KR20220144121A - Apparatus For Dissolving Gas - Google Patents

Abstract

The present invention relates to a gas dissolving apparatus that can be used in wastewater purification facilities and the like, and can effectively dissolve gases such as air in liquids such as wastewater. The gas dissolving apparatus comprises: a treatment tank in which wastewater to be treated is stored; an induction pipe installed inside the treatment tank to form a right angle with respect to a liquid surface of the wastewater; a waste water circulation supply unit pumping the waste water and supplying the same to an inside of the induction pipe; and a microbubble supply unit supplying microbubbles to the outside of the induction pipe such that the microbubbles rise along a sidewall of the induction pipe and then are sucked into the induction pipe by negative pressure.

Description

Gas dissolving device {Apparatus For Dissolving Gas}

The present invention relates to a gas dissolving device, and more particularly, to a gas dissolving device that can effectively dissolve a gas such as air in a liquid such as wastewater, which can be used in a waste water purification facility.

In order to purify wastewater such as slaughter wastewater, livestock wastewater, chemical wastewater, and blast furnace wastewater, purification facilities using biological treatment methods are being used. This purification plant widely uses the method of aeration of wastewater through an oxygen supply. Oxygen supplied to wastewater rapidly decomposes organic matter in wastewater by greatly proliferating aerobic microorganisms.

The reactor used in the purification facility of the prior patent registration No. 10-0227819 is of a tower type, and a draft tube with both ends open is installed vertically in the center of the inside. A two-phase (gas and liquid) nozzle is installed at the top of the inside of the reactor. When liquid is injected into the induction tube through this nozzle, a liquid jet is formed at the tip of the nozzle, and external air is naturally sucked in through the air tube in the center of the nozzle by the resulting negative pressure.

Liquid Jet promotes gas-liquid contact by forming strong turbulence while microbubbles the inhaled air, and continuous circulation of the gas-liquid mixture extends the residence time of the bubbles in the reactor, resulting in 0.06kg·O ₂ /㎥·h The oxygen transfer rate in the normal activated sludge aeration tank can be increased to 0.5-3 kg·O ₂ /m3·h, and the oxygen utilization rate can be increased to more than 50%. In addition, strong turbulence can have the effect of maximizing mass transfer between oxygen, organic matter, and microorganisms.

However, according to this prior art, there is a limit on the absolute input amount of air, and thus the purification ability is also limited.

Meanwhile, Korean Patent Registration No. 10-1708552 discloses a reaction in which a circulating water discharge nozzle is mounted at the lower end of a circulating water pipe having a cone-shaped orifice shape at the lower end, and a gas supply pipe is connected to one side of the lower end outside the circulating water pipe. A water inlet pipe is installed, a cylindrical guide pipe is connected to the center of the bottom, the upper end of the guide pipe has an orifice shape, and a plurality of gas inlets are provided around the gas chamber between the reaction water inlet pipe and the water inlet pipe. is formed, and a spiral collision plate is mounted on the inner wall of the guide tube, and the circulating water sprayed at high speed from the circulating water discharge nozzle and the reaction water passing through the orifice together with the supplied gas, increase the flow rate and reduce the pressure change. turbulence occurs, the gas is finely pulverized, the primary diffusion, and the reaction water with the primary diffusion moves to the lower part of the induction tube and collides with the spiral collision plate installed on the inner wall of the guide tube again, resulting in turbulence, Due to the secondary diffusion in which the contact between the reaction water and the gas increases, the gas becomes sufficiently dissolved in the reaction water, and the effective gas such as oxygen is more efficiently dissolved in the target liquid such as various types of wastewater and wastewater treatment By making it possible to more effectively perform It is designed to significantly reduce operating and maintenance costs.

However, according to this prior art, there is a problem in that the capacity of the circulation pump is proportionally increased and the power cost is also increased in order to input air as a type using a venturi.

Korean Patent Registration No. 10-0227819 Republic of Korea Patent No. 10-1708552

An object of the present invention is to provide a gas dissolving device for a purification facility capable of increasing the processing capacity compared to the capacity of the pump and the like. More specifically, an object of the present invention is to provide a gas dissolving device that is not difficult to manufacture and can reduce manufacturing costs.

The above object, a treatment tank in which the wastewater to be treated is stored; an induction pipe installed inside the treatment tank to form a right angle with respect to the liquid level of the wastewater; a wastewater circulation supply unit for pumping the wastewater and supplying it to the inside of the guide pipe; a microbubble supply unit that ascends along the sidewall of the guide tube by supplying microbubbles to the outside of the guide tube and is sucked into the guide tube by negative pressure;

It is achieved by a gas dissolving device comprising a.

According to another feature of the present invention, the microbubble supply unit further comprises a guide tube fitted to the outside of the guide tube is installed; The microbubbles may be supplied between the guide tube and the guide tube.

According to another feature of the present invention, the waste water circulation supply unit is a circulation water pump; It is connected to the output side of the circulation water pump and may include a waste water outlet pipe installed upside down on the upper part of the guide pipe so that the outlet is installed on the upper side of the guide pipe in the downward direction.

According to another feature of the present invention, further comprising a compressed air supply unit so that compressed air can be supplied to the inside of the guide pipe; The compressed air supply unit,

blower; It may include; as providing a flow path through which the compressed air generated by the blower is supplied, it is connected to the output end of the blower and is installed inside the waste water discharge pipe.

According to the above configuration, by having a structure capable of greatly increasing the amount of microbubbles supplied, the dissolved oxygen amount of wastewater can be increased, and consequently, a gas dissolving device capable of doubling the ability of wastewater purification using aerobic microorganisms is provided. Although the gas dissolving apparatus of the present invention is based on being used for a waste purification facility, it can be utilized in various industrial fields to increase the gas solubility of the treatment liquid.

1 is an overall configuration diagram of a gas dissolving apparatus according to an embodiment of the present invention.
2 is a cross-sectional configuration diagram of a main part of a gas dissolving apparatus according to an embodiment of the present invention.

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

The gas dissolving apparatus of the present invention includes a treatment tank 10, an induction pipe 20, a wastewater circulation supply unit, and a microbubble supply unit. And if necessary, it may further include a compressed air supply unit. Although the gas dissolving apparatus of the present invention can be used in various industrial fields, it is assumed that it is used in a wastewater purification facility. Therefore, the treatment liquid may be wastewater or sewage, and will be described below by representing wastewater.

The treatment tank 10 is an open top storage tank for storing wastewater to be treated. Wastewater can be supplied and/or discharged continuously or intermittently along the direction of the arrow (see wastewater IN, wastewater OUT).

The wastewater circulation supply unit pumps the wastewater contained in the treatment tank 10 and supplies it to the inside of the guide pipe 20 , in particular, in a direct downward direction. The waste water circulation supply unit may include a waste water outlet pipe 30 introduced to the inside of the guide pipe, a circulating water pump 31, and a waste water supply pipe 32 connecting the circulating water pump 31 and the waste water outlet pipe. . The circulation water pump 31 is installed outside the treatment tank 10 . The waste water outlet pipe 30 is connected to the output side of the circulating water pump and is installed upside down on the guide pipe 30 . As a result, the discharge port of the wastewater discharge pipe 30 is opened downwardly on the upper inner side of the guide pipe 20 . The lower end 33 of the wastewater discharge pipe 30 may have a narrowed outlet in the form of a funnel in order to increase the speed of the fluid.

According to this configuration, as shown in FIG. 1 , the wastewater in the treatment tank 10 circulates continuously or at least once in the direction of the arrows K1 and K2 . In addition, a negative pressure is applied to the space S between the wastewater outlet pipe 30 and the upper end of the guide pipe 20 according to the hydrodynamic principle. By this negative pressure, microbubbles, which will be described later, are sucked into the guide tube 20 .

According to a feature of the present invention, a microbubble supply unit for supplying microbubbles (P) to the inside of the guide tube 20 is further included. The microbubble supply unit takes a method such that the microbubbles P rise along the sidewall of the guide tube 20 due to the specific gravity difference and are sucked into the inside through the upper end of the guide tube 20 by negative pressure.

The microbubble supply unit includes a microbubble generator 41 installed outside the treatment tank 10 , one end connected to the microbubble generator 41 and the other end extending to the outside of the guide tube 20 in the treatment tank 10 . and a microbubble supply pipe 42 that is The other end of the microbubble supply pipe 42 may be in a ring shape and may be branched into two or more multiple single pipes. This is to ensure that a plurality of microbubble ejection holes 43 provided by the microbubble supply pipe 42 are provided around the induction pipe 20 . According to this, it is possible to supply the microbubbles P in a uniformly dispersed state along the periphery of the guide tube 20 . The microbubbles P naturally rise toward the liquid level due to the difference in specific gravity.

According to an embodiment of the present invention, the microbubble supply unit further includes a guide tube 40 fitted to the outside of the guide tube 20 . That is, the guide tube 20 is disposed in the center of the guide tube 40 . And the microbubbles P may be supplied between the guide tube 20 and the guide tube 40 . This is to allow the microbubbles P to rise while being guided along the outer wall of the guide tube 20 without spreading outward.

The smaller the particle size of the microbubbles P, the more preferable, but there is no limitation on the particle size. Various microbubble generating means (for example, for an aquarium) provided on the market may be used.

The microbubbles (P) that have risen to the top of the guide tube 20 are sucked into the inside of the guide tube 20 by the negative pressure acting on the upper end of the guide tube 20 as described above. In this process, microbubbles (P) are directly and intensively supplied and diffused in the circulating wastewater.

According to another embodiment of the present invention, a compressed air supply unit is further included so that compressed air can be supplied to the inside of the guide tube 20 . The compressed air supply unit can further increase the vacuum degree of the negative pressure, thereby increasing the supply flow rate of the microbubbles (P). Furthermore, the compressed air supply unit may further act directly or indirectly to increase the amount of dissolved oxygen in the wastewater.

The compressed air supply unit provides a flow path through which a blower 51 installed outside the treatment tank 10 and compressed air generated from the blower 51 is supplied, and is connected to the output end of the blower 51 and discharges waste water. It may include an air outlet pipe 50 that is installed in the inside of the pipe 30 .

The lower end of the air outlet pipe 50 may protrude downward from the lower end 33 of the waste water outlet pipe as shown in the enlarged view of FIG. 2 . Compressed air may be supplied continuously or in bursts. Compressed air may be supplied in various ways in order to promote a vortex of wastewater to increase the mixing amount with microbubbles.

What has been described above is only a few examples based on the technical idea of the present invention. Those skilled in the art will be able to make various modifications using the illustrated bar without going beyond the scope of the technical spirit of the present invention expressed through the claims. For example, all embodiments described above can be freely combined and implemented by those skilled in the art, and any combination should be construed as being included in the scope of the present invention.

10: treatment tank 20: guide tube
30: waste water discharge pipe 31: circulating water pump
32: waste water supply pipe 33: bottom
40: guide tube 41: microbubble generator
42: micro-bubble supply pipe 43: micro-bubble ejection hole
50: air blowing pipe 51: blower (blower)
P: microbubbles

Claims (5)

a treatment tank in which wastewater to be treated is stored;
an induction pipe installed inside the treatment tank to form a right angle with respect to the liquid level of the wastewater;
a wastewater circulation supply unit for pumping the wastewater and supplying it to the inside of the guide pipe; and
a microbubble supply unit that ascends along the sidewall of the guide tube by supplying microbubbles to the outside of the guide tube and is sucked into the guide tube by negative pressure;
Gas dissolving device comprising a.
According to claim 1,
The microbubble supply unit,
It further comprises a guide tube fitted to the outside of the guide tube;
Gas dissolving device, characterized in that the microbubbles are supplied between the guide tube and the guide tube.
According to claim 2, wherein the microbubble supply unit;
a microbubble generator 41 installed outside the treatment tank;
One end is connected to the microbubble generator 41 and the other end is extended to the outer side of the guide tube and includes a microbubble supply pipe 42 providing a microbubble blowing hole 43;
The gas dissolving device, characterized in that the microbubble ejection hole 43 is provided in plurality around the guide tube.
According to claim 1, The waste water circulation supply unit;
a circulation water pump installed outside the treatment tank; and
a wastewater discharge pipe connected to the output side of the circulation water pump and installed upside down on the top of the guide pipe so that the discharge port is installed on the upper side of the guide pipe in the downward direction;
The gas dissolving device, characterized in that the lower end (33) of the wastewater discharge pipe is in a form in which the outlet is narrowed.
According to claim 1,
The wastewater circulation supply unit may include: a circulation water pump installed outside the treatment tank; and
a wastewater discharge pipe connected to the output side of the circulation water pump and installed upside down on the top of the guide pipe so that the discharge port is installed on the upper side of the guide pipe in the downward direction;
Further comprising a compressed air supply unit so that compressed air can be supplied to the inside of the guide tube;
The compressed air supply unit,
blower; and an air jet pipe connected to the output end of the blower as providing a flow path through which the compressed air generated by the blower is supplied and installed inside the waste water jet pipe.

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