KR200373515Y1 - The membrane unit that can prevent fouling of air diffuser - Google Patents

Abstract

The present invention relates to a membrane unit device capable of preventing the occlusion of the diffuser, and the circulation of the water and the air supplied to the separator unit is smoothly prevented, thus preventing the blockage of each separator and minimizing the inflow of foreign substances into the diffuser. While cleaning the inside of the diffuser easily, by stacking the membrane unit to increase the efficiency of the immersion membrane separation system.

To this end, the present invention, in the membrane unit (100) consisting of a separator frame (10) having a separator (14), and an air diffuser (20) for supplying air to each separator, the outer side of the separator frame (10) The diffuser 20 coupled to the upper module support and connected to the upper module support, and the diffuser 20 coupled to the lower portion of the separator frame 10 by the coupling means forms a flow path of air and has a plurality of nozzle holes on the lower surface thereof. It is formed in the elliptical shape having a 23, the air supply pipe 21 and the sludge discharge pipe 22 is formed on one side of the diffuser 20 of the elliptical shape, respectively, the sludge discharge pipe 22 to open and close the sludge discharge pipe The mortgage means are combined.

Description

Membrane unit for preventing diffuser obstruction {THE MEMBRANE UNIT THAT CAN PREVENT FOULING OF AIR DIFFUSER}

The present invention relates to a membrane unit of an immersion membrane separation system that treats and purifies sewage and sewage. More specifically, air is smoothly supplied to the membrane unit and the circulation of water flows through the supplied air. The present invention relates to a membrane unit device capable of preventing the obstruction of the diffuser as well as preventing the blockage of each separator as well as minimizing the inflow of foreign substances into the diffuser.

In general, the immersion membrane separation system cleans the wastewater and sewage by filtering and filtering dissolved pollutants and microorganisms and suspended solids contained in the wastewater and sewage by biological or physical processes. to be.

The membrane unit of the immersion membrane separation system to filter the foreign substances contained in the waste water and sewage to filter, that is, while receiving the guidance of the guide rail (not shown) fixed in the aerobic tank unit is put into or taken out of the aerobic tank In the separation membrane unit, the sewage and the waste water contained in the aerobic tank, that is, the foreign matter contained in the mixed solution are filtered to filter and purify the mixed solution with clean water.

As shown in FIG. 1, the separation membrane unit 100 is provided with a separation membrane frame 10 having a plurality of separation membranes 14 for filtering foreign matter contained in the aerobic tank. The lower part of the separator frame 10 is coupled to the diffuser 20 to supply air sent from the outside to each separator 14 of the separator frame 10.

The separator frame 01 is provided with a support part 11 forming an outline. The upper part of each of the separators 14 is fixed to the upper part of the support part 11 and passes through each of the separators 14. While the foreign material is filtered and the treated water flows into the upper module support (12) of the hollow tube shape having a 'H' shape flowing, the suction pump in the center of the upper module support (12) The discharge pipe 12a for discharging the treated water in the upper module support 12 to the outside by the pumping force of the is formed.

A lower module support 13 having a channel shape for supporting and fixing a lower portion of each of the separation membranes 14 is provided below the support portion 12a, and upper and lower modules are provided at both sides of each of the separation membranes 14. A collecting pipe 15 is provided, which is supported by and fixed by the supports 12 and 13, and collects the treated water filtered while passing through the separation membranes 14.

In addition, the diffuser 20 has an air inlet 20a to allow air to be introduced from the outside, and a hollow tube to form a flow path of air introduced through the air inlet 20a. It is coupled to the support portion 11, the diffuser 20 is coupled to a plurality of nozzles (20b) for supplying air to each of the separation membrane (14) as well as to generate water flow by the supplied air, The nozzles 20b are formed with a plurality of nozzle holes 20c for discharging air in the nozzles 20b to form air in the form of air bubbles.

In the immersion membrane separation system configured as described above, the sewage membrane and the sewage, that is, the mixed liquid are introduced into the aerobic tank according to the operation of the immersion membrane separation system, and the membrane unit 100 installed in the aerobic tank by the mixed liquid introduced into the aerobic tank is Because of being locked, the mixed solution is present in the membrane unit (100).

The membrane unit 100 in the aerobic tank is a mixed solution in each of the separation membranes 14 when the mixed liquid passes through the plurality of membranes 14 installed in the membrane frame 10 of the membrane unit 100 by the pumping force of the suction pump. The foreign matter contained in the filter is filtered, the treated water in the filtered state is introduced into each of the separation membrane (14).

The treated water flowing into each of the separation membranes 14 of the separation membrane frame 10 is collected into collection pipes 15 installed at both sides of each separation membrane 14.

The treated water collected in the collecting pipe 15 is introduced into the upper module support 12 while flowing in the collecting pipe 15 by a suction pump that is continuously operated, and the treated water introduced into the upper module support 12. Is discharged to the outside of the upper module support 12 through the discharge pipe (12a) is sent to the treatment tank from the exhalation tank.

At this time, the air generated in the blower installed in the outside into the diffuser 20 installed in the lower portion of the membrane frame 10 is introduced through the air inlet hole 20a of the diffuser 20, the diffuser 20a The air introduced into the) is sent to each nozzle 20b while flowing in the diffuser 20.

The air sent to the nozzles 20b is discharged in the form of air bubbles through the nozzle holes 20c of the nozzles 20b to generate water flow and are supplied to the separators 14 of the membrane frame 10. .

Therefore, foreign matters of the mixed solution adhering to the surface of each separator 14 are not only dropped by the air supplied, but foreign matters of the mixed solution are prevented from sticking to each of the separators 14 by the water flow.

However, the membrane unit of the immersion membrane separation system can prevent the foreign matter attached to each membrane from being detached or stuck to some extent by the air sent from the diffuser, but it cannot be completely removed. Since the foreign matter is stuck to the surface of the treatment volume is reduced and there is a problem that the risk of damaging the separator occurs.

Thus, there is a problem in that timely and economic losses occur as the separation membrane unit is periodically taken out of the aerobic tank and cleaned with a cleaning chemical to remove foreign substances caught in each separation membrane.

In addition, since the shape of the upper module support of the separator frame is made of 'H' shape, the resistance of the water flow is generated in the center of the upper module support when the water flow generated by the air supplied to each separator from the diffuser is circulated. Therefore, there was a problem that the circulation of the water flow is not made smoothly.

Therefore, as the rate of rise of air bubbles decreases and the rate of flow of water flows from the bottom of the membrane unit to the top becomes slow, the nozzle hole of the diffuser must be enlarged or the air supply is increased to increase the rate of rise of water flow. As a result, there was a problem in that the cost wasted, such as a decrease in oxygen transfer efficiency and excessive power supply for air supply.

In addition, since each nozzle of the diffuser is formed in a straight shape and air inlet is formed in the side of the diffuser, air flowing in and flowing through the air inlet is discharged smoothly through each nozzle at each end of each nozzle. As the amount of air discharged toward the central portion of each nozzle decreases, not only the whole membrane may not be supplied evenly, but also there is a problem that clogging due to foreign substances occurs on the surface of the central portion of each separator.

In addition, since each nozzle hole of the diffuser penetrates in a straight line, when the diffuser is operated for a long time, foreign substances, microorganism sludge, and suspended solids contained in the mixed solution may flow into the diffuser through the nozzle holes and may be stuck and blocked. In addition, due to this, as the air cannot be smoothly supplied from the diffuser to each of the separators, foreign substances adhered to the surfaces of the separators are not easily removed, and the cleaning is not performed by air bubbles. There was also a problem that the blockage of the membrane easily occurs.

In addition, when the membrane frame and the diffuser are manufactured in the membrane unit, not only the manufacturing process of the membrane unit is complicated, but also the manufacturing cost of materials and the like are difficult to increase and carry.

The present invention has been made to solve the above-mentioned conventional problems, to change the structure of the separator frame and the diffuser structure of the separator unit so that air is smoothly supplied to each separator of the separator frame from the elliptical type diffuser. There is a purpose.

In addition, the circulation of the water flow generated by the air evenly supplied from the diffuser to each of the separators is made smoothly, and the foreign matters attached to the separators easily fall off as well as the foreign matters do not adhere to the separators. The purpose is to prevent clogging of each separator and to clean each separator smoothly.

In addition, the present invention is easy to replace and clean (washing) of the diffuser by attaching and detaching the diffuser to the separator frame, as well as to simplify the manufacturing process of the separator unit as well as to reduce and transport the production cost of materials, etc. The purpose is to make this easy.

In addition, the present invention is to form an air supply pipe and a sludge discharge pipe in each of the elliptical diffuser so that air is smoothly introduced into the diffuser through the air supply pipe and foreign matter (sludge, etc.) in the diffuser through the sludge discharge pipe. The purpose is to allow easy discharge.

In addition, the present invention is to connect the electric valve to the sludge discharge pipe of the diffuser to open and close the sludge discharge pipe automatically by the set time by the electric valve, even through the sludge discharge pipe in the state without removing the membrane unit in the aeration tank. The purpose is to facilitate the discharge of sludge in the diffuser.

In addition, the present invention is to form a baffle bar in the center of the elliptical diffuser to improve the efficiency of the separation membrane unit by increasing the rate of rise of the water flow generated by the air discharged from the nozzle hole of the diffuser. There is a purpose.

In addition, the present invention is formed by the counter-sink (COUNTER SINK) method of each nozzle hole of the diffuser to facilitate the discharge of air from the diffuser, as well as foreign substances such as suspended solids and contaminants contained in the mixed liquid into the diffuser The goal is to minimize this influx.

In addition, since the membrane unit of the present invention is installed by stacking the multi-stage in the vertical direction, it is possible to reduce the installation space of the membrane unit and thus to process a large capacity in a limited site, and to install only one diffuser in the multi-stage membrane unit. Even if the purpose is to increase the efficiency of the membrane unit as well as to improve the overall efficiency of the immersion membrane separation system.

1 is a perspective view showing a membrane unit of the conventional immersion membrane separation system.

Figure 2 is an exploded perspective view showing a membrane unit of the present invention immersion membrane separation system.

Figure 3 is a perspective view showing the structure of the separator unit device of the present invention.

Figure 4 is a bottom view showing the diffuser of the present invention membrane unit device from the bottom.

Figure 5 is a bottom view showing a state in which the baffle bar is coupled to the diffuser of FIG.

Figure 6 is another embodiment showing the present invention diffuser.

Figure 7 is a bottom view showing a state in which the baffle bar is coupled to the diffuser of FIG.

Figure 8 is a perspective view showing a state in which the electric valve coupled to the diffuser of the separator unit device of the present invention.

9 is a front view showing a state in which the present invention membrane unit devices are stacked.

* Description of the symbols for the main parts of the drawings *

10: membrane frame 11: support

14: Membrane 16: Connection

20: diffuser 21: air supply pipe

22: sludge discharge pipe 22a: cap

23: nozzle hole 24: coupling hole

25: fastener 30: baffle bar

40: sludge discharge pipe 50: electric valve

100: membrane unit

In order to achieve the above object, the present invention is a separator frame having a support and a pair of upper module support, left and right side plates and a plurality of separator membranes to filter out foreign substances contained in the mixed liquid in the aerobic tank, and In the separator unit consisting of a diffuser unit for supplying air to each separator, it is located on the outside of the separator frame as well as coupling the connection portion having a discharge port to be connected to one side of the pair of upper module support, The diffuser coupled to the lower portion by the coupling means is formed in an elliptical shape having a plurality of nozzle holes in the lower surface to form a flow path of air flowing into the diffuser and into the diffuser on one side of the diffuser of the elliptical shape. The diffuser together with the air supply line to allow outside air to enter A sludge discharge tube for discharging the sludge in the tube is formed, and an inlet of the sludge discharge tube is provided with a separation unit for preventing the obstruction of the diffuser, characterized in that the closing means for opening and closing the sludge discharge tube is coupled.

Hereinafter, a preferred embodiment according to the embodiment of the present invention configured as described above will be described in more detail with reference to FIGS. 2 to 4.

Figure 2 is an exploded perspective view showing the membrane unit of the present invention immersion membrane separation system, Figure 3 is a perspective view showing the structure of the membrane unit of the present invention, Figure 4 shows the diffuser of the membrane unit of the present invention from the bottom surface Bottom view.

The present invention is installed in the aerobic tank of the immersion membrane separation system to filter out the pollutants, wastewater and sewage in the aerobic tank such as dissolved pollutants, microorganisms, suspended solids, etc. Separation membrane unit 100 is provided.

The membrane unit 100 is provided with a membrane frame 10 for filtering foreign substances contained in the mixed liquid in the aerobic tank, the lower portion of the membrane frame 10 to supply air sent from the outside to the membrane frame 10. The diffuser 20 is detachably coupled by a coupling means.

The separator frame 10 is provided with a rectangular support portion 11 is formed to form the outer periphery of the membrane frame 10, the front, rear plates (11a, 11b) on the front, rear of the support portion 11 The left and right side plates 11c and 11d are coupled to the left and right sides of the support 11 in a detachable manner, and the left and right side plates 11c and 11d are detachably coupled to each other according to the guide of the guide unit 17. Is separated and formed at least two to facilitate coupling to the membrane frame (10).

The upper portion of the support portion 11 is coupled to a pair of upper module support 12 in the form of a hollow tube in the corresponding position to each other, and the lower portion of the channel (channel) in the lower portion of the support portion 110 The module support 13 is coupled.

Before and after the membrane frame 10, the front and rear plates 11a and 11b for blocking the front and rear surfaces of the membrane frame 10 are coupled to the support 11, and the left and right sides of the membrane frame 10 On the right side, left and right side plates 11c and 11d for blocking the membrane frame 10 are coupled to the support 11, and the front and rear plates 11a and 11b are guides 17 coupled to the support 11. Sliding along) is detachably coupled to the membrane frame 10, the left and right side plates (11c, 11d) are coupled to the support (11).

The front, rear plate (11a, 11b) and the left, right side plate (11c, 11d) can be changed according to the working method and the location to be installed, here for convenience the width of the membrane frame 10 as shown in the figure The narrow side was used as the front and rear sides, and the wider side of the membrane frame 10 was used as the left and right sides.

Inside the separation membrane frame 10, that is, inside the support part 11, a plurality of separation membranes 14 in the form of membranes for filtering out foreign substances contained in the mixed liquid in the aerobic tank are combined, and both sides of the separation membranes 14, respectively. The collection pipe 15 is provided with the foreign matter contained in the mixed liquid passing through each of the separation membranes 14 to collect the treated water.

That is, as the upper portion of the collecting pipe 15 is coupled to the pair of upper module support 12, the upper portion of each separation membrane 14 is fixed to the upper module support 12, respectively, and is fixed to the collecting pipe 15. As the lower part of the separator is coupled to the lower module support 13, the lower part of each separator 14 is fixed to the lower module support 13, respectively.

One side of the pair of upper module support 12 is connected to the connection pipe 16 connected to each side of the pair of upper module support 12 so that the treated water collected in the collection pipe 15 is discharged to the outside of the aerobic tank. Is coupled, the connector 16 is coupled to penetrate through a pair of upper module support (12).

A predetermined position of the connecting pipe 16 is sent to the pair of upper module support 12 through the collecting pipe 15 to the treated water introduced into the connecting pipe 16 by a pumping force of a pump (not shown). A discharge port 16a for discharging to the outside of the aerobic tank is formed.

The connection pipe 16 smoothly circulates the flow of water by the air supplied from the diffuser 20 to each separator 14 in the separator frame 10 to prevent blockage of the separators 14. It is located outside of the membrane frame 10 to be made.

The diffuser 20 is located in the bottom of the membrane frame 10 in the form of a hollow tube to form a flow path of the introduced air while the air supplied by a blower installed outside Formed.

The diffuser 20 is fixed to the bottom of the separator frame 10 to be detachable by a coupling means.

The diffuser 20 has a flow of air introduced from the outside smoothly in the diffuser 20 as shown in FIGS. 2 to 4, and the air discharged from the diffuser 20 is separated from each separator ( 14) It is formed in an oval shape so that it is evenly supplied.

On the lower surface of the diffuser 20 to discharge the air in the diffuser 20 to evenly supply the air flowing into the diffuser 20 to each separator 14 of the separator frame 10. A plurality of nozzle holes 23 are formed.

As shown in FIG. 4, the nozzle holes 23 are easily discharged from the diffuser 20 to the outside through the nozzle holes 23, and foreign matters contained in the mixed liquid in the aerobic tank at the stop of the blower. And the sludge is formed in the counter sink (COUNTER SINK) method to prevent the inflow into the diffuser 20 as much as possible.

In the counter sink method, as shown in FIG. 4, each nozzle hole 23 is located outside the diameter of each nozzle hole 23 in which the nozzle holes 23 are located inside the diffuser 20. The diameter of 23 is larger, and the diameter of each nozzle hole 23 located on the outer side is formed to gradually widen from the inside of the diffuser 20 toward the outside.

Here, the oval-shaped diffuser 20 is connected to a pipe (not shown) coupled to a blower (BLOWER) on one side of the diffuser 20 as shown in FIGS. 2 and 4 to supply from the blower. An air supply pipe 21 is formed to allow external air to flow into the diffuser 20, and on the other side of the diffuser 20, foreign substances and sludge accumulated or existing in the diffuser 20 are discharged. A sludge discharge pipe 22 is formed.

The air supply pipe 21 and the sludge discharge pipe 22 is formed to form a pair of air supply pipe 21 and the sludge discharge pipe 22 on one side of the diffuser 20 as shown in Figs.

Coupling means for coupling the diffuser 20 to the separator frame 10, the air supply pipe 21 and the sludge discharge pipe 22 formed on one side of the diffuser 20 of the elliptical shape is shown in FIGS. Likewise, a pair of coupling holes 24 into which the air supply pipe 21 and the sludge discharge pipe 22 of the diffuser 20 are inserted and fixed are formed in the front plate 11a of the separator frame 10. On the rear plate 11b of the membrane frame 10, a U bolt 26 into which the nut 27 is fastened is inserted into an opposite side of the air supply pipe 21 and the sludge discharge pipe 22 of the diffuser 20. The ball 25 is formed.

In the above, the coupling hole 24 and the fastening hole 25 may be formed on any of the front and rear plates 11a and 11b, respectively, depending on the purpose, effect, and manufacturing method.

In addition, as another embodiment of the air supply pipe 21 and the sludge discharge pipe 22 is installed in the diffuser 20, as shown in Figure 6, to introduce a large amount of air into the diffuser 20 or In order to remove sludge in the diffuser 20 more easily and quickly, air supply pipes 21 and sludge discharge tubes 22 are formed on both sides of the diffuser 20, respectively.

Each of the air supply pipes 21 and the sludge discharge pipes 22 formed on both sides of the diffuser 20 is formed so as to be in a diagonal direction with respect to the diffuser 20, that is, staggered with each other.

The coupling means for coupling the diffuser 20 to each of the membrane frame 10 formed with a pair of air supply pipe 21 and a sludge discharge pipe 22 formed on both sides of the diffuser 20 of the elliptical shape is a membrane frame In the front and rear plates 11a and 11b of FIG. 10, a pair of coupling holes 24 are formed, in which a pair of air supply pipes 21 and a sludge discharge pipe 22 are respectively inserted and fixed.

Here, the opening and closing means for opening and closing the sludge discharge pipe 22 is coupled to the inlet of the sludge discharge pipe 22.

Opening and closing means of the sludge discharge pipe 22 is detachably coupled to the cap 22a for opening and closing the sludge discharge pipe 22 while being coupled and separated at the inlet of the sludge discharge pipe 22, as shown in FIG. .

That is, when the separation membrane unit 100 is in operation, the inlet of the sludge discharge pipe 22 is blocked with a cap 22a to prevent air from escaping through the sludge discharge pipe 22, and the separation membrane unit 100 is In order to stop and discharge the sludge in the diffuser 20, the cap 22a is removed from the inlet of the sludge discharge tube 22 and the pressure in the diffuser 20 is increased by the pressure of the air supplied to the air supply pipe 21. After removing the foreign matter and sludge attached to the surface is the sludge is discharged to the outside through the sludge discharge pipe 22.

In addition, the opening and closing means of the sludge discharge pipe 22, as shown in Figure 8, the sludge discharge pipe 40 of the hollow tube form is coupled to the inlet of the sludge discharge pipe 22, the sludge discharge pipe 40 The predetermined position, that is, the position that is not immersed in the mixed liquid of the aerobic tank is coupled to the electric valve 50 for automatically opening and closing the sludge discharge pipe 22 according to the set time.

That is, when the membrane unit 100 is in operation, the electric valve 50 is operated to close the sludge discharge pipe 22, thereby preventing air from escaping through the sludge discharge pipe 22, and the membrane unit 100. ) Stops and discharges the sludge in the diffuser 20, the operation of the electric valve 50 to open the sludge discharge pipe 22, so that the diffuser 20 by the pressure of the air supplied to the air supply pipe 21 The foreign matter and sludge accumulated or existing in the inside of the) is to be discharged to the outside through the sludge discharge pipe 22.

A manual valve may be used as the opening and closing means of the sludge discharge pipe 22 without using the electric valve 50, which may be selectively used in consideration of the purpose or effect of work and various circumstances.

In order to remove or remove the sludge in the diffuser 20, the sludge accumulated or existing in the diffuser 20 by the air supplied into the diffuser 20 through the air supply pipe 21 is sludge and foreign matter It is discharged to the outside of the diffuser 20 through the discharge pipe 22.

On the other hand, the sludge discharge pipe 40 to which the electric valve 50 is coupled may be fixed to the membrane frame 10 using a U bolt, that is, such as an angle or a fixed plate to the membrane frame 10. After combining the government unit, the sludge discharge pipe 40 is contacted with the fixing unit, and then the U bolt may be fastened to be fixed to the fixing unit while surrounding the sludge discharge pipe 40. As described above, the sludge discharge pipe 40 is fixed. ) May be provided with a separate member for fixing to the membrane frame (10).

Here, according to the position where the air supply pipe 21 and the sludge discharge pipe 22 of the diffuser 20 is formed and the diffuser 20 is coupled to the separator frame 10, Positions of the coupling holes 24 and the fastening holes 25 may be different in the rear plates 11a and 11b, which can be detachably fixed to the diffuser 20 in the separator frame 10. It does not matter what direction and wherever formed, as well as to provide a variety of purposes depending on the purpose, effect and installation method of the membrane unit (100).

In the central portion of the elliptical diffuser 20, as shown in FIGS. 5 and 7, water flow generated by the air supplied to each separator 14 from the diffuser 20 is easily provided to each separator 14. The baffle bar 30 is coupled to increase the flow rate of the water flow by the air supplied to each of the separation membranes 14 as well.

On the other hand, the membrane unit 100 may be installed in a multi-stage stacking in the vertical direction as shown in Figure 9, that is, the membrane unit 100 is laminated on the support portion 11 located above and below the membrane frame 10 When the bolt (a) is fastened to each of the plurality of bolt holes 28 are formed.

In other words, each bolt hole 28 of the support part 11 located above the lower side membrane unit 100 and each bolt hole of the support part 11 positioned below the upper side separation membrane unit 100 ( 28 and the plurality of separation membrane units (100) stacked on a limited site because the membrane unit 100 is stacked in a multi-stage in the vertical direction by fastening the bolt (a) to each matched bolt hole (28) after matching each; ) Can be installed.

The connecting portion 16 of the upper separation membrane unit 100 and the connecting portion 16 of the lower separation membrane unit 100 are connected by a pipe, and the treated water treated in the upper and lower separation membrane units 100 is combined. The upper and lower side connecting portions 16 may be connected in any manner as long as they are made.

Referring to the operation of the present invention configured as described above are as follows.

First, a pair of upper and lower module supports 12 and 13 are respectively coupled to upper and lower portions of the support 11 of the separator frame 10, and then a plurality of separators 14 are positioned inside the support 11. The separation membrane 14 is fixed to the upper and lower module supports 12 and 13 so as to be fixed.

In this case, the front and rear plates 11a and 11b are coupled to the front and rear surfaces of the membrane frame 10, and the left and right side plates 11c and 11d are coupled to the left and right sides of the membrane frame 10. The left and right side plates 11c and 11d are detachably coupled while sliding up and down along the guide portion 17 installed on the support 11.

Each end of the pair of upper module support 12 is coupled to the pair of upper module support 12 and the connecting tube 16 to be connected to each other so as to protrude to the outside of the membrane frame 10, Since the discharge pipe 16a is formed in the connection pipe 16, the foreign matter is filtered while passing through each of the separation membranes 14 through the discharge hole 16a to filter the filtered and purified water from the outside of the separation membrane unit 100. To be discharged.

In addition, the diffuser 20, that is, the diffuser 20 having an elliptical shape is fixedly coupled to the lower portion of the separator frame 10, that is, a pair of couplings formed on the front plate 11a of the separator frame 10. Since the air supply pipe 21 and the sludge discharge pipe 22 formed on one side of the diffuser 20 are respectively inserted into the ball 24, one side of the diffuser 20 is fixed to the separator frame 10 and fixed. The other side of the diffuser 20 is fixed to the separator frame 10 by the U bolt 26 and the nut 27 fastened to the fastening hole 25 formed in the rear plate (11b).

Here, according to the shape of the diffuser 20, that is, in the diffuser 20 of the form as shown in FIG. 6, the front and rear plates 11a and 11 of the separator frame 10 are not used without the U bolt 26. Only the pair of coupling holes 24 respectively formed in 11b) may detachably couple the diffuser 20 to the separator frame 10.

The operating state of the diffuser 20 according to the shape of the diffuser 20 will be described focusing on one embodiment, and the above-described embodiment and the other embodiment have the same operation, function, and effect but only in different shapes. Do.

As described above, as the separator frame 10 to which the plurality of separators 14 are coupled and the diffuser 20 are coupled to the lower portion of the separator frame 10, the production of the separator unit 100 is completed.

When the membrane unit 100 is put into an aerobic tank and the immersion membrane separation system is operated, the mixed liquid flows into the aerobic tank, and the membrane unit 100 is locked to the introduced mixed liquid.

The mixed liquid in the membrane unit 100 flows into each separator 14 of the separator frame 10, that is, each separator 14 having fine pores (0.1 to 0.4 μm), that is, is included in the mixed liquid. Foreign material will be filtered out.

The mixed liquid filtered out of the foreign matter, that is, the purified water and the treated water is collected into collecting pipes 15 installed at both sides of the separation membranes 14, and the treated water collected into the collecting pipes 15 is a pair of upper modules. It is sent to the connecting portion 16 while flowing in the support (12).

The treated water sent to the connecting portion 16 is discharged to the outside of the separation membrane unit 100 through the discharge port 16a of the connecting portion 16 by the pumping force of the suction pump continuously operated to flow into the treated water pipe. Will be sent into the treatment tank.

Here, the diffuser 20 is installed in the lower portion of the membrane frame 10 to supply air to each of the separation membrane 14, that is, the air generated from the blower installed outside the aerobic tank is connected to the pipe coupled to the blower It is supplied into the diffuser 20 through the air supply pipe 21 of the diffuser 20.

Air supplied into the diffuser 20 is discharged to the outside of the diffuser 20 through a plurality of nozzle holes 23 formed in the lower surface of the diffuser 20 while flowing in the diffuser 20 having an elliptical shape. do.

At this time, the sludge discharge pipe 22 of the diffuser 20 is blocked by the electric valve 50 or the cap 22a coupled to the sludge discharge pipe 40.

The air in the diffuser 20 is discharged in the form of air bubbles through the nozzle holes 23 to generate water flow, that is, the water flow is generated as the mixed liquid flows by the pressure of the discharged air, It is sent to the separator (14).

On the other hand, if the sludge discharge pipe 40 coupled with the electric valve 50 is connected to the sludge discharge pipe 22 of the diffuser 20 as shown in FIG. By setting it to 50, the membrane unit 100 is operated and stopped, or the sludge discharge pipe 22 is automatically opened and closed because the electric valve 50 is operated and opened according to the set signal.

That is, when the separation membrane unit 100 is operated, the electric valve 50 operates to close the sludge discharge pipe 22, and the separation membrane unit 100 stops or the foreign matter and sludge in the diffuser 20. When the cleaning to remove the electric valve 50 is operated to open the sludge discharge pipe (22).

When the sludge discharge pipe 22 is opened by the electric valve 50, the air supplied to the air supply pipe 21 of the diffuser 20 flows inside the diffuser 20 and the Along with the sludge accumulated in the inside and the foreign matter is discharged to the outside of the diffuser 20 through the sludge discharge pipe 22.

Here, when the baffle bar 30 is formed in the center of the diffuser 20 as shown in FIGS. 5 and 7, the air is discharged through the nozzle holes 23 of the diffuser 20. The water flow rate is increased by the baffle bar 30 to each of the separation membranes 14.

That is, the baffle bar 30 serves to hold the circulation direction of the water flow so that the water flow can be circulated in a certain direction, so that the water flow of the air is smoothly separated by the baffle bar 30. Is supplied.

The air, that is, the water flow, sent to each of the separation membranes 14 not only removes foreign substances adhering to the surface of each separation membrane 14 that filters out the foreign substances contained in the mixed solution from the surface of each separation membrane 14, but also each of the separation membranes. To prevent foreign matter from adhering to the surface of (14).

Since the shape of the diffuser 20 is elliptical, external air smoothly flows into the diffuser 20 as well as the introduced air easily flows in the diffuser 20 while the diffuser 20 Discharge evenly throughout.

Therefore, as air is evenly supplied from each diffuser 20 to each separator 14, the efficiency and performance of the separator unit 100 may be improved by preventing clogging at the surface of each separator 14.

On the other hand, since each nozzle hole 23 of the diffuser 20 is formed in a counter sink method, each nozzle hole 23 in the diffuser 20 when the separation membrane unit 100 is in operation. Air is smoothly discharged through) to be supplied to each separator 14.

In addition, when the separation membrane unit 100 is not operated or air is not supplied into the diffuser 20, the mixed liquid flows into the diffuser 20 through the nozzle holes 23. As the sludge contained in the mixed solution is accumulated in the upper portion of each nozzle hole 23, only a small amount of sludge flows into the diffuser 20, so that the inflow of the sludge can be minimized.

On the other hand, in order to remove the foreign matter and sludge accumulated in the inside of the diffuser 20, the membrane unit 100 is removed from the aeration tank to separate the diffuser 20 from the membrane frame 10, that is, the nut 27 ) And the U bolt 26 and then the air supply pipe 21 and the sludge discharge pipe 22 are removed from the front plate 11a of the membrane frame 10 so that the diffuser 20 is separated from the membrane frame 10. Are separated).

Then, after separating the cap (22a) blocking the sludge discharge pipe 22 of the diffuser (20) and then flowing a strong pressure of air and liquid (cleaning liquid) through the air supply pipe 21 when The sludge in the diffuser 20 is easily discharged to the outside of the diffuser 20 through the sludge discharge pipe 22 by the air and the liquid of the high pressure, thereby cleaning and cleaning the inside of the diffuser 20 cleanly. Done.

On the other hand, the present invention, as shown in Figure 9, to install a plurality of the plurality of membrane unit 100 in the vertical direction, that is, a plurality of bolt holes on the lower portion, the support 11 of the membrane frame 10 And forming 28 to match each bolt hole 28 of the upper side membrane frame 10 and the lower side membrane frame 10 and then to fasten the bolts a to the matched bolt holes 28. Accordingly, the separator unit 100 is stacked in multiple stages.

At this time, the connection pipe 16 forming the flow path of the treated water treated in the lower side membrane unit 100 and the connection pipe 16 forming the flow path of the treated water treated in the upper side membrane unit 100. Combine to connect with each other. At this time, the connection method of the connecting tube 16 may be any method of sending the treated water from the lower side membrane unit 100 to the upper side membrane unit 100, which may be used for work purposes or effects. Various modifications are possible.

As described above, each of the separation membrane unit 100 installed in multiple stages by the air supplied from the diffuser 20 of the lower side separation membrane unit 10 by installing a plurality of stages in the vertical direction. There is an effect of cleaning the separation membrane (14).

Here, the separator unit 100 may be used by selectively combining the diffuser 20 as shown in FIG. 4 or FIG. 6 with the separator frame 10 according to the purpose or effect of the separator unit 100. The separator unit 100 may be stacked in multiple stages using the diffuser 20 selectively coupled, and the cap 22a or the electric valve 50 may be attached to the sludge discharge pipe 22 of the diffuser 20. It can be selectively combined, all of which can be used in any way depending on the purpose or effect of the membrane unit 100 and the working conditions and methods.

As described above, the membrane unit device capable of preventing the obstruction of the diffuser according to the present invention has been described with reference to the illustrated drawings, but the present invention is not limited by the embodiments and drawings described herein, and those skilled in the art within the technical scope of the present invention. Of course, various modifications may be made.

As described above, the present invention forms the position of the connection pipe for discharging the treated water out of the aerobic tank in the separation membrane frame of the separation membrane unit outside the separation membrane frame, that is, by forming the connection pipe in the shape of the upper portion of the separation membrane frame in the form of "c". In addition, there is an effect that the circulation of the water flow by the air generated in the membrane unit is smoothly performed.

In addition, the diffuser of the separation membrane unit is formed in an elliptical shape, and the air supply pipe and the sludge discharge pipe are formed in the diffuser, respectively, so that the outside air is smoothly supplied into the diffuser through the air supply pipe, as well as the diffuser. There is also an effect that the flow of air is smooth.

In addition, through the sludge discharge pipe of the diffuser can easily and smoothly discharge the foreign matter and sludge accumulated inside the diffuser to the outside of the diffuser, the efficiency of the diffuser as well as the efficiency of the separation membrane unit. There is also.

Therefore, not only air is uniformly supplied from the diffuser to each separator of the separator frame, but also the foreign matters attached to each separator easily fall off as the circulation of the water flow generated by the supplied air is smoothly performed. By preventing foreign matter from adhering to each separator, it is possible to prevent clogging of the separator and to improve the cleaning effect of the separator.

In addition, by forming at least one air supply pipe and a sludge discharge pipe in the diffuser, as well as facilitate the inflow of air into the diffuser by the air supply pipe as well as the sludge discharge in the diffuser is easily made by the sludge discharge pipe. In some cases, the sludge discharge pipe is used as an air supply pipe, thereby increasing the efficiency of the separation membrane unit by supplying a larger amount of air into the diffuser.

In addition, a baffle bar is formed at the center of the diffuser, thereby maintaining a constant circulation direction of the flow of water generated by the air discharged through each nozzle hole of the diffuser by the baffle bar, as well as increasing the rising speed of the stream. By removing the foreign matter from each separator, there is also an effect of improving the efficiency of the membrane unit.

In addition, by installing the electric valve to open and close the sludge discharge pipe of the diffuser so as to be located on the surface of the aerobic tank, the sludge discharge pipe is automatically opened according to the time the sludge discharge pipe is set by the electric valve and the operation and stop of the separation membrane unit. By opening and closing, the sludge discharge pipe can be discharged more easily through the sludge discharge pipe without taking the membrane unit out of the aerobic tank, and the membrane unit can be more easily manipulated according to the discharge of the sludge.

On the other hand, by installing the valve to open and close the sludge discharge pipe to be positioned on the water surface of the aerobic tank instead of the electric valve, by manually operating the manual valve to open and close the sludge discharge pipe to the outside of the exhalation tank There is also an effect of easily discharging the sludge accumulated in the inside of the diffuser to the outside of the diffuser without taking out.

And, by forming each nozzle hole of the diffuser in the counter sink (COUNTER SINK) method, the air is smoothly discharged through each nozzle hole from the inside of the diffuser to the outside, as well as the diffuser when the membrane unit is not operated There is also an effect of minimizing the introduction of sludge and contaminants, etc. contained in the mixed solution flowing through each nozzle hole into the diffuser.

In addition, since the diffuser is detachably coupled to the separator frame, replacement and cleaning (cleaning) of the diffuser can be easily performed, and the manufacturing process of the separator frame and the diffuser, that is, the separator unit is simple, and the manufacturing cost is reduced. This reduction and manpower is reduced, as well as the ease of operation due to the weight of the membrane frame is improved, as well as the material is easily carried.

In addition, by installing a plurality of membrane units stacked in a vertical direction, the membrane unit, that is, each membrane is cleaned with only one diffuser, thereby increasing the efficiency of the membrane unit and reducing the installation space of the membrane unit. Therefore, the large capacity can be processed at a limited site, thereby increasing the overall efficiency of the immersion membrane separation system.

This effect is a very useful design that improves the quality of the overall product and the consumer's reliability of the product.

Claims (9)

In order to filter out foreign substances contained in the mixed liquid in the aerobic tank, a separator frame having a support unit, a pair of upper module supports, left and right side plates and a plurality of separators, and an diffuser pipe for supplying air to each separator of the separator frame. In the separation membrane unit, It is located on the outside of the membrane frame as well as coupling the connection portion having a discharge port to be connected to one side of the pair of upper module support, The diffuser coupled to the lower portion of the separator frame by the coupling means is formed in an elliptical shape having a plurality of nozzle holes on a lower surface to form a flow path of air flowing into the diffuser. One side of the elliptical diffuser is formed with a sludge discharge tube for discharging the sludge in the diffuser, along with an air supply pipe to allow external air to flow into the diffuser, Separation membrane unit device capable of preventing the occlusion of the diffuser, characterized in that the inlet of the sludge discharge pipe is coupled to the closing means for opening and closing the sludge discharge pipe. The method of claim 1, The coupling means forms a pair of coupling holes for inserting and fixing the air supply pipe and the sludge discharge pipe of the diffuser in the front plate of the membrane frame, and the opposite side of the air supply pipe and the sludge discharge pipe of the diffuser in the rear plate of the separator frame. Separator unit device capable of preventing occlusion of the diffuser, characterized in that for forming a fastening hole to which the U bolt is fastened to be fixed to the U bolt. The method of claim 1, An air supply pipe and a sludge discharge pipe formed on one side of the diffuser are formed on the other side of the diffuser having an elliptical shape, and the air supply pipe and the sludge discharge pipe formed on one side and the other side of the diffuser are alternately positioned. Membrane unit device that can be prevented. The method according to claim 1 or 3, Coupling means is a membrane unit device capable of preventing the occlusion of the diffuser, characterized in that the front and rear plates of the separator frame to form a pair of coupling holes to allow the air supply pipe and the sludge discharge pipe of the diffuser respectively inserted and fixed. The method according to claim 1 or 3, Separation membrane unit apparatus for preventing obstruction of the diffuser, characterized in that the center of the elliptical diffuser is coupled to a baffle bar to increase the flow rate of the water flow generated by the air supplied from the diffuser. The method of claim 1, The opening and closing means is a separation membrane unit capable of preventing the occlusion of the diffuser, characterized in that the sludge discharge pipe is coupled to the inlet of the sludge discharge pipe, and an electric valve for opening and closing the sludge discharge pipe within a predetermined time is coupled to a predetermined position of the sludge discharge pipe. Device. The method of claim 1, The opening and closing means is a membrane unit device capable of preventing obstruction of the diffuser, characterized in that the cap is coupled to open and close the inlet of the sludge discharge pipe. The method of claim 1, Each nozzle hole is formed in a counter sink to prevent sludge contained in the mixed liquid in the aerobic tank and into the diffuser, while the air is discharged from the diffuser. Device. The method of claim 1, Separation membrane unit capable of preventing the occlusion of the diffuser, characterized in that a plurality of bolt holes for fastening the bolts are formed on the upper and lower portions of the front and rear support of the separation membrane frame to stack the plurality of separation membrane frames in multiple stages.