KR20220137387A - Wastewater treatment apparatus using stirring convection of air supply and filtration - Google Patents

Abstract

The present invention relates to a wastewater treatment device using agitation convection of air supply and filtration. The wastewater treatment device using agitation convection and filtration of air supply comprises: a cylindrical filter pipe including an upper part containing a plurality of discharge holes and a lower part positioned below the upper part, wherein an upper end of the upper part is blocked and a lower end of the lower part has a wastewater inlet; a filter material surrounding a surface of the upper part of the filter pipe; a main body forming a storage space containing filtered water filtered through the filter pipe and the filter material, covering the upper part of the filter pipe, having an outlet for discharging microbubble water to the outside at an upper end, and having an air injection line formed on a side of a lower end part; a vortex forming part formed at a lower end of the main body, having a through hole through which the filter pipe penetrates, having a perforated plate with a plurality of perforated holes for allowing wastewater to flow into the storage space stacked around the through hole, wherein the perforated holes facing vertically are formed in a zigzag pattern; and a diffusion wing part communicating with an end of the outlet and collecting and radially discharging the microbubble water discharged from the outlet. Accordingly, operation can be performed efficiently by increasing the amount of water circulation.

Description

Wastewater treatment apparatus using stirring convection of air supply and filtration

The present invention relates to a wastewater treatment device that enables efficient operation by simultaneously generating and filtering microbubble water.

In the existing wastewater treatment system, the microbubble generation method is a pressurized bubbling method that pressurizes air with an air compressor to saturate it with water, then lowers the pressure to below atmospheric pressure to create microbubbles, and a nozzle (diffuser tube) with fine holes for air. The diffusion-type foaming method, which generates air bubbles by passing through them, is widely used.

For example, in Korean Patent Registration No. 0902189, a cylindrical body having an inlet and an outlet on both sides; a vortex forming part disposed on the inlet side inside the cylindrical body to form a vortex of a fluid containing air bubbles passing through the cylindrical body; and a bubble generating unit disposed on the side of the outlet inside the cylindrical body to form ultra-fine air bubbles contained in the fluid that has passed through the vortex forming unit, wherein the bubble generating unit includes a portion of the exhaust port of the body a fixing rod detachably coupled to the exhaust port while opening; a support rod having one end coupled to the fixing rod and disposed along the axial direction of the body; and an air crushing unit coupled to the outer periphery of the support rod to crush air bubbles passing through the body.

However, even in the case of the above technology, it is not easy to uniformly refine the bubbles down to a micro size or less. There are problems that are difficult to anticipate.

Korean Patent Registration No. 0902189

The present invention has been devised to solve the above problems, and it is intended to provide a wastewater treatment device capable of increasing the reaction surface area by the microbubbles by generating uniform microbubbles, as well as allowing filtration to be performed at the same time. .

As a means for solving the above problems, the wastewater treatment apparatus (hereinafter referred to as "the apparatus of the present invention") using agitated convection and filtration of air supply of the present invention is an upper part including a plurality of discharge holes and a lower part of the upper part. a cylindrical filter tube comprising a lower layer positioned thereon, the upper end of the upper layer being blocked, and the lower end of the lower layer having a wastewater inlet; a filter medium surrounding the upper surface of the filter tube; a body covering the upper layer of the filter tube while forming a storage space containing the filtered water filtered through the filter tube and the filter medium, and having an outlet for discharging the microbubble water to the outside at the upper end, and an air injection line is formed on the lower side side; A perforated plate is stacked at the bottom of the main body, a through hole through which the filter tube passes, and a plurality of perforated holes for allowing wastewater to flow into the storage space around the through hole are stacked, and the perforations facing up and down are formed in a zigzag pattern. a vortex forming part; It is characterized in that it comprises a; diffusion wing portion communicating with the end of the outlet while collecting the microbubble water discharged from the outlet in a radial shape.

As an example, the diffusion wing unit includes a collection chamber in which the microbubbles that are discharged through communication with the end of the discharge port are collected, and a discharge chamber that protrudes in a radial direction while communicating with the collection chamber and has a second discharge hole formed on each side thereof. A wastewater treatment device using agitated convection and filtration of air supply.

As an example, the filter medium is characterized in that it includes a filtering body surrounding the filter tube and a filter end projecting radially from the filtering body to the storage space.

As an example, the perforation is characterized in that a thread is formed on the inner periphery.

As an example, the vortex forming part is characterized in that it further comprises a plurality of vortex forming rods which protrude radially in the centripetal direction on the upper or lower portion of the perforated plate and are threaded on the outer periphery.

As an example, the perforations of each perforated plate are characterized in that the diameter is different.

In one example, the perforated plate is characterized in that the thread direction of the perforation is different.

As an example, between the perforated plate, a sludge cutting port including a central pipe and a plurality of cutting blades protruding radially from the central pipe is further included.

As described above, in the present invention, the process of generation and filtration of microbubble water is carried out simultaneously in one device, so that installation and operation are simple, and facility and energy costs can be greatly reduced, and the amount of water circulation is reduced. It has the advantage of being able to increase and efficiently operate.

1 is a side cross-sectional view showing an operating state of the present invention.
Figure 2 is a plan view showing a diffusion wing portion as one configuration of the present invention.
Figure 3 is an operating state diagram showing an embodiment of the diffusion wing portion as one configuration of the present invention.
Figure 4 is a view of the operating state of the vortex forming part as one configuration of the present invention.
Figure 5 is a perspective view showing an embodiment of the perforated plate in the present invention.
6A and 6B are operational state diagrams showing a main mechanism for causing a vortex collision in the embodiment shown in FIG. 5;
7 is an operation state diagram showing another example of the present invention.
8 is a side cross-sectional view showing another example of the present invention.
9 is a plan view showing an embodiment of a filter medium as one configuration of the present invention.
10 is a side cross-sectional view showing an example in which the sludge incision hole is further included in the perforated plate.

Hereinafter, the configuration and operation of the present invention will be described in more detail based on the accompanying drawings. In describing the present invention, the terms or words used in the present specification and claims are based on the principle that the inventor can appropriately define the concept of the term in order to best describe his or her invention. It should be interpreted as meaning and concept consistent with the technical idea of

As shown in FIG. 1 , the device 1 of the present invention includes an upper part including a plurality of discharge holes 51 and a lower part located below the upper part, the upper part of the upper part is blocked, and the lower part of the lower part is Cylindrical filter tube (5) having a wastewater inlet (52); a filter medium (6) surrounding the upper surface of the filter tube (5); While forming a storage space 23 containing the filtered water filtered through the filter tube 5 and the filter medium 6, the outlet 22 covers the upper layer of the filter tube 5 and discharges the microbubble water to the outside at the top. ) having a main body (2) having an air injection line (21) formed on the side of the lower end; A plurality of perforated holes 311 configured at the lower end of the main body 2 and through which the filter tube 5 passes are formed, and a plurality of perforated holes 311 are formed around the through holes 312 so that wastewater flows into the storage space 23 . ) Doedoe the perforated plate 31 on which is formed is stacked, the vortex forming part 3 in which the perforations 311 facing up and down are formed in a zigzag; It is characterized in that it includes; a diffusion wing portion (4) communicating with the end of the outlet (22) and discharging it radially while collecting the microbubble water discharged from the outlet (22).

The apparatus 1 of the present invention provides an apparatus capable of simultaneously performing the filtration process and the aeration process (generation of microbubble water) in one device. According to this, there is no need to operate a suction pump and there is no need to install a separate aeration device. .

That is, without installing a separate suction pump, the wastewater can be pulled up into the filter tube 5 and filtered, and the filtered water can be discharged. Water circulation is made while forming a vortex to generate microbubble water, thereby increasing microbial culture and activation.

Therefore, not only the installation is simple and the operation process is simplified, but also the facility cost and energy cost can be greatly reduced, and the purification effect can be greatly improved.

Although not shown in the drawings, when the air injection line is also configured in the filter tube 5, the oxygen transfer rate is high and aerobic microorganisms are provided to directly deliver oxygen into the filter tube 5 or to inject oxygen into the storage space 23 The proliferation of microorganisms becomes active, and microorganisms can be intensively cultured without microbial detachment, and as a result, the activation of microorganisms can be achieved in a short time. Therefore, a microbial community is formed, contaminants are filtered, and only organic matter is adsorbed to proliferate microorganisms.

The filter tube 5 has a long cylindrical shape in the vertical direction, and can be largely divided into two regions. That is, the filter tube 5 includes an upper layer and a lower layer positioned below it, and the upper end of the filter tube 5, that is, the upper end of the upper layer, is blocked, and the lower end of the filter tube 5, that is, , the lower end of the lower layer has an open structure and a wastewater inlet (52).

In this case, the upper layer includes a plurality of discharge holes 51 . The filter tube 5 performs filtration to filter out foreign substances while ejecting the wastewater W1 introduced through the wastewater inlet 52 through the discharge hole 51 .

The upper layer of the filter tube (5) having a plurality of discharge holes (51) has a surface surrounded by a filter material (6). The wastewater that has been primarily filtered through the discharge hole 51 is filtered secondarily while passing through the filter medium 6 , and as it passes through the filter medium 6 , water molecules are split and air in the storage space 23 . and the mixing rate will be increased. That is, the microbubble generation rate is increased.

The inflow of wastewater into the filter tube (5) is caused by an upward flow in the storage space (23) as air is injected from the main body (2) through the air injection line (21) into the filter tube (5). Also, the waste water flows in without the configuration of a separate suction pump. Although not shown in the drawings, by directly injecting air into the filter tube 5, an upward flow is generated inside the filter tube 5, and thus wastewater may be introduced.

In this case, as mentioned above, not only the culturing of microorganisms is made inside the filter tube 5, but also the higher the pressure inside the filter tube 5 when the air is dispersed in the form of air bubbles, so the culturing power of microorganisms is further increased. . Accordingly, organic matter decomposition by microorganisms actively occurs inside the filter tube 5, so that the filtration effect in the filter tube 5 for decomposing and filtering the suspended solids in the wastewater is further improved.

The filter medium 6 surrounds the surface of the upper layer 23 of the filter tube 5 in which the plurality of discharge holes 51 are formed. The wastewater sucked up into the filter tube (5) passes through the discharge hole (51) and then passes through the filter medium (6) to filter organic matter. The decomposition of organic matter by microorganisms is also performed.

The filter medium 6 may be made of an adsorbent material, specifically, may be made of a material including polyvinylidene chloride, polypropylene, or a combination thereof, and may be used in the form of a filament yarn.

Also, in the present invention, as shown in FIG. 9 , an embodiment of a filter medium 6 is presented. The filter medium 6 of this embodiment includes a filter body 61 surrounding the filter tube 5 and the filter body 61 . ), characterized in that it comprises a filtering end (62) radially protruding from the storage space (23).

The operating mechanism of the filtration body 61 is the same as described above, and the filtration end 62 is made of the same material as the filtration body 61 and is formed in the vortex forming unit 3 to form an upward vortex. It is to be filtered while collided with and passed through the filter end (62). That is, the filtration body 61 mainly filtration of the waste water (W1) introduced through the filter tube (5) is the main operating mechanism, the filtration stage 62 is the waste water (W2) flowing in through the vortex forming part (3) Filtration is the main operating mechanism.

The main body 2 covers the upper layer of the filter tube 5 while forming a storage space 23 containing the filtered water filtered through the filter tube 5 and the filter medium 6, and the microbubble water is discharged from the top. It has a discharge port 22 for discharging to the air and characterized in that the air injection line 21 is formed on the side of the lower end. The filter tube 5 is fixed to be located inside the main body 2, and the fixing of the filter tube 5 in the main body 2 is a vortex forming part 3 configured at the lower end of the main body 2 ) is preferably fixed by

When air is injected into the storage space 23 through the air injection line 21, an upward flow is generated, and the inflow of wastewater W2 through the vortex forming part 3 is induced by this upward flow.

As described above, the present invention increases the amount of water circulation and controls the generation of sand sections by allowing the inflow of the wastewater W1 by the filter pipe 5 and the inflow of the wastewater W2 by the vortex forming part 3 to occur. .

The vortex forming part 3 is configured at the lower end of the main body 2 and a through hole 312 through which the filter tube 5 passes is formed. It is characterized in that the perforated plate 31 on which a plurality of perforated holes 311 to be introduced is formed is stacked, and the perforated holes 311 facing up and down are formed in a zigzag manner.

That is, the incoming wastewater (W2) passes through the perforations 311 of the plurality of perforated plates 31, but as shown in FIG. The fluid is to be guided to the perforated plate 311 while colliding with the body of the upper perforated plate 311 . In this process, collisions and vortices of fluids are formed, and collisions and frictions between vortices are maximized by collisions and vortices formed in a plurality of places, so that the refinement efficiency of the fluid is further doubled. efficiency will increase.

Preferably, a thread 311-1 is formed on the inner periphery of the perforated hole 311 so that a vortex is automatically formed by passing through the perforation 311, so that it is appropriate to further double the refinement efficiency of the fluid.

In the present invention, the thread 311-1 is configured in the perforated hole 311 as described above, but as mentioned above, a representative embodiment for maximizing the collision and friction between the vortexes is presented in FIGS. 6A and 6B.

The embodiment presented in FIG. 6A is characterized in that the perforated plate 31 is stacked in plurality, and the perforated plate 31 to be stacked is arranged in a shape in which the perforated holes 311 facing up and down are crossed.

As shown in the drawing, the vortex (S1) formed while passing through the perforated hole 311 located at the lower portion is guided into the perforation 311 while colliding with the body of the perforated hole 311 located at the upper portion, and is guided into the upper It is to form another vortex (S2) in the perforation (311). That is, a plurality of vortexes S1 and S2 are formed upward and downward, and a collision of the vortex S1 is formed to maximize collision and friction between the vortexes.

In addition, as shown in FIG. 7 , an example in which the miniaturization is doubled by varying the diameter of the perforated plate 31 constituting the perforated plate 31 to vary the pressure in the vortex formed is further presented.

As shown in the figure, the diameter d2 of the perforated plate 31 constituting the perforated plate 31 positioned at the lower portion is larger than the diameter d1 of the perforated hole 311 constituting the perforated plate 31 positioned at the upper portion. As shown in the example shown in Fig. 6a, as the diameter of the vortex (S1, S2) formed in addition to being arranged in an intersecting shape, the perforations 311 facing up and down are induced to induce a change in pressure so that the fluid and the miniaturization of the air is to be doubled.

On the other hand, the embodiment presented in Figure 6b is characterized in that the direction of the thread 311-1 of the perforated hole 311 constituting the perforated plate 31 is arranged differently. That is, as shown in Figure 6b, the direction of the screw thread 311-1 in the adjacent perforation 311 is arranged to be opposite, and the vortex currents S1 and S2 generated from each perforation 311 are rotated in the opposite direction. It is to increase the efficiency of micronization of air and fluid by causing greater collision and friction between rotations.

Meanwhile, in the present invention, an embodiment in which the miniaturization efficiency is further doubled by forming a three-dimensional vortex is shown in FIG. 8 .

In this embodiment, the vortex forming part 3 has a plurality of vortex forming rods 35 which protrude radially in the centripetal direction on the upper or lower part of the perforated plate 31 and have threads 351 formed on the outer periphery. It is characterized in that it is composed.

Although the figure shows an example in which the vortex forming rod 35 is configured on the upper part of the perforated plate 31, it may be configured at the lower part and may be formed while crossing up and down.

The reason why the vortex forming rod 35 is formed in this way is that a plurality of longitudinal vortexes are formed while passing through the perforated plate 31 as shown in the figure, and the longitudinal vortex collides with the plurality of vortex forming rods 35 in the transverse direction As a vortex is formed, the longitudinal vortex and the lateral vortex collide with each other to further double the efficiency of refinement of air and fluid.

That is, as a plurality of vortices are formed in the longitudinal and transverse directions, more three-dimensional vortices are formed, and collision and friction are induced in multiple directions, thereby further doubling the efficiency of miniaturization of air and fluid.

According to the above configuration, in the present invention, it is possible to increase the efficiency of the device so that filtration and air diffusion (generation of microbubble water) are performed at the same time. In addition, although the figure shows an example in which the air injection line 21 is formed only in the main body 2, an air injection line for injecting air into the filter tube 5 is also formed, so that when filtration is mainly performed, the filter tube 5 is used. By allowing air to be injected, wastewater can be introduced into the vortex forming part 3 by the upflow, and when the microbubble water is mainly generated, the main air pressure line 21 is operated to operate the filter pipe 5 by the upflow. to allow wastewater to flow in. That is, selective driving becomes possible.

As described above, the treated water, which has been filtered and produced in the storage space 23 of the main body 2 , is transferred to the diffusion wing 4 through the outlet 22 .

The diffusion wing portion 4 communicates with the end of the outlet 22 and projects a collection chamber 41 in which the discharged microbubbles are collected and in communication with the collection chamber 41, and protrudes in a radial direction on each side. It characterized in that it includes a discharge chamber (42) in which the discharge hole (421) is formed.

In addition, the diffusion wing portion 4 further includes an upper plate 44 covering the upper surface and a lower plate 43 communicating with the outlet 22 and the collecting chamber 41 although not shown in the drawings.

With this configuration, the microbubble water discharged through the outlet 22 flows from the collection chamber 41 to each discharge chamber 42 and is discharged to each second discharge hole 421. In this process, collision and Friction is induced so that microbubbles are further doubled and at the same time, microbubbles are discharged in a radially wide area.

The second discharge hole 421 formed on the surface exposed to the outside of each discharge chamber 42 is to discharge the number of microbubbles to a wide area, and the second discharge hole 421 formed on the side surface is adjacent to the discharge chamber. (42) to face collision and friction between the number of discharged microbubbles to be induced.

In addition, as shown in FIG. 2 , a thread 421-1 is formed on the inner periphery of the second discharge hole 421 so that a vortex is further imposed on the number of discharged microbubbles, so that it spreads over a wider area and a collision and friction area It is reasonable to make it larger.

In addition, as shown in FIG. 3 , the diffusion blade 4 allows the cross section of each discharge chamber 42 to form an inclined gradient in one direction, and the diffusion blade 4 is rotationally interlocked at the outlet 22 . In the discharging process of the microbubble water from the diffusion blade portion 4, rotational force is applied to the diffusion blade portion 4 to increase the rate of collision and friction, and may be configured to further enlarge the spreading area.

Here, the configuration for the diffusion wing 4 to rotate and interlock at the outlet 22 may be expressed by a known structure such as the bearing 45 .

On the other hand, in the present invention, as shown in FIG. 10 , a sludge incision port 32 including a central pipe 321 between the perforated plate 31 and a plurality of cutting blades 322 radially protruding from the central pipe 321 . An example in which is further included is shown.

That is, the sludge incision hole 32 is placed between the perforated plates 31, and the sludge incision hole 32 separates the upper and lower perforated plates 31 and pulverizes the sludge mixed in the fluid passing through the perforated plate 31. This is to increase the sludge removal efficiency and to control the sludge deposition in the perforations 311 and the like.

The sludge passing through the perforated plate 31 is pulverized by the vortex and cut by the central pipe 321 and each cutting blade 322 to control the sludge deposition, and the central pipe 321 and cutting Even by collision with the wing 322, the water molecules and bubbles can be miniaturized.

Preferably, the upper and lower sludge incision ports 32 are suitable for each cutting blade 322 to intersect.

Those skilled in the art from the above description will be able to see that various changes and modifications are possible without departing from the technical spirit of the present invention. Accordingly, the technical scope of the present invention is not limited to the content described in the detailed description of the specification, but should be defined by the claims.

1: present invention 2: main body
3: vortex forming part 4: diffusion wing part

Claims (8)

a cylindrical filter tube comprising an upper portion including a plurality of discharge holes and a lower portion positioned below the upper portion, the upper end of the upper portion being blocked, and the lower end of the lower portion having a wastewater inlet;
a filter medium surrounding the upper surface of the filter tube;
a body covering the upper layer of the filter tube while forming a storage space containing the filtered water filtered through the filter tube and the filter medium, and having an outlet for discharging the microbubble water to the outside at the upper end, and an air injection line is formed on the lower side side;
A perforated plate is stacked at the bottom of the main body, a through hole through which the filter tube passes, and a plurality of perforated holes for allowing wastewater to flow into the storage space around the through hole are stacked, and the perforations facing up and down are formed in a zigzag pattern. a vortex forming part;
a diffusion wing unit communicating with the end of the outlet to collect and discharge the microbubble water discharged from the outlet in a radial manner;
A wastewater treatment apparatus using agitated convection and filtration of air supply, characterized in that it comprises a.
The method of claim 1,
The diffusion wing portion,
Agitation of air supply, characterized in that it comprises a collection chamber in which the microbubble water discharged in communication with the end of the discharge port is collected, and a discharge chamber which communicates with the collection chamber and protrudes in a radial direction and has a second discharge hole formed on each side. Wastewater treatment device using convection and filtration.
3. The method of claim 2,
The filter medium is a wastewater treatment apparatus using agitated convection and filtration of air supply, characterized in that it comprises a filtering body surrounding the filter tube, and a filter end projecting radially from the filtering body to the storage space.
The method of claim 1,
A wastewater treatment apparatus using agitation convection and filtration of air supply, characterized in that the perforation has a thread formed on the inner periphery.
The method of claim 1,
Agitated convection and filtration of air supply, characterized in that the vortex forming part further comprises a plurality of vortex forming rods which protrude radially in the centripetal direction from the upper or lower part of the perforated plate and have threads formed on the outer periphery.
The method of claim 1,
A wastewater treatment device using agitated convection and filtration of air supply, characterized in that the perforations of each perforated plate have different diameters.
5. The method of claim 4,
A wastewater treatment device using agitated convection and filtration of air supply, characterized in that the thread direction of the perforated plate is different in the perforated plate.
The method of claim 1,
A wastewater treatment apparatus using agitated convection and filtration of air supply, characterized in that the sludge cutting port including a central pipe and a plurality of cutting blades projecting radially from the central pipe is further included between the perforated plate.

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