KR101708552B1 - Gas Solution System - Google Patents

Abstract

The present invention relates to a gas dissolving apparatus,
A circulation water discharge nozzle is mounted to a lower end portion of a circulation water pipe having a conical orifice shape at its lower end,
A reaction water inflow pipe connected to a gas supply pipe at one side of the lower end of the circulation water pipe is installed, a cylindrical induction pipe is connected to the center of the bottom,
Wherein an upper end portion of the induction pipe has an orifice shape and a plurality of gas injection ports are provided around the induction pipe, a gas chamber is formed between the reaction pipe and the reaction water inflow pipe,
And a spiral impingement plate is mounted on an inner wall of the induction pipe,
A first diffusion in which gas is finely undifferentiated due to an increase in flow velocity and a decrease in pressure due to turbulence generated by the circulation water injected at high speed from the circulating water discharge nozzle and the gas supplied through the orifice,
As the reaction water with the primary diffusion moves to the lower part of the induction pipe, it collides with the helical impingement plate installed on the inner wall of the induction pipe, and turbulence is generated, and by the secondary diffusion,
The gas is sufficiently dissolved in the reaction water to effectively dissolve the effective gas such as oxygen in the target liquid such as various ozone and wastewater so that the wastewater treatment can be performed more effectively,
It is possible to greatly reduce the size of the reactor, thereby greatly reducing the initial facility investment cost,
The operation time can be shortened by reducing the amount of air to be introduced and the mixing efficiency of the chemicals and the flocculant, thereby greatly reducing the operation cost and the maintenance cost.

Description

Gas dissolution apparatus

The present invention relates to a gas dissolving apparatus,

It is possible to effectively dissolve an effective gas such as oxygen in a target liquid such as various ozone and wastewater,

And more particularly, to a gas dissolving apparatus capable of more effectively performing wastewater treatment.

Generally, when the wastewater is treated, the amount of oxygen dissolved in the wastewater is increased,

In order to activate the decomposition of harmful components in waste water by aerobic microorganisms,

As shown in Figure 1,

The wastewater is introduced into the aeration tank 31 and the air generated in the blower 32 is injected into the wastewater through the air diffuser 33,

The wastewater is moved to the chemical reaction tank 34, stirred with the chemical in the agitator 35, subjected to a primary reaction,

The wastewater is again moved to the flocculation tank 36 and stirred with the flocculant by the agitator 37 so that the sludge contained in the wastewater is collected by coagulation sedimentation and the treated water is discharged to the outside .

However, in the case of such a conventional waste water treatment method,

O, there is a defect that the treatment efficiency is lowered because oxygen is not sufficiently supplied to the wastewater, and the wastewater is discharged without being completely purified,

In order to overcome this problem, the capacity of the reactor is greatly increased,

The amount of air, chemicals and coagulants to be injected must be greatly increased and the operation time must be increased, thereby causing the operation cost and the maintenance cost to increase.

Document 1. Domestic patent registration No. 10-1010893 (Bulletin published on January 25, 2011) Document 2: Korean Utility Registration No. 20-0255003 (published on Dec. 1, 2001) Japanese Patent Application Laid-Open No. 9-201520 (published on Aug. 5, 1997)

The present invention has been made in order to solve all the problems of the conventional waste water treatment apparatus,

It is an object of the present invention to efficiently dissolve an effective gas such as oxygen in a target liquid such as various ozone and wastewater,

It is possible to greatly reduce the size of the reaction vessel, thereby drastically reducing the initial facility investment cost,

It is possible to shorten the operation time by reducing the amount of air to be introduced and the mixing efficiency of the chemicals and the flocculant, thereby greatly reducing the operation cost and the maintenance cost.

To this end,

The circulation water discharge nozzle is mounted on the lower end of the circulation water pipe having the conical orifice shape at the lower end,

A reaction water inflow pipe connected to a gas supply pipe at one side of the lower end of the circulation water pipe is installed, a cylindrical induction pipe is connected to the bottom center,

Wherein an upper end portion of the induction pipe has an orifice shape and a plurality of gas injection ports are provided around the induction pipe to form a gas chamber between itself and the reactive water inflow pipe,

And a spiral impingement plate mounted on an inner wall of the induction pipe.

A first diffusion in which gas is finely undifferentiated due to an increase in flow velocity and a decrease in pressure due to turbulence generated by the circulation water injected at high speed from the circulating water discharge nozzle and the gas supplied through the orifice,

As the reaction water with the primary diffusion moves to the lower part of the induction pipe, it collides with the helical impingement plate installed on the inner wall of the induction pipe, and turbulence is generated, and by the secondary diffusion,

The gas is sufficiently dissolved in the reaction water to effectively dissolve the effective gas such as oxygen in the target liquid such as various ozone and wastewater so that the wastewater treatment can be performed more effectively,

It is possible to greatly reduce the size of the reactor, thereby greatly reducing the initial facility investment cost,

It is possible to shorten the operation time by reducing the amount of air to be introduced and the mixing efficiency of the chemicals and the flocculant, thereby greatly reducing the operation cost and the maintenance cost.

The present invention is characterized in that a circulation water jetted at a high speed from a circulating water discharge nozzle and a gas supplied with reaction water passing through an orifice are simultaneously subjected to a turbulent flow caused by an increased flow rate and a lowered pressure change, ,

As the reaction water with the primary diffusion moves to the lower part of the induction pipe, it collides with the helical impingement plate installed on the inner wall of the induction pipe, and turbulence is generated, and by the secondary diffusion,

The gas is sufficiently dissolved in the reaction water to effectively dissolve the effective gas such as oxygen in the target liquid such as various ozone and wastewater so that the wastewater treatment can be performed more effectively,

It is possible to greatly reduce the size of the reactor, thereby greatly reducing the initial facility investment cost,

The reduction of the amount of air to be introduced and the increase of the mixing efficiency of the chemicals and the flocculant shorten the operation time and greatly reduce the operation cost and the maintenance cost.

1 is a diagram showing a conventional process,
Fig. 2 is a process chart of the present invention,
3 is a configuration diagram showing a configuration state of a preferred embodiment of the present invention,
4 is a configuration diagram showing a configuration state of another embodiment of the present invention;
5 is a configuration diagram of an oxidation reaction tank applied to still another embodiment of the present invention,
6 is a configuration diagram of a flocculation tank applied to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Fig. 2 is a process chart of the present invention,

3 is a configuration diagram showing a configuration of a preferred embodiment of the present invention,

In the gas dissolving apparatus of the present invention,

A reaction tank 3 in which a gas dissolving apparatus 1 is vertically installed,

A circulation pump 5 for continuously circulating the reaction water in the reaction tank 3,

And a blower 7 for supplying gas to the gas dissolving apparatus 1.

Again, the gas dissolving apparatus (1)

A circulating water discharge nozzle 11 is attached to the lower end of a circulating water pipe 9 having a conical orifice shape at the lower end,

A reaction water inflow pipe 14 connected to a gas supply pipe 12 is installed at the lower end of the circulation water pipe 9 and a cylindrical induction pipe 15 ).

The upper end of the induction pipe 15 has an orifice shape and a plurality of gas injection ports 17 are provided around the induction pipe 15 to form a gas chamber 19 with the reaction water inflow pipe 14.

A spiral impingement plate 21 is mounted on the inner wall of the induction pipe 15.

The gas dissolving apparatus of the present invention having the above-

When the circulating water flows into the gas dissolving apparatus 1 installed vertically in the reaction tank 3 through the circulating water pipe 9 by the circulating pump 5,

The circulation water is rapidly injected into the induction pipe 15 through the circulation water discharge nozzle 11 by the circulation water pipe 9 whose lower end is narrowed into a cone shape.

The internal pressure of the induction pipe 15 is lowered by the circulating water sprayed at such a high speed so that the reaction water in the upper part of the reaction tank 3 flows into the reaction water inflow pipe 14 and the orifice- The gas is injected into the induction pipe 15 together with the gas injected from the gas injection port 17 of the gas chamber 19,

At this time, in the circulating water discharge nozzle, turbulence due to an increased flow velocity and a lowered pressure change occurs together with the gas supplied with the reaction water that has passed through the circulating water and the orifice, thereby causing primary diffusion where the gas is finely undifferentiated.

The reaction water having the first-order diffusion spreads to the lower portion of the induction pipe 15 and again collides with the helical impingement plate 21 installed on the inner wall surface of the induction pipe 15 to generate turbulence, Secondary diffusion with increasing contact occurs.

By this first and second diffusion, the reaction water becomes a state in which the gas is sufficiently dissolved,

After colliding with the bottom surface of the reaction tank 3, the water is raised again to the upper part, and is sucked up again by the suction force of the upper portion of the induction pipe 15, thereby having a structure of repeatedly circulating.

Through such a process, the reaction water and the minute bubbles sufficiently contact with each other to sufficiently dissolve and stir the gas.

4 is a block diagram showing a configuration of another embodiment of the present invention,

The gas chamber 19 is formed outside the reaction water inlet pipe 14 and the lower portion of the induction pipe 15 is expanded.

During the secondary diffusion, the flow rate of the reaction water having the primary diffusion diffused to the lower portion of the expanded induction pipe 15 is reduced to collide with the helical impingement plate 21 installed on the inner wall surface of the induction pipe 15, The contact time of the reaction water and the gas is increased,

So that the gas can be sufficiently dissolved through more sufficient contact between the reaction water and the microbubbles.

5 is a configuration diagram of an oxidation reaction tank applied to still another embodiment of the present invention,

It is possible to inject the chemical into the reaction water inflow pipe 14 of the gas dissolving apparatus 1,

It is possible to simultaneously perform the function of supplying oxygen and the function of agitating the medicine and the raw water as in the case of the oxidation tank equipped with the conventional aeration tank 31 and the chemical tank 34.

6 is a view of the construction of a coagulation bath applied to another embodiment of the present invention.

The object to be dissolved is reacted with the coagulant instead of the gas in the gas dissolving apparatus 1 and the coagulant can be put in place of the gas supply pipe 12 so that it can be applied to the coagulation tank 36 facility.

Therefore, according to the gas dissolving apparatus of the present invention,

The circulation water sprayed at high speed from the circulating water discharge nozzle 11 and the reaction gas passing through the orifice together with the supplied gas are subjected to the turbulent flow caused by the increased flow rate and the lowered pressure change, ,

The reaction water in which the primary diffusion occurs is moved to the lower portion of the induction pipe 15 and again collides with the helical impingement plate 21 provided on the inner wall surface of the induction pipe 15 to generate turbulence, By secondary diffusion,

The gas is sufficiently dissolved in the reaction water to effectively dissolve the effective gas such as oxygen in the target liquid such as various ozone and wastewater so that the wastewater treatment can be performed more effectively,

The size of the reaction vessel can be largely reduced, the initial facility investment cost is greatly reduced,

It is possible to shorten the operation time by reducing the amount of the introduced air and the mixing efficiency of the chemicals and the flocculant, thereby greatly reducing the operation cost and the maintenance cost.

While the present invention has been described in connection with certain exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

One ; Gas dissolving device
3: Reactor
5: Circulation pump
7: Blower
9: Circulating water piping
11: Circulating water discharge nozzle
12: gas supply pipe
14: Reaction water inlet piping
15: Induction tube
17: gas inlet
19: gas chamber
21: Collision plate
31: Aeration tank
34: chemical reaction tank
36: Coagulation tank

Claims (4)

A circulating water discharge nozzle 11 is attached to a lower end portion of a circulating water pipe 9 having a conical orifice shape at its lower end,
A reaction water inflow pipe 14 connected to a gas supply pipe 12 at one side of the lower end of the circulation water pipe 9 is connected to a cylindrical induction pipe 15 at the center of the bottom,
The upper end of the induction pipe 15 has an orifice shape and a gas injection port 17 is provided around the induction pipe 15 to form a gas chamber 19 between the upper end of the induction pipe 15 and the reaction water inflow pipe 14,
And a spiral impingement plate (21) is mounted on the inner wall of the induction pipe (15). The method according to claim 1,
Wherein a gas chamber (19) is formed outside the reaction water inflow pipe (14), and a lower side portion of the induction pipe (15) is extended. The method according to claim 1,
So that the chemical can be introduced into the reaction water inflow pipe (14). The method according to claim 1,
So that the coagulant can be introduced instead of the gas supply pipe (12).

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