KR101241950B1 - Hollowfiber membrane module for water treatment - Google Patents

Abstract

PURPOSE: A hollow fiber membrane module for water treatment is provided to extend the washing cycle of hollow fiber membranes by preventing sludge and adulteration from being concentrated between the hollow fiber membranes, and to enable users to easily attach and detach module heads including the hollow fiber membranes. CONSTITUTION: A hollow fiber membrane module for water treatment comprises plural hollow fiber membranes(10), plural module heads(20), an integrated water collection head, and plural air nozzles(36). One end of the hollow fiber membranes is sealed, and the other end of the hollow fiber membranes is opened. The module heads include plural connection holes(21) on both longitudinal ends which are connected to the opened ends of the hollow fiber membranes. Central holes connected to the connection holes are installed in the module heads, and a water collection port connected to the central holes is located on one ends of the module heads.

Description

Hollowfiber membrane module for water treatment

The present invention relates to an immersion type hollow fiber membrane module for dipping a solid and fluid such as sludge or contaminants by directly depositing in a fluid tank containing a fluid containing sludge or contaminants, and more particularly, in a fluid containing sludge or contaminants. A plurality of hollow fiber membranes having a thread shape to filter solids and suck only fluid, a module head for collecting the fluid sucked from the plurality of hollow fiber membranes, and a fluid collected from the plurality of module heads are collected again into a central hole. Field of the Invention The present invention relates to a hollow fiber membrane module for water treatment including an integrated collection head for transferring to an outside of a fluid tank.

The biggest problem to be solved in the recent water treatment filtration module process using a membrane is the reduction of permeability due to the membrane contamination. In other words, it must be possible to maintain a high permeability for a long time to exhibit the effect of reducing the processing cost or maintenance cost per unit treatment amount.

In addition, various types of membrane modules have been developed to solve the membrane contamination problem as described above, and various water treatment filtration modules such as a cross flow method or a dead end method have been developed.

Specifically, the method using the immersion-type hollow fiber membrane module for water treatment is to immerse the hollow fiber membrane module for water treatment directly in the fluid tank to be treated, and to apply the vacuum to the hollow fiber membrane (hollow fiber membrane) to separate the fluid through the hollow fiber membrane. will be. This method can reduce the manufacturing cost of the membrane module, there is an advantage that can reduce the facility cost or operating cost because no equipment for the circulation of the fluid required for the existing separation process.

In connection with the above, the representative immersion type hollow fiber membrane module for water treatment in recent years, as shown in Figure 1, both ends of the membrane formed hollow of the hollow fiber membrane fixed to the two module heads using an adhesive such as epoxy, two modules It is designed to collect fluid (called 'permeate') from which sludge or contaminants have been removed from the head. However, the prior art has a problem that the sludge or contaminants are concentrated on the hollow fiber membrane adjacent to the upper module head by the air bubbles moving from the bottom to the top.

Another embodiment of the immersion type hollow fiber membrane module for water treatment was configured to fold one hollow fiber membrane into a U-shape and fix both ends to one module head as shown in FIG. 2. However, the prior art has a problem that a large amount of coarse contaminants (eg, hair, leaves, fibers, vinyl, etc.) or deposited sludge is bonded between the U-shaped hollow fiber membrane, buoyancy of air bubbles sprayed from the bottom to prevent contamination There was a problem in that the condensate accumulates intensively on the module head to which the hollow fiber membrane is bonded.

The contaminants increase the tension of the hollow fiber membrane attached to the module head with an adhesive such as epoxy, causing breakage (single yarn) of the hollow fiber membrane, completely losing the separation function of the hollow fiber membrane, or deteriorating the movement of the hollow fiber membrane in the untreated fluid. There is a problem that the pollution prevention effect by the air cleaning is sharply lowered.

In addition, Korean Patent No. 10-0732436 relates to a membrane filter for water treatment, which is inserted into the head member by a head member having a permeate collection chamber with a permeate outlet and an end opened toward the permeate collection chamber. A membrane filter for water treatment comprising at least one fiber bundle consisting of a closed capillary membrane at the other end has been proposed, but it has not solved the problem of depositing sludge or contaminants on the capillary membrane corresponding to the separator, and continued research and development to solve this problem. This is required.

The present invention has been made to improve the problems according to the prior art of the hollow fiber membrane module for water treatment, the module using a conventional hollow fiber membrane between the hollow fiber membrane and the hollow fiber membrane or the module head and hollow at both ends of the hollow fiber membrane for clamping the hollow fiber membrane Sludge or contaminants are easily deposited between the deserts, and as a result, clogging of the hollow fiber membranes is accelerated, resulting in a shorter cleaning cycle of the hollow fiber membranes.

The length of the hollow fiber membrane is relatively long, and the suction force applied from the module head to the hollow fiber membrane is insufficiently applied to the end of the hollow fiber membrane, resulting in a sharp drop in filtration capacity at the end of the hollow fiber membrane. The main purpose is to provide.

The present invention is to realize the desired object as described above,

A plurality of hollow fiber membranes having the other end closed and one end opened; A plurality of communication holes for communicating and clamping each side of the plurality of hollow fiber membranes are provided on both sides of the longitudinal direction, and has a central hole communicating with the plurality of communication holes therein, and at one end of the catchment port communicating with the central hole. A plurality of module heads; Integrated catchments having a plurality of individual catches communicated with each of the catch ports of the plurality of module heads in the longitudinal direction, and having a central hole communicating with the plurality of individual catches, and having an integrated catch port communicating with the central hole at one end. It proposes a hollow fiber membrane module for water treatment comprising a head.

The hollow fiber membrane module for water treatment according to the present invention presented as described above allows the other end of the hollow fiber membrane to freely move in a fluid containing sludge or contaminants through the hollow fiber membranes provided at one end of each side communication with both sides of the module head. The sludge or contaminants are not concentrated between the hollow fiber membranes and the hollow fiber membranes, thereby prolonging the cleaning cycle of the hollow fiber membranes, thereby obtaining an effect of solving the early clogging problem of the hollow fiber membranes, which is a problem of the conventional immersion membrane apparatus. :

By fastening a plurality of module heads provided with hollow fiber membranes so as to communicate with one integrated collection head, the module head can be easily detached from the integrated collection head, and the plurality of module heads and the integrated collection heads are assembled in one assembly. It can be configured to achieve the effect of facilitating packaging, transportation and assembly:

Only one end of the hollow fiber membrane is fastened to communicate with the module head and the other end is freely movable in the fluid containing sludge or contaminants, so that the air bubbles supplied from the lower part of the fluid tank can easily move the hollow fiber membrane, Sludge or contaminants adsorbed on the surface of the swells naturally spontaneously obtain a natural cleaning effect of the hollow fiber membrane.

1 to 2 is a partial perspective view showing a hollow fiber membrane module for water treatment according to the prior art.
Figure 3 is a partial perspective view showing a module head and a hollow fiber membrane of the hollow fiber membrane module for water treatment according to a preferred embodiment of the present invention.
Figure 4 is a partial cross-sectional perspective view showing a module head of the hollow fiber membrane module for water treatment according to a preferred embodiment of the present invention.
Figure 5 (a) to (b) is a partial perspective view showing the integrated collection head of the hollow fiber membrane module for water treatment according to a preferred embodiment of the present invention.
6 to 7 is a perspective view showing the coupling between the module head and the integrated collecting head of the hollow fiber membrane module for water treatment according to a preferred embodiment of the present invention.
8 to 10 is a perspective view showing the coupling between the fixing cover and the auxiliary fixing cover of the hollow fiber membrane module for water treatment according to a preferred embodiment of the present invention.
Figure 11 (a) to (b) is a partial perspective view showing a module head of the hollow fiber membrane module for water treatment according to a preferred embodiment of the present invention.

The present invention relates to a hollow fiber membrane module for immersion type water treatment that separates fluid from solids such as sludge or contaminants by directly depositing in a fluid tank containing fluid containing sludge or contaminants, the other end of which is closed, and one end of which is open. A plurality of hollow fiber membranes 10 having; A plurality of communication holes 21 communicating with one side of the plurality of hollow fiber membranes 10 and clamping are provided on both sides of the longitudinal direction, and a central hole 22 communicating with the plurality of communication holes 21 therein. A plurality of module heads 20 having a water collecting port 23 communicating with the central hole 22 at one end thereof; It is provided with a plurality of individual catches 31 communicated with each of the catches 23 of the plurality of module heads 20 in the longitudinal direction, and has a central hole 32 communicated with the plurality of individual catches 31. It is related to the hollow fiber membrane module for water treatment, including; integrated catch head 30 having an integrated catch port 33 in communication with the central hole 32 at one end.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described more fully hereinafter with reference to the accompanying drawings, in which preferred embodiments of the invention are shown.

Specifically, the plurality of hollow fiber membranes 10 is configured to have the other end closed and one end of the open state, the hollow fiber membrane of the general filtration (MF, Micro filtration) or ultrafiltration (UF, Ultra filtration) (10) is used. In addition, the hollow fiber membrane 10 is configured in a thread form of 0.2 ~ 3mm, the inside is provided with a hollow in which the fluid can flow in the longitudinal direction. In addition, one side of the hollow fiber membrane 10 is clamped (fastened) so that the communication hole 21 of the following module head 20 and the hollow of the hollow fiber membrane 10 can communicate, and the other side using an adhesive, heat treatment or other polymer It is a closed finish. At this point, the finished part must be pressure, temperature, or physically stable.

In addition, the plurality of module heads 20 includes a plurality of communication holes 21 communicating at one side of the plurality of hollow fiber membranes 10 and clamped on both sides of the longitudinal direction, respectively, and a plurality of communication holes 21 therein. ) Having a central hole 22 in communication with one end, and having a water collecting port 23 in communication with the central hole 22 at one end, sludge or contaminants sucked from the plurality of hollow fiber membranes 10 as shown in FIG. Collects the separated fluid (hereinafter referred to as 'separation water').

That is, each of the plurality of communication holes 21 formed in the longitudinal direction of both sides of the module head 20 formed of a circular, elliptical or polygonal is fastened to one end of each of the plurality of hollow fiber membranes 10, and the hollow fiber membrane 10 Receiving water from the hollow formed in the receiving. At this time, the coupling between the communication hole 21 and one end of the hollow fiber membrane 10 may have any configuration so that the separation water of the hollow fiber membrane 10 can be stably introduced into the communication hole 21, It is preferable to configure the clamping using a heat treatment or other polymer.

In addition, the central hole 22 which is configured in a hollow shape inside the module head 20 and communicates with the plurality of communication holes 21 and collects the separated water introduced from the plurality of communication holes 21 communicates as shown in FIG. 4. It has a larger internal diameter than the hole 21 and collects the separated water supplied from the plurality of communication holes 21 to be collectively transferred to the water collecting port 23.

In connection with the above, at one end of the module head 20 is provided with a water collecting port 23 in communication with the central hole 22 to draw out the separated water collected in the central hole 22 to the outside of the module head 20. And the other end is closed so that the separation water collected in the central hole 22 does not escape to the outside of the module head (20). At this time, the other end of the module head 20 is a certain portion of the fluid tank, when the module head 20 is installed in the longitudinal direction horizontal to the ground, as shown in Figure 11 of the fixed cover 40 or the auxiliary fixing cover 45 The module head fixing part 24 may be provided to be firmly fixed to a predetermined portion.

That is, the hollow fiber membrane sag prevention bar 50 is configured to traverse a pair of fixing cover 40, respectively, both ends are fastened to a predetermined portion of the inner surface of the pair of fixing cover 40, respectively. At this time, the hollow fiber membrane sag prevention bar 50 is formed in a rod-like or plate-like, formed across a pair of fixing cover 40 at a position corresponding to a predetermined portion of the height formed by the plurality of hollow fiber membrane (10) Preferably, the hollow fiber membrane deflection prevention bar 50 of the above configuration allows the hollow fiber membrane 10 having the other end to be unfixed to maintain a relatively constant interval in the horizontal direction, and the hollow fiber membrane 10 It exerts the effect of being struck down by gravity or buoyancy to prevent tangling with each other.

In addition, the integrated catch head 30 is provided with a plurality of individual catches 31 communicating with each of the catches 23 of the plurality of module heads 20 in the longitudinal direction, and communicates with the plurality of individual catches 31 therein. It has a central hole (32), which has an integrated water collecting port 33 in communication with the central hole 32 at one end, collecting the separated water collected in each of the plurality of module heads 20 again to the outside of the fluid tank It is a structure for drawing out.

That is, the plurality of individual catches 31 are provided on one side of the integrated catch head 30 in the longitudinal direction of the integrated catch head 30, and each communicate with each of the catch ports 23 of the module head 20. Then, the separated water collected in the central hole 22 of the module head 20 is drawn out. In addition, the central hole 32 of the integrated catchment head 30 has a plurality of individual catches 31 all communicate with each other, and the individual catches 31 are formed in the longitudinal direction of the integrated catcher head 30 inside the integrated catcher head 30. The separated water received at the) is transferred to the integrated water collecting port 33 provided at one end of the integrated water collecting head 30.

At this time, it will be apparent that the central hole 32 of the integrated collection head 30 should have a separation water capacity to accommodate all the separation water received from each of the plurality of individual collection ports 31.

That is, the integrated collection port 33 provided at one end of the integrated collection head 30 is connected to the separation water suction device (suction pump or backwash pump) configured at the outside of the fluid tank so that the separation water from the integrated collection head 30 to the outside of the fluid tank. It provides a suction force to be drawn out, the suction force of the suction device is the integrated catch 33, the central hole 22 of the integrated catch head 30, individual catch 31, the catch 23, the module head 20 Sequentially applied to the hollow of the central hole 22, the communication hole 21 and the hollow fiber membrane (10) of the) is applied to the fluid containing the sludge or contaminants of the fluid tank located outside the hollow fiber membrane (10), Separation of sludge or contaminants provides a force that allows only the separation water to be sucked into the hollow of the hollow fiber membrane 10, and the separation water sucked into the hollow of the hollow fiber membrane 10 to the outside of the fluid tank through the integrated collection port 33. It is also used as a conveying force.

In addition, the integrated collection head 30 according to the present invention has an air inlet 34 at the other end as shown in FIG. 5, and an air passage 35 communicating with the air inlet 34 at the outside of the central hole 32. It is provided in the longitudinal direction of the integrated collection head 30, and both sides of the longitudinal direction may be configured to further include a plurality of air nozzles 36 in communication with the air passage (35).

That is, the air inlet 34, the air passage 35 and the air nozzle 36 injects air into the fluid tank in which the hollow fiber membrane module for water treatment according to the present invention is embedded, and the hollow fiber membrane 10 by the injected air bubbles. It provides the effect of removing sludge or contaminants adhering to the surface.

Specifically, the air inlet 34 is provided at a predetermined portion of the other end of the integrated collection head 30 to receive air generated by a general air generator outside the fluid tank. In addition, the air passage 35 receiving air from the air inlet 34 is provided in the longitudinal direction corresponding to one end at the other end of the integrated collecting head 30, the integrated collecting head corresponding to the outside of the central hole 32 ( It is configured to be provided at a predetermined portion of 30).

In addition, the plurality of air nozzles 36 communicating with the air passage 35 have a predetermined interval in the longitudinal direction of the integrated collection head 30 and are formed on the outer surface of the integrated collection head 30, and the air passage 35 ) Into the fluid containing sludge or contaminants. At this time, the air nozzle 36 may be configured in any form as long as it can supply a predetermined air in the form of air bubbles in the air passage 35, but when the air is not supplied from the air inlet 34, the fluid of the fluid tank It may be configured in the form of a solenoid so that the back flow into the air path 35 through the air nozzle 36.

In addition, the air nozzle 36 is configured to have a predetermined interval on both sides in the longitudinal direction of the integrated collection head 30, the air discharged from the air nozzle 36 is provided with hollow on both sides of the module head 20 It is preferable to configure so that it can be supplied to the desert (10).

Specifically, the integrated catching head 30 has a predetermined length from one end to the other end, and has a central hole 32 formed in the longitudinal direction therein to separate the separated water drawn out from the plurality of individual catches 31. And the air is supplied to the air inlet 34 through the air passage 35 provided in the longitudinal direction on the outside of the central hole 32 on the basis of the separation wall 37 formed in the longitudinal direction of the integrated collection head 30. It is configured to supply the received air as the air nozzle 36 into the fluid tank.

That is, the integrated collection head 30 is configured in a double pipe form to transfer the separation water to the central hole 32 of the inner hollow, it is preferably configured to transfer the air to the air passage 35 of the outer hollow.

In connection with the above, the integrated collection head 30 according to the present invention is located in a portion corresponding to the lower portion of the fluid tank, the air supplied into the fluid tank from the air nozzle 36 provided in the integrated collection head 30 The droplet is preferably configured to rise from the bottom of the fluid tank to the upper direction and to remove sludge or contaminants attached to the surface of the hollow fiber membrane 10.

That is, the air supplied into the fluid tank through the air nozzle 36 is raised from the bottom of the fluid containing the sludge or contaminants in the form of air bubbles. At this time, the rising air bubble collides with the hollow fiber membrane 10, and a predetermined turbulence is formed in the fluid by the shaking of the hollow fiber membrane 10, and only one end thereof is clamped to the module head 20 by the formed turbulence. The other end and the body of the hollow fiber membrane 10 is shaken up, down, left and right so that sludge and contaminants attached to the surface of the hollow fiber membrane 10 fall. As a result, the hollow fiber membrane module for water treatment according to the present invention can obtain the effect of lengthening the cleaning cycle of the hollow fiber membrane 10, and the contact area between the hollow fiber membrane 10 and the air bubbles as compared to the conventional hollow fiber membrane module for water treatment. By widening the small amount of air supply, high cleaning effect and energy efficiency for air supply can be obtained.

In addition, the hollow fiber membrane module for water treatment according to the present invention forms a predetermined area, as shown in Figure 8 to 10, a pair of fixed cover 40 is a predetermined portion is fastened to each of both ends of the integrated collection head 30, respectively )Wow; A side surface of the horizontal slope ('hollow fiber membrane module for water treatment') by forming a predetermined area, a pair of auxiliary fixing cover 45 is fastened to both ends of each of both ends of the fixing cover 40, respectively; Corresponding to all four sides) may be configured to be wrapped.

That is, the pair of fixed cover 40 is a configuration for stably maintaining the integrated collection head 30 to which the plurality of module heads 20 including the hollow fiber membrane 10 are fastened in the fluid tank. It is configured in the form of a plate having an area, one of the fixing cover 40 is fastened to one end of the integrated collection head 30, the other fixed cover 40 is the other end of the integrated collection head 30 It is fastened to and supports both sides of the integrated collection head (30).

At this time, the lower surface or any one side of the fixing cover 40 is configured to be supported on the lower surface or one side of the inside of the fluid tank, and the fixing cover 40 of the fixed cover 40 is fastened to one end of the integrated collection head 30 It is preferable to have an integrated catchment hole 41 to allow the integrated catcher 33 to be connected or penetrated at a predetermined portion, and to a predetermined portion of the fixed cover 40 fastened to the other end of the integrated catcher head 30. Preferably, the air inlet hole 42 for allowing the air inlet 34 to be connected or penetrated is provided.

In addition, the pair of auxiliary fixing cover 45 is configured to improve the holding force of the fixing cover 40, it is configured in the form of a plate having a predetermined area, the same direction as the longitudinal direction of the integrated collection head 30 It has a length, and each end is configured to be fastened to both ends of the fixing cover 40, respectively, so as to cover the horizontal slope around the integrated catch head 30 together with the fixing cover 40.

At this time, the fastening between the fixing cover 40 and the auxiliary fixing cover 45 is any one of the method of fitting fastening using a predetermined fastening groove (not shown) and the locking jaw (not shown) or bolt fastening using bolts and nuts. Can be used.

In addition, the present invention, when the fixed cover 40 is configured in the hollow fiber membrane module for water treatment, the hollow fiber membrane sag prevention bar 50 having the same length direction as the integrated collection head 30 between the pair of fixed cover 40 ) May further comprise one or more.

That is, the hollow fiber membrane sag prevention bar 50 is configured to traverse a pair of fixing cover 40, respectively, both ends are fastened to a predetermined portion of the inner surface of the pair of fixing cover 40, respectively. At this time, the hollow fiber membrane sag prevention bar 50 is formed in a rod-like or plate-like, formed across a pair of fixing cover 40 at a position corresponding to a predetermined portion of the height formed by the plurality of hollow fiber membrane (10) Preferably, the hollow fiber membrane sag prevention bar 50 of the above configuration allows the hollow fiber membrane 10 having the other end to be unfixed and free to maintain a relatively constant interval in the horizontal or vertical direction, and the hollow fiber membrane 10 ) Is struck downward by gravity or buoyancy to prevent tangling.

In addition, the fastening between the hollow fiber membrane deflection prevention bar 50 and the fixing cover 40 has a certain fastening relationship so that the hollow fiber membrane deflection prevention bar 50 can be firmly fastened to a predetermined portion of the inner surface of the fixing cover 40. 9, the fixed cover 40 has a fastening groove 43 to allow a predetermined portion of the distal end of the hollow fiber membrane deflection prevention bar 50 to be inserted therein, and the hollow fiber membrane deflection prevention bar 40. Both ends of the predetermined portion 50 is preferably inserted into the fastening groove 43 is fastened.

In addition, the fixing cover 40 or the auxiliary fixing cover 45 of the present invention may further comprise one or more vortex forming portion 60 having a shape protruding to a predetermined height on the inner surface.

That is, the vortex forming part 60 protrudes a predetermined length into the space formed by the fixing cover 40 or the auxiliary fixing cover 45 at a predetermined portion of the inner surface of the fixing cover 40 or the auxiliary fixing cover 45. It is configured in such a way that the turbulent fluid formed by the air bubbles discharged from the air nozzle 36 strikes the vortex forming unit 60 so that a more powerful turbulence can be formed.

At this time, the protruding length of the vortex forming unit 60 can be freely applied according to the judgment of those skilled in the art, and the turbulent flow of the fluid formed by the vortex forming unit 60 has the effect of shaking the hollow fiber membrane 10 more strongly. Thus, the effect that the sludge or contaminants adhered to the surface of the hollow fiber membrane 10 can be more easily dropped from the surface of the hollow fiber membrane 10 can be realized.

Hereinafter, the separation water generation procedure by the hollow fiber membrane module for water treatment of the present invention will be described.

First, the operator operates the air generator connected to the air inlet 34 to inject air bubbles into the fluid tank containing the fluid including sludge or contaminants. Thereafter, the suction device connected to the integrated water collecting port 33 is operated so that the suction power of the suction device is centered on the central hole 22 of the integrated water collecting head 30, the individual water collecting holes 31, the water collecting port 23, and the center of the module head 20. The holes 22, the communication holes 21, and the hollow fiber membranes 10 are sequentially applied to the hollows.

The suction force applied to the hollow fiber membrane 10 applies a suction force to the fluid containing the sludge or contaminants of the fluid tank located on the outside of the hollow fiber membrane 10, and sucks only the separated water except the sludge or the contaminant into the hollow.

Thereafter, the separated water introduced into the hollow of the hollow fiber membrane 10 is the communication hole 21, the central hole 22 of the module head 20, the collecting port 23, the individual collecting port 31, the integrated collecting head 30 Through the central hole 22 in sequence, it is drawn out of the fluid tank through the integrated water collecting port 33.

While the separation water is withdrawn from the hollow fiber membrane 10 to the integrated water collecting port 33 as described above, the air supplied to the air inlet 34 moves the air passage 35 and the air nozzle 36 sequentially to accommodate the fluid. The air injected into the fluid tank and injected into the fluid tank in the form of air bubbles shakes the body and the other end portion of the hollow fiber membrane 10 to remove sludge or contaminants attached to the surface of the hollow fiber membrane 10 from the hollow fiber membrane 10. Drop it.

In connection with the above, the separated water drawn out to the integrated drain by the hollow fiber membrane module for water treatment of the present invention is a reprocessing process for ultrapure water treatment such as reverse osmosis process, EDI process, ion exchange resin process or degassing tower process, etc. However, it can be recycled and used through other water recycling processes.

The above has been described with reference to a preferred embodiment of the present invention, but is not limited to the above embodiment, the person having ordinary skill in the art to which the present invention pertains through the above embodiments without departing from the gist of the present invention Can be implemented in a variety of changes.

10: hollow fiber membrane 20: module head
21: communication hole 22: central hall
23: catch port 24: module head fixing portion
30: integrated catch head 31: individual catch
32: central hall 33: integrated catchment
34: air inlet 35: by air
36: air nozzle 37: partition wall
40: fixed cover 41: integrated collection hole
42: air inlet hole 43: fastening groove
45: auxiliary fixing cover 50: hollow fiber membrane sag prevention bar
60: vortex forming part

Claims (5)

The other end is closed, and one end is a plurality of hollow fiber membrane 10 to maintain a constant interval in the horizontal direction in the open state;
A plurality of communication holes 21 communicating with and clamping the one end of each of the plurality of hollow fiber membranes 10 in an open state are provided at both sides in the longitudinal direction, and a center communicating with the plurality of communication holes 21 therein. A plurality of module heads 20 having a hole 22 and having a water collecting port 23 communicating with the central hole 22 at one end thereof;
It is provided with a plurality of individual catches 31 communicated with each of the catches 23 of the plurality of module heads 20 in the longitudinal direction, and has a central hole 32 communicated with the plurality of individual catches 31. An integrated catch head 30 having an integrated catch port 33 connected to the central hole 32 at one end thereof;
The integrated collecting head 30 has an air inlet 34 at the other end, and an air passage 35 communicating with the air inlet 34 on the outside of the central hole 32 in the longitudinal direction of the integrated collecting head 30. It is provided with, a plurality of air nozzles 36 in communication with the air passage 35 on both sides in the longitudinal direction; Hollow fiber membrane module for water treatment, characterized in that configured to have.
delete The method of claim 1,
The hollow fiber membrane module includes:
A pair of fixing covers 40 forming a predetermined area and having a predetermined portion fastened to each of both ends of the integrated collection head 30;
At least one hollow fiber membrane sag prevention bar 50 which is fastened to the inner surfaces of the pair of fixing covers 40 and has the same length direction as the integrated collection head 30;
Forming a predetermined area, a pair of auxiliary fixing cover 45 is fastened to both ends of each of both ends of the fixed cover 40; the horizontal slope by the water treatment, characterized in that the configuration is wrapped Hollow fiber membrane module.
delete The method of claim 3,
The fixing cover 40 or the auxiliary fixing cover 45,
The hollow fiber membrane module for water treatment, characterized in that it further comprises one or more vortex forming portion (60) having a shape protruding to a predetermined height on the inner surface.

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