KR200340731Y1 - Air Diffuser - Google Patents

Abstract

The present invention relates to an air dispersing device, the inlet connecting the cylindrical chamber and the side wall of the chamber and the outside air compressor installed in the reaction tank so that the air discharge opening is formed on the upper side and the air discharge opening is located on the upper side An air diffuser for supplying wastewater in the reactor in the form of a bubble to the air flowing through the inlet pipe from the air compressor, the lower surface of the inlet pipe and the chamber at a position lower than the inlet pipe It characterized in that it comprises an air distribution pipe which is installed branched from the inlet pipe to connect. As a result, it is possible to prevent a decrease in absorption efficiency due to an increase in the speed of the air introduced into the chamber from the inlet pipe.

Description

Air diffuser {Air Diffuser}

The present invention relates to an air dispersing apparatus, and more particularly, to an air dispersing apparatus which receives compressed air supplied from the outside and supplies the waste water contained in the reactor in the form of bubbles.

Methods of using microorganisms as a means for purifying wastewater are widely known, and a method for purifying wastewater using such microorganisms requires a means for continuously supplying oxygen to the wastewater for the survival of microorganisms. Here, wastewater means water that can be purified by oxygen supply such as sewage and sewage.

As a conventional method of supplying oxygen to wastewater, as shown in Figs. 5 and 6, there is provided an air dispersing device which blows air from the bottom of the wastewater into a bubble form and rises by buoyancy. In this way, supplying air in the form of bubbles increases the contact area and the contact time between oxygen and the wastewater, thereby increasing the solubility of oxygen (not easily dissolved in the liquid).

5 is a cross-sectional view of a conventional diffuser device.

Conventional diffuser device is installed in the reaction tank (not shown), the pipe is fixed to the inlet pipe 102 and the reaction tank (not shown) by the inlet pipe 102 and the fixing base (103, 103 ') It has a mold chamber 101.

Fine holes are formed in the entire region of the chamber 101.

The conventional diffuser device having such a configuration operates as follows.

Air is supplied from the air compressor (not shown) to the chamber 101 through the inlet pipe 102, and the air supplied to the chamber 101 is converted into a bubble form through the micropores and accommodated in the reactor. Supplied to.

6 is a sectional view of another conventional diffuser.

Another conventional diffuser device is an upward opening cylindrical chamber 201, an inlet pipe 202 connected to the chamber 201, a net 203 sequentially installed along the height direction of the chamber 201 and It has a cover net 204.

Another conventional diffuser having such a configuration operates as follows.

Air is supplied from the air compressor (not shown) to the chamber 201 through the inlet pipe 202, and the air supplied to the chamber 201 is converted into the bubble form while passing through the mesh 203, and then the cover net ( 204) to the wastewater contained in the reactor.

Bubbles supplied to the wastewater from these conventional air diffusers are absorbed by the wastewater while rising by buoyancy, and the rest is discharged to the atmosphere from the upper surface of the wastewater.

As bubbles are absorbed into the wastewater, dissolved oxygen (DO) in the wastewater increases.

Meanwhile, the dissolved oxygen (DO) in the wastewater required for purification depends on the nature of the wastewater and the level of purification. The desired dissolved oxygen value can be obtained by adjusting the pressure of compressed air discharged from the air compressor. In other words, by increasing the pressure of the compressed air can increase the amount of air absorbed in the waste water. Here, the correlation between the dissolved oxygen value in the waste water and the pressure of the compressed air discharged from the air compressor can be obtained by experiments, and this correlation reflects the discharge of the compressed air and the absorption efficiency of the air in the waste water (= oxygen Absorption efficiency), that is, the ratio of absorbed compressed air to supplied compressed air can be obtained.

By the way, according to the conventional diffuser, the pressure of the compressed air is increased and the velocity of the compressed air flowing into the chamber (101, 201) through the inlet pipe (102, 202) is a critical speed value (absorption efficiency decreases with the increase of the inlet speed). When the speed value is exceeded), the contact time between the bubble and the waste water is reduced, thereby reducing the absorption efficiency of the unit compressed air.

Accordingly, an object of the present invention is to provide an air dispersing device capable of preventing a decrease in absorption efficiency due to an increase in the speed of compressed air introduced into a chamber from an inlet pipe.

1 is a partial cutaway perspective view of an air diffuser according to an embodiment of the present invention;

2 is a cross-sectional view taken along line B-B 'of FIG. 1;

Figure 3 is a state of use of the diffuser device according to an embodiment of the present invention,

4 is a cross-sectional view of an diffuser according to another embodiment of the present invention;

5 is a cross-sectional view of a conventional diffuser device;

6 is a sectional view of another conventional diffuser.

Explanation of symbols on the main parts of the drawings

10, 10 ': diffuser 11, 11', 101, 201: chamber

12: Separation partition 13, 13 ': air exhaust opening

15: center space 17: circumference space

18, 18 ', 102, 202: inlet pipe 19, 19', 19 ": air dispersion pipe

151: air compressor 153: reactor

The object is, according to the present invention, the air discharge opening is formed in the upper side and the inlet connecting the cylindrical chamber and the side wall of the chamber and the air compressor is installed inside the reaction tank so that the air discharge opening is located on the upper side An air diffuser for supplying wastewater in the reactor in the form of a bubble to the air flowing through the inlet pipe from the air compressor, the lower surface of the inlet pipe and the chamber at a position lower than the inlet pipe It is achieved by the diffuser device characterized in that it comprises an air dispersing pipe branched from the inlet pipe to be connected.

Here, the bottom of the chamber to partition the inner space of the chamber into a central space and a circumferential space to prevent the air absorption amount is reduced by the flow interference between the air flowing into the chamber through the air distribution pipe and the inlet pipe, respectively A separation partition standing up from the surface; The air dispersion pipe is preferably formed to communicate with the central space.

The chamber is formed to have a circular cross section so as to increase the amount of wastewater introduced into the chamber to increase the contact area between the compressed air and the wastewater, and the separation partition is formed to have a predetermined distance from the sidewall of the chamber over the entire area. It is formed to maintain, the inlet pipe can be connected in a tangential direction to the side wall of the chamber.

In addition, it is preferable that the chamber is formed to have a hypotonic narrow shape so that the bubble passing through the air discharge opening can be diffused outward to increase the absorption amount of the bubble.

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

1 is a partial cutaway perspective view of an air diffuser according to an embodiment of the present invention, Figure 2 is a cross-sectional view taken along line BB 'of FIG.

The air diffuser 10 according to the embodiment of the present invention, as shown in these figures, a chamber 11 having a circular cross-section having a lower light reciprocation shape and a bottom of the chamber 11. It has the separating partition 12 which stood up from the surface.

An air exhaust opening 13 is formed above the chamber 11.

Separation partition 12 is formed to maintain a constant distance from the side wall of the chamber 11 over the entire area, the interior space of the chamber 11 by the separation partition 12, the central space 15 and the peripheral space ( 17).

And the diffuser device 10 according to an embodiment of the present invention, the left end is a straight inlet pipe 18, the inlet pipe 18 and the chamber 11 connected to the side wall of the chamber 11 in a tangential direction It has an air distribution pipe 19 for connecting the central space 15 of.

The right end of the inlet pipe 18 is connected to the air compressor 151. The air compressor 151 supplies compressed air to the inlet pipe 18 through a nozzle (not shown).

The air dispersing pipe 19 is connected to the lower side of the inlet pipe 18 in the vertical direction of the inlet pipe 18, and two bent regions are formed in the middle region, and perpendicular to the bottom surface of the chamber 11. Is connected. And the air dispersion pipe 19 is formed to have a diameter smaller than the inlet pipe (18). Accordingly, the loss head of the air dispersion pipe 19 has a loss head larger than the inlet pipe loss head between the branch point A and the chamber 11.

The diffuser device 10 according to an embodiment of the present invention having such a configuration, as shown in FIG. 3, is installed and used in a plurality of reaction tanks 153. same. For convenience of explanation, the diffuser device according to one embodiment of the present invention is installed inside the reaction tank 153, and wastewater is introduced into the internal space of the chamber 11 through the air discharge opening 13.

When the compressed air from the air compressor 151 is introduced from the right end of the inlet pipe 18 through a nozzle (not shown), the compressed air is distributed to the inlet pipe 18 and the air dispersion pipe 19 to the chamber 11 It flows into the inner space of). At this time, since the head of the air dispersion tube 19 has a large loss head, most compressed air flows into the circumferential space 17 of the chamber 11 through the inlet pipe 18. Herein, the amount of compressed air flowing into the central space 15 of the chamber 11 through the air distribution pipe 19 enters a branch point A, that is, a connection point between the inflow pipe 18 and the air distribution pipe 19. The pressure of the compressed air, that is, the pressure head, increases. When the pressure head of the compressed air entering the branch point A is smaller than the loss head of the air distribution pipe 19, the compressed air from the air compressor 151 is almost entirely discharged from the chamber 11 through the inlet pipe 18. It flows into the circumferential space 17.

The compressed air introduced into the circumferential space 17 of the chamber 11 through the inlet pipe 18 rises while forming a vortex along the circumferential space, and then, in the form of bubbles through the air discharge opening 13, It will be discharged to the inside. At this time, since the chamber 11 is formed in the shape of a lower light image, bubbles discharged through the air discharge opening 13 diffuse into a region larger than the cross-sectional area of the air discharge opening 13.

The process in which the compressed air is converted into bubbles in the chamber 11 and discharged through the air discharge opening 13 will be described in detail as follows.

Since compressed air flows in a tangential direction into the circumferential space 17 of the chamber 11, the wastewater introduced into the circumferential space 17 rises while forming a vortex with compressed air, and then the air discharge opening 13 It is discharged to the inside of the reaction tank 153 through the circumferential region of the. Thus, the discharge of the compressed air and the waste water through the circumferential region of the air discharge opening 13 is due to the centrifugal force of the vortex.

Due to the vortices formed in the circumferential space 17 of the chamber 11, a pressure difference is generated inside the chamber 11. That is, since the upper side is lower than the lower side in the height direction of the chamber 11 and the pressure is lower than the outer side in the radial direction of the chamber 11, the pressure inside the upper side of the chamber 11 as a whole is the lowest. . Accordingly, the wastewater contained in the reaction tank 153 is introduced into the chamber 11 while drawing a parabola through the central region of the air discharge opening 13. At this time, the wastewater flows into the central space 15 as well as the peripheral space 17 of the chamber 11.

Wastewater introduced into the chamber 11 is mixed with the compressed air rising while forming a vortex, thereby promoting the conversion of compressed air into air bubbles (compressed air enters the wastewater even if the compressed air does not form a vortex). Bubbles will occur).

On the other hand, the compressed air introduced into the central space 15 of the chamber 11 through the air dispersion pipe 19 rises along the height direction of the chamber 11 and is discharged into the reaction tank 153 in the form of bubbles. . The liquid air introduced into the central space 15 of the chamber 11 is bubbled in the process of mixing with the wastewater introduced into the central space of the chamber 11 by vortices formed in the peripheral space 17 of the chamber 11. Is converted.

Bubbles discharged into the reaction tank 153 are absorbed by the wastewater while rising by buoyancy, and the rest is discharged into the atmosphere from the upper surface of the wastewater.

As described above, according to one embodiment of the present invention, by providing an air distribution pipe 19 connecting the intermediate region of the inlet pipe 18 and the bottom surface of the chamber 11, through the inlet pipe 18 The speed of the compressed air flowing into the chamber 11 can be reduced. Accordingly, it is possible to prevent the compressed air from flowing into the interior space of the chamber 11 at a speed exceeding the threshold speed value at which the absorption efficiency is reduced.

In addition, the partition wall 12 is erected and installed on the bottom surface of the chamber 11 to partition the inner space of the chamber 11 into the central space 15 and the circumferential space 17, while the air dispersion pipe 19 is divided into the chamber ( By connecting to the bottom surface of the chamber 11 to communicate with the central space 15 of the 11, between the compressed air introduced into the chamber 11 through the air distribution pipe 19 and the inlet pipe 18, respectively Flow interference can be prevented. Accordingly, the area of contact between the air and the waste water, that is, the amount of air absorption can be prevented from being reduced.

In addition, the chamber 11 is formed to have a circular cross section, and the separating partition 12 is formed to maintain a constant distance from the side wall of the chamber 11 over the entire area, and the inflow pipe 18 is tangent to the side wall of the chamber 11. By connecting along the direction, the compressed air flowing into the circumferential space 17 of the chamber 11 through the inlet pipe 18 forms a vortex, thereby increasing the amount of wastewater introduced into the chamber 11. Accordingly, the contact area between the wastewater and the compressed air, that is, the amount of air absorption can be increased.

In addition, the side walls of the chamber 11 and the separating partition 12 are formed to have inward inclination, that is, the chamber 11 is formed to have a downward light narrowing shape so as to pass through the air exhaust opening 13. By allowing the bubbles to diffuse outward, it is possible to increase the contact area between the bubbles and the waste water, that is, the amount of air absorbed by the waste water.

Meanwhile, in the above-described embodiment, one air dispersing tube 19 is formed, but as shown in FIG. 4, the present invention may be implemented to have two or more air dispersing tubes. In the case where two or more air dispersion pipes are formed, the contact area between the wastewater and the compressed air is enlarged to increase the absorption efficiency of air (oxygen).

In FIG. 4, reference numeral 10 'denotes an diffuser device according to another embodiment of the present invention, 11' denotes a chamber, 13 'denotes an air discharge opening, 18' denotes an inlet tube, 19 'and 19 "denotes an air distribution tube.

In the above-described embodiment, the present invention is implemented by supplying compressed air to the inlet pipe 18, but the present invention can be implemented by supplying pure oxygen or other gas containing oxygen to the inlet pipe 18.

Therefore, according to the present invention, it is possible to prevent the decrease in absorption efficiency due to the increase in the speed of the air introduced into the chamber from the inlet pipe.

Claims (4)

An air discharge opening is formed at an upper side thereof, and has a cylindrical chamber installed inside the reaction tank so that the air discharge opening is located at an upper side thereof, and an inlet pipe connecting the side wall of the chamber and an external air compressor. In the diffuser device for supplying the air flowing through the inlet pipe in the form of bubbles to the wastewater in the reaction tank, And an air dispersing pipe branched from the inlet pipe so as to connect the inlet pipe and the bottom surface of the chamber at a lower position than the inlet pipe. The method of claim 1, A separation partition standing upright from the bottom surface of the chamber so as to divide the internal space of the chamber into a central space and a peripheral space; The air dispersing device is characterized in that formed in communication with the central space. The method of claim 2, The chamber is formed to have a circular cross-section, the separation partition is formed to maintain a predetermined distance from the side wall of the chamber over the entire area, the inlet pipe is characterized in that it is connected in a tangential direction to the side wall of the chamber Diffuser. The method of claim 3, The chamber is characterized in that the diffuser device is formed to have a lower light image.