KR101977655B1 - oxygen dissolving equipments for fish room comprising a dissolving part for generating vortex - Google Patents

Abstract

It is an object of the present invention to provide an oxygen dissolver for water use that can increase the oxygen dissolution efficiency of water supplied into the water tank together with oxygen by using a vortex generating dissolution part generating a rotating vortex in a short flow path. In order to accomplish the object of the present invention, the present invention provides a water treatment system comprising a plurality of water tanks (8) filled with live fishes, a raw water pump (2) for raising seawater to supply it to the water tank (8) (1) comprising a piping (4) for supplying the raised seawater to the water tank (8), a pipe (4) for connecting between the raw water pump (2) and the water tank (5), which is connected to the pipe (4); An oxygen supply vent 100 for supplying oxygen to the upstream side of the solubilizer pipe 52; And a vortex generating oxygen dissolving unit 300 for generating a rotating vortex in the seawater on the downstream side of the oxygen supply vortex unit 100 to increase the solubility of oxygen in the seawater, Oxygen is supplied into the seawater flowing through the dissolver pipe 52 through the oxygen dispersion nozzle 140 provided in the dissolver vessel pipe 52 from the oxygen supply source 120 of the vortex generating oxygen dissolver 300, The first multi-layer flow path portion 310 and the second multi-layer flow path portion 320 having different velocity distributions generate rotating vortices.

Description

TECHNICAL FIELD [0001] The present invention relates to an oxygen dissolving apparatus having a vortex dissolution zone,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an oxygen dissolver for water supply for supplying oxygen to a water tank of a fished vessel, and more particularly, to a water fired oxygen dissolver for use in a water- To an oxygen dissolver for a water tank capable of further increasing the oxygen dissolution efficiency.

In order to survive and maintain the viability of the captured live fish, the ship supplies oxygen to the water filled in the live fish tank to dissolve it. As used herein, the term " lysis " is defined to include the meaning of a dissolved state in which oxygen is present in water for a long time in a microbubble state.

The saturation solubility of oxygen in water at room temperature is about 7.6 ppm, and the actual dissolved amount is about 6.4 ppm for fresh water and about 7.2 ppm for seawater. Biologically, the oxygen dissolved amount required for the survival of fish is known to be 4 ppm or more. In the process of capturing and transporting fish using a ship, it is impossible to prevent the fish from being smothered in the fish tank, so that it is difficult to secure survival and freshness of the fish due to a drastic decrease in the amount of dissolved oxygen. To solve this problem, oxygen is supplied from the outside.

One method of artificially supplying oxygen is to use a chemical dissolving agent. Although this method uses a catalyst, high pressure and high temperature are required to dissolve the gas in the liquid, and a dissolving method using a pressurized tank and a mixer is generally used. To obtain high solubility, the pressure method is effective but the demand is limited due to the continuity of production, the initial cost of the equipment, and the scale of the equipment. As an alternative to this, a water tank for aeration which supplies a large amount of air in a micro-bubble state through a plurality of dispersing machines in a water treatment plant has been proposed. This is not a method of physically dissolving air but a method of making the air bubble size as fine as possible to increase the contact area with water to increase the dissolution rate in water. Dispersing machine is used easily because it does not require any special equipment. However, unlike water treatment plant which requires 6ppm drinking water level by aerating general air, dissolving efficiency is improved in fishery application where liquefied oxygen (oxygen tube) The economic loss due to the amount of oxygen consumed unnecessarily is 10 to 30%.

For the above reasons, dissolving machines which increase the efficiency of the dissolution by increasing the contact time with water while passing through separate mechanical devices or piping structures, separately from the aeration section (pipeline or water tank) It is being used for intestines.

Patent Registration No. 10-1108508

In order to maintain a certain amount of dissolved oxygen, an aeration type disperser is connected to an oxygen tank by connecting a hose to a live fish tank. However, the dissolution efficiency of the disperser is only 10 to 30%. It is difficult to use the dissolver for cultivation or purification treatment because of the limitation of the installation space and the capacity of the power supply due to the characteristics of the ship.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a water-soluble oxygen dissolver for use in water, which can increase the oxygen dissolution efficiency of water supplied into a water tank together with oxygen by using a vortex generating dissolution part generating a rotating vortex in a short flow path.

According to an aspect of the present invention, there is provided a watercraft comprising a plurality of water tanks filled with live fishes, a raw water pump for supplying sea water to the water tank, and a pipe for supplying seawater drawn from the raw water pump to the water tank, There is provided an oxygen dissolver for water supply which is installed in a pipe-like manner in a pipe connecting the raw water pump and the water tank. Wherein the water soluble oxygen dissolver comprises: a dissolver pipe connected to the pipe; An oxygen supply pipe for supplying oxygen to the upstream side of the dissolver pipe; And a vortex generating oxygen dissolving unit for generating a rotating vortex in the seawater on the downstream side of the oxygen supply vortex unit to increase the solubility of oxygen in the seawater, wherein the oxygen supply aeration unit is configured to supply oxygen from an external oxygen supply source to the dissolver pipe And the vortex generating oxygen dissolving unit generates rotating vortices by the first multi-layer flow path portion and the second multi-layer flow path portion having different velocity distributions.

According to one embodiment, the first multi-layer flow path portion and the second multi-layer flow path portion are separated from each other with respect to the center plate and are adjacent to each other on the left and right sides, and the flow distribution of the first multi- It is the opposite of the distribution of the euro.

According to one embodiment, the first multi-layer flow path portion includes multi-layered high-speed flow paths formed by a plurality of downwardly facing beveled plates along the flowing direction of seawater, and a plurality of uppermost beveled plates among the plurality of beveled plates, Wherein the second multi-layer flow path portion includes a plurality of high velocity flow paths formed by a plurality of upwardly facing beveled plates along a flowing direction of the seawater, and a plurality of beveled plates And a low-speed flow passage in which the cross-sectional area of the flow passage gradually increases along the seawater flow direction by the lowermost bevel board.

According to one embodiment, the vortex generating oxygen dissolving portion may further include an intermediate velocity flow path formed between the first multi-layer flow path portion and the inner surface of the second multi-layer flow path portion and the dissolver pipe.

According to one embodiment, the ultrasonic oxygen dissolving unit includes an ultrasonic oscillation circuit, and the ultrasonic oscillation circuit is provided between the oxygen supply oscillator and the vortex generation oxygen dissolution unit. And an ultrasonic vibrator that vibrates in the seawater by oscillated ultrasonic waves.

The oxygen-dissolving apparatus for water-supply according to the present invention has advantages of being able to increase the oxygen-dissolving efficiency of water supplied into the water tank together with oxygen by using a vortex generating dissolution part which is installed in a limited space of a ship and generates a rotating vortex in a short flow path Respectively.

Other objects and advantages of the present invention will be better understood from the following description of the embodiments.

1 is a schematic view showing a ship (fishing boat) to which an oxygen dissolver for water-supply according to the present invention is applied.
2 is a configuration diagram showing a water-soluble oxygen solubilizer according to the present invention.
3 is a cross-sectional view taken along line aa of Fig.
Fig. 4 is a cross-sectional view taken along line bb in Fig.
5 is a cross-sectional view taken along line cc of Fig.
6 is a cross-sectional view taken along the line dd in Fig.
7 is a cross-sectional view taken along line ee of Fig.
FIG. 8 is a configuration diagram showing an oxygen dissolver for water treatment according to another embodiment of the present invention.
FIG. 9 is a configuration diagram illustrating a water-soluble oxygen solubilizer according to another embodiment of the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings and the description thereof are intended to aid those of ordinary skill in the art in understanding the present invention. Accordingly, the drawings and description are not to be construed as limiting the scope of the invention.

FIG. 1 is a schematic view showing a ship (fishing boat) to which an oxygen solubilizer according to the present invention is applied, FIG. 2 is a diagram showing the oxygen dissolver for water treatment according to the present invention, FIG. 5 is a cross-sectional view taken along line cc of Fig. 2, Fig. 6 is a cross-sectional view taken along dd of Fig. 3, and Fig. 7 is a cross- Sectional view taken along line ee of FIG.

Referring to Fig. 1, a ship 1 includes a plurality of water tanks 8 filled with live fishes, and a raw water pump 2 for supplying sea water to the water tank 8. The ship 1 also includes a pipe 4 for supplying seawater drawn up from the raw water pump 2 to a plurality of water tanks 8. The pipe 4 is connected to the raw water pump 4 And a plurality of distribution and supply pipes 44 connected to the respective water tanks 8 while branching from the main supply pipe 42. [ The vessel 1 is provided with an oxygen dissolver 5 for supplying oxygen to increase the dissolved oxygen amount of the seawater supplied to the water tank 8 and dissolving the oxygen in seawater to the main supply pipe 42 side .

The raw water pump 2 can be operated by being supplied with electric power from the electric power supply unit in the engine room 3 while being disposed adjacent to the engine room 3. The plurality of distribution and supply pipelines 44 are provided with valves to control the amount of seawater supplied to the selected water tank 8.

2, the oxygen dissolver 5 is installed in a pipe 4 connecting the raw water pump 2 and the water tank 8. 1) and dispense feed line 44 (see FIG. 1), the oxygen dissolver 5 is connected to the main supply line 44 (FIG. 1 See FIG. The oxygen dissolver 5 has a solubilizer pipe 52 connected to the main supply pipe by a flange 51 and integrated in the pipe 4 and has an oxygen supply width And a vortex generating oxygen dissolving unit 300 generating a rotating vortex in the water at the downstream side of the oxygen supply vortex unit 100 to increase the solubility of oxygen in the seawater.

The oxygen supply vent 100 supplies oxygen stored in an external oxygen source 120 such as a liquefied oxygen storage unit, an oxygen cylinder, an oxygen generator, etc. to the dissolver through an oxygen dispersion nozzle 140 installed in the dissolver pipe 52. And to supply the piping 52 into the flowing seawater.

3 to 7, the vortex generating oxygen dissolving unit 300 includes a first multi-layer flow channel unit 310 and a second multi-layer flow channel unit 320 separated from each other by the center plate 301, . The vortex generating oxygen dissolving unit 300 forms a plurality of channels so as to help maximize the contact between water and oxygen while using a short channel. The first multi-layer flow path portion 310 and the second multi-layer flow path portion 320 are separated from each other on the basis of the center plate 301, and the distribution directions of the flow paths are reversed, Can be generated. More specifically, the first multi-layer flow path portion 310 and the second multi-layer flow path portion 320 are staggered so that the bevels of the flow paths or the beveled plates are opposite to each other.

The first multi-layer flow path unit 310 includes a plurality of multi-layered high-speed flow paths 312 formed by a plurality of downwardly facing beveled plates 311 along the direction in which seawater flows, And a low-speed flow path 314 in which the cross-sectional area of the flow path gradually increases along the direction of the seawater flow by the beveled plate 311. The seawater having passed through the multi-layered high-speed flow paths 312 shows a flow approaching the low-speed flow path 314 side, and a rotational vortex is generated on the downstream side of the first multi-layer flow path portion 310. At this time, it is preferable that the multi-layered high-speed flow paths 312 have a constant flow path cross-section from the inlet end to the outlet end. The multi-layered high-speed flow paths 312 are arranged such that the flow path length is shortened from the upper side to the lower side.

In addition, the second multi-layer flow path portion 320 is disposed in such a manner that the distribution of the first multi-layer flow path portion 310 and the flow paths is opposite to that of the first multi-layer flow path portion 310, And a low speed flow path 324 in which the flow cross sectional area gradually increases along the direction of the sea water flow by the lowermost bevel angle plate 321 of the plurality of bevel angle plates 321. The seawater having passed through the multi-layered high-speed flow paths 322 shows a flow approaching the low-speed flow path 324 side, and a rotating vortex is generated on the downstream side of the second multi-layer flow path portion 320. At this time, the multi-layered high-speed flow paths 322 preferably have a constant flow path cross-section from the inlet end to the outlet end. Further, the multi-layered high-speed flow paths 324 are arranged such that the flow path length is shortened from the lower side toward the upper side.

 A medium speed flow path 330 is formed between the inner surface of the first multilayer flow path portion 310 and the inner surface of the second multilayer flow path portion 320 and the dissolver pipe 52. As described above, by changing the distribution of the flow path including the high-speed flow paths and the low-speed flow paths provided in the first multi-layer flow path portion 310 and the second multi-layer flow path portion 320, A rotating vortex occurs.

FIG. 8 is a configuration diagram showing an oxygen dissolver for water treatment according to another embodiment of the present invention.

8, the water-treating oxygen dissolver 5 according to the present embodiment has a dissolver piping 52 (not shown) connected to a pipe 4 connecting the raw water pump 2 and the water tank 8, And is integrated into the pipe 4 by the flange 51. [ The oxygen-dissolving apparatus 5 for water treatment includes an oxygen supply vent 100 for supplying oxygen to the upstream side and a circulation vortex generator for generating circulating vortices in the oxygen- And an ultrasonic oxygen dissolving unit 200 is additionally provided between the oxygen supply vent 100 and the vortex generating oxygen dissolving unit 300 so as to increase the solubility of oxygen to the vortex generating oxygen dissolving unit 300. [ .

The ultrasonic oxygen dissolving unit 200 includes an ultrasonic oscillation circuit 210 and an ultrasonic vibration unit 220 that generates vibration in the seawater by ultrasonic waves generated by the ultrasonic oscillation circuit 210. The ultrasonic vibration unit 220 directly transmits vibration from the center of the dissolver pipe 52 to the water flowing through the dissolver pipe 52. With the above construction, when ultrasonic waves are generated in seawater, cavitation phenomenon occurs in which oxygen molecules dissolved in seawater resonate to cause particle acceleration. According to the present embodiment, oxygen supplied to seawater is instantaneously accelerated by ultrasonic vibration in the molecular unit to be micro-saturated. As described above, the oxygen sufficiently oxygenated in the ultrasonic oxygen dissolving unit 200 sufficiently comes into contact with the seawater in which the rotating vortex is generated in the vortex generating oxygen dissolving unit 300 located on the downstream side thereof, and is dissolved with higher solubility.

9, the ultrasonic vibration unit 220 is directly connected to the dissolver pipe 52, as shown in FIG. 9, which is different from that of the previous embodiment, And ultrasonic vibration is applied to the dissolver pipe 52 and the ultrasonic vibration of the seawater flowing through the dissolver pipe 52 is performed.

1: ship 2: raw water pump
4: piping 5: water-soluble oxygen dissolver
100: oxygen supply width base part 200: ultrasonic oxygen dissection
300: Vortex generated oxygen dissolution part 310: First multi-layer flow path part
320: second multi-layer flow path portion 311, 321:
312, 322: high-speed flow path 314, 324:
330: Dependent Euro

Claims (5)

A raw water pump 2 for supplying seawater to the water tank 8 and supplying the seawater drawn from the raw water pump 2 to the water tank 8; (5) which is installed in a pipe-like manner in a pipe (4) connecting the raw water pump (2) and the water tank (8) in a ship (1) ,
A dissolver pipe (52) coupled to the pipe (4);
An oxygen supply vent 100 for supplying oxygen to the upstream side of the solubilizer pipe 52; And
And a vortex generating oxygen dissolving unit 300 generating a rotating vortex in the seawater on the downstream side of the oxygen supply vortex unit 100 to increase the solubility of oxygen in the seawater,
The oxygen supply vent 100 supplies oxygen from the external oxygen supply source 120 to the seawater flowing through the dissolver piping 52 through the oxygen dispersion nozzle 140 installed in the dissolver piping 52, The vortex generating oxygen dissolving unit 300 generates rotational vortices by the first multi-layer flow channel unit 310 and the second multi-layer flow channel unit 320 having different velocity distributions,
The first multi-layer flow path unit 310 includes a plurality of multi-layered high-speed flow paths 312 formed by a plurality of downwardly facing beveled plates 311 along the direction in which seawater flows, And a low-speed flow path 314 in which the cross-sectional area of the flow path gradually increases along the direction of the seawater flow by the bevel angle plate 311. The second multi-layer flow path portion 320 includes a plurality of upwardly- And a low velocity flow path 324 in which the cross sectional flow area gradually increases along the direction of the sea water flow by the lowermost beveled plate 321 of the plurality of bevel plates 321, Wherein the water-soluble oxygen-dissolving agent is water-soluble. The flow control valve according to claim 1, wherein the first multi-layer flow path portion (310) and the second multi-layer flow path portion (320) are separated from each other with respect to the center plate (301) (310) is opposite to the channel distribution of the second multi-layer flow path portion (320). delete The vortex generating oxygen dissolving unit (300) according to claim 1, wherein the vortex generating oxygen dissolving unit (300) is a medium velocity generating unit that is formed between the inner surface of the first multilayer flow path unit (310) and the second multilayer flow path unit And a flow path (330). delete

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