KR20140101275A - Emission-Type Jet Aerator - Google Patents

Abstract

Provided is the present invention relating to an emission-type jet aerator, comprising: a main body whose lower part has a supporting part and an upper part is open to maximize the stirring efficiency by injecting compressed air with an inflow of wastewater via a blower, and by mixing wastewater with air step by step, which improves contact efficiency between the wastewater and air; a wastewater guide member connected to the open upper part of the main body to interwork, and has a wastewater entrance unit whereby wastewater enters; a nozzle fixated and installed on the main body which sprays wastewater from the wastewater entrance unit of the wastewater member; an air supplying unit connected to and installed on the nozzle which sprays compressed air and wastewater from the waste water entrance unit; and a nozzle tip connected to an end of the nozzle, which improves the internal pressure during the process of spraying air and wastewater.

Description

[0001] Emission-Type Jet Aerator [0002]

The present invention relates to a radial jet aerator, and more particularly, to a radial jet aerator, which is capable of injecting compressed air through a blower together with the inflow of wastewater and doubly mixing the wastewater and air through the steps, To a radial jet aerator.

Generally, when biologically treating wastewater such as wastewater, manure, and livestock wastewater, it is essential that a process of oxidizing organic matter or ammonia nitrogen by supplying air to a microorganism, which is a key element of wastewater treatment, Oxygen is diffused into water and microorganisms use it to oxidize and decompose organic matter to supply energy and purify wastewater.

However, such an air supply is essential for maintaining the dissolved oxygen concentration in the water, but it is always in an oxygen deficient state unless the oxygen is dissolved to form a large amount of minute bubbles because the solubility of oxygen is low.

Therefore, various types of water aerator (or width equipment: a), which is an apparatus for supplying oxygen to water by an acid-based aeration system that supplies air into aeration tank in which microorganisms are inhabited, or a surface aeration system that artificially forms a vortex on a water surface (Hereinafter abbreviated as "an aerator").

The aerator is configured to suck treated water (hereinafter referred to as "wastewater") from the upper portion of the suction housing by a negative pressure generated by the rotational force of an impeller connected to an underwater motor and discharge the treated water in a reverse direction of the suction direction At the same time, the air introduced into the diffuser is discharged along with the discharging direction of the wastewater, thereby continuously maintaining or increasing the amount of dissolved oxygen in the wastewater, thereby creating an environment for activating the microorganisms.

As a conventional technique disclosed in relation to the above-described air conditioner, Korean Patent Registration No. 10-0542865 (2006.01.05.) Discloses an aerator main body to which air is supplied through a turbocharger, Wherein a plurality of through holes are formed on a T tube of an aerator main body communicated with the air supply main body, and the diffuser is disposed on a bottom surface of the aerator body in a state of being communicated with a through hole of the T tube A plurality of connecting pipes connecting the jacket and the T pipe, a plurality of connecting pipes connected to a lower end of the connecting pipe, and a plurality of connecting pipes located on the connecting pipe, Thereby increasing the amount of oxygen and reducing the installation cost and operation cost.

However, in the conventional air conditioner, the efficiency of contact between the waste water and the air is considerably low only by injecting the air in the circulation process of the sewage to be discharged after the sewage is introduced, and thus the air is discharged separately. The additional equipment of the air supply line only increases the equipment cost and the spraying power of the nozzle to which the wastewater is discharged is still low and the stirring distance according to the injection of the wastewater and the air is short and at the same time the stirring efficiency between the wastewater and the air and the generation efficiency of the fine bubbles There was a problem that it fell.

In addition, the conventional air conditioner has a problem in that a drift phenomenon occurs in which the wastewater and the air are not well mixed with each other because air is forcedly injected from the outside through the blower to increase the discharge flow velocity of the wastewater or air.

Disclosure of Invention Technical Problem [7] Accordingly, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a device for mixing vapors and compressed air in a nozzle with a means for generating a vortex, thereby effectively stirring wastewater and air, The present invention is directed to a radial jet aerator.

A radial jet aerator proposed by the present invention includes a main body having an upper portion opened and a lower portion formed at a lower portion thereof; A sewage guide member connected to the upper opened portion of the main body and having a sewage inlet portion to allow sewage to flow into the upper portion; A nozzle fixedly installed on the main body and capable of spraying wastewater flowing into the wastewater inlet portion of the wastewater guide member; An air supply unit connected to the nozzle and supplying the compressed air together with the wastewater introduced through the wastewater inlet so as to be jetted; And a nozzle tip coupled to one end of the nozzle and configured to raise an internal pressure in the process of injecting waste water and air.

And a sewage guide nozzle connected to the main body at the inside of the nozzle to guide and inject the injection path of the wastewater introduced into the main body.

And a guide inclined nozzle provided between the outer surface of the sewage guide nozzle and the inner surface of the nozzle for guiding the air supplied from the air supply unit to the primary wastewater to be mixed with strong pressure to the wastewater injected through the sewage guide nozzle do.

The nozzle tip generates a vortex due to the backwash of the wastewater, thereby forming a backflow guide formed to be secondarily mixed in the inner space of the nozzle.

The backflow guide portion is formed in such a shape that the diameter gradually expands based on the spraying direction of the wastewater mixed with air.

According to the radial jet aerator of the present invention, a guide inclined nozzle for guiding the flow of wastewater and air so that the air having a pressure strong against the wastewater can be mixed first, and a vortex is generated in the first mixed water and air Since the backflow guide portion provided so as to be able to be mixed secondarily is formed in the nozzle, the stirring efficiency can be maximized by continuous double mixing and the explosive spraying force according to the fast flow velocity can be provided.

Since the radial jet aerator according to the present invention is installed in a digester, it does not require a separate pump or piping due to the circulation of sewage water, thereby greatly reducing facility cost. Also, the energy consumption is reduced and the facility maintenance cost is greatly reduced. The size is small, and the convenience of maintenance can be provided.

1 is a side view showing an embodiment according to the present invention;
2 is a plan view showing an embodiment according to the present invention.
3 is a partially enlarged cross-sectional view showing a nozzle according to an embodiment of the present invention.
4 is a sectional view showing an installation state in an embodiment according to the present invention;
5 (a) and 5 (b) are cross-sectional views showing gas compression injection in an embodiment of the present invention, respectively.

According to the present invention, there is provided a portable terminal comprising: a body having an upper portion opened and a lower portion formed on the lower portion; A sewage guide member connected to the upper opened portion of the main body and having a sewage inlet portion to allow sewage to flow into the upper portion; A nozzle fixedly installed on the main body and capable of spraying wastewater flowing into the wastewater inlet portion of the wastewater guide member; An air supply unit connected to the nozzle and supplying the compressed air together with the wastewater introduced through the wastewater inlet so as to be jetted; And a nozzle tip coupled to one end of the nozzle and configured to raise an internal pressure in the process of injecting waste water and air.

And a wastewater guide nozzle connected to the main body at the inside of the nozzle to guide and inject the injection path of the wastewater introduced into the main body.

And a guide inclined nozzle provided between the outer surface of the sewage guide nozzle and the inner surface of the nozzle and guiding the air supplied from the air supply unit to the sewage injected through the sewage guide nozzle so as to be primarily mixed with strong pressure The present invention is characterized by the technical features.

And a backflow guide portion formed in the nozzle tip to generate a vortex due to the backwash of the wastewater and to be mixed in the inner space of the nozzle in a secondary mixing manner.

Further, the backflow guide portion is characterized in that the diameter of the radial jet aerator is gradually expanded on the basis of the spraying direction of the wastewater mixed with air.

Next, preferred embodiments of the radial jet aerator according to the present invention will be described in detail with reference to the drawings.

Throughout the specification, the term "wastewater" is not limited to wastewater, which is simply a domestic wastewater, and is not limited to organic wastes such as agricultural / livestock wastes or waste wastewater sludge, desorption filtrate of food wastes, surplus sludge, Wastewater and other wastewater.

1 and 2, an embodiment of the radial jet aerator 100 according to the present invention includes a main body 100, a wastewater guide member 120, a nozzle 130, (150), and a nozzle tip (140).

The main body 100 has a receiving portion 111 formed at a lower portion thereof. That is, the receiving portion 111 is formed to be capable of being held in contact with a flat bottom surface so that the main body 100 can be installed at a predetermined position.

Although not shown in the drawing, the receiving portion 111 of the main body 100 is provided with a flange having a fastening hole so that the receiving portion 111 can be mounted on the floor by fixing the fastening portion 111 through a connecting member such as a bolt or the like, It is also possible to do.

The main body 100 is formed with an open top (not shown) so that wastewater to be treated can be introduced into the internal hollow space of the main body 100.

The opening means an opening part or an opening part for communicating the main body 100 and the wastewater guide member 120 with each other.

The wastewater guide member 120 is formed on the open top of the main body 100. That is, the wastewater guide member 120 is installed so as to communicate with the open top of the main body 100.

The wastewater guiding member 120 may be installed on the main body 100 in a screw-tightening manner, and may be installed on the main body 100 by welding or other conventional fastening means. Do.

A waste water inlet 121 is formed at an upper portion of the waste water guide member 120 to allow sewage to flow toward the inner hollow space of the main body 100.

A guide slope 122 is formed in the upper inner circumferential surface of the waste water inlet 121. That is, the guide inclined surface 122 has an upper-light-narrowed structure to guide the direction in which the wastewater flows in toward the inflow hole provided in the wastewater inflow section 121.

An underwater motor M is installed at an upper center of the sewage guide member 120. That is, one end of the submerged motor M is provided with a rotary vane which is located in the inner space of the main body 100 and is rotatable. The rotary vane is rotated from the rotary vane rotated by the submerged motor M, (121). ≪ / RTI >

The nozzle 130 is formed to be capable of injecting wastewater flowing into the wastewater inlet 121 of the wastewater guiding member 120 and is fixedly positioned on the main body 100, As shown in FIG.

Preferably, the plurality of nozzles 130 are formed on the outer circumferential surface of the main body 100.

1 and 2, a plurality of nozzles 130 are provided along the outer circumferential surface of the main body 100, and the nozzles 130 are radially installed at regular intervals along the circumference of the main body 100, It is possible.

Also, although not shown in the drawing, the nozzle 130 may be provided on the main body 100, and may be linearly connected to the main body 100 to form a pipe.

The nozzle 130 functions to mix the wastewater flowing through the wastewater guide member 120 and the air supplied through the air supply unit 150 so as to be jetted together.

The air referred to in the present invention is defined as a concept including oxygen gas and the like.

The nozzle 130 is a passage for discharging the air together with the wastewater. The nozzle 130 is formed in a cylindrical tube shape. The nozzle 130 is fixed on the outer circumferential surface of the main body 100 and extends outward. To form a narrow passage.

As shown in FIG. 3, the nozzle 130 further includes a sewage guide nozzle 113 having a smaller diameter than the nozzle 130.

The sewage guide nozzle 113 is connected to the main body 100 to guide and inject the injection path of the wastewater flowing into the main body 100. That is, the sewage guide nozzle 113 is fixed to the main body 100, and is disposed in the inner space of the nozzle 130 to inject sewage.

Like the nozzle 130, the sewage guide nozzle 113 is formed so as to be gradually narrower toward the outside from the main body 100.

As shown in FIG. 3, the nozzle 130 has a guide slant nozzle 131 for guiding air to the wastewater injected through the wastewater guide nozzle 113.

The guide inclined nozzle 131 is configured to be primarily mixed with the wastewater and the air, and the air supplied from the air supply unit 150 to the wastewater injected through the wastewater guide nozzle 113 is pressurized with a strong pressure As shown in FIG.

The guide inclined nozzle 131 is fixedly installed between the outer surface of the sewage guide nozzle 113 and the inner surface of the nozzle 130.

The guide inclined nozzle 131 is formed in a funnel shape having an inclined surface so as to form a narrow space in a direction in which air is injected.

The guide inclined nozzle 131 is positioned so that the inclined surface can be adjacent to one end of the sewage guide nozzle 113. The air moved along the inclined surface of the guide inclined nozzle 131 is guided to the inclined surface of the guide inclined nozzle 131 and the outer surface of the sewage guide nozzle 113 And is formed so as to be in contact with the wastewater under strong pressure.

The air supply unit 150 is configured to supply air from the outside toward the inner space of the nozzle 130.

The air supply unit 150 supplies air to the nozzle 130 so that compressed air can be injected together with the wastewater discharged into the sewage guide nozzle 113 through the wastewater inlet 121 And is connected to an upper portion of the nozzle 130.

The air supply unit 150 includes an annular pipe 151 to which air is supplied, an air injection pipe 152 to inject air into the upper portion of the annular pipe 151, And a connection pipe 153 connected to the annular pipe 151 and the nozzle 130 so as to communicate with each other.

The annular tube 151 is formed in a ring shape along the periphery at a distance from the main body 100.

The connection pipe 153 is formed in a number corresponding to the number of the plurality of nozzles 130 provided along the outer circumference of the main body 100.

The nozzle tip 140 is formed to raise the internal pressure in the process of injecting the waste water and the air to the outside.

The nozzle tip 140 is coupled to one end of the nozzle 130.

The nozzle tip 140 can be coupled to the end of the nozzle 130 by a screw fastening structure or welding as well as other conventional fastening means.

A reverse flow guide unit 141 is formed in the nozzle tip 140 to generate a swirling flow due to backwashing of the wastewater so that the wastewater and air are mixed secondarily in the inner space of the nozzle 130.

The backflow guide portion 141 is formed in such a shape that the diameter gradually expands based on the spraying direction of the wastewater mixed with air.

Also, although not shown in the drawing, the backflow guide portion 141 of the nozzle tip 140 may have a pointed portion that is connected to an end of the nozzle 130, or may have a rounded shape .

When the backflow guide portion 141 is formed in the nozzle tip 140 as described above, the wastewater and air primarily mixed through the guide slope nozzle 131 can flow through the inner space of the nozzle 130, It is possible to maximize the stirring efficiency between the wastewater and the air.

Next, operation of the radial jet aerator according to a preferred embodiment of the present invention will be described with reference to FIGS. 4 and 5. FIG.

The jet aerator 100 of the present invention is installed in the inner space of the digester 300 as shown in FIG. 4 so as to be in contact with the bottom surface of the digester 300 by the receiving portion 111 of the main body 100, The air supply unit 200 is connected to the air supply pipe 152 of the air supply unit 150 so that air can be supplied.

The wastewater stored in the digester 300 flows into the wastewater inlet 121 of the wastewater guide member 120 by the operation of the underwater motor M. [ At this time, the guiding slope 122 of the wastewater guide member 120 serves to guide wastewater into the main body 100 toward the wastewater inlet 121.

The wastewater introduced by the wastewater guide member 120 is injected into the main body 100 through the opening and then injected through the nozzle 130 in all directions. At this time, the wastewater is guided through the wastewater guide nozzle 113, passes through the inner space of the nozzle 130, and is injected into the nozzle tip 140.

The air supplied from the air supply unit 200 is injected through the air injection pipe 152 of the air supply unit 150 and then flows into the annular pipe 151 and the air introduced into the annular pipe 151 Is introduced into the nozzle 130 through the connection pipe 153.

5 (a), the guide inclined nozzle 131 mounted inside the nozzle 130 is connected to the connection pipe (not shown) of the air supply unit 150 through the wastewater guide nozzle 113 153 so that they can be mixed with each other.

The wastewater and air which are rapidly moved along the guide inclined nozzle 131 move along the inner space of the nozzle 130 and advance toward the nozzle tip 140. At this time, The nozzle tip 140 is partially returned to the backflow guide portion 141 formed inside the nozzle tip 140 while a certain pressure of water and air are in contact with the nozzle tip 140. Due to the reverse flow of the wastewater, . That is, the air and the wastewater are not directly sprayed to the outside of the nozzle 130 but are formed by swirling air and sewage by the wastewater backflow guide part 141, so that the agitation efficiency and the microbubble generation efficiency This is very good.

That is, according to the radial jet aerator of the present invention configured as above, the guide inclined nozzle for guiding the flow of the wastewater and the air so that the air having the strong pressure to the wastewater can be primarily mixed, Since the backflow guide part provided in the nozzle to generate the vapors in the air and to be mixed in the secondary is constituted in the nozzle, it is possible to maximize the stirring efficiency by continuous double mixing and to provide the explosive spraying force according to the high flow velocity.

Further, since the radial jet aerator according to the present invention is installed in a digester, it does not require a separate pump or piping due to the circulation of waste water, thereby greatly reducing the equipment cost. Also, the energy consumption is reduced and the facility maintenance cost is greatly reduced. It is possible to provide convenience in maintenance because of its small size.

Although the preferred embodiments of the radial jet aerator according to the present invention have been described above, the present invention is not limited thereto. Various modifications may be made within the scope of the appended claims, the specification and the accompanying drawings, And falls within the scope of the present invention.

100: jet aerator 110: main body 111:
113: sewage guide nozzle 120: wastewater guide member 121: waste water inlet
122: guide slope 130: nozzle 131: guide slope nozzle
140: nozzle tip 141: backflow guide part 150: air supply unit
151: annular tube 152: air inlet tube 153: connecting tube
200: Air feeder 300: Digester M: Submersible motor

Claims (5)

A main body having an upper opening and a lower receiving portion;
A sewage guide member connected to the upper opened portion of the main body and having a sewage inlet portion to allow sewage to flow into the upper portion;
A nozzle fixedly installed on the main body and capable of spraying wastewater flowing into the wastewater inlet portion of the wastewater guide member;
An air supply unit connected to the nozzle and supplying the compressed air together with the wastewater introduced through the wastewater inlet so as to be jetted;
And a nozzle tip coupled to one end of the nozzle and configured to raise an internal pressure in the process of injecting waste water and air.
The method according to claim 1,
And a wastewater guide nozzle connected to the main body at an inner side of the nozzle to guide and inject the injection path of the wastewater introduced into the main body.
The method of claim 2,
And a guide inclined nozzle which is installed between the outer surface of the sewage guide nozzle and the inner surface of the nozzle and guides the air supplied from the air supply unit to the wastewater injected through the sewage guide nozzle to be mixed with strong pressure Wherein the radial jet aerator is a radial jet aerator.
The method according to claim 1,
And a backflow guide portion formed inside the nozzle tip to generate a vortex due to the backwash of the wastewater and to be mixed in the inner space of the nozzle.
The method of claim 4,
Wherein the backflow guide portion has a shape in which a diameter gradually expands with reference to an injection direction of wastewater mixed with air.

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