KR20050112554A - Air diffuser with nozzle throat - Google Patents

Abstract

The present invention relates to a nozzle-type diffuser device used in the aeration process of the sewage / wastewater treatment plant. More specifically, the shear stress between the air bubble and water supplied from the diffuser device by the nozzle neck at the outlet of the diffuser is supplied to the water. To increase the residence time of air bubbles in water and widen the contact area between air bubbles and water by forming small bubbles to increase the oxygen transfer efficiency. will be.

To this end, the present invention and the air supply inlet is formed so that air is introduced into the body of the air diffuser; A nozzle contraction inclined surface which is continuously formed from the air supply inlet and increases a flow rate of the introduced air; A bubble distribution plate is provided above the outlet to uniformly distribute the air bubbles injected from the air outlet, including an air outlet formed continuously from the nozzle contraction inclined surface and injecting air having an increased flow velocity. It provides a nozzle type diffuser further comprising.

Description

Nozzle type diffuser {AIR DIFFUSER WITH NOZZLE THROAT}

The present invention relates to a nozzle type air diffuser mainly used in the aeration process of the sewage / wastewater treatment plant, and more specifically, the air bubble and the shear of water supplied to the water by exiting the air diffuser by installing a nozzle neck at the outlet of the diffuser Improves stress and activates cracking of bubbles to form small bubbles to increase the residence time of air bubbles in water, widen the contact area between air bubbles and water, and distribute the bubbles uniformly to deliver high oxygen A nozzle type diffuser for obtaining efficiency.

A general conventional diffuser device is composed of a connector body 21, a fixing table 22, 24 and a pipe 23, as shown in FIG. In the conventional air diffuser, the air entering the connector body 21 passes through the fine holes 23a formed in the pipe 23 and is formed into small air bubbles and is supplied into the water. In this case, the pipe 23 has a separate hole. Rather than being present, when the pipe is made of ceramic or polyethylene (PE), the micro holes are produced in advance.

However, the conventional conventional diffuser is a device that simply passes the supplied air through the micro-pores 23a to reduce the size of the air bubbles. In particular, impurities between the micro-pores 23a propagate or flow into the air. The fine pores 23a are frequently blocked by the particles, and the amount of air flow rapidly decreases during use, and the oxygen transfer performance is lowered. In order to eliminate the clogging of the fine pores 23a, the air diffuser must be separated and frequently maintained. There is a ham.

In order to solve the problems of the conventional conventional diffuser, there is a "spreader using acoustic resonance" of the Republic of Korea Patent Registration No. 10-206746, which the inventors have applied for a patent.

In the air diffuser using the acoustic resonance, as shown in FIGS. 2A and 2B, the compressed air entering the inlet 2 provided in the tangential direction of the chamber 1 rotates inside the chamber 1 to vortex. And exit to exit (3). When the compressed air is discharged into the water through the outlet (3), a resonance occurs at a specific frequency due to the pressure difference between the compressed air and the water around the air diffuser, the acoustic energy is transferred to the water as a result of air bubbles It increases the dissolution rate of oxygen by increasing the mass transfer performance from water to water.

In addition, the conventional acoustic resonance diffuser is a semi-permanent diffuser that does not require the maintenance and cleaning of the diffuser because there is no fine hole (23a) formed in a typical diffuser does not cause clogging caused by long operation. .

However, the above-mentioned conventional acoustic resonance diffuser has a problem that the oxygen transfer performance is low despite the advantage that clogging does not occur.

That is, the conventional acoustic resonance diffuser measured using the American Society of Civil Engineers' Regulation (ASCE 2-92) has a standard Oxygen Transfer Efficiency (SOTE) of 18% at 150 L / min of supply air flow. It shows less value than the diffuser or membrane diffuser. This is because in the conventional acoustic resonance diffuser, the splitting of the large air bubbles coming out of the outlet 3 is not activated, so that the bubbles have a short residence time and the contact area between the air bubbles and the water is small.

In order to solve the above problems of the prior art, an object of the present invention is to pass the momentum (mass multiplied by the mass and velocity of the object) to the bubbles supplied to the water exiting the exit of the air diffuser device between the air bubbles and water The present invention provides a nozzle type diffuser device in which the oxygen transfer performance of the diffuser device is improved by increasing the shear stress to effectively improve the splitting of bubbles.

In addition, another object of the present invention is to increase the shear stress between the air bubbles and the water by delivering a sufficient momentum to the air bubbles supplied to the water exiting the exit of the air diffuser to effectively improve the splitting of the air bubbles, and at the same time injected It is an object of the present invention to provide a nozzle-type diffuser device in which a bubble distribution plate having an improved oxygen transfer performance of the diffuser device is formed by providing a bubble distribution plate that uniformly distributes the bubble distribution plate on the outlet of the diffuser device.

In order to achieve the above object, the present invention is an air dispersing apparatus used for supplying air to the aeration process of the wastewater treatment plant, the air supply inlet is formed so that air is introduced into the body of the apparatus; A nozzle contraction inclined surface which is continuously formed from the air supply inlet and increases a flow rate of the introduced air; It provides a nozzle-type diffuser device comprising an air outlet formed in the form of a nozzle neck that is continuously formed from the nozzle shrinkage inclined surface to inject air with increased flow rate.

In addition, the present invention is an air dispersing apparatus used for supplying air to the aeration process of the wastewater treatment plant, the air supply inlet formed so that the air flows into the air dispersing apparatus body; A nozzle contraction inclined surface which is continuously formed from the air supply inlet and increases a flow rate of the introduced air; An air outlet formed continuously from the nozzle contraction slope to form a nozzle neck for injecting air having an increased flow rate; It provides a nozzle-type diffuser device comprising a bubble distribution plate installed on the top of the outlet to uniformly distribute the air bubbles injected from the air outlet.

In addition, the present invention is the outlet diameter is enlarged by the outlet enlarged inclined surface that the air outlet is continuously formed from the nozzle neck, a spiral or radial guide groove is formed on the nozzle contraction inclined surface, spiral or Provided is a nozzle type diffuser in which radial guide grooves are formed.

In another aspect, the present invention provides a nozzle type diffuser device characterized in that the pulsating pressure control chamber having a diameter larger than the air supply inlet is formed between the air supply inlet and the nozzle contraction inclined surface.

In another aspect, the present invention provides a nozzle type diffuser having a diameter of the air supply inlet is larger than the diameter of the nozzle neck and the diameter of the nozzle outlet, the shape of the nozzle neck is one of circular, elliptical and polygonal shape.

In addition, in the present invention, the bubble distribution plate is one of a shape selected from a reverse cone shape, a reverse hemisphere shape, and a plate shape, and the diameter (Φ 4) of the bubble distribution plate is the diameter (Φ 2) of the nozzle neck and the diameter of the air outlet ( Provided is a nozzle type diffuser formed larger than φ3).

In addition, the present invention is to provide a nozzle-type diffuser device in which the helical or radial guide groove is formed in the bubble distribution plate.

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

Figure 3a is a perspective view showing a first embodiment of the nozzle type diffuser according to the present invention, Figure 3b is a perspective view showing a second embodiment of the nozzle type diffuser according to the present invention, Figure 4a is a 4 is a cross-sectional view showing a second embodiment of the nozzle type diffuser according to the present invention.

The present invention has been applied to the specific embodiments as shown in each of the above drawings, the present invention is not limited to these specific embodiments, and various modifications can be made without departing from the spirit of the present invention.

As shown in Figure 3a, the nozzle-type diffuser according to the present invention is based on the cylindrical body of the cylindrical body formed with the respective functional parts therein, pulsating pressure control chamber to reduce the pulsating pressure of the supplied air ( In the case where 10) is formed, as shown in FIG. 3B, the outer shape is a form in which a circular protruding portion is formed at the center of the device body 4.

In the nozzle-type diffuser of the present invention having the appearance as described above, as shown in FIG. 4A (a), the air supply inlet 5 of the diffuser device having a diameter of φ1 is formed of the apparatus body 4. It is formed at the bottom, and the air supplied therefrom flows along the nozzle contraction inclined surface 6 which is formed continuously with the air supply inlet 5 in the form of a contraction angle θ so that the speed becomes faster and the pressure becomes lower.

The contraction angle Θ of the nozzle shrinkage inclined surface 6 may be any range as long as the diameter of the nozzle neck 7 may be smaller than the diameter of the air supply inlet 5. However, when the contraction angle Θ is formed too rapidly, the nozzle shrinkage slope 6 becomes long, which makes the height H of the apparatus body 4 unnecessarily large, and the contraction angle Θ is too large. In this case, part of the air supplied to the air supply inlet 5 causes energy loss in the form of eddy, which is an unnecessary secondary flow in the space between the nozzle neck 7 and the nozzle shrinkage inclined surface 6. The contraction angle (Θ) of 6) should be maintained at an appropriate level.

The air passing through the nozzle shrinkage inclined surface 6 formed as described above becomes the maximum speed when passing through the nozzle neck 7 having a diameter of φ2 and the length L, and the air bubbles having such a high flow rate and low pressure are the air outlets. (8) comes out and is fed into the water.

On the other hand, in the nozzle type diffuser according to the present invention, as shown in (b) of FIG. 4A, the air outlet 8 is formed by the outlet enlarged inclined surface 9 which is formed continuously to the nozzle neck 7 described above. The diameter Φ 3 may be formed to be enlarged.

That is, the diameter of the outlet enlarged inclined surface 9 which is formed continuously in the nozzle neck 7 is formed larger than the nozzle neck 7 so that the load applied to the device body 4 by the high pressure air in accordance with the air conditioner operating conditions. This can be reduced. At this time, the angle is preferably formed to be the same as the angle of the nozzle shrinkage inclined surface (6).

The high-speed air bubbles exiting the air outlet 8 of the nozzle type diffuser of the present invention, respectively formed as described above, are in contact with the water around the diffuser having a low flow rate. Shear stresses are generated and the splitting of air bubbles is activated. From this, small bubbles are generated, and small bubbles have long residence time in water and wide contact area of water-bubble to increase oxygen transfer performance.

Figure 5a is a perspective view showing a third embodiment of the nozzle type diffuser according to the present invention, Figure 5b is a perspective view showing a fourth embodiment of the nozzle type diffuser according to the present invention, Figure 6a is a 3 is a cross-sectional view showing a third embodiment of the nozzle type diffuser according to the present invention, and FIG. 6B is a cross-sectional view showing a fourth embodiment of the nozzle type diffuser according to the present invention.

As shown in Fig. 5a, the nozzle-type diffuser device having a bubble distribution plate according to the present invention is based on a cylindrical body body 4 having respective functional parts formed therein, which reduces the pulsation pressure of the supplied air. When the dynamic pressure control chamber 10 is formed, as shown in FIG. 5B, the outer shape is a form in which a circular protruding portion is formed at the center of the device body 4.

In addition, the bubble distribution plate 20 constituting the present invention is in the form of being fixed to the support 21 at regular intervals on the upper end of the device body 4 in which the air outlet 8 is formed.

7 is a cross-sectional view showing the shape of the bubble distribution plate of the nozzle type diffuser according to the present invention, wherein the bubble distribution plate 20 serves to uniformly distribute the bubbles discharged from the air outlet (8). The shape can be applied in various forms such as inverted cone shape, inverted hemisphere shape and plate shape. The shape selection of the bubble distribution plate 20 can be selected and applied in various ways depending on the aeration equipment to which the diffuser of the present invention is applied.

In the nozzle type diffuser device in which the bubble distribution plate of the present invention is formed with the appearance as described above, as shown in FIG. 6A (a), the air supply inlet 5 of the diffuser device having a diameter of φ1 is the device body. It is formed in the lower portion of (4), the air supplied from it flows along the nozzle shrinkage inclined surface (6) formed continuously with the air supply inlet (5) in the form of a contraction angle θ, the speed is high and the pressure is low You lose.

The contraction angle Θ of the nozzle shrinkage inclined surface 6 may be any range as long as the diameter of the nozzle neck 7 may be smaller than the diameter of the air supply inlet 5. However, when the contraction angle Θ is formed too rapidly, the nozzle shrinkage slope 6 becomes long, which makes the height H of the apparatus body 4 unnecessarily large, and the contraction angle Θ is too large. In this case, part of the air supplied to the air supply inlet 5 causes energy loss in the form of eddy, which is unnecessary secondary flow in the space between the nozzle neck 7 and the nozzle shrinkage slope 6, The contraction angle (Θ) of 6) should be maintained at an appropriate level.

The air passing through the nozzle shrinkage inclined surface 6 formed as described above becomes the maximum speed when passing through the nozzle neck 7 having a diameter of φ2 and the length L, and the air bubbles having such a high flow rate and low pressure are the air outlets. (8) comes out and is fed into the water.

In addition, as shown in Figures 5a to 6b, the bubbles exiting the air outlet 8 is uniformly distributed by the bubble distribution plate 20 installed on the top, which is a bubble exiting the air outlet 8 It is to distribute uniformly.

On the other hand, in the nozzle-type diffuser device having a bubble distribution plate according to the present invention, as shown in Figure 6a (b) and 6b (b), the exit enlarged inclined surface formed continuously in the nozzle neck (7) described above (9) can be formed to enlarge the diameter (Φ 3) of the air outlet (8).

That is, the diameter of the outlet enlarged inclined surface 9 which is formed continuously in the nozzle neck 7 is formed larger than the nozzle neck 7 so that the load applied to the device body 4 by the high pressure air in accordance with the air conditioner operating conditions. This can be reduced. At this time, the angle is preferably formed to be the same as the angle of the nozzle shrinkage inclined surface (6).

The high-speed air bubbles exiting the air outlet 8 of the nozzle type diffuser of the present invention, respectively formed as described above, are in contact with the water around the diffuser having a low flow rate. Shear stresses are generated and the splitting of air bubbles is activated.

In addition, since the bubbles injected from the air outlet 8 are uniformly distributed and supplied to the object to be treated by the action of the bubble distribution plate 20, floc caused by particles in the object to be treated, such as waste water, with improved oxygen transfer ability. This prevents the destruction of phenomena to ensure the sedimentation concentration of activated sludge.

When the nozzle-type diffuser according to the present invention is applied in waste water treatment or the like, the nozzle type diffuser may be used in conjunction with an air or oxygen supply device, thereby forming an appropriate fastening means. As the fastening means, various conventionally known methods such as bolting fastening or quick joint fastening can be employed. Various materials such as metal, ceramic, and plastic may be used as the material of the nozzle type diffuser according to the present invention.

Looking at the operation of the diffuser device of the present invention.

First, the compressed air supplied to the air supply inlet 5 of the nozzle type air diffuser according to the present invention flows along the nozzle contraction inclined surface 6, and the speed is increased, and is maximized when passing through the nozzle neck 7. Air bubbles having such a high velocity flow out of the air outlet 8 of the air diffuser and are supplied into the water.

The high velocity air bubble exiting the air outlet 8 is in contact with the water around the air flow device having a low flow rate, and the shear stress is generated due to the large velocity difference at the interface between the water and the bubble, so that the splitting of the air bubble is activated. From this, the oxygen transfer performance of the nozzle type diffuser of the present invention is increased.

In general, Standard Oxygen Transfer Efficiency (SOTE) at a water temperature of 20 ℃ representing the performance of the diffuser is represented by the following equation (1).

In order to understand the standard oxygen transfer efficiency, it is necessary to examine the oxygen movement from the gas phase to the liquid phase. Equation 2 for the oxygen transfer rate (dW / dt) as follows is mainly used.

In Equation 2, it can be seen that the moving speed of oxygen (dW / dt) in water is proportional to the gas-liquid contact area (a) and the oxygen transfer coefficient (k _L ) of the gas-liquid interface. The contact area (gas-liquid contact area; a) of gas and water increases as the size of the bubble becomes smaller in water, for the same amount of gas. In addition, the oxygen transfer coefficient (k _L ) of the gas-liquid interface is inversely proportional to the thickness of the interface between the bubbles and water, and the oxygen transfer coefficient (k _L ) is more stable than the static state due to vortices or turbulent flows. It is known to decrease and increase.

Taken together, in order to increase the standard oxygen transfer efficiency, first, to generate fine air bubbles to increase the contact area of water and air, and to increase the contact time with water, It is horizontal to extend the residence time in water.

The present invention considers both of the above methods and is designed to improve the low oxygen transfer performance of the conventional acoustic resonance diffuser.

That is, the air diffuser formed with the above-described nozzle shrinkage inclined surface 6 and the air outlet 8 enlarged by the outlet enlarged inclined surface 9 generate fine air bubbles to increase the contact area of water and air. It is.

In addition, the pulsation pressure of the air supplied by forming the pulsation pressure control chamber 10 between the nozzle contraction inclined surface 6 and the air supply inlet 5 to about two to three times the diameter of the air supply inlet 5. By reducing the load on the device body (4) to reduce the oxygen transfer performance is also improved.

8 is a cross-sectional view showing a guide groove formed in the nozzle shrinkage inclined surface and the bubble distribution plate constituting the nozzle-type diffuser according to the present invention.

On the other hand, the present invention is to form a guide groove 11 in the nozzle shrinkage inclined surface 6, the outlet enlarged inclined surface 9 and the bubble distribution plate 20 constituting the nozzle-type diffuser. That is, a spiral groove 11a or a radial groove 11b may be formed on the nozzle contraction slope 6 and the bubble distribution plate 20 of the air diffuser of the present invention. Increasing the turbulence intensity of the air speeding up along the nozzle shrinkage slope 6, and in the case of the guide groove 11 of the radial (11b) serves to improve the direction of the supplied air.

In addition, the guide groove 11 formed in the outlet enlarged inclined surface 9 is to adjust the diffusion angle of the bubbles exiting the nozzle neck 7, the guide groove 11 formed in the bubble distribution plate 20 The shear stress between the bubble exiting the air outlet 8 and the bubble distribution plate 20 is to be improved.

In addition, the shape of the nozzle neck 7 formed in the present invention may be installed in the form of circular and polygon as well as circular. That is, the shape of the nozzle neck 7 may be determined in consideration of the shape and size of the aeration device to which the nozzle type diffuser is applied and the amount of air required.

Therefore, the nozzle type diffuser according to the present invention does not use the acoustic resonant frequency of the conventional acoustic resonance type diffuser using vortex air, but gives a large momentum to the air bubbles exiting the outlet 8, Bubble splitting was activated by large shear stress (flow difference).

The nozzle type diffuser according to the present invention can be applied to supply gas such as oxygen to liquid in beer fermentation process, microbial fermentation process, other wastewater treatment process, or other chemical process, in addition to oxygen supply of sewage treatment plant. It can also be used to mix two types of materials, such as liquids and solids, or liquids and liquids.

As described above, the present invention provides a large momentum to the air bubbles exiting the air outlet by installing a nozzle neck at the air bubble outlet of the air diffuser device, and the air flow rate after the air bubble exits the air diffuser (large shear stress) The splitting of the bubbles is activated by the air bubbles, and the bubbles exiting the air outlet are uniformly distributed by passing through the bubble distribution plate. The shear stress at the water and bubble boundary is one of the biggest factors affecting the splitting of bubbles. The increase in the shear stress at the gas-liquid interface is related to the pressure of the gas inside the bubble and the surface tension at the gas-liquid interface. This means that the balance is broken, which causes the large bubbles to break up into smaller bubbles to reach a new equilibrium. The air split into small bubbles has an effect of more efficiently supplying oxygen into the water while staying in the water for a long time. That is, in the case of the conventional diffuser using acoustic resonance, it was found that there is about 18% of standard oxygen transfer efficiency (SOTE), but the nozzle type diffuser of the present invention has a standard oxygen transfer efficiency (SOTE) of about 20 to 30%. Significantly improved. In addition, the nozzle type diffuser device of the present invention is simple in structure and does not require maintenance and cleaning in use, and its size is small and the overall height of the diffuser is economical. In addition, depending on the conditions of use, there is an effect that can be installed in the horizontal direction or downward as well as upstream installation of the diffuser outlet is a general installation method.

1 is a cross-sectional view showing a conventional general diffuser;

Figure 2a is a cross-sectional view showing an air diffuser using a conventional acoustic resonance;

Figure 2b is a plan sectional view showing a diffuser using a conventional acoustic resonance;

3A is a perspective view showing a first embodiment of a nozzle type diffuser according to the present invention;

3B is a perspective view showing a second embodiment of the nozzle type diffuser according to the present invention;

4A is a sectional view showing a first embodiment of a nozzle type diffuser according to the present invention;

4B is a sectional view showing a second embodiment of a nozzle type diffuser according to the present invention;

5A is a perspective view showing a third embodiment of a nozzle type diffuser according to the present invention;

5B is a perspective view showing a fourth embodiment of the nozzle type diffuser according to the present invention;

6A is a sectional view showing a third embodiment of a nozzle type diffuser according to the present invention;

6B is a sectional view showing a fourth embodiment of the nozzle type diffuser according to the present invention;

7 is a cross-sectional view showing the form of a bubble distribution plate of the nozzle type diffuser according to the present invention;

8 is a cross-sectional view showing a guide groove formed in the nozzle shrinkage inclined surface and the bubble distribution plate constituting the nozzle-type diffuser according to the present invention.

♣ Explanation of symbols for main part of drawing ♣

d1: chamber lower diameter d2: chamber upper diameter

d3: inlet diameter h: chamber height

φ1: Air supply inlet diameter φ2: Nozzle neck diameter

θ: Nozzle contraction angle H: Height of device body

L: Nozzle Neck Length 1: Chamber

2: entrance 3: exit

4 device body 5 air supply inlet

6: Nozzle shrink slope 7: Nozzle neck

8: air outlet 9: exit enlarged slope

10: pulsation pressure control chamber 20: bubble distribution plate

Claims (11)

In the diffuser device used for supplying air to the aeration process of the wastewater treatment plant, An air supply inlet configured to introduce air into the body of the apparatus; A nozzle contraction inclined surface which is continuously formed from the air supply inlet and increases a flow rate of the introduced air; And an air outlet formed in the form of a nozzle neck which is continuously formed from the nozzle contraction inclined surface and injects air having an increased flow rate. In the diffuser device used for supplying air to the aeration process of the wastewater treatment plant, An air supply inlet configured to introduce air into the air diffuser body; A nozzle contraction inclined surface which is continuously formed from the air supply inlet and increases a flow rate of the introduced air; An air outlet formed continuously from the nozzle contraction slope to form a nozzle neck for injecting air having an increased flow rate; And a bubble distribution plate disposed above the outlet to uniformly distribute the air bubbles injected from the air outlet. The nozzle type diffuser device according to claim 1 or 2, wherein the air outlet is enlarged by an outlet enlarged inclined surface formed continuously from the nozzle neck. The nozzle type diffuser device according to claim 1 or 2, wherein the nozzle contracting inclined surface is formed with a helical or radial guide groove. The nozzle type diffuser of claim 3, wherein the outlet enlarged inclined surface is formed with a helical or radial guide groove. The nozzle type diffuser device according to claim 1 or 2, wherein a pulsating pressure control chamber having a diameter larger than that of the air supply inlet is formed between the air supply inlet and the nozzle contraction inclined surface. The nozzle type diffuser device according to claim 1 or 2, wherein the diameter of the air supply inlet is larger than the diameter of the nozzle neck and the diameter of the nozzle outlet. The nozzle type diffuser of claim 1 or 2, wherein the shape of the nozzle neck is one of circular, elliptical, and polygonal shapes. The nozzle type diffuser device according to claim 2, wherein the bubble distribution plate has one form selected from a reverse cone shape, a reverse hemisphere shape, and a plate shape. The nozzle type diffuser device according to claim 2 or 9, wherein a diameter of the bubble distribution plate is larger than a diameter of the nozzle neck and a diameter of the air outlet. The nozzle type diffuser of claim 2 or 9, wherein the bubble distribution plate is formed with a helical or radial guide groove.