KR101384239B1 - Submerged ceramic separation membrane module assembly and apparatus for treating wastewater by using the same - Google Patents

Abstract

The present invention relates to a submerged ceramic separation membrane module assembly which is obtained by assembling multiple separation membrane modules including: a porous separation membrane in a tubular shape; and a water collecting pipe with multiple flow holes for collecting treated water from the separation membrane by being installed on the inside of the separation membrane. [Reference numerals] (AA) Cassette, clearance of 10 mm; (BB) Water (suction); (CC) Air or water (backwash)

Description

Submerged ceramic separation membrane module assembly and apparatus for treating wastewater by using the same}

The present invention can minimize the membrane fouling due to the structure of the solid membrane module, improve the water treatment efficiency by inducing a hydrodynamically stable flow, and can improve the operating efficiency by reducing the pressure loss by watertight assembly The present invention relates to an immersion type ceramic separator module assembly that is easy to install and manage according to scale, and a sewage and wastewater treatment apparatus using the same.

In general, the MBR (Membrane Bio Reactor) process using the immersion membrane module refers to a process in which the membrane module is directly immersed in a bioreactor and only the treated water is filtered out through solid-liquid separation by the membrane.

The membrane used in the MBR process generally refers to a solid membrane that can separate the mixture by selectively passing specific components through the fine pores of the membrane. Hollow fiber membrane, tubular type membrane and flat membrane are used for the separation membrane.

In the prior art, Korean Patent Registration No. 10-0932739 is formed in the shape of a hollow rectangular frame so that it can be used as an air diffuser pipe, connected to the blower on one side of the air diffuser line connecting port is connected to the air diffuser line for distributing air inside A main frame structure; A plurality of separation membrane modules installed vertically in the main frame, the suction pipes being installed at one end of the upper head, and formed with insertion holes at the other end to be continuously coupled to the neighboring upper heads and installed in multiple stages; And fixedly installed on one side of the upper end of the main frame to form an integrated structure with the main frame, and a connection hole connected to the suction pipe of each of the separation membrane modules on one side thereof, and discharged the treated water through the filtration pump on the upper surface. The present invention proposes a separator unit having an diffuser pipe integrated membrane frame structure and a suction pipe integrated membrane module, including a filtration pipe having a filtration line connector connected to the filtration line.

However, according to the above technique, when the membrane module is deformed in the rectangular frame during the suction process or the backwashing process, there is a problem that membrane contamination may occur due to the easy deposition of foreign matter on the deformable part. There is a problem that the pressure loss is generated at the joint at the time of fastening to lower the operating efficiency.

Republic of Korea Patent Registration No. 10-0932739

Accordingly, the present invention is to solve the above-described problems, to prevent membrane contamination due to deformation of the membrane module, and to immerse the ceramic membrane module module assembly and the sewage and wastewater using the same that can solve the problem of lowering the operating efficiency due to pressure loss It is to provide a processing device.

Immersion type ceramic separator module assembly according to the problem to be solved of the present invention, the tubular porous membrane and the water intake pipe formed with a plurality of flow holes to take the treated water from the separator in the separator and the separator and the water intake Characterized in that the assembly of the plurality of membrane modules including a coupler disposed between the tube.

Preferably, the coupler has a hollow formed therein so that the hollow inserts the intake pipes so that upper and lower inserting grooves are formed, respectively, so that the lower and upper ends of the separation membrane assembled to the inserting grooves are inserted. It is reasonable.

Here, the plurality of membrane modules are assembled in a tubular module intake tube to form a module cassette, and the plurality of module cassettes are assembled in a tubular frame intake tube, and the suction pipe and the back washing tube are connected to the frame intake tube. It is done.

In addition, the intake pipe is composed of a tubular intake pipe body and the intake pipe screw portion having a diameter smaller than the intake pipe body at both ends of the intake pipe body, the module intake pipe is formed in a pair of module fastening holes The separation pipe module is assembled to the module intake pipe by a nut coupling to the intake pipe screw portion through the intake pipe body through the other water pipe through the intake pipe body, characterized in that the module cassette is formed.

In addition, the module intake pipe is a tubular module intake pipe body, both ends of the module intake pipe body has a diameter smaller than the intake pipe body and formed at least one intake port and the end of the module intake pipe insert It consists of a module intake pipe screw formed, the frame intake pipe is formed in a pair of fasteners of the cassette is formed through the module intake pipe insertion portion through one of the cassette fastening hole while the module intake pipe screw portion penetrates the other cassette fastening hole through the module intake The module cassette is assembled to the frame intake pipe by nut coupling to a pipe screw.

In addition, the module intake pipe is formed in a pair of module fastening holes through the intake pipe body through one module fastening hole, the hollow is formed inside the intake pipe body is inserted into the hollow inner circumference and one end of the outer circumference The tapered and protruding first insertion portion is formed, and the other end portion is characterized in that the first sealing sphere is formed with a rim groove in which the end of the separation membrane is inserted.

In addition, the intake pipe screw portion and the module intake pipe screw portion is nut-coupled to the module fastening hole and the cassette fastening hole, respectively, the hollow is formed inside the intake pipe screw portion and the module intake pipe screw portion is inserted into the hollow inner circumference One end is formed with a second insertion portion protruding while the outer periphery is tapered, and the other end is characterized in that the second sealing tool is formed so that the head is formed on the outer surface of the module fastening hole and the cassette fastening hole, respectively.

In addition, a pair of cassette fastening holes are formed in the frame intake pipe so that the module intake pipe insertion part penetrates through one cassette fastening hole, and a hollow is formed therein, such that the module intake pipe insertion part is inserted into the hollow inner circumference, and thus an outer circumference is formed. It is configured to be tapered, characterized in that the third sealing hole is disposed between the cassette fastening hole and the module intake pipe insert.

On the other hand, the present invention also proposes a sewage and wastewater treatment apparatus, characterized in that the immersed ceramic membrane module assembly is configured in the aerobic tank.

As described above, the submerged ceramic membrane module assembly according to the present invention minimizes membrane contamination due to membrane deformation by using a rigid membrane module, and improves water treatment efficiency by allowing a stable flow of the fluid inside the membrane while introducing the fluid in multiple directions. There is an advantage that can be improved.

In addition, the immersion type ceramic separator module assembly according to the present invention has the advantage of improving the operating efficiency by reducing the pressure loss by watertight coupling between the components in the suction operation and backwash operation.

In addition, the immersion type ceramic separator module assembly according to the present invention has an advantage in that it is easy to manage because each component is formed by assembly so that only a separator or a combination of membranes in which a device failure occurs due to occlusion or the like can be replaced.

1 is a perspective view showing an immersion type ceramic separator module assembly of the present invention.
Figure 2 is a side cross-sectional view showing a membrane module of one configuration of the present invention.
3 is an exploded perspective view showing the assembling relationship between the components of the present invention.
Figure 4 is a detailed view showing the coupling relationship of the portion A in Figure 3;
Figure 5 is a schematic diagram showing an embodiment of the waste water treatment apparatus of the present invention.

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

The submerged ceramic membrane module assembly 1 of the present invention is formed by assembling a plurality of membrane modules 10 as shown in FIG. 1, and in the assembly of the plurality of membrane modules 10, a plurality of membrane modules 10 is provided. ) Are respectively assembled to a pair of module intake pipe 20 at both ends to form a plate-shaped module cassette, the plurality of module cassettes are assembled by the frame intake pipe (30) of the submerged membrane module assembly (1) of the present invention Will be completed.

In addition, as shown in FIG. 1, the four frame intake pipes 30 for fastening the plurality of module cassettes are connected by the fastening pipe 100 while communicating inside the suction pipe 50 and the fastening pipe 100. It is to ensure that the customs clearance 60 is connected.

In this configuration, the submerged membrane module assembly 1 of the present invention allows the suction process and the backwashing process to be performed. First, the suction process is not shown in the drawing, but the suction force acts on the suction pipe 50 by the operation of the suction pump. When each of the treated water filtered foreign matter from the raw water, such as sewage, wastewater through each membrane module 10 is introduced into each membrane module 10, the introduced treated water is the module intake pipe 20, the frame intake pipe 30, while the fastening pipe 100 flows in order to be discharged to the outside through the suction pipe (50).

In addition, in the backwashing process, when the air or water is injected through the backwashing pipe 60, the flow of water or air in a direction opposite to the suction process is generated, the fastening pipe 100, the frame intake pipe 30, and the module intake Pipe 20, each of the membrane module 10 to flow in order to discharge the foreign matter deposited on the membrane module 10 while water or air is discharged to the outside of the membrane module 10.

Hereinafter, each configuration of the present invention will be described in detail.

The separator module 10 has a plurality of flow holes 121 to take the treated water from the separator 11 and the separator 11 of the porous material in a tubular shape as shown in FIG. The formed water intake pipe 12 is included.

The separator 11 is not limited to the cross-sectional shape of the tubular shape, but preferably configured to have a circular tubular shape, which causes turbulence to be generated based on the shape of the separator 11 in the above-mentioned suction process. It is to prevent membrane contamination by being able to easily remove the foreign matter deposited on the separation membrane (11).

In addition, the separator 11 is to filter foreign matter from raw water as a porous material, but is not limited to the material, but preferably made of a porous material in a tubular shape including silica powder and alumina powder. Can be.

The separator 11 is made of high purity silica and alumina in powder form, and then mixed with an aqueous solution in which an organic binder is dissolved to form a wettable powder to facilitate molding. The silica powder and alumina are completed by molding the powder into a tubular shape using a press mold and cutting the powder into a required length.

Next, the micropores are formed through a sintering process. That is, by firing the organic matter between the powder through the calcination process to form micropores, and to withstand the pressure during the hydraulic pressure and air injection, it is possible to achieve a firm compression molding through the calcination process. The average pore of the separation membrane 11 formed in this way is reasonable to be limited to the range of 0.01㎛ 0.3㎛.

In addition, when forming the separator 11, it is reasonable that the mixing ratio of silica powder and alumina powder is blended in a ratio of 85:10 to 95: 1 by weight. The reason for this blending is that when the mixing ratio of the alumina powder is increased, the strength is excellent, but there is a problem that the resistance value of the separator 11 when the same flow rate is passed through the same area due to the decrease in the porosity is large, and the mixing ratio of the silica powder is greatly increased. In this case, the strength is somewhat lowered. However, since the strength is small and the resistance value can be reduced, it is limited as described above.

The water intake pipe 12 has a configuration in which a plurality of flow holes 121 are formed inside the separation membrane 11 so that the treated water may be withdrawn from the separation membrane 11 during the suction process. 20) to flow the treated water, during the backwashing step is to introduce water or air from the module intake pipe 20 to discharge the water or air to the outside of the separation membrane (11).

As shown in FIGS. 3 and 4, the intake pipe 12 has a tubular intake pipe body 122 and the intake pipe body 122 having a diameter smaller than the intake pipe body 122 at both ends of the intake pipe body 122 ( 123 is configured such that both ends of the intake pipe body 122 and the intake pipe screw 123 is exposed at both ends of the separator 11 (membrane assembly) to communicate with the module intake pipe 20 to be described below. While easy assembly is possible.

In addition, the inner periphery of the separation membrane 11 and the outer periphery of the intake pipe 12 are formed so that a certain clearance is formed to ensure a smooth flow of the fluid and at the same time the load acting on the separation membrane (11) It is preferable that the solid membrane module 10 is formed by supporting the 12 so that the coupler 13 is configured as shown in FIG. 2.

The coupler 13 has a hollow 131 formed therein so that the hollow 131 inserts the intake pipe 12 so that the insertion grooves 132 are formed at upper and lower ends thereof, respectively. 132 is to be inserted into the lower and upper ends of the membrane 11 assembled up and down.

That is, the intake pipe 12 is internally formed by the coupler 13 to form a predetermined gap, and at the same time, the separation membrane 11 can be assembled up and down, and in particular, the separation membrane 11 and the intake pipe 12. It is possible to control the deformation of the separation membrane 11 by enabling load transfer therebetween.

The membrane module 10 is fastened to a pair of module intake pipe 20 as shown in Figure 3 to form a module cassette, the module intake pipe 20 is a tubular shape in Figure 3, such as a square tube Is being presented.

The module intake pipe 20 has a pair of module fastening holes 21 formed at a position where the membrane module 10 is fastened in a longitudinal direction, and the water intake pipe body 122 penetrates through one module fastening hole 211. While the intake pipe screw part 123 penetrates the other module fastening hole 212, the membrane module 10 is assembled to the module intake pipe 20 by a nut coupling (n) to the intake pipe screw part 123. To form a module cassette.

The membrane fastening tube 212 penetrates the module fastening hole 211 so that the flow hole 121 is positioned inside the module intake tube 20, thereby separating the membrane module 10 and the module intake tube 20. Are mutually in communication with each other, and the water inlet pipe screw part 123 penetrates through the module fastening hole 212 so as to be a nut coupling (n). To communicate with each other.

Meanwhile, in the module cassette, the module fastening hole 211 and the water intake pipe body 122 are formed to communicate with each other during the fastening between the membrane module 10 and the module intake pipe 20 to form a watertight joint. As shown in 4, the first sealing hole 70 is to be placed, and the second sealing hole 80 is to be placed between the module fastening hole 212 and the intake pipe screw 123.

The first sealing hole 70 has a hollow 71 formed therein so that the water intake pipe body 122 is inserted into the inner circumference of the hollow 71 and the first insertion part protrudes while the outer circumference is tapered at one end thereof. 72 is formed and the other end portion is formed so that the edge groove 73 is inserted into the end of the separation membrane (11).

The hollow 71 allows the inner circumferential edge of the separation membrane 11 and the outer circumferential edge of the water intake pipe 12 to be held at a predetermined clearance, and based on the tapered shape of the first insertion unit 72. The first inserting portion 72 is inserted into the module fastening hole 211 to secure the watertightness from the module fastening hole 211 by pressurization, and the inner peripheral edge of the separation membrane 11 by the edge recess 73. And the outer periphery of the water intake pipe 12 is formed so that the separation membrane 11 is mounted on the outer periphery of the module intake pipe 20.

In addition, the second sealing hole 80 has a hollow 81 formed therein so that the water intake pipe screw portion 123 is inserted into the inner circumference of the hollow 81 and the outer circumferential edge is tapered at one end thereof. Insertion portion 82 is formed and the other end so that the head 83 is formed to be caught on the outer surface of the module fastening hole (212).

The hollow 81 is used to hold the position of the intake pipe screw 123, and the second inserting portion 82 is formed in the module fastening hole 212 based on the tapered shape of the second inserting portion 82. The watertightness from the module fastening hole 212 is secured by pressurization while the head is inserted, and the head 83 opens the module intake pipe 20 of the module fastening hole 212 by a nut coupling n. By pressurizing, watertightness is ensured in the module fastening hole 212.

The membrane module 10 and the module intake pipe 20 are fastened by the first sealing hole 70 and the second sealing hole 80 to ensure watertightness at the joint, thereby reducing the pressure loss in the suction process and the backwashing process. This is to prevent the efficiency from being lowered.

In addition, the first sealing hole 70 and the second sealing hole 80 hold the clearance between the separation membrane 11 and the intake pipe 12 at both ends of the membrane module 10 to allow load transfer between the two components. This will also serve to provide a robust membrane module (10).

Meanwhile, as shown in FIGS. 3 and 4, the module intake pipe 20 has a tubular module intake pipe body 22 and both ends of the module intake pipe body 22 having a diameter smaller than that of the intake pipe body and at least one intake port. 231 is formed of the module intake pipe inserting portion 23 and the module intake pipe screw portion 24 formed at the end of the module intake pipe inserting portion 23 is a plurality of module cassettes to the frame intake pipe (30) When fastening, the module intake pipe 20 and the frame intake pipe 30 to be in a structure that communicate with each other.

To this end, the frame intake pipe 30 is presented in a tubular shape in the shape of a square tube, and the plurality of cassettes are longitudinally connected to the frame intake pipe 30 at positions where the module intake pipe 20 is fastened, respectively. A hole 31 is formed in a pair, and the module intake pipe inserting portion 23 penetrates through the one cassette fastening hole 311 so that the module intake pipe screw portion 24 penetrates the other cassette fastening hole 312 so that the module is intake. The module intake pipe 20 (module cassette) is assembled to the frame intake pipe 30 by a nut coupling n to the pipe screw portion 24.

The module intake pipe 20 and the frame intake pipe 20 may pass through the cassette intake hole 311 so that the intake port 231 is positioned inside the frame intake pipe 30. 30) is to be in communication with each other, the module intake pipe screw portion 24 to pass through the cassette fastening hole 312 to be a nut coupling (n) by the module intake pipe 20 both ends of the frame taking It is to be fastened while communicating with each other in the pipe (30).

In this case, the connection between the module intake pipe 20 and the frame intake pipe 30 to communicate with each other but to form a tight joint is formed between the cassette fastening hole 311 and the module intake pipe insert 23 As shown in 4, the third sealing hole 90 is to be placed, and the above-mentioned second sealing hole 80 is to be placed between the cassette fastening hole 312 and the module intake pipe screw part 24. .

The third sealing hole (90) has a hollow (91) formed therein so that the outer periphery is tapered as the module intake pipe inserting portion (23) is inserted into the inner circumference of the hollow (91). 311) and the module intake pipe insertion portion 23 is to be placed.

The module 91 may be firmly fixed to the inside of the frame intake pipe 30 by the hollow 91, and the cassette fastening hole 311 may be pressurized based on a tapered shape of an outer circumference thereof. This ensures watertightness.

In addition, the second sealing hole 80 is to hold the position of the module intake pipe 20 by the hollow 81, the cassette fastening hole (based on the tapered shape of the second insertion portion 82) The watertightness from the cassette fastening hole 312 is secured by pressurization while the second inserting portion 82 is inserted into 312, and the head 83 is fastened to the cassette fastening hole 312 by a nut coupling n. The watertightness is secured in the cassette fastening hole 312 by pressing the frame intake pipe 30 of the portion.

When the module intake pipe 20 and the frame intake pipe 30 are fastened by the third sealing hole 90 and the second sealing hole 80, the watertightness is ensured at the joint, so that the pressure is lost in the suction process and the backwashing process. This is to prevent the efficiency from being lowered.

On the other hand, the present invention also provides a sewage and wastewater treatment apparatus, characterized in that the submerged membrane module assembly (1) is configured in the aerobic tank.

5 shows an embodiment of the bar, the wastewater treatment apparatus of the present embodiment includes an anaerobic tank, an aerobic tank, and a degassing tank, and shows an example in which two immersion type membrane module assemblies (1) are installed in the aerobic tank. have.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be defined by the claims.

1: submerged membrane module assembly 10: membrane module
11: separator 12: water intake pipe
20: module intake pipe 30: frame intake pipe

Claims (9)

Assembly of a plurality of membrane modules including a separator of a porous material in a tubular shape and a water intake tube having a plurality of flow holes formed therein to take out the treated water from the separator and a coupler disposed between the separator and the intake tube. Constituted by
The coupler has a hollow formed therein so that the hollow inserts the intake pipes so that upper and lower inserting grooves are formed, respectively, so that the lower and upper ends of the separation membrane assembled to the inserting groove are inserted. Immersion type ceramic separator module assembly.
delete delete The method of claim 1,
The plurality of membrane modules are assembled in a tubular module intake tube to form a module cassette, and the plurality of module cassettes are assembled in a tubular frame intake tube, and the suction pipe and the back washing tube are connected to the frame intake tube.
The intake pipe is composed of a tubular intake pipe body and the intake pipe screw portion having a diameter smaller than the intake pipe body at both ends of the intake pipe body, the module intake pipe is formed in a pair of module fastening holes to the one module fastening hole Immersion type ceramic separator module characterized in that the separator module is assembled to the module intake pipe by the nut coupling to the intake pipe screw through the intake pipe body through the other module fastening hole to form a module cassette Assembly.
5. The method of claim 4,
The module intake pipe is formed at the end of the module intake pipe body and the module intake pipe insert portion and the module intake pipe body having a diameter smaller than the intake pipe body and at least one intake port is formed at both ends of the module intake pipe body; It consists of a module intake pipe screw portion, the frame intake pipe is formed in a pair of fasteners of the cassette through the module intake pipe inserting portion through one cassette fastening hole while the module intake pipe screw portion penetrates the other cassette fastening hole through the module intake pipe screw portion Immersion type ceramic separator module assembly, characterized in that the module cassette is assembled to the frame intake pipe by a nut.
5. The method of claim 4,
The module intake pipe is formed in a pair of module fastening holes to penetrate the water intake pipe body in one module fastening hole, a hollow is formed inside the water intake pipe body is inserted into the hollow inner circumference and the outer peripheral edge tapered at one end Submerged ceramic separator module assembly, characterized in that the first insert is formed to protrude and the other end is formed with a first sealing hole is formed in the rim groove in which the end of the separator is inserted.
6. The method of claim 5,
The water intake pipe screw portion and the module water intake pipe screw portion are nut-coupled to the module fastening hole and the cassette fastening hole, respectively, and a hollow is formed therein, so that the water intake pipe screw portion and the module water intake pipe screw portion are inserted into one end of the hollow inner circumference. The submerged ceramic separator module assembly, characterized in that the outer periphery is formed with a second insertion portion protruding and the other end portion is formed with a second sealing hole is formed on the other end of the module fastening hole and the cassette fastening hole.
6. The method of claim 5,
Cassette fastening holes are formed in a pair of frame intake pipes so that the module intake pipe insertion part penetrates through one cassette fastening hole, and a hollow is formed therein so that the outer periphery of the module intake pipe is inserted into the hollow inner periphery. Is configured to immersed ceramic separator module assembly, characterized in that the third sealing hole is arranged between the cassette fastening hole and the module intake pipe insert.
The sewage and wastewater treatment apparatus according to any one of claims 1 and 4 to 8, wherein the submerged ceramic separator module assembly is configured in an aerobic tank.

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