KR101903369B1 - oxygen dissolving apparatus - Google Patents

Abstract

The present invention relates to an air conditioner which is capable of introducing contaminated water such as a pond or a reservoir into an assembly case to which an inflow pipe is connected, And a storage tank which is connected to a drain pipe for dissolving and returning to a pond or a reservoir. The storage tank is provided with a lower induction inner tube and a lower induction outer tube to raise the inflow water upward, So that oxygen can be dissolved in the oxygen storage tank. Then, the oxygen is introduced into the lower induction inner pipe of the support plate downwardly installed at the center of the bottom of the support plate to be dissolved while contacting the stored oxygen, And the outer circumferential surface of the oxygen storage tube is rotated, And the upper induction pipe is downwardly disposed on the upper side of the storage tank and the upper side of the upper induction pipe is provided with a plurality of oxygen supply holes for passing oxygen upward through the lower induction outer pipe to the upper side The water introduced by the perforated support plate is guided downward to allow the oxygen to dissolve, and then the oxygen retention pipe is assembled to the upper side of the support plate so that the oxygen supplied through the oxygen supply hole of the support plate can be retained There is provided an apparatus for dissolving oxygen in water capable of supplying oxygen retained in an oxygen retention pipe to an assembly case by connecting an oxygen retention pipe and an assembly case with a recovery pipe.

Description

[0001] The present invention relates to an oxygen dissolving apparatus,

The present invention relates to an apparatus for dissolving oxygen for supplying oxygen to polluted water such as a pond or a reservoir by forcibly supplying oxygen and purifying the polluted water with purified water. More particularly, the present invention relates to an apparatus for dissolving oxygen in a pond or a reservoir, And a storage tank for dissolving oxygen in the water introduced through the assembly case and connecting a discharge pipe for returning the water to a pond or a reservoir or the like is provided on the other side of the assembly case, The bottom of the storage tank is provided with a lower induction pipe and a lower plate inducing the lower induction pipe to guide the inflow water upward to dissolve oxygen, and then downwardly installing the oxygen storage pipe at the bottom of the support plate. And the oxygen stored in the lower guiding in- So that it is dissolved while being in contact with the water, and a screw piece is formed on the outer peripheral surface of the oxygen storage tube so that it can be rapidly mixed with oxygen by moving up and down around the outer circumference of the oxygen storage tube, and the upper induction tube And the upper side of the upper induction tube is provided with a plurality of oxygen supply holes for passing oxygen upward through the inside of the lower induction outer tube, And then the oxygen retention pipe is assembled to the upper part of the support plate so that the oxygen supplied through the oxygen supply hole of the support plate can be retained and the oxygen retention pipe and the assembly case are connected to each other through the recovery pipe, Which is supplied through the assembly case, Circulated to the upper side by the upper induction tubes installed upward on the support plate and circulated to the lower side by the upper induction tubes downwardly installed on the support plate and finally dissolving the oxygen by induction circulation to the inner lower side of the storage tank, It is possible to increase the oxygen solubility very quickly and efficiently by the circulation path, and when the pressure inside the oxygen retention pipe is lowered, the oxygen generator is operated and the oxygen is supplied to the oxygen supplier through the first oxygen supply pipe to increase the pressure in the oxygen retention pipe, When the pressure in the pipe increases above a certain level, the oxygen generator is stopped and oxygen supply is stopped. Thus, efficient and economical operation becomes possible. Oxygen supplied from the oxygen supplier is guided to the lower induction inside and outside of the pedestal plate and to the upper induction pipe Because they are supplied at the same time, (BOD) of the water can be rapidly increased, and it is possible to increase the water content of the bottom of the support plate The oxygen stored in the oxygen storage pipe is dissolved in contact with water for a long time while the water introduced into the lower induction inner pipe of the support plate rises while being rotated by the screw pieces formed on the outer peripheral surface of the oxygen storage pipe, And the oxygen solubility can be increased more efficiently by making rapid mixing with the oxygen generated from the storage tank, the support plate and the oxygen retention tube, Remanufacturing is also easy and mass production is possible. The present invention relates to an apparatus for dissolving oxygen in water.

A conventional apparatus for dissolving oxygen is disclosed in Japanese Patent No. 10-1683601 (published on Dec. 12, 2016) "Oxygen dissolution apparatus with improved structure ".

The above-mentioned prior art is characterized in that the above-mentioned prior art is characterized in that "the hollow portion has a hollow portion and the hollow portion is separated into a dissolving portion and a collecting portion, a water moving pipe for injecting water into the dissolving tank, And an oxygen-water discharging portion for discharging oxygen-dissolved water from the dissolving tank, wherein the water moving pipe is provided with a water inflow portion on one side and a water discharge portion on the other side, And one or more oxygen recharging portions are provided between the inflow portion and the water discharge portion so that oxygen is introduced into the water movement pipe. "

However, in the above-described prior art, the partition walls formed with the plurality of diffusion means are all kept open upward, and only one water discharge portion at the center is installed downward, After passing the bulkhead, the water circulation is cut off from the next bulkhead, and the water level is raised.

This is because the bottom portion of the central partition wall is overhanged and the oxygen is collected by the plurality of hollows formed in the separation portion, so that the pressure acting on the collection portion is weak, which interferes with the circulation of water.

Therefore, the above-mentioned prior art has a problem in that oxygen solubility is below the expected value because the above-mentioned prior art does not circulate through the plurality of partition walls sequentially but merely overflows the upper part of the plurality of partition walls.

SUMMARY OF THE INVENTION An object of the present invention is to solve such conventional problems,

The water introduced through the assembly case is circulated upward by the lower guided inside and outer tubes installed upward on the base plate and circulated downward by the upper guiding tubes downwardly installed on the support plate and finally circulated to the inside lower side of the storage tank It is possible to increase the oxygen solubility very quickly and efficiently by a complicated circulation path, and when the pressure inside the oxygen retention pipe is lowered, the oxygen generator is operated and oxygen is supplied to the oxygen supplier through the first oxygen supply pipe, When the pressure in the pipe increases and the pressure in the oxygen retention pipe becomes higher than a certain level, the oxygen generator is stopped and the supply of oxygen is stopped so that efficient and economical operation becomes possible. In addition, And the upper induction tube of the support plate Therefore, it is possible to further improve the solubility and to efficiently dissolve oxygen in the contaminants, so that the biochemical oxygen demand (BOD) of the water can be rapidly increased, and the bottom center of the support plate The oxygen stored in the oxygen storage pipe downwardly is dissolved in contact with water for a long time while the water introduced into the lower induction pipe of the support plate by the screw pieces formed on the outer circumferential surface of the oxygen storage pipe is rotated It is possible to increase the solubility of oxygen more efficiently by making rapid mixing with the oxygen generated from the oxygen supplier, and by making the storage tank, the support plate, the support plate and the oxygen retention tube simultaneously by separate processes, This simple and conservative Piece to provide the objective of ever mass production is possible.

According to an aspect of the present invention,

An assembling case in which an assembly case is assembled is formed on one side portion and oxygen is dissolved in water introduced through an assembly case on the other side so that contaminated water such as a pond or a reservoir can be introduced into an assembling case to which an inflow pipe is connected, And a storage tank connected to a discharge pipe for returning to a storage tank or a reservoir. The storage tank has a lower induction inner pipe and a lower plate installed upward to guide the inflow water upward, So that the dissolved oxygen can be dissolved in the lower induction inner pipe of the support plate downwardly installed at the center of the bottom of the support plate to be dissolved while being in contact with the rising oxygen, So as to rise while rotating the outer peripheral portion of the oxygen storage tube, And the upper induction pipe is downwardly disposed on the upper side of the storage tank. On the upper side of the upper induction pipe, a plurality of oxygen supply holes for passing oxygen upward through the lower induction outer pipe are drilled The water introduced by the support plate is lowered so that oxygen can be dissolved while lowering the oxygen, and then the oxygen retention pipe is assembled to the upper part of the support plate so that the oxygen supplied through the oxygen supply hole of the support plate can be retained, The object of the present invention can be achieved by connecting the pipe and the assembly case to the assembly case by connecting oxygen to the assembly case by connecting the pipe and the assembly case with the recovery pipe.

According to the present invention as described above, the water introduced through the assembly case is circulated upward by the lower induction internal and external tubes installed upward on the support plate, circulated downward by the upper induction tubes downwardly installed on the support plate, It is possible to increase oxygen solubility very quickly and efficiently by a complicated circulation path because the oxygen is dissolved while inducing circulation to the inner lower side of the tank.

When the pressure inside the oxygen retention pipe is lowered, the oxygen generator is operated and oxygen is supplied to the oxygen supplier through the first oxygen supply pipe, so that the pressure in the oxygen retention pipe increases and the pressure in the oxygen retention pipe becomes higher than a certain level The oxygen generator is stopped and the supply of oxygen is stopped so that an efficient and economical operation is possible.

In the present invention as described above, oxygen supplied from the oxygen supplier is simultaneously supplied to the lower induction and outer tube of the support plate and to the upper induction tube of the support plate, so that oxygen is easily dissolved during circulation of the water, And can efficiently dissolve oxygen in the pollutants, thereby increasing the biochemical oxygen demand (BOD) of water quickly.

According to the present invention as described above, the oxygen stored in the oxygen storage tube downwardly installed at the center of the bottom of the support plate dissolves in contact with water for a long time, and at the same time, by the screw pieces formed on the outer circumferential surface of the oxygen storage tube, The water introduced into the lower induction pipe is swirled while being swirled so as to be rapidly mixed with oxygen generated from the oxygen supplier, thereby increasing the solubility of oxygen more efficiently.

The present invention as described above makes it possible to simultaneously produce a storage tank, a support plate, a support plate, and an oxygen retention tube in separate processes, thereby manufacturing the device by assembly. Therefore, it is possible to produce a useful effect I have.

1 is a sectional view for explaining a configuration of an apparatus for dissolving oxygen according to the present invention
2 is a schematic cross-sectional view of an apparatus for dissolving oxygen according to the present invention,
3 is a functional sectional view showing the operation of a venturi tube in an apparatus for dissolving oxygen according to the present invention
Figure 3 is a schematic cross-sectional view of the apparatus for dissolving oxygen according to the present invention,

The construction of the present invention will be described in detail with reference to the accompanying drawings.
An assembly case 151 to which an inflow pipe 152 for introducing polluted water such as a pond or a reservoir is connected,
A discharge pipe 103 for dissolving oxygen in the water introduced through the assembly case 151 and returning it to a pond or a reservoir is formed on one side of the assembly case 102 where the assembly case 151 is assembled, A storage tank 101 for connecting the storage tank 101,
Below the storage tank 101, there are provided a lower induction inner pipe 113 and a lower induction outer pipe 112 for upwardly guiding the inflow water to dissolve the oxygen while upwardly arranging the lower induction outer pipe 112,
An oxygen storage pipe 125 which is introduced downward to the center of the bottom of the support plate 122 so as to be melted while being in contact with the stored oxygen, which flows into the lower guide inner pipe 113 of the support plate 111,
A screw piece 126 formed on an outer circumferential surface of the oxygen storage tube 125 so as to be rotated while rotating around the outer circumferential surface of the oxygen storage tube 125 to rapidly mix with oxygen,
An upper guide pipe 123 for dissolving oxygen while downwardly guiding the inflow water downward is formed on the upper side of the storage tank 101 and a lower guide outer pipe 112 A support plate 121 for passing a plurality of oxygen supply holes 122 for passing oxygen upward through the inside of the support plate 121,
An oxygen retention pipe 131 assembled to an upper portion of the support plate 121 to retain the oxygen supplied through the oxygen supply hole 122 of the support plate 121,

And a return pipe 146 connecting the oxygen retention pipe 131 and the assembly case 151 to recover the oxygen retained in the oxygen retention pipe 131 and supply the collected oxygen to the assembly case 151.

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The assembly case 151 is provided with a plurality of venturi tubes 151 formed inside the assembly case 151 so as to be supplied to the lower guide inner tube 113 of the support plate 111 while the flow rate of water flowing into the inlet pipe 152 is increased, A pipe 153,

A second oxygen supply pipe 147 for connecting the venturi pipe 153 and the return pipe 146 to supply the oxygen recovered from the oxygen retention pipe 131 to the venturi pipe 153 through the return pipe 146, Respectively.

The oxygen generated from the oxygen generator 141 is supplied to the inside of the lower guiding tube 113 and the outer tube 113 of the supporting plate 111 and the upper guiding tube 123 of the supporting plate 121, The second assembly hole 115 of the upper and lower guide tubes 113 and 112 and the third assembly hole 127 of the upper guide tube 123 are connected to the first assembly hole 104 of the storage tank 101 And an oxygen supplier 149 connected to the oxygen generator 141 and the first oxygen supply pipe 142.

The medicine case 144 is further connected to the inflow pipe 152 and the medicine supply pipe 145 so as to supply and mix the medicines to the contaminated water flowing into the inflow pipe 152 of the assembly case 151 It is.

When the pressure in the oxygen retention pipe 131 drops, the oxygen generator 141 operates to supply oxygen to the oxygen supplier 149 through the first oxygen supply pipe 142 to remove the pressure in the oxygen retention pipe 131 And when the pressure in the oxygen retention pipe 131 is maintained to be normal, the oxygen generator 141 is stopped and the supply of oxygen is stopped.

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Hereinafter, the operation of the present invention will be described.

FIG. 2 is a functional sectional view for explaining the operation of the apparatus for dissolving oxygen according to the present invention. In the inflow pipe 152 connected to the assembly case 151, contaminated water in a pond or a reservoir is supplied to a pump (not shown) It is forced by pressure.

The contaminated water flowing into the inflow pipe 152 is discharged to the outside through the first joint hole 114 formed in the assembly guide 102 of the storage tank 101 and the lower induction and outer tubes 113 and 112 of the support plate 111 And a second coupling hole 124 formed in the upper induction pipe 123 of the support plate 121. [

The water introduced into the assembly case 151 flows through the plurality of venturi pipes 153 at a high flow rate as shown in FIG. 3 to the lower side of the lower guide inner tube 113, which is upwardly installed above the support plate 111 .

The oxygen generated from the oxygen generator 141 is supplied to the oxygen supplier 149 through the first oxygen supply pipe 142, that is, the first assembly hole 104 of the storage tank 101, A second assembly hole 115 formed in the outer tube 113 and a third coupling hole 127 formed in the upper induction pipe 123 of the support plate 121.

The oxygen supplier 149 simultaneously supplies the oxygen to the inside of the lower guiding plate 113 and the outer tube 113 of the supporting plate 111 and the upper guide pipe 123 of the supporting plate 121 and the inside of the storage tank 101 4 as shown in Fig.

The water supplied to the lower induction internal pipe 113 from the venturi pipe 153 is circulated to the upper side along the inside of the lower induction internal pipe 113 while part of the water circulates through the oxygen storage pipe 125 of the support plate 121 And the water moving to the remaining upper portion is rotated by the screw pieces 126 formed on the outer circumferential surface of the oxygen storage tube 125 to mix the oxygen with the water. do.

As described above, the water, which is circulated to the upper side of the lower induction internal pipe 113, moves from the upper side to the lower side of the upper induction pipe 123 of the support plate 121, So that oxygen is dissolved again.

The water gathered at the bottom of the support plate 111 by the lower portion of the upper guide pipe 123 is circulated upward along the lower guide induction pipe 112 of the support plate 111 by the pressure of the pump, So that oxygen again comes into contact with the oxygen supplied from the oxygen supplier 149, so that oxygen is dissolved again.

Since the oxygen contacts the contaminated water several times as described above, the water that finally collects on the bottom surface of the storage tank 101 is converted into the water having a higher biochemical oxygen demand (BOD) and is discharged through the discharge pipe 103 It is discharged to the pond or reservoir again, so that a good water quality environment can be created.

In the present invention, a plurality of oxygen supply holes 122 are formed in the outer side of the support plate 121. The circulation water flows into the inlet pipe 152, (112).

That is, when the water exceeds the lower induction outer pipe 112 of the support plate 111, oxygen not yet mixed is guided to the oxygen supply hole 122 formed in the upper support plate 121, .

The oxygen remaining in the oxygen retention pipe 131 is supplied to the second oxygen supply pipe 147 connected to the venturi pipe 153 through the return pipe 146 coupled to the second through hole 134 So that the concentration of the solution can be further increased.

When the pressure in the oxygen retention pipe 131 drops, the oxygen generator 141 is operated according to an instruction from a control box (not shown) to supply oxygen to the oxygen supplier 149 through the first oxygen supply pipe 142 When the pressure in the oxygen retention pipe 131 is released and the pressure in the oxygen retention pipe 131 is maintained at a normal level, the oxygen generator 141 is stopped and the supply of oxygen is stopped. You can.

A pressure gauge 154 is coupled to the first through hole 132 of the oxygen retention pipe 131 to sense the pressure of the oxygen retention pipe 131.

Meanwhile, in the chemical container 144 provided at the side of the oxygen generator 141, chemicals are supplied to the chemical supply pipe 145 so that contaminated water can be treated.

1, the storage tank 101, the support plate 111, the support plate 121, the oxygen retention pipe 131, and the like are simultaneously manufactured in separate processes, Making it easy to make and easy to maintain.

101-Storage tank 102-Assembly tube
103-discharge pipe 104-first assembly
111-Supporting plate 112-Lower induction appearance
113-Lower induction inner tube 114-First coupling hole
115 - Second assembler 121 - Support plate
122-oxygen supply hole 123-upper induction pipe
124 - second coupling hole 125 - oxygen storage tube
126-Screw piece 127-Third assembly
131-Oxygen retention pipe 132-First through hole
134 - Second through hole 141 - Oxygen generator
142 - first oxygen supply pipe 144 - chemical container
145 - Drug supply pipe 146 - Return pipe
147 - Second oxygen supply pipe 151 - Assembly case 152 - Inflow pipe 153 - Venturi pipe
154-Pressure gauge

Claims (6)

An assembly case 151 to which an inflow pipe 152 for introducing polluted water such as a pond or a reservoir is connected,
A discharge pipe 103 for dissolving oxygen in the water introduced through the assembly case 151 and returning it to a pond or a reservoir is formed on one side of the assembly case 102 where the assembly case 151 is assembled, A storage tank 101 for connecting the storage tank 101,
Below the storage tank 101, there are provided a lower induction inner pipe 113 and a lower induction outer pipe 112 for upwardly guiding the inflow water to dissolve the oxygen while upwardly arranging the lower induction outer pipe 112,
An oxygen storage pipe 125 which is introduced downward to the center of the bottom of the support plate 122 so as to be melted while being in contact with the stored oxygen, which flows into the lower guide inner pipe 113 of the support plate 111,
A screw piece 126 formed on an outer circumferential surface of the oxygen storage tube 125 so as to be rotated while rotating around the outer circumferential surface of the oxygen storage tube 125 to rapidly mix with oxygen,
An upper guide pipe 123 for dissolving oxygen while downwardly guiding the inflow water downward is formed on the upper side of the storage tank 101 and a lower guide outer pipe 112 A support plate 121 for passing a plurality of oxygen supply holes 122 for passing oxygen upward through the inside of the support plate 121,
An oxygen retention pipe 131 assembled to an upper portion of the support plate 121 to retain the oxygen supplied through the oxygen supply hole 122 of the support plate 121,
And a recovery pipe 146 connecting the oxygen retention pipe 131 and the assembly case 151 so as to recover the oxygen retained in the oxygen retention pipe 131 and supply the collected oxygen to the assembly case 151. [ A device that dissolves oxygen in water. The method according to claim 1,
A plurality of venturi tubes (not shown) formed inside the assembly case 151 are installed in the assembly case 151 so as to be supplied to the lower guide inner tube 113 of the support plate 111 while the flow rate of water flowing into the inlet pipe 152 is increased, 153,
A second oxygen supply pipe 147 for connecting the venturi pipe 153 and the return pipe 146 to supply the oxygen recovered from the oxygen retention pipe 131 to the venturi pipe 153 through the return pipe 146, Wherein the oxygen is dissolved in water. The method according to claim 1,
In order to supply the oxygen generated from the oxygen generator 141 to the inside of the lower guide tube 113, the outer tube 113 of the storage tank 101 and the support plate 121, and the upper induction tube 123 of the support plate 121, The first assembly hole 104 of the storage tank 101 and the second assembly hole 115 of the upper and lower guide tubes 113 and 112 and the third assembly hole 127 of the upper guide tube 123 And an oxygen supplier (149) connected to the oxygen generator (141) and the first oxygen supply pipe (142). The method according to claim 1,
And a chemical container 144 connected to the inflow pipe 152 and the chemical supply pipe 145 for supplying and mixing the chemicals to the contaminated water flowing into the inflow pipe 152 of the assembly case 151 A feature that dissolves oxygen in water. delete The method according to claim 1,
When the pressure in the oxygen retention pipe 131 drops, the oxygen generator 141 operates to supply oxygen to the oxygen supplier 149 through the first oxygen supply pipe 142 to relieve the pressure in the oxygen retention pipe 131 Wherein when the pressure in the oxygen retention pipe (131) is maintained at a normal level, the oxygen generator (141) is stopped to stop the supply of oxygen.

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