to FIG. 1.
FIG. 1 is a schematic configuration diagram showing a circulation flow of water supplied to a water tank 2 provided with an oxygen supply device 1, using a partial sectional view. The oxygen supply device 1 is used in connection with a water pipe 9b for supplying water to the aquarium 2, for example, when temporarily storing seafood landed in the ocean in the aquarium 2. As water stored in the aquarium, for example, seawater (hereinafter referred to as “water”) is used. Note that water such as fresh water may be used depending on the type of fish and shellfish, and the nature of the water stored in the water tank in which the oxygen supply device is installed can be appropriately changed.

First, the water tank 2 will be described. As shown in FIG. 1, the water tank 2 has a length of 1.8 m and a width of 1.
It is formed in a rectangular parallelepiped shape (the cross section of the water tank is shown in FIG. 1) having a length of 8 m, a depth of 1.2 m and a volume of 388 L. Further, the water tank 2 is provided with a filtering device 3 for filtering the water polluted in the water tank 2. The water tank 2 is provided with a water intake port 5 for feeding the dirty water in the water tank 2 to the filtering device 3. The water intake port 5 is provided on the side surface of the water tank 2 at a position lower than the water surface in the water tank 2, and the dirty water in the water tank 2 flows from the water intake port 5 to the water pipe 9
Overflow toward a. The water sent from the filtration water supply port 6 to the filtering device 3 is regenerated into water that has been filtered and purified by the filtering device 3. The purified water is sent by the pump 4 at a flow rate of, for example, 300 L / min from the filtering water intake 7 through the water pipe 9b, and from the water supply port 8 to the oxygen supply device 1 so as to return to the water tank 2. It has become. The water pipes 9a and 9b are formed by connecting a plurality of resin piping materials with a joint (not shown). In addition, as the water pipe, a pipe having corrosion resistance is used.
A resin pipe material having a diameter of 40 mm and made of vinyl chloride is used.

Next, the oxygen supply device 1 will be described with reference to FIGS.
Will be explained. FIG. 2 is a schematic diagram showing the oxygen supply device 1. As shown in FIG. 2, the oxygen supply device 1 includes a throttle portion 15, a connecting portion 16, an air introducing portion 17, and a discharge portion 18. When the oxygen supply device 1 is installed in the water tank 2, the connection port 19a of the connection portion 16 of the oxygen supply device 1 is connected to the water pipe 9b that is communicated from the discharge side of the pump 4.
In addition, in the present embodiment, the oxygen supply device 1 is installed in the water tank 2 having a circulation pipe for filtering the dirty water in the water tank 2 with the filtering device 3 and returning the purified water to the water tank 2 again. The oxygen supply device 1 may be installed in a water tank of a flow path that constantly discharges dirty water while constantly supplying fresh water. in this case,
The connection port 19a of the connection portion 16 of the oxygen supply device 1 is connected to a water pipe that constantly supplies fresh water.

The connecting portion 16 of the oxygen supply device 1 has a water supply port 8 of a water pipe 9b for supplying water into the water tank 2, and the oxygen supply device 1
It is a water channel that connects the narrowed portion 15 of the above with a water pipe 19. As shown in FIG. 2, the water pipe 19 is communicated with the water pipe 9b via a joint (not shown) that connects the connection port 19a of the water pipe 19 and the water pipe 9b. Further, one end of the water pipe 19 opposite to the connection port 19a has an oxygen supply device 1 described later.
First joining side 32a of the connecting member 32 in the narrowed portion 15 of
(See FIG. 3). As the water pipe 19, a pipe having corrosion resistance is used. For example, a vinyl chloride caliber 4
0 mm resin pipe material or the like is used.

Next, the air introducing portion 17 of the oxygen supply device will be described with reference to FIGS. 2 and 3. FIG. 3 is a sectional view showing a part of the oxygen supply device 1 of FIG.
It is a figure of the state which opened. As shown in FIG. 2, the air introduction part 17 of the oxygen supply device 1 is an air conduit for supplying oxygen (air) in the atmosphere to the throttle part 15 of the oxygen supply device 1 and communicates with the throttle part 15. Has been done. Air introduction part 1
7, an air pipe 23 for taking in oxygen (air) in the atmosphere
And a valve 21 that variably adjusts the amount of air supplied to the throttle unit 15. As shown in FIG. 3, the valve 21 rotates the knob 24 of the valve 21 in the arrow direction to open or close the air pipeline. Further, if the valve 21 is provided in the air introduction part 17, by restricting the cross-sectional area of the air conduit in the valve 21 by a predetermined amount when the valve 21 is open, the air supplied from the atmosphere to the restricting part 15 is reduced. It may be possible to increase the suction amount.

The valve 21 is connected to the joint side connection port 31b of the joint 31 via the air pipe 20 at one end of the valve body 25. Further, the valve 21 is connected to one end of the air pipe 23 via the air pipe 20 and the joint 22 on the other end side of the valve body 25. The other end of the air pipe 23 is open and serves as an air introduction port 23a for introducing oxygen (air) in the atmosphere into the pipe. A pipe material having corrosion resistance is used for the valve 21, the joint 22, and the air pipes 20 and 23. For example, a resin pipe member made of vinyl chloride and having a diameter of 13 mm is used. In the present embodiment, the shape of the conduit of the air introducing portion 17, that is, the shape of the air conduit from the air introducing port 23a to the air connecting port 31a is formed in an inverted L shape as shown in FIG. However, the shape of the conduit of the air introducing portion can be changed in various ways. For example, for convenience of the place where the oxygen supply device 1 is installed, it is possible to form the pipe line of the air introduction portion in an arbitrary shape by combining a plurality of various pipe members. In addition, if the location where the valve 21 is provided is in the range of the air pipeline from the air introduction port 23a to the joint side connection port 31b of the joint 31,
It is not limited. Further, although the valve 21 is provided in the air introducing portion 17, the valve 21 may be omitted, and the arrangement of the valve can be changed as appropriate.

Next, the throttle portion 15 of the oxygen supply device 1 will be described. As shown in FIG. 3, the throttle unit 15 of the oxygen supply device 1 merges the water supplied from the connection unit 16 side with the air supplied from the air introduction unit 17, and the water and the air are mixed. The water stream is sent to the discharge section 18 side. In the present embodiment, the throttle unit 15 of the oxygen supply device 1
Are arranged at a position higher than the water surface of the aquarium 2. The location of the throttle unit 15 of the oxygen supply device 1 can be changed as appropriate. The throttle portion 15 is connected to the connecting portion 16 of the oxygen supply device 1 by connecting the water pipe 19 to the first connecting side 32 a of the connecting member 32. The connection member 32 is a joint that connects piping members having different diameters, and the first connection side 3
The diameter of 2a is larger than the diameter of the second connection side 32b. That is, the water pipe 19 is the first member of the connecting member 32.
At the connection side 32a, the water pipe 19 is connected to the connecting member 32 in a state where the outer peripheral surface of the water pipe 19 is in contact with the inner peripheral surface of the connecting member 32. The connecting member 32 is connected to the joint 31 in a state where the outer peripheral surface of the connecting member 32 on the second connection side 32b side is in contact with the inner peripheral surface of the joint 31 on the in-side connection port 31a side. In addition, in order to prevent the flow of water from changing as much as possible, the inner peripheral diameter of the water pipe 19 and the second connection side 32 of the connecting member 32.
It is preferable that the inner peripheral diameter of b is substantially the same.

Further, the first connecting side 32a of the connecting member 32 is
The support member 36 is provided in a state of being inscribed together with the outer peripheral surface of and the outer peripheral surface of the in-side connection port 31a of the joint 31. When the oxygen supply device 1 is fixed to the side wall or the like of the water tank 2, for example, a fixture 37 provided on the side wall of the water tank 2.
The support member 36 is held by the oxygen supply device 1
Is fixed to the aquarium 2. In the present embodiment, the support member 36 is provided on the narrowed portion 15, but the support member 36 may be omitted.

Next, regarding the throttle tube 33 of the throttle unit 15,
This will be described with reference to FIGS. 3 and 4. FIG. 4 is a perspective view showing the throttle tube 33 provided inside the joint 31.
As shown in FIG. 3, the throttle pipe 33 changes the cross-sectional area of the water channel when water flows, and is composed of a water pipe 34 and a plate member 35. A pipe material having corrosion resistance is used for the water pipe 34, for example, a vinyl chloride caliber of 40 mm.
The resin-made piping material etc. of are used. The in-side connecting port 34a of the water pipe 34 is connected to the second connecting side 32b of the connecting member 32, and the end face 39 of the in-side connecting port 34a of the water pipe 34 is
It is cut in a round slice.

Further, at a predetermined position of the water pipe 34, as shown in FIGS. 3 and 4, the water pipe 34 is inclined at a predetermined angle θ with respect to the axial direction connecting the in-side connection port 34a and the out-side connection port 34b. A groove 38 having a length described later is provided. A plate member 35 having a thickness corresponding to the width of the groove 38 is fitted in the groove 38. The outer peripheral shape of the plate member 35 on the outer peripheral side of the water pipe 34 is the water pipe 3
4 is formed in a shape along the outer peripheral surface. The groove 3
The angle θ for inclining 8 can be changed appropriately.

The end surface of the out-side connection port 34b of the water pipe 34 is cut into a circular slice with respect to the water pipe 34. The water pipe 34 is connected to the connecting member 32 so that the outer connection port 31c of the joint 31 does not buffer the outer connection port 34b of the water pipe 34 and the end 61a of the water pipe 61. Further, in order to prevent the change with respect to the flow of water as much as possible, the end surface of the out-side connection port 34b and the end portion 6 are
It is preferable to form it so that the distance from 1a is small.

Here, a method of attaching the plate member 35 to the water pipe 34 will be described in detail. When water flows in the throttle pipe 33, a portion of the inner peripheral surface of the water pipe 34 that intersects with the plate member 35 is defined as a portion 40, and a cross-sectional area of the water channel in a range from the in-side connection port 34a to the portion 40 is defined as Sa. Also, the plate member 3
At the position where the tip 43 of 5 is located in the throttle tube 33,
Let Sb be the cross-sectional area of the water channel surrounded by the inner peripheral surface of the water pipe 34 and the tip 43 of the plate member 35. When the plate member 35 is attached to the water pipe 34 at a predetermined angle θ, the ratio Sb / Sa according to the cross-sectional area of the water channel is, for example, Sb / Sa = 0.
It is set to 4. That is, the plate member 35
Is provided in a state of being inclined to the water pipe 34 so that the cross-sectional area of the water channel becomes gradually smaller along the direction of the water flow. At this time, the length of the plate member 35 (position of the tip end 43) is
A maximum cross-sectional area Sa for the water channel in the throttle pipe 33,
The ratio Sb / Sa with the minimum sectional area Sb is set to be a predetermined ratio. In addition, Sb /
The Sa ratio is preferably set within a range of 0.4 ≦ Sb / Sa ≦ 0.7, for example, and the Sb / Sa ratio can be appropriately changed.

Further, as shown in FIGS. 3 and 4, the inclined surface 41 of the water pipe 34 allows the air (oxygen) introduced from the air pipe 23 to the air introduction pipe 42 to hit the plate member 35 over a wide range. Is formed in. In the present embodiment, when the plate member 35 is viewed from the direction of arrow A in FIG. 4, it is preferable to form the inclined surface 41 in a state where the upper portion 41a of the inclined surface 41 cannot be seen. As a result, the air introduced into the air introduction pipe 42 is rectified by hitting the plate member 35, and the rectified air and the water flowing in the throttle pipe 33 easily merge.

Next, the discharge part 18 of the oxygen supply device 1 will be described. The discharge part 18 of the oxygen supply device 1 communicates with the throttle part 15 of the oxygen supply device 1, as shown in FIG. The discharge unit 18 is a water channel that discharges a water flow in which water and air (oxygen) are mixed in the throttle unit 15 into the water in the water tank 2, and is composed of water pipes 61 and 63 and an L-shaped joint 62. . As the water pipes 61 and 63, pipes having corrosion resistance are used, and, for example, a resin piping material made of vinyl chloride and having a diameter of 40 mm is used. The L-shaped joint 62 is a joint having a diameter that can be connected to the water pipes 61 and 63. The L-shaped joint 62 is formed of a corrosion-resistant pipe material such as a vinyl chloride resin pipe material. ing.

The water pipe 63 of the discharge section 18 is disposed near the bottom of the water tank 2 in a direction along the bottom so as to discharge a water flow in which water and air (oxygen) are mixed in a wide range within the water tank 2. Has been done. One end of the water pipe 63 is open, and serves as a discharge port 63a for discharging a water flow, in which water and air (oxygen) are mixed, into the water. The other end of the water pipe 63 is
It communicates with one end of the L-shaped joint 62. One end of the water pipe 61 communicates with the out-side connection port 31c of the joint 31, and the other end of the water pipe 61 communicates with the other end of the L-shaped joint 62. Therefore, the length of the water pipe 61 from the out-side connection port 31c of the joint 31 to one end of the L-shaped joint 62 corresponds to the position where the throttle portion 15 is arranged and the water depth where the water pipe 63 is arranged in water. Is set.

Next, the operation of the oxygen supply device 1 configured as described above will be described with reference to FIG. Figure 5
FIG. 6 is a diagram schematically showing a state in which a flow of air introduced from the air introduction part 17 and a water flow sent from the connection part 16 join together. As shown in FIG. 5, the water channel 51 is provided with a throttle member 52 and an air channel 53. The air flow path 53 is in communication with the water flow path 51. Diaphragm member 52
Reduces the cross section of the water flow path 51 in the direction of water flow so that the speed of the water flowing in the water flow path 51 changes.
The throttle member 52 also has a rectifying function of changing the flow direction of the air introduced from the air flow path 53.

The water flowing from the input side 51a of the water flow path 51 shown in FIG. 5 toward the output side 51c of the water flow path 51 is decelerated when passing through the throttle portion 51b of the water flow path 51. The water flow is the leading edge 52a of the throttle member 52 of the water flow path 51.
When passing through, the flow velocity of the water flow becomes the most decelerated state. Immediately after the water flow passes through the tip 52a of the throttle member 52, the velocity of the water flowing out of the output side 51c of the water flow path 51 is
Temporarily accelerates rapidly. At this time, the water pressure in the water flow becomes negative. Therefore, when the atmospheric pressure air is introduced from the air flow path 53 into the water flow in the negative pressure state, a large amount of air (oxygen) rectified by the throttle member 52 enters the water in the form of fine bubbles. It becomes easy to be sucked. That is, since air (oxygen) is naturally aspirated into the water flow at atmospheric pressure, for example, a large amount of air due to fine air bubbles is generated as compared with the case of forcibly supplying air pressurized by a compressor into water. (Oxygen) easily mixes into the water stream efficiently.
Therefore, a large amount of oxygen component in the air is dissolved in water, so that the amount of oxygen required for fish and shellfish to breed and cultivate in an aquarium can be supplied into the water.

Further, when the valve 21 is closed, the air in the atmosphere is shut off by the valve 21, so that the water flow sent from the water supply port 8 of the water pipe 9b to the connecting portion 16 is discharged as it is from the discharge port 63a ( (See FIG. 1). As a result, air (oxygen) in the form of fine bubbles does not diffuse into the water tank 2, so that the inside of the water can be seen through and the state of seafood can be observed. Further, by adjusting the opening degree of the valve 21, it becomes possible to adjust the amount of dissolved oxygen supplied into the water.

The effects of the oxygen supply device 1 of the present embodiment will be described. In Experiment 1, fish was cultivated while discharging a water flow containing a large amount of air (oxygen) in the water in the water tank 2 by the oxygen supply device 1 and mortality of fish was observed (see FIG. 1). . In Experiment 2, fish was cultivated while a water flow containing air (oxygen) was discharged to a water tank 102 by a conventional fisheries oxygen supply device 101, and the mortality rate of the fish was observed (see FIG. 8). In Experiment 2, the experiment was performed under the same conditions as Experiment 1 except that the fisheries oxygen supply device 101 was not used.

Experiment 1 was conducted under the following conditions. (1) Specifications of water tank and oxygen supply device: The water tank 2 and oxygen supply device 1 described above were used. (2) Type of fish used in the experiment: sea bream, kanpachi, hamachi (3) Experiment period: 1 year (4) Water property in the water tank: seawater (5) Circulation amount of water by pump 4: 300 L / min ( 6) Valve: Completely open circuit (7) Throttling ratio due to the cross-sectional area of the water channel in the throttle tube: The above-mentioned state within the throttle tube 33, the ratio S depending on the cross-sectional area of the water channel
b / Sa is 0.4

As a result of the experiment, the mortality rate of fish dying during the experiment is shown. According to the result of Experiment 1, the mortality rate of each fish was about 1%. On the other hand, in the result of Experiment 2, the mortality rate of each fish was about 10%. From these experimental results, the fish in the aquarium in which the oxygen supply device 1 is installed is better than the fish in the aquarium 102 in which the conventional oxygen supply device 101 for fisheries is installed. It turns out that the survival rate is high. As described above, the reason why the mortality rate of fish decreased is that the oxygen supply device 1 of the present invention increases the amount of dissolved oxygen in water in the aquarium 2 as compared with the conventional method. It is thought that the number of deaths was reduced. That is, it is considered that the amount of dissolved oxygen in the water increased, which made it easier for fish to breathe.

Further, in the oxygen supply device 1, since a water flow containing a large amount of air (oxygen) in the form of fine bubbles is discharged in water, the fine bubbles are scattered in the water in the water tank 2 for a long period of time. Come to do. As a result, the fine air bubbles come into contact with the dirt adhering to the inner surface forming the aquarium 2, the surface of seafood, the seaweed that propagates in the aquarium 2, the surface of seaweeds such as kelp, etc. The bubbles rise toward the surface of the water. Therefore, particularly when the surface of the seafood is cleaned of stains, the occurrence of diseases such as skin diseases on the seafood is suppressed. Therefore, the oxygen supply device 1 is considered to reduce the mortality rate of seafood. That is, when the oxygen supply device 1 is used in the water tank 2, the air (oxygen) contained in the water flow discharged in water becomes fine bubbles. The bubbles are smaller than the bubbles formed by the conventional method, and are scattered in the water in the water tank 2 for a long time. This allows
The air bubbles easily come into contact with the dirt adhering to the surface of the seafood or the like, and the cleaning effect for removing the dirt adhering to the surface of the seafood or the like is improved. When the filtering device 3 is provided together with the water tank 2, the dirt attached to the surface of the seafood or the like floats on the water surface, and then the dirt is removed by the filtering device 3. Therefore, the cleanliness of the water in the water tank 2 is improved.

Next, a second embodiment of the present invention will be described with reference to FIG.
And FIG. 7 will be described. In the first embodiment, the case where the oxygen supply device 1 is provided in the water tank 2 has been described, but in the present embodiment, the oxygen supply device for marine products (hereinafter, referred to as “oxygen supply device”) is provided in the fishing ground for sea surface culture. ) 81 will be described. In the following, the same components as those in the first embodiment will be designated by the same reference numerals and description thereof will be omitted.

First, an outline of sea surface culture will be briefly described. FIG. 6 is an image diagram of a fishing ground where aquaculture is performed on the surface of the sea. FIG. 7 shows an oxygen supply device 8 at a fishing ground 82 for marine aquaculture.
It is a schematic block diagram in which 1 was provided. As shown in FIG. 6, the marine aquaculture fishing ground (hereinafter, referred to as “aquaculture fishing ground”) 82 is provided in a water area having a relatively shallow water and relatively close to the coastal area of the ocean 80, and is surrounded by a frame platform 83. The water area within the specified area is designated as a fishing ground. By providing a fish cage (commonly called “kowari”) 84 surrounded by a resin net under the water surface of the aquaculture fishing ground 82, seafood is cultivated in the fish cage 84.

Relatively coastal area of ocean 80 (left part of FIG. 6)
Is provided with a plurality of aquaculture fishing grounds 82. As shown in FIG. 6, the aquaculture fishing ground 82 is configured by surrounding the frame platform 83 in a rectangular shape with respect to the water area that is a part of the ocean 80. The frame platform 83, which is one side of the aquaculture fishing ground 82, has a predetermined length. The frame platform 83 is
It is supported at the bottom of the ocean 80. In the aquaculture fishing ground 82, as shown in FIG. 7, a plurality of cages 84 are arranged in a state of being fixed to the frame platform 83 by a flow stop (not shown). The cage 84 is, for example, a net made of resin such as polyethylene, and is formed in a rectangular parallelepiped shape having a length of 3 m, a width of 3 m, and a height of 3 m.

As shown in FIG. 7, water supply means 85 is installed on the frame platform 83. The water supply means 85 includes a pump 86, a water suction pipe 87, a water supply pipe 88, and a power generation unit (not shown). Water absorption pipe 87 and pump 86
And the water supply pipe 88 communicate with each other. The pump 86 pumps seawater from a water absorption pipe 87, one end of which is provided below the water surface, and supplies the seawater to a water supply pipe 88. A power generator that is a driving source of the pump 86 or the like uses, for example, a power generator using the power of a small engine.

In the aquaculture fishing ground 82, as shown in FIG.
An oxygen supply device 81 is installed. In this embodiment, one oxygen supply device 81 is provided for one cage 84.
Is provided. It should be noted that one oxygen supply device 81 may branch the water pipe 63 into a plurality of water pipes 63 and discharge a water flow containing a large amount of oxygen toward the plurality of cages 84. Further, the method of discharging the water flow containing a large amount of oxygen toward the plurality of cages 84 can be appropriately changed.

In the oxygen supply device 1, the diameter of the air pipe 23 is 13 mm, but in the oxygen supply device 81, the air pipe 23 is
The air tube 89 whose diameter is changed from 13 mm to 16 mm is used. As a result, the air pipes, valves, and joints of the present embodiment, which correspond to the air pipes 20, valves 21, and joints 22 of the first embodiment, use piping materials having a diameter of 16 mm. Further, in the oxygen supply device 1, the valve 21 of the air introduction part 17 is provided between the joint 22 and the joint 31, but in the oxygen supply device 81, it is provided in the middle of the air pipe 89 connected to the joint 22. .

Connection port 19 of water pipe 19 of oxygen supply device 81
The a is communicated with the water supply pipe 88. Oxygen supply device 81
The fixing member 90 holds the support member 36,
It is moored to the frame platform 83. Further, the water suction pipe 87, the air pipe 89, and the like are moored to the frame platform 83 at arbitrary points. The water pipe 61 is formed to have a length such that the water pipe 63 can be arranged under the cage 84.

The operation of the oxygen supply device 81 configured as described above will be described. When discharging a water stream containing a large amount of air (oxygen) toward the cage 84, the valve 21
Open the circuit. The amount of air (oxygen amount) supplied into the water is adjusted, for example, by adjusting the opening amount of the knob 24 (see FIG. 3) in accordance with the type and number of fish and shellfish raised in the cage 84. Next, the power generation part is operated to bring the pump 86 into an operating state. As a result, the seawater sucked from the water suction pipe 87 is transferred to the water supply pipe 88.
And is supplied to the oxygen supply device 81 via. At this time, the air introduced from the air pipe 89 is supplied to the water pipe 8 in the throttle portion 15.
It merges with the water stream sent from 8. Then, a water flow containing a large amount of air (oxygen) in the form of fine bubbles is discharged from the water pipe 63.

The effects of the oxygen supply device 81 of the second embodiment will be described. In Experiment 3, the seafood was cultivated while releasing a water flow containing a large amount of air (oxygen) in the form of fine bubbles into the water of the aquaculture fishing ground 82 by the oxygen supply device 81.
The mortality of seafood and the growth rate of surviving seafood were observed (see FIG. 7). Experiment 4 is an oxygen supply device 101 for fisheries.
The fish and shellfish were cultivated while releasing a water stream containing air (oxygen) into the water of the aquaculture fishery 82, and the mortality of the fish and the growth rate of the surviving fish and shellfish were observed. In Experiment 4, the experiment was performed under the same conditions as Experiment 3, except that the oxygen supply device for marine products 101 was not used.

Experiment 3 was conducted under the following conditions. (1) Specifications of cage and oxygen supply device: The cage 84 and oxygen supply device 81 described above were used. (2) Number of cages and oxygen supply devices: 1 cage 84
For this, one oxygen supply device 81 is installed. The brackish oysters were packed in aquaculture cages arranged in the cage 84. (3) Type of seafood used in the experiment: red sea bream, kanpachi, hamachi, and oyster (4) Experimental period: 1 year (5) Circulation amount of water by the water supply means 85: 300 L / mi
n (6) Valve: Completely open circuit (7) Throttle ratio due to cross-sectional area of water channel in throttle pipe: State in throttle pipe 33 described above, ratio S due to cross-sectional area of water channel
b / Sa is 0.4

As a result of the experiment, first, the mortality rate of fish and shellfish dying during the experiment period is shown. According to the result of Experiment 3, the mortality rate of each seafood was about 1%. On the other hand, according to the result of Experiment 4, the mortality rate of each seafood was about 10%. From these experimental results, the case where the seafood is cultivated in the aquaculture fishing ground 82 in which the oxygen supply device 81 is installed is the case where the seafood is cultivated in the aquaculture fishing ground 82 in which the conventional fisheries oxygen supply device 101 is installed. From this, it can be seen that the survival rate of seafood in the aquaculture fishing ground 82 is high. As described above, the reason why the mortality rate of the seafood is decreased is that the oxygen supply device 81 of the present embodiment is
It is considered that the amount of dissolved oxygen in water in the cage 84 was increased by using the above method, so that the death of fish and shellfish due to oxygen deficiency was decreased. In other words, it is considered that the increased dissolved oxygen content in the water made it easier for the seafood to breathe.

Next, through Experiment 3 and Experiment 4, as another experiment result, the growth rate of the brassiere that survives in the cage in the cage 84 in the fishery 82 for aquaculture will be shown. Generally, the growth period of Shinogaki is from October every year to March of the following year. According to the results of Experiment 3, the true brackish seeds grew at an average growth rate of 0.8 mm per day. On the other hand, in the results of Experiment 4, the polishing rate was 0.3 mm on average per day. From these experimental results, the oxygen supply device 81
The case where the brackish fish is cultivated in the cages in the cages 84 of the aquaculture fishery 82 in which the brackish oysters are cultivated is better than the case where the brackish oysters are cultivated in the aquaculture fishery that has the conventional oxygen supply device 101 for fisheries. It can be seen that the growth rate of is fast. As described above, the reason why the growth rate of the true brackish seeds is increased is that the oxygen supply device 81 of the present invention is used, whereby the amount of dissolved oxygen in water in the aquaculture cage in the cage 84 is increased as compared with the conventional method. , It is considered that the garnish became easier to breathe and the growth rate of the garnish was promoted.

Further, in the oxygen supply device 81, a water flow containing a large amount of air (oxygen) in the form of fine bubbles is discharged in water, so that the fine bubbles form a cage 8 in the aquaculture fishing ground 82.
4 will be spread over a wide area for a long time.
As a result, fine air bubbles come into contact with dirt adhering to the nets that form the fish cage 84, the surface of seafood, and the surface of seaweeds such as wakame seaweed that grow in the fish cage 84, and air bubbles are generated together with the dirt. Ascend to the surface of the water. Therefore, particularly when the surface of the seafood is cleaned of stains, the occurrence of diseases such as skin diseases on the seafood is suppressed. Therefore, the oxygen supply device 81 is considered to reduce the mortality rate of seafood. That is, when the oxygen supply device 81 is used in the aquaculture fishing ground 82, the air (oxygen) contained in the water flow discharged in water is used.
Becomes fine bubbles. The bubbles are smaller than the bubbles formed by the conventional method and are scattered in the water in the cage 84 for a long time. This makes it easier for the air bubbles to come into contact with the dirt attached to the surface of the seafood or the like, and improves the cleaning effect for removing the dirt attached to the surface of the seafood or the like. Also,
For example, it becomes difficult for marine algae, mussels and the like to adhere to a cultured cage filled with brass and the like.

The present invention is not limited to the above-described embodiments, but may be modified as appropriate without departing from the spirit of the invention. For example, although the case where the seafood landed in the ocean is temporarily bred in the water tank 2 has been described, the use of the water tank provided with the oxygen supply device can be variously changed. As an example, a tank installed in a vehicle for transporting live fish,
An aquarium used to cultivate live fish for fishing and fish in the fish market, an aquarium where fish for viewing are cultivated in aquariums, and a live fish farm for restaurants and sushi restaurants. An oxygen supply device may be installed in a water tank or the like. Also, by connecting a plurality of various resin piping members, the oxygen supply devices 1, 8
However, the pipes may be integrally formed by welding or bonding, and the material forming the oxygen supply device and the connecting method between the materials can be variously changed. Further, although the throttle portion 15, the connecting portion 16, the air introducing portion 17, and the discharge portion 18 are each formed by using a pipe member made of vinyl chloride, the connecting portion of the oxygen supply device, the throttle portion, the air introducing portion, and the discharge portion are provided. In addition, "the water pipe and the air pipe may each be a pipe having pressure resistance" may be used. Also, the oxygen supply devices 1 and 8
The throttle portion 15, the connection portion 16, the air introduction portion 17, and the discharge portion 18 of No. 1 were respectively formed by using a vinyl chloride piping member. The material of the piping member, the size of the diameter, and the connecting method of the piping members are as follows. , Various changes are possible. Further, the size and capacity of the water tank 2 and the size and material of the fish cage 84 are not limited. Further, although the fixture 37 is held by the support member 36 and the oxygen supply device 1 is fixed to the water tank 2, the method of attaching the oxygen supply device 1 to the water tank 2 can be variously changed. Further, the water supply means 85 is composed of the pump 86, the water suction pipe 87, the water supply pipe 88, and the power generation part.
It suffices to flow from the connection port 19a of the water pipe 19 of the oxygen supply device 81 toward the discharge part 18, and the configuration of the water supply means can be appropriately changed.

[0041]

As described above in detail, if the oxygen supply device for fisheries according to the present invention is used in a fish tank or a fishing ground, the amount of dissolved oxygen in water can be increased. Alternatively, it is possible to suppress the growth delay of raw fish and shellfish due to diseases and lack of oxygen. Further, the oxygen supply device for marine products does not use a power source such as a compressor or a blower when supplying air into water, so that the cost is low and it is economical.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram showing a circulation flow of water in a water tank provided with an oxygen supply device according to a first embodiment.

FIG. 2 is a schematic diagram showing an oxygen supply device.

3 is a cross-sectional view of the oxygen supply device shown in FIG.

FIG. 4 is a perspective view showing a throttle tube provided in a joint.

FIG. 5 is a diagram schematically showing a state in which a flow of air introduced from an air introduction unit and a water flow fed from a connection unit merge.

FIG. 6 is an image diagram of a fishing ground for sea surface aquaculture.

FIG. 7 is a schematic configuration diagram in which an oxygen supply device according to a second embodiment is provided in a fish farm for aquaculture.

FIG. 8 is a schematic configuration diagram showing a circulation flow of water in a water tank provided with a conventional oxygen supply device in the water tank.

[Explanation of symbols]

1, 81 ... Oxygen supply device (oxygen supply device for fisheries) 2 ... Aquarium 3 ... Filtration device (circulation system) 9a, 9b ... Water pipe (circulation system) 15 ... Throttle part (water pipe) 16 ... Connection part (water pipe) 17 ... Air introduction part (air pipe) 18 ... Discharge part (water pipe) 21 ... Valve 33 ... Throttle tube (throttle means) 35 ... Plate member (plate-shaped member) 64 ... Outlet 82 ... Aquaculture fishing ground (fishing ground) 84 ... Ikeken 85 ... Water supply means 110 ... Compressor 112 ... Air dispersion nozzle Sa ... Cross-sectional area of water channel (maximum cross-sectional area of water channel) Sb ... Cross-sectional area of water channel (minimum cross-sectional area of water channel)

Claims (5)

[Claims] 1. An oxygen supply device for marine products, which supplies oxygen into water in a water tank or a fishing ground, comprising: a water pipe serving as a water channel for supplying water into the water tank or the fishing ground; An oxygen pipe capable of introducing oxygen and having an air pipe connected to the water pipe on the other end side, and in the water pipe, a throttling means for changing the speed of the water flow is provided in the pipe immediately before the water pipe and the air pipe are connected. According to the above, the oxygen supply device for marine products is characterized in that the water that has passed through the throttling means is mixed with the oxygen in the atmosphere supplied from the air pipe and rectified by the throttling means. 2. The oxygen supply device for marine products according to claim 1, wherein the water pipe and the air pipe are each formed of a pipe having corrosion resistance. 3. The oxygen supply device for marine products according to claim 1, wherein the throttle means has a ratio of (minimum cross-sectional area of the water pipe) and (maximum cross-sectional area of the water pipe) at a predetermined ratio. An oxygen supply device for fisheries, which is formed by inclining a plate member so that the cross-sectional area of the water pipe becomes smaller along the direction of the water flow in the set state. 4. The oxygen supply device for marine products according to claim 1, wherein the air pipe is provided with a valve capable of variably adjusting an air supply amount. Characteristic oxygen supply device for marine products. 5. The oxygen supply device for fisheries according to claim 1, wherein the water pipe takes out dirty water in the water tank, filters the water, and returns the filtered water to the water tank again. An oxygen supply device for fisheries, which is formed by a circulation system and is characterized by mixing filtered water and oxygen.