JP2003334551A - Membrane filtration device and membrane filtration method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To quickly and automatically restore at least 95% (of the maximum amount of water to be supplied) water supply capacity in a short time even when a membrane module is broken. <P>SOLUTION: A turbidity measurement means TuIR1, a cutoff valve V1, a return valve V11, membrane module valves V101, V102, V103, V104, and V105, and valve control means are provided. The valve control means, when the turbidity measurement means detects turbidity from the first filtration series 11, opens the return valve V11, closes the cutoff valve V1, and changes over a plurality of membrane modules M11, M12, M13, M14, and M15 in the first filtration series in turn to supply filtrate. The membrane module of high turbidity is detected by the turbidity measurement means, the membrane module valve of the detected membrane module is closed, and the membrane module valves of the other membrane modules are opened to supply filtrate. The filtrate is returned to a raw water tank. When no abnormal turbidity is found in the filtrate, the return valve is closed. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a membrane filtration device using a membrane module used in a water purification facility for purifying and supplying raw water taken from lakes and rivers, and particularly to turbidity management when the membrane module is damaged. The present invention relates to a membrane filtration device and a membrane filtration method in which only a damaged membrane module is stopped when the value exceeds a value and water supply from other membrane modules is continued.

[0002]

2. Description of the Related Art In recent years, there is concern about contamination of purified water by Cryptosporidium which is a pathogenic microorganism. For such a water source, the provisional guideline for Cryptosporidium specifies that the turbidity of the treated purified water should be 0.1 degrees or less. For this reason, the water treatment facility is further strengthening its monitoring of water turbidity.

Recently, a membrane filtration method which can obtain high quality water has been widely introduced to water purification. This membrane filtration method is not only a water purification method that facilitates automation of operation management of a water purification facility and also can eliminate labor shortage, but is also an excellent method that can remove Cryptosporidium. Further, in order to increase the amount of purified water, a multi-series system in which two or more series of membrane filtration devices are arranged in parallel has been adopted. Then, a turbidity measuring device for detecting the breakage of the membrane is installed for each series, and the treated water is constantly monitored.

FIG. 7 is a block diagram showing the outline of a conventional membrane filtration device (when there are four filtration series). In FIG.
When the membrane of the membrane module of the first filtration series 11 is damaged, the turbidity detected by the turbidity measuring instrument TuIR1 provided in the series increases, and the turbidity is, for example, 1 / of the provisional reference value.
When the temperature reaches 0.01 degree of 10 (referred to as a turbidity control value), the control means (not shown) closes the shutoff valve V1, and the other second filtration series 12, the third filtration series 13, and the fourth filtration series. Filtration series 14
The operation is to make membrane permeate by (maximum water supply of 75
% Water supply). After that, the first filtration series 1 in which the membrane was damaged
After manually inspecting the membrane module in 1 to determine the damaged membrane module, the damaged membrane module was renewed, and then the suspended matter remaining in the pipe was washed and then returned to 100% operation. ing.

FIG. 8 is a diagram showing the water supply capacity over time in the conventional example. 7 and 8, if the membrane of the membrane module included in the first filtration series 11 is damaged,
In the state where the first filtration series 11 is stopped, the operation is continued with the other three filtration series of the second filtration series 12, the third filtration series 13, and the fourth filtration series 14, so that the maximum water supply amount Three
/ 4 (75%) water supply will be continued, during which the damaged membrane module will be identified and recovery work will be performed.

[0006]

However, when the membrane module is damaged and an abnormality in turbidity is detected, it rushes to the site, determines the damaged membrane module, removes and replaces it, and cleans the inside of the pipe. In order to perform recovery work, the first filtration series 11 has a long time (about 12 hours or more).
There was a problem of stopping the water supply for a long time.

By the way, according to the guideline for introducing a membrane filtration device in small-scale water supply (1994), even if one line of the membrane filtration device having a multi-line filtration system is stopped, 75% or more of the maximum water supply amount is required. It is required to have water supply capacity.

The present invention has been made to solve the above-mentioned problems, and when abnormal turbidity is detected in treated water from a filtration series having a membrane module, the filtration series is immediately stopped, and By identifying the damaged membrane module in the filtration series and automatically restarting the operation of the remaining membrane modules with the membrane module stopped, any membrane module in the multiple series may be damaged. Also, an object of the present invention is to provide a membrane filtration device and a membrane filtration method capable of promptly restoring the water supply capacity unattended.

[0009]

According to a first aspect of the present invention, which solves the above-mentioned problems, raw water fed from a raw water tank is connected in parallel and passes through a filtration series composed of a plurality of membrane modules. In a membrane filtration device to be filtered, a turbidity measuring unit provided at each outlet of the filtration series to measure the turbidity of membrane permeated water, and provided at each outlet of the filtration series, the membrane permeated water being supplied. A shutoff valve for shutting off the passage of water as a water, a return valve for returning the membrane permeated water to the raw water tank, a membrane module valve for controlling the water transmission of the membrane permeated water from the membrane module, and controlling the opening and closing of the valve. The valve control means, the valve control means, when the turbidity measuring means detects an abnormal turbidity in which the membrane-permeated water sent from the filtration series exceeds a predetermined reference value, the filtration series Open the return valve and open the shutoff valve After closing, a plurality of membrane modules in the filtration series are sequentially switched to send membrane permeated water to each membrane module, the turbidity measuring means identifies a membrane module exhibiting abnormal turbidity, and the membrane module of this membrane module While closing the valve, the shut-off valve is opened, the return valve is closed, and the membrane module valve of another membrane module is opened to feed the membrane permeated water.

According to the first aspect of the present invention, even if the membrane of the membrane module is damaged, it is possible to identify which membrane module of the membrane is damaged by the turbidity measuring means. With the valve control means, it is possible to stop only the membrane module whose membrane has been damaged and operate the other membrane modules, and it is possible to secure the amount of water supply according to the standard.

The invention according to a second aspect is characterized in that, in the invention according to the first aspect, the filtration series is provided with a membrane module valve at each outlet or inlet of the membrane module.

According to the invention of claim 2, claim 1
In addition to the effect according to the invention described in (1), by providing a membrane module valve at each outlet or inlet of the membrane module, it is possible to stop the transmission of the membrane permeated water having an abnormal turbidity.

According to a third aspect of the present invention, in the first aspect of the present invention, the turbidity measuring means of the membrane permeated water from the membrane module detects an abnormal turbidity, closes the shutoff valve, and returns the return. As a result of opening the valve, the turbidity measuring means, the shutoff valve, and the return valve are arranged so that the membrane permeated water is returned to the raw water tank via the return valve. To do.

According to the invention of claim 3, claim 1
In addition to the effect according to the invention described in (1), when the turbidity measuring means detects an abnormality in turbidity, the permeation of the membrane-permeated water showing an abnormality is cut off, so that the membrane-permeated water that does not meet the standard is not supplied as purified water.

The invention as set forth in claim 4 is a membrane filtration method in which raw water fed from a raw water tank is connected in parallel and is filtered through a filtration series consisting of a plurality of membrane modules, wherein the membrane is separated from the filtration series. The turbidity of the permeated water is measured, and when the turbidity shows an abnormal value, the permeation of the permeated water from the filtration series showing the abnormality is interrupted, and the raw water is switched by switching sequentially for each membrane module of the filtration series. It is characterized in that the water is sent to measure the turbidity, and as a result, the sending of the membrane permeated water from the membrane module that shows an abnormality is stopped, while the water sent from the other membrane module is restarted.

According to the invention described in claim 4, even if the membrane of the membrane module is damaged, it is possible to identify which membrane module of the membrane is damaged by the turbidity measuring means. With the valve control means, it is possible to stop only the membrane module whose membrane has been damaged and operate the other membrane modules, and it is possible to secure the amount of water supply according to the standard.

The invention according to claim 5 is characterized in that, in the invention according to claim 4, an additive having turbidity is added to the raw water tank.

According to the invention of claim 5, claim 4
In addition to the effects of the invention described in (1), when detecting an abnormality module, even if the raw water has a low turbidity and there is a possibility that the abnormality of the turbidity may not be detected, the turbidity component By adding, the membrane module with the damaged membrane can be easily identified.

[0019]

BEST MODE FOR CARRYING OUT THE INVENTION Preferred embodiments of the membrane filtration device according to the present invention will be described in detail below with reference to the drawings.

FIG. 1 is a block diagram showing an outline of the membrane filtration device of the present invention (four filtration series). In FIG.
Raw water is taken into the first filtration series 11, the second filtration series 12, the third filtration series 13, and the fourth filtration series 14.
In the latter stage of these filtration series 11, 12, 13, and 14,
Turbidity measuring instruments TuIR1, Tu for detecting the turbidity of membrane-permeated water
IR2, TuIR3, and TuIR4 are provided, and a flow meter FIQ for detecting the flow rate of the membrane permeate is provided at the subsequent stage.
1, FIQ2, FIQ3, and FIQ4 are provided.
Further, in the subsequent stage, return valves V11, V12, V13 and V14 for returning the membrane permeated water to the raw water when the turbidity measuring device detects abnormal turbidity are provided. Further, it has shut-off valves V1, V2, V3, V4 for supplying or stopping the membrane permeated water as feed water, and the turbidity measuring device T
When at least one of uIR1, TuIR2, TuIR3, and TuIR4 detects an abnormality, the return valve of the series to which the turbidity meter that detected the abnormality is connected is opened, and the shutoff valve is closed to close the series. Stop the water supply.

In order that the permeated water showing abnormal turbidity is not supplied as feed water, if the turbidity measuring device detects an abnormal turbidity, it is shut off before the permeated water showing abnormality is sent as feed water. Water must be stopped by the valve and returned to the raw water tank by the return valve. Therefore, the turbidity measuring means, the shutoff valve, and the return valve need to be arranged so as to realize them. When this is temporally captured, the membrane permeated water showing an abnormal turbidity is the first filtration series 11
From the time to the shutoff valve V1 in the pipe,
The following formula (1) is established between the detection time t2 of the turbidity measuring instrument TuIR1 and the time t3 when the shutoff valve V1 is “closed” and the return valve V11 is “open” electrically. In addition, the second filtration series 12, the third filtration series 13,
It is desirable that the same relationship be established in the fourth filtration series 14 as well. t1> t2 + t3 (1) At this time, abnormal turbidity is detected before the membrane permeated water reaches the water supply side, the return valve opens and the membrane permeated water showing abnormal turbidity is returned to the raw water tank through the return valve. To be done.

FIG. 2 is a schematic configuration diagram showing a schematic configuration for one series of the membrane filtration device, and shows the first filtration series 11 as an example. In FIG. 2, the first filtration series 11 includes the membrane modules M11, M12, M13, M14, and M.
Membrane module valves V101, V10 provided with five 15 in parallel and provided on the outlet side of the membrane permeate of each membrane module
The membrane permeated water is sent as feed water through 2, V103, V104, V105 and the shutoff valve V1. These membrane module valves are controlled by valve control means.

Next, the operation will be described. The filtration series is composed of four series of a first filtration series 11, a second filtration series 12, a third filtration series 13, and a fourth filtration series 14, of which the filtration series of the first filtration series 11 has. A case where the membrane module M11 is damaged will be described.

As shown in FIG. 2, when the membrane of the membrane module M11 of the first filtration series 11 is damaged and the turbidity of the permeate of the membrane reaches the turbidity control value of 0.01 degree or more, the membrane module First filtration series 11 turbidity meter TuIR including M11
In 1 with an alarm notifying that the membrane is broken, the shut-off valve V1 of the damaged first filtration series 11 is closed and the return valve V11 is opened to return the membrane permeated water to the raw water tank. This treatment prevents the permeated water having a turbidity of more than 0.01 degrees from being mixed into the water supply side.

On the other hand, the second filtration series 12, the third filtration series 13, and the fourth filtration series 14, which have no abnormal turbidity,
Continue operation and continue supplying water. As a result, in this example, the membrane filtration device 1 according to the present invention is composed of four filtration series, and thus the water supply amount at this time is 75% of the maximum water supply amount.
(3/4).

Next, the first with the broken membrane module
In the filtration series 11 of No. 1, while the raw water (including the returned membrane permeated water) is circulated by the raw water pump and the circulation pump P, the damaged membrane module M11 is specified (details of the specifying method will be described later), and the damaged filtration is performed. The sequence number and the damaged membrane module number are displayed on a display plate (not shown). The membrane module M11 indicated by this number is in a stopped state because the membrane module valve V101 connected to this membrane module M11 has already been closed. At this time, the undamaged membrane modules M12, M13, M14, M15 start operation, but after cleaning the inside of the pipe and opening the shutoff valve to start the operation, when the filtration series and the shutoff valve are Because of the membrane permeate that remains between the two, there is a risk that the membrane permeate will exceed the permissible turbidity. Therefore, the turbidity meter TuIR
When 1 shows a normal value, the return valve V11 is closed, the shutoff valve V1 is opened, and water supply is started. As described above, the membrane filtration device 1 according to this example has four filtration series, and each of the filtration series has five membrane modules, and the membrane permeation of this one membrane module. Since the amount of water produced corresponds to 1/20 (5%) of the total, the amount of water supply at this time is 19/20 (95%) of the maximum amount of water supply.

FIG. 3 is a flow chart showing a method of sequentially inspecting a damaged membrane module according to this embodiment of the invention and returning it. In FIG. 1, when the turbidity meter TuIR1 of the first filtration series 11 detects abnormal turbidity, the return valve V11 is opened and the shutoff valve V1 is closed,
Water supply to the outside of the membrane permeate is stopped. By this operation, as shown in FIG. 3, filtration series 1 in which abnormal turbidity was detected
All the membrane module valves of No. 1 are closed (step S1). Next, the flow rate of the permeated water is adjusted to one membrane module (step S2). Next, the first membrane module valve V
Open 101 (step S3). Next, the turbidity is detected by the turbidity measuring device TuIR1 (step S4).

As a result, the membrane module M11 exhibiting abnormal turbidity is identified, and which membrane module is damaged can be identified (step S5). Thus, all membrane modules M11, M12, M13, M14, M
The turbidity of the water permeated by the membrane 15 is sequentially measured (step S
6: YES). As a result, the membrane module valve whose turbidity is within the standard is opened (step S7). After that, the turbidity measuring device T
When uIR1 is stabilized at a normal value (equal to or less than the control turbidity) (step S8: YES), the return valve V11 is closed and the cutoff valve V1 is opened (step S9).

In this way, one membrane module valve is opened and the other membrane module valves are closed, the membrane permeated water is returned, and the turbidity is sequentially measured. As a result, the membrane module with the broken membrane shows an abnormal value, and the membrane module with the broken membrane is identified. Usually, the time required for this is about 2 hours.

FIG. 5 is a diagram showing an operating state until the membrane module having a damaged membrane according to the present embodiment of the present invention is specified and restored. As shown in FIG. 5, when the filtration unit having the damaged membrane module is detected and stopped, the water supply amount becomes 3/4 (75%) of the maximum water supply amount, but after 2 hours, it becomes 19/20. The water supply has returned to (95%).

When the raw water has a low turbidity, the damage of the membrane module tends to be difficult to judge even with a high-performance turbidity measuring instrument. This tendency is particularly exhibited in a large-scale membrane filtration device that requires a large number of large-scale membrane modules to be arranged. If 10,000 hollow fibers are stored per large membrane module, 1
When turbidity leaks from the hollow fiber of the book, the set value detected by the turbidity meter is set to 0.01 turbidity, and the recovery rate is 90 to 9
If the number of membrane modules in one filtration series is 5% and the number of membrane modules is 5, the turbidity required for raw water is calculated to be about 10 degrees.

Therefore, by injecting the turbidity having such a turbidity, it is possible to detect the membrane module in which the membrane is damaged. In short, the turbidity may be easily detected according to each condition. The suspended matter may be added during normal operation, or may be added only when the damaged membrane module is specified.

At this time, as the turbidity, turbidity of cleaning waste water may be blended to adjust the turbidity. Also,
Powdered activated carbon, bentonite, or kaolin may be used. In some cases, from the viewpoint of recycling, magnetic ferrite-based or martensite-based stainless powder is used, and a powder having a particle size range of 1 to 5 μm is injected, and a magnetic recovery device is used on the drain side. You may collect it.

According to the present invention, in a filtration series having a membrane module with a broken membrane, the supply of the permeated water from the filtration series from which abnormal turbidity is detected is stopped, and the broken membrane module in the filtration series is specified. Only the membrane module is stopped, the filtration series that had stopped the supply of the permeated water is automatically restored, and after a very short time, the water supply capacity of approximately 95% or more of the maximum water supply is reached. It is possible to return. Moreover, it is possible to save the trouble of restoration and further enhance the labor saving of the membrane filtration device. At this time,
The reserve capacity of the membrane is exerted to increase the water supply capacity to the maximum water supply of 10
It is also possible to set it to 0%. In this case, there is no need to replace the membrane in a short time, and maintenance can be performed without reducing the amount of water supply when the membrane is about to be chemically cleaned or when the differential pressure between the membranes is high. it can.

Further, by incorporating a return pipe for returning the membrane permeated water, it is possible to continuously monitor the turbidity until the water is restored, and it is possible to provide a reliable operation method that does not temporarily deteriorate the quality of the water to be supplied. .

Further, when the operation is carried out according to the steps of the above-mentioned automatic restoration system, it is possible to avoid the risk of sending the membrane permeated water having the turbidity exceeding 0.01 degree to the water supply side. Also, when the membrane breakage is detected, an alarm notifying the breakage of the membrane module is communicated through a telemeter or the like. Conventionally, in a facility having a membrane filtration device, it takes a lot of time to judge a damaged module or to clean a pipe, it is difficult to restore the response in a short time, and specialized knowledge is required for the membrane. On the other hand, the membrane filtration device according to the present invention automatically identifies the damaged membrane module and restores the water supply, and also displays the filtration series number having the damaged membrane module and the damaged membrane module number. Since it can be displayed, it does not take a long time to identify a damaged membrane module and does not require an advanced technician. Further, conventionally, the filtration device in which the membrane module is damaged is operated with a low water supply capacity until complete restoration, but the membrane filtration device according to the present invention can be operated with a high water supply capacity after a very short time. It is continued and rarely requires urgent response.

The embodiment described above is an example for explaining the present invention, and the present invention is not limited to the above-mentioned embodiment, and various modifications are made within the scope of the gist of the invention. Is possible. For example, when specifying a membrane module with a damaged membrane, it is possible to reduce the confirmation time by passing 1/2 of the total number of membrane modules and performing sequential inspections. Further, as shown in FIG. 6, a membrane module valve may be provided on the inlet side of the membrane module. Moreover, although the case where the number of filtration series is four has been described, any number of filtration series may be provided as long as it is two or more. Regarding the membrane module, five cases have been described, but any number may be provided. Regarding the broken membrane module number shown on the display board, a series of numbers may be given to all membrane modules and the number may be displayed.)

[Examples] Examples will be described below. FIG. 4 is a graph showing the turbidity of membrane permeate treated by a damaged membrane module. In FIG. 4, out of the five membrane modules M11, M12, M13, M14 and M15, one hollow fiber in the membrane module M13 is cut to show the measurement result of turbidity. The conditions at this time were as follows.・ Water passing process 80 minutes ・ Raw water turbidity adjusted to 10 degrees (by powdered activated carbon) ・ Membrane module 72 m ² / piece, number of hollow fibers 10,000 per membrane module ・ Raw water flux 1.8 m / day, raw Water volume 720 m ³ / day, recovery rate 95%

As shown in FIG. 4, the damaged membrane module can be identified as the membrane module M13 exhibiting abnormal turbidity, can be determined by a densitometer, and can be automatically handled. At this time, the maximum turbidity did not exceed 0.01 degrees even after the water flow was restored.

Further, in order to identify the membrane module in which the membrane is damaged at an early stage, it is possible to increase the injection amount of the suspended matter to increase the turbidity to 2-3 times and accelerate the identification. This is particularly effective when the number of filtration series and the number of membrane modules are large.

By the way, when the membrane filtration device was restored by the conventional method, the turbidity increased when the permeated water was passed through the pipe after washing, and the maximum turbidity was detected to be 0.15 degree. It took about 30 minutes to reach a turbidity of 0.01 to 0.02 degree.

[0042]

As described above, according to the invention described in claim 1, even if the membrane of the membrane module is damaged, the valve control means can specify the membrane module having the damaged membrane. The other membrane modules can be operated by stopping only the membrane module whose membrane has been damaged, and it is possible to secure the water supply amount according to the standard.

According to the second aspect of the present invention, by providing the membrane module valve at the outlet or the inlet of the membrane module, it is possible to stop the transmission of the membrane permeated water having an abnormal turbidity.

According to the third aspect of the present invention, when the turbidity measuring means detects an abnormality in the turbidity, the permeation of the permeated water showing the abnormality is cut off. Therefore, the permeated water that does not meet the standard is supplied as purified water. There is nothing to do.

According to the fourth aspect of the present invention, even if the membrane of the membrane module is damaged, the valve control means can identify the membrane module with the damaged membrane, so that only the membrane module with the damaged membrane is used. Then, the other membrane modules can be operated and the amount of water supply can be secured according to the standard.

According to the invention described in claim 5, when the abnormal membrane module is detected, the raw water has a low turbidity,
Even when there is a possibility that the abnormality of the turbidity cannot be detected, the membrane module in which the membrane is damaged can be easily identified by adding the turbidity component.

[Brief description of drawings]

FIG. 1 is a system diagram showing an outline of a membrane filtration device according to an embodiment of the present invention.

FIG. 2 is a system diagram schematically showing a membrane module valve provided on the treated water side of the membrane module according to the embodiment of the present invention.

FIG. 3 is a flowchart for identifying a damaged membrane module according to an embodiment of the present invention.

FIG. 4 is a graph showing the turbidity of membrane permeated water processed by a damaged membrane module according to an embodiment of the present invention.

FIG. 5 is a diagram showing an operating state in which a damaged membrane module according to an embodiment of the present invention is specified and restored.

FIG. 6 is a system diagram schematically showing a membrane module valve provided on the raw water side of the membrane module according to the embodiment of the present invention.

FIG. 7 is a system diagram showing an outline of a conventional membrane filtration device.

FIG. 8 is a diagram showing an operating state in which a damaged membrane module according to a conventional example is specified and restored.

[Explanation of symbols]

1 Membrane Filtration Device 11 First Filtration Series 12 Second Filtration Series 13 Third Filtration Series 14 Fourth Filtration Series V1, V2, V3, V4 Shutoff Valves V11, V12, V13, V14 Return Valves V101, V102, V103, V104, V105
Module valve

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Hiroyoshi Ueda             Kurita, 3-4-3 Nishi-Shinjuku, Shinjuku-ku, Tokyo             Industry Co., Ltd. F-term (reference) 4D006 GA02 KA67 KE13P KE22Q                       LA03 PB04

Claims (5)

[Claims] 1. A membrane filtration device in which raw water fed from a raw water tank is connected in parallel and filtered through a filtration series consisting of a plurality of membrane modules, wherein a membrane is provided at each outlet of the filtration series. Turbidity measuring means for measuring the turbidity of the permeated water, a shut-off valve provided at each outlet of the filtration series for blocking passage of the permeated water as feed water, and the permeated water in the raw water tank. A return valve for returning the water, a membrane module valve for controlling the water supply of the permeated water from the membrane module, and a valve control means for controlling the opening and closing of the valve, wherein the valve control means supplies the water from the filtration series. When the turbidity measuring means detects an abnormal turbidity in which the permeated water passed through the membrane exceeds a predetermined reference value, the return valve of the filtration series is opened, the shutoff valve is closed, and a plurality of membranes in the filtration series are opened. Switch modules one after another Membrane permeated water is sent to the membrane module, the turbidity measuring means identifies the membrane module exhibiting abnormal turbidity, and the membrane module valve of this membrane module is closed, while the shutoff valve is opened and the return valve is closed. , A membrane filtration device which opens a membrane module valve of another membrane module to feed permeated water. 2. The membrane filtration device according to claim 1, wherein the filtration series is provided with the membrane module valve at each outlet or inlet of the membrane module. 3. The membrane permeated water from the membrane module detects the abnormal turbidity, closes the shutoff valve and opens the return valve, and as a result, the permeated water of the membrane permeates the return valve. The membrane filtration device according to claim 1, wherein the turbidity measuring means, the shutoff valve, and the return valve are arranged so as to be returned to the raw water tank via the same. 4. A membrane filtration method in which raw water sent from a raw water tank is filtered in parallel through a filtration series consisting of a plurality of membrane modules, and the turbidity of the membrane permeate is determined from the filtration series. When measured and the turbidity shows an abnormal value,
While stopping the transmission of the membrane permeate that has passed through the filtration series showing an abnormality, the membrane modules of the filtration series are sequentially switched and the raw water is sent to measure the turbidity. A membrane filtration method, characterized in that the water supply of the membrane-permeated water is stopped while the water supply of the membrane-permeated water from another membrane module is restarted. 5. The membrane filtration method according to claim 4, wherein an additive having turbidity is added to the raw water tank.