JP2000197884A - Clogging preventing device of filter apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent the clogging of a hollow fiber membrane during filtering work in an apparatus for filtering a liquid high in the content of a suspended substance. SOLUTION: Raw water W1 is circulated to flow between a concn. and circulation tank 1 and a hollow fiber membrane module 2 and clear permeated water W2 is taken out of the hollow fiber membrane module 2. The raw water W1 circulated to flow also flows through a bypass piping 20 and fine air bubbles are mixed into the raw water W1 by the mixer 2 disposed on the bypass piping 20. These fine air bubbles collide with the inner surfaces of membranes or burst on the inner surfaces thereof when flow through the hollow fiber membranes in the hollow fiber membrane module 2 to generate burst vibration to remove the suspended substance bonded to the inner surfaces of the membranes.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for preventing clogging of a filtration device, and more particularly to a device for filtering highly contaminated liquid using a cylindrical membrane filter (hollow fiber membrane or ceramic membrane). The device is devised so that clogging of the filter can be effectively prevented.

[0002]

2. Description of the Related Art A hollow fiber membrane is known as a medium for microfiltration. This hollow fiber membrane is generally used in a relatively high-tech field such as a medical field, production of ultrapure water, and sterilization of tap water. That is, it is generally used to filter a low-contamination liquid. This is because the hollow fiber membrane has an extremely small pore diameter of 0.1 μm to 0.001 μm. Therefore, simply filtering a highly contaminated liquid will cause contaminants to adhere to the surface of the membrane or enter and adhere to the inside of the membrane. This is because clogging occurs and filtration becomes impossible.

[0003] The applicant of the present application has developed and commercialized a filtering device capable of filtering highly polluted liquids by using the above hollow fiber membranes by special measures. As will be described in detail later, this filtration device can remove contaminants (heavy metals, surfactants, ceramic fine particles, organic contaminants, etc.) in the liquid and solidify it, and can use the clarified liquid for recycling. It can be discharged to the outside without pollution.
Examples of highly polluted liquids include barrel polishing wastewater, glass polishing wastewater, semiconductor cutting wastewater, and suspended wastewater in the food field.

Here, an internal pressure circulation type filtration device developed by the present applicant and already commercialized will be described with reference to FIG.
In this filtration device, the concentration circulation tank 1 and the hollow fiber membrane module 2 are connected by a first piping system 3 and a second piping system 4, and a pump 5 is interposed in the first piping system 3. . Then, the raw water W1 supplied to the concentration circulation tank 1 is pumped to the hollow fiber membrane module 2 by the pump 5, and the raw water W1 flowing out of the hollow fiber membrane module 2 is returned to the concentration circulation tank 1 by the piping system 4. ing. Thus, the raw water W1 is circulated and circulated between the concentration circulation tank 1 and the hollow fiber membrane module 2.

[0005] In the piping system 3, a pre-filter 6 is interposed between the pump 5 and the hollow fiber membrane module 2. The prefilter 6 uses, for example, a wire mesh. As this wire mesh, the size of one mesh is, for example, 0.3 mm ^2, and the inner diameter area of the hollow fiber membrane (2 m
A wire mesh having a mesh smaller than m ² ) is used.

As shown in FIG. 3, the hollow fiber membrane module 2 is formed by arranging a plurality of hollow fiber membranes 2b in an outer cylinder 2a. Both ends of each hollow fiber membrane 2b are fixed inside the outer cylinder 2a by fixing materials 2c. The raw water W1 supplied from the module inlet 2d is supplied to each hollow fiber membrane 2d.
b, flows in the internal space of each hollow fiber membrane 2b, flows out of the outlet end face 2f of each hollow fiber membrane 2b, and flows out of the module outlet 2g to the outside.

[0007] The permeated water W2 that has permeated from the inner peripheral surface of each hollow fiber membrane 2b toward the outer peripheral surface and has been clarified is vertically moved between the outer peripheral surface of each hollow fiber membrane 2b and the inner peripheral surface of the outer cylinder 2a. And is collected in a space surrounded by the fixing member 2c and taken out through the piping system 7. That is, the permeated water W2 can be separated and taken out from the raw water 1.

Returning to FIG. 2, the description will be continued. The permeated water W2 taken out through the piping system 7 is stored in the permeated water receiving tank 8. On the other hand, the raw water W1 containing the pollutant is stored in the raw water storage tank 9, and is supplied to the concentration circulation tank 1 by the pump 10 via the piping system 11. Further, the concentrated water receiving tank 12
Is connected to the concentration and circulation tank 1 by a piping system 14 with a valve 13 interposed.

As described above, in this filtration device, the raw water W1 is circulated and circulated between the concentration circulation tank 1 and the hollow fiber membrane module 2 (circulation type), and the raw water W1 to which pressure has been applied is passed through the hollow fiber membrane. Since it is made to flow through the internal space of 2b (internal pressure type), it is called an "internal pressure circulation type" filtration device.

In the filtering device having the above-described structure, the filtering operation is performed by the following operation. Raw water W1 which is a highly polluted liquid (barrel polishing wastewater, glass polishing wastewater, semiconductor cutting wastewater, suspended wastewater in the food field, etc.) is stored in a raw water storage tank 9 arranged in an underground pit or the like of a factory. When performing the filtering operation, first, the raw water W1 is supplied from the raw water storage tank 9 to the concentration circulation tank 1 by the pump 10 with the valve 13 closed, for example, at a supply rate of 500 to 1000 liters / hour. Then, the pump 5 is started, and the raw water W1 is supplied to the concentration / circulation tank 1 → the pump 5 → the pre-filter 6 →
It is circulated and circulated along the circulation route of the hollow fiber membrane module 2 → concentration circulation tank 1.

At this time, the flow velocity (linear velocity) of the raw water W1 flowing in the internal space of each hollow fiber membrane 2b of the hollow fiber membrane module 2
The pumping force of the pump 5 for pumping the raw water W1 to the hollow fiber membrane module 2 is adjusted so that the speed is as high as 1.5 to 5 m / sec. At this time, the pressure of the raw water W1 at the module inlet 2d is, for example, 2.2 Kg / cm ² , and the pressure of the raw water W1 at the module outlet 2g is, for example, 0.6 Kg / cm ² . Further, by pumping the raw water W1 by the pump 5, the circulating flow rate of the raw water W1 circulating along the circulation path (the piping system 3 and the piping system 4)
Is set to, for example, 600 liters / minute.

The raw water 1 flowing out of the concentration circulation tank 1 and pumped by the pump 5 passes through the pre-filter 6 to remove large dust. The raw water W1 supplied to the hollow fiber membrane module 2 through the pre-filter 6 causes the internal space of each hollow fiber membrane 2b to flow at a high linear velocity (1.5 to 5 m / h).
Second). As described above, since the linear velocity is set to be high, the raw water W is formed in the internal space of each hollow fiber membrane 2b.
1 turbulently flows and collides violently with the membrane surface on the inner peripheral side, so that even when the highly contaminated raw water W1 is circulated in the hollow fiber membrane 2b, the hollow fiber membrane 2b is less likely to be clogged. I have. In other words, even if contaminants adhere to the inner peripheral membrane surface,
The turbulent flow scrapes off the deposits.

While the raw water W1 flows through the internal space of each hollow fiber membrane 2b, a part of the pressurized raw water W1 (a few% of the flow rate) in the raw water W1 The light is transmitted from the peripheral surface toward the outer peripheral surface. The permeated water is clear permeated water W2 from which pollutants have been removed. The permeated water W2 is supplied to a permeated water receiving tank 8 via a piping system 7.
Sent to The permeated water W2 stored in the permeated water receiving tank 8 is
Since it does not contain pollutants, it is reused or discharged out of the equipment without pollution.

After all, the raw water W1 is supplied to the hollow fiber membrane module 2
, The permeated water W2 is concentrated by an amount corresponding to the permeated water W2 which is taken out to the outside. Concentrated raw water W
1 returns to the concentration circulating tank 1 via the piping system 4. For this reason, the raw water W1 concentrated through the hollow fiber membrane module 2 returns to the concentration circulation tank 1, and the raw water W1 supplied from the raw water storage tank 9 is newly added.

When the filtering operation is to be stopped, first, the operation of the pump 10 is stopped while the operation of the pump 5 is continued. In this way, the raw water W1 is no longer supplied from the raw water storage tank 9 to the concentration circulation tank 1. on the other hand,
The raw water W1 circulates and flows along the circulation path of the concentration circulation tank 1 → the pump 5 → the prefilter 6 → the hollow fiber membrane module 2 → the concentration circulation tank 1. As the permeated water W2 is extracted from the circulating raw water W1 by the hollow fiber membrane module 2, the water content decreases and the concentration increases.

When the remaining amount of the raw water W1 remaining in the concentration circulating tank 1 becomes, for example, 50 to 100 liters, the operation of the pump 5 is stopped.

Next, the valve 13 is opened to concentrate the concentrated water W3 (water having a higher concentration of the raw water W1) remaining in the concentration circulating tank 1 through the piping system 14. It is sent to the water receiving tank 12 and stored. When all the concentrated water W3 has been sent to the concentrated water receiving tank 12, the valve 13 is closed. The concentrated water W3 stored in the concentrated water receiving tank 12 is dehydrated and solidified. The solidified sludge (pollutant) is disposed of in a pollution-free manner.

When the filtration operation is performed for a long period of time, pollutants adhere to the inner surface of the hollow fiber membrane 2b. In order to remove such contaminants attached to the surface of the hollow fiber membrane 2b, the following operation is performed. That is, after the filtration operation is stopped, the permeated water W2 is supplied to the module outlet 2g of the hollow fiber membrane module 2 by applying pressure through a pipe (not shown), and the permeated water W2 is directed from the outlet end face 2f to the inlet end face 2e. The inside of each hollow fiber membrane 2b is circulated at a high flow rate. The circulated water is drained from the module inlet 2d via a pipe (not shown).
That is, after the filtration operation is stopped, a backwashing operation (flushing) is performed to remove contaminants adhering to the membrane surface of the hollow fiber membrane 2b, thereby preventing clogging.

In addition to the method of performing the backwashing operation (flushing) with clean water, there is also a method of performing the backwashing operation (flushing) by cleaning with a chemical after stopping the operation, or using air.

If clogging cannot be eliminated even by a backwashing operation or the like, the hollow fiber membrane 2b has been replaced with a new one. Particularly when the pollution is severe, the hollow fiber membrane has to be replaced about once every three days.

[0021]

By the way, in the above-mentioned filtration apparatus, in order to prevent the hollow fiber membrane 2b from being clogged, the filtration operation must be temporarily stopped and a backwashing operation (flushing) must be performed. I had to. In other words, the adherence of pollutants due to aging is inevitable, and in order to prevent clogging, a back-washing operation (flushing) after stopping the filtration operation is required. Such a backwashing operation (flushing) was troublesome.

Accordingly, the applicant of the present application has repeatedly conducted experiments and studies on whether or not the phenomenon of pollutants adhering to the hollow fiber membrane itself can be prevented. If such a thing can be realized, a backwashing operation (flushing) or the like after stopping the filtration operation becomes unnecessary, and the continuous filtration operation time is extended and the life of the hollow fiber membrane is extended.

The present applicant has conducted the following experiment for the purpose of removing pollutants adhering to the inner peripheral surface of the hollow fiber membrane 2b during the filtration operation. That is, in the raw water W1 circulating along the circulation path of the concentration circulating tank 1 → pump 5 → prefilter 6 → hollow fiber membrane module 2 → concentration circulating tank 1, a fine sphere made of ceramic (having a diameter of 0.1 mm) 〜0.3 mm). By doing so, minute true spheres circulate inside the hollow fiber membrane 2b in a turbulent flow, and the true spheres collide with the inner peripheral surface of the membrane to remove contaminants adhering to the membrane surface. The experiment was performed with the expectation that it could be scraped off.

As a result of the above experiment, as a result, a large number of true spheres were clogged inside the hollow fiber membrane 2b, or true spheres entered the hollow fiber membrane 2b. In other words, it has been found that mixing of true spheres rather promotes clogging of the hollow fiber membrane 2b. As a result, the experiment failed.

In examining the above experiment, it was found that the following phenomenon occurred. In other words, when the lint-like pollutant circulates and circulates many times along the circulation path, the lint-like pollutant entangles other pollutants while being entangled, and its size grows. come. The large contaminants grown in this way may be larger than the inner diameter area of the hollow fiber membrane 2b, and most of them adhere and accumulate on the inlet end face 2e of the hollow fiber membrane 2b.

According to the present invention, in view of the current state of the filtration device having the above-described configuration, it is possible to remove contaminants adhering to the inner peripheral surface of a membrane filter such as a hollow fiber membrane during the filtration operation. An object of the present invention is to provide a maintenance-free clogging prevention device for a filtration device that can capture a growing pollutant and prevent clogging of a membrane filter such as a hollow fiber membrane.

[0027]

According to the present invention, there is provided a concentrating and circulating tank to which raw water containing pollutants is supplied, and a plurality of cylindrical membrane filters disposed inside an outer cylinder. The raw water supplied from the module inlet portion flows in from the inlet end surface of each membrane filter, flows through the internal space of each membrane filter, flows out from the outlet end surface of each membrane filter, and flows out of the module outlet portion to the outside. Along with
A first filter that connects a membrane filter module from which permeated water permeating from an inner peripheral surface to an outer peripheral surface of the membrane filter is separated and taken out from the raw water, and the concentration circulation tank and a module inlet of the membrane filter module; A pump for pumping the raw water toward the membrane filter module, and a second piping system for returning the raw water flowing out of a module outlet of the membrane filter module to the concentration circulation tank. In the filtration device comprising:
A part of the raw water flows in from the piping system and a bypass pipe for returning the raw water flowing back to the first piping system is disposed between the pump and the membrane filter module in the first piping system, The bypass pipe is provided with a mixer that generates fine bubbles in the raw water by mixing air into the raw water with an air pressure higher than the water pressure at the module inlet.

[0028] Further, in the constitution of the present invention, the mixer is characterized in that air is continuously or intermittently mixed into raw water.

Further, in the configuration of the present invention, a concentrating and circulating tank to which raw water containing pollutants is supplied, and a plurality of cylindrical membrane filters are arranged inside the outer cylinder, and are formed from the module inlet. The supplied raw water flows in from the inlet end face of each membrane filter, flows through the internal space of each membrane filter, flows out from the outlet end face of each membrane filter, flows out of the module outlet to the outside, and has the inner periphery of the membrane filter. Through a membrane filter module through which permeated water permeating from the surface toward the outer peripheral surface is separated and taken out from the raw water, and through a first piping system that communicates the concentration circulating tank with a module inlet of the membrane filter module. A pump for pumping the raw water toward the membrane filter module, and a condensing circuit for flowing the raw water flowing out of a module outlet of the membrane filter module. By disposing a wire mesh for separation in the concentration circulating tank in a filtration device comprising a second piping system returning to the tank, the concentration circulating tank is replaced with a first tank to which new raw water is supplied; And a second tank to which the raw water returned via the piping system is supplied. Further, a bag-shaped wire mesh having an open upper surface is arranged in the second tank, and the second piping system is The raw water returned via this is supplied from the upper surface of the bag-shaped wire mesh, and the mesh size of the separation wire mesh and the bag-shaped wire mesh is smaller than the inner diameter area of the membrane filter. It is characterized by the following.

[0030] Further, according to the structure of the present invention, the membrane filter comprises:
It is a hollow fiber membrane or a ceramic membrane.

[0031]

Embodiments of the present invention will be described below in detail with reference to the drawings. 2 and 3 are denoted by the same reference numerals, and duplicate description will be omitted.

FIG. 1 shows an apparatus for preventing clogging of a filtration device according to an embodiment of the present invention. As shown in FIG. 1, in the present embodiment, a bypass pipe 20 is disposed between the pump 5 and the hollow fiber membrane module (membrane filter module) 2 in the first piping system 3. For this reason, a part of the raw water W1 pumped from the pump 5 flows from the piping system 3 to the bypass piping 20, flows through the bypass piping 20, returns to the piping system 3 again, and then returns to the hollow fiber membrane module 2. Flowing in.

A mixer 21 is interposed in the bypass pipe 20. The mixer 21 includes a bypass pipe 2
The air is continuously or intermittently mixed into the raw water W1 flowing through the inside. At this time, the pressure of the mixed air is higher than the water pressure (for example, 2.2 kg / cm ² ) at the module inlet 2 d of the hollow fiber membrane module 2. In this way, by making the mixed air pressure higher than the water pressure at the module inlet 2d, the raw water W1 is prevented from spouting outside at the mixer 21 portion.

By mixing the raw water W1 with air by the mixer 21, fine bubbles are generated in the raw water W1.
These fine bubbles enter the hollow fiber membrane module 2 through the bypass pipe 20 and the pipe system 3.

On the other hand, the concentration circulation tank 1
The first tank 1a and the second tank 1
And a tank 1b. In the first tank 1a, a bag-shaped wire netting 32 having an open top surface and a peripheral surface (a peripheral surface formed of four surfaces) and a bottom surface is disposed.
A bag-shaped wire net 33 having an open upper surface, a peripheral surface (a peripheral surface formed of four surfaces), and a bottom surface is disposed in the upper surface.
The mesh size of the wire meshes 31 and 33 is smaller than the inner diameter area (2.0 mm ² ) of the hollow fiber membrane 2b.
3 mm ² . The mesh size of the wire mesh 32 is
It is wider than the inner diameter area (2.0 mm ² ) of the hollow fiber membrane 2b, for example, 3 mm ² .

The raw water W1 newly supplied from the raw water storage tank 9 to the concentration and circulation tank 1 via the piping system 11 flows into the upper surface of the wire mesh 32, passes through the wire mesh 32, and then flows into the first tank 1a. Like that. The raw water W1 flowing out of the hollow fiber membrane module 2 and circulating into the concentration circulation tank 1 via the piping system 4 flows into the upper surface of the wire mesh 33, and
3, and then flow into the second tank 1b.
The new raw water W1 that has flowed into the first tank 1a flows into the second tank 1b from the first tank 1a through the wire mesh 31.

The prefilter 6 used in the apparatus shown in FIG. 2 is unnecessary in this embodiment.

In the filtering apparatus according to the present embodiment having the above-described configuration, fine air bubbles are generated in the raw water W1 by mixing air into the raw water W1 by the mixer 21. The microbubbles enter the hollow fiber membrane module 2 through the bypass pipe 20 and the pipe system 3, and flow through the internal space of each hollow fiber membrane 2b. At this time, the microbubbles collide with the inner peripheral surface of each hollow fiber membrane 2b due to the turbulence of the raw water W1 flowing at high speed inside the hollow fiber membrane 2b. In addition, the microbubbles burst and rupture vibration (ultrasonic vibration) is generated.

As described above, the microbubbles collide with the membrane surface, or the bursting vibration (ultrasonic vibration) caused by the rupture of the microbubbles acts on the membrane surface, so that the contaminants adhering to the membrane surface are separated. At the same time, the adhesion of pollutants is less likely to occur. For this reason, pollutants adhere to the membrane surface.
The accumulation is prevented, and the prevention of clogging of the hollow fiber membrane 2b can be simultaneously performed while performing the filtration operation.

Depending on the state of the raw water W1 and the characteristics of the pollutants, air may be continuously or intermittently mixed into the raw water W1 by the mixer 21.

On the other hand, the raw water W1 newly supplied from the raw water storage tank 9 to the concentration circulation tank 1 flows into the first tank 1a after passing through the wire mesh 32, so that coarse dust (contaminant) is removed by the wire mesh 32. It is removed by filtration.

Among the trash (contaminant) contained in the raw water W1, the trash (contaminant) smaller than the mesh of the wire mesh 32 is transferred from the first tank 1a to the second tank 1b through the wire mesh 31. Is filtered and removed by the wire net 31 when flowing into the air.

Further, the garbage (contaminant) that has grown by circulating along the circulation path between the concentration circulation tank 1 and the hollow fiber membrane module 2 is filtered and removed by passing through the wire mesh 33. Is done. Further, in the internal space of the bag-shaped wire netting 33, the returned raw water W1 is supplied (dropped) from the upper surface of the wire netting 33, so that it is swirled and agitated, and the growth of dust due to entanglement or entrapment of dust (contaminant) is positively promoted. Promoted. As a result, dust (contaminants) actively grown in the wire mesh 33 can be filtered and removed by the wire mesh 33.

As described above, the garbage (contaminant) originally contained in the raw water W1 is removed by the wire meshes 32 and 31, and has been actively grown in the wire mesh 33 or grown by circulation and distribution. Garbage (pollutants) is a wire mesh 33
Thus, clogging of each hollow fiber membrane 2b can be effectively prevented.

In this embodiment, since the pre-filter 6 provided in the apparatus shown in FIG. 2 becomes unnecessary, pressure loss due to the pre-filter is eliminated, and the efficiency of the pump 5 is improved.

In the above embodiment, the hollow fiber membrane module is used as the membrane filter module. However, a ceramic membrane module in which a plurality of cylindrical ceramic membranes are arranged inside the outer cylinder may be used. Even in a filtration device using this ceramic membrane module, clogging can be prevented by applying the present invention.

[0047]

As described above in detail with the embodiments, in the present invention, fine bubbles are caused to flow through the internal space of each membrane filter (hollow fiber membrane or ceramic membrane) of the membrane filter module. Therefore, microbubbles collide with the membrane surface on the inner peripheral side of the membrane filter, or burst vibration caused by bursting of the microbubbles acts on the membrane surface, and contaminants adhering to the membrane surface can be peeled off. Prevention of clogging can be performed during the filtration operation. Thus, maintenance-free operation is not required, and clogging prevention operation (backwashing operation or the like) after the filtration operation is not required, the continuous filtration operation time is extended, and the life of the membrane filter is extended, and the replacement of the membrane filter is not required.

Further, according to the present invention, the trash originally contained in the raw water can be removed by the separating wire mesh arranged in the concentration circulation tank, and the raw water is swirled in the internal space of the bag-shaped wire mesh arranged in the second tank. -The garbage was allowed to grow by agitation, and the garbage that had become larger could be removed with a bag-like wire mesh. For this reason, clogging of the membrane filter (hollow fiber membrane or ceramic membrane) can be effectively prevented.

[Brief description of the drawings]

FIG. 1 is a configuration diagram showing a clogging prevention device of a filtration device according to an embodiment of the present invention.

FIG. 2 is a configuration diagram showing a current filtration device.

FIG. 3 is a configuration diagram showing a hollow fiber membrane module.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Concentration circulation tank 1a 1st tank 1b 2nd tank 2 Hollow fiber membrane module 2a Outer cylinder 2b Hollow fiber membrane 2c Fixing material 2d Module entrance part 2e Inlet end face 2f Exit end face 2g Module outlet part 3 Piping system 4 Piping system 5 Pump 6 Pre-filter 7 Piping system 8 Permeated water receiving tank 9 Raw water storage tank 10 Pump 11 Piping system 12 Concentrated water receiving tank 13 Valve 14 Piping system 20 Bypass piping 21 Mixer 31, 32, 33 Wire mesh W1 Raw water W2 Permeated water W3 Concentrated water

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) B01D 63/02 B01D 65/08 63/06 71/02 65/08 B01F 3/04 A 71/02 5 / 02 Z B01F 3/04 B01D 29/04 510C 5/02 530A 29/38 540 (72) Inventor Mitsuhiro Ogami 6-32, Futawahigashi, 6-chome, Funabashi-shi, Chiba Pref. Naoyuki Kato 3-8-2 Nihombashi, Chuo-ku, Tokyo F-term in Kuraray Co., Ltd. (Reference) 4D006 GA02 HA02 HA18 JA31A JA34A JA35A JA56A JA59A JA70A KA02 KA41 KA43 KB14 KC14 MA01 MC03 PB06 PB24 PC02 PC41 4D064 AA40 BC18 BC21 BC23 DC07 4 AC16 AE13

Claims (4)

[Claims] 1. A concentrating and circulating tank to which raw water containing pollutants is supplied, and a plurality of cylindrical membrane filters arranged and formed inside an outer cylinder, wherein the raw water supplied from a module inlet is formed. Flows from the inlet end face of each membrane filter, circulates through the internal space of each membrane filter, flows out of the outlet end face of each membrane filter, flows out of the module outlet, and from the inner peripheral face to the outer peripheral face of the membrane filter. A membrane filter module from which permeated water permeating toward the raw water is separated and taken out from the raw water; and a first piping system that communicates the concentration circulation tank with a module inlet of the membrane filter module,
A first pump for pumping the raw water toward the membrane filter module; and a second piping system for returning the raw water flowing out of a module outlet of the membrane filter module to the concentration circulation tank. A bypass pipe for returning the raw water flowing into the first piping system together with a part of the raw water flowing from the piping system, between the pump and the membrane filter module in the first piping system; The bypass pipe is provided with a mixer that generates fine bubbles in the raw water by mixing air into the raw water with an air pressure higher than the water pressure at the module inlet part. Prevention device. 2. The apparatus according to claim 1, wherein the mixer continuously or intermittently mixes air into the raw water. 3. A concentrating and circulating tank to which raw water containing pollutants is supplied, and a plurality of tubular membrane filters arranged and formed inside an outer cylinder, wherein the raw water supplied from a module inlet is provided. Flows from the inlet end face of each membrane filter, circulates through the internal space of each membrane filter, flows out of the outlet end face of each membrane filter, flows out of the module outlet, and from the inner peripheral face to the outer peripheral face of the membrane filter. A membrane filter module from which permeated water permeating toward the raw water is separated and taken out from the raw water; and a first piping system that communicates the concentration circulation tank with a module inlet of the membrane filter module,
A pump for pumping the raw water toward the membrane filter module; and a second piping system for returning the raw water flowing out of a module outlet of the membrane filter module to the concentration circulation tank. By disposing a wire netting for separation, the concentration and circulation tank is provided with a first tank to which new raw water is supplied, and a second tank to which raw water returned via the second piping system is supplied. And a bag-shaped wire mesh having an open upper surface is arranged in the second tank, and raw water returned via the second piping system is supplied from the upper surface of the bag-shaped wire mesh. The clogging prevention device for a filtration device, wherein the mesh size of the separation wire mesh and the bag-shaped wire mesh is smaller than the inner diameter area of the membrane filter. 4. The device for preventing clogging of a filtration device according to claim 1, wherein the membrane filter is a hollow fiber membrane or a ceramic membrane.