JP4929202B2 - Method and apparatus for cleaning reverse osmosis membrane module - Google Patents

Description

The present invention relates to a method and apparatus for cleaning a reverse osmosis membrane module, in particular, without increasing the size of the equipment, and can further adjust the cleaning liquid so that the reverse osmosis membrane does not deteriorate due to the cleaning liquid, soil components of the reverse osmosis membrane is about cleaning method and apparatus of the reverse osmosis membrane module which does not circulate together with the cleaning liquid.

  Pure water is supplied by supplying raw water such as seawater to the reverse osmosis membrane module, allowing water to permeate through the pores at the molecular level of the reverse osmosis membrane, and blocking the permeation of ionic and nonionic substances. A reverse osmosis membrane module for extracting permeated water is widely used for producing pure water because of its high impurity removal performance and simple operation. In such a pure water production apparatus, since impurities are separated by a reverse osmosis membrane, if used for a long time, the reverse osmosis membrane is contaminated and the permeation flux is lowered.

FIG. 5 is a configuration diagram illustrating a reverse osmosis membrane module and a cleaning device thereof according to the related art.
The production of pure water using the reverse osmosis membrane module and the method for cleaning the reverse osmosis membrane module in the prior art will be described with reference to FIG.
First, operation during the production of pure water will be described.
In FIG. 5, 1 is raw water such as seawater, 2 is a reverse osmosis membrane module, 3 is permeate, 4 is a permeate tank, and 5 is concentrated water.
In FIG. 5, raw water 1 such as seawater is boosted to a pressure at which water and impurities can be separated by a reverse osmosis membrane module 2 described later, and sent to the reverse osmosis membrane module 2. The reverse osmosis membrane module 2 is a reverse osmosis membrane made of, for example, cellulose acetate or aromatic polyamide, formed in a hollow fiber type or a spiral type and housed in a container. The reverse osmosis action converts the raw water 1 into the reverse osmosis membrane module 2. The permeated water 3 that has permeated through the osmotic membrane is separated from the concentrated water 5 having an increased impurity concentration without permeating through the reverse osmosis membrane. The permeated water 3 is stored in the permeated water tank 4 as pure water, and the concentrated water 5 is discharged to the outside and processed.

Next, cleaning of the reverse osmosis membrane module 2 will be described.
The reverse osmosis membrane module 2 is cleaned with chemicals such as acid or alkali according to the contaminants of the osmosis membrane. Depending on the state of contamination of the film, after the acid cleaning, further alkali cleaning may be performed.
When cleaning is performed, the permeated water stored in the permeated water tank 4 is supplied to the cleaning liquid tank 7 by a predetermined amount. Thereafter, a cleaning chemical 8 such as acid or alkali is introduced into the cleaning liquid tank 7 by a cleaning chemical pump 9. Then, by rotating the stirrer 12 provided in the cleaning liquid tank 7 to perform stirring, the permeated water and the cleaning chemical are mixed in the cleaning liquid tank 7 to adjust the cleaning liquid having a predetermined chemical concentration. When the cleaning liquid with the predetermined chemical concentration is adjusted, the cleaning liquid tank 7 → the cleaning liquid pump 11 → the reverse osmosis membrane module 2 → using the cleaning liquid pump 11 while the supply of the raw water 1 to the reverse osmosis membrane module 2 is stopped → The reverse osmosis membrane is cleaned by circulating the cleaning liquid through the circulation line 10 in the order of the cleaning liquid tank 7.

  In FIG. 5, the cleaning liquid is adjusted by stirring water and cleaning chemicals in a tank provided with a stirrer 12, but Patent Document 1 includes a mixing circulation line that circulates in the order of tank → pump → tank. A technique is disclosed in which cleaning chemicals are introduced into the water circulating in the mixing circulation line and the cleaning liquid is adjusted by circulation.

Japanese Patent Laid-Open No. 2002-307058

However, both the technique described in FIG. 5 and the technique disclosed in Patent Document 1 require the provision of an adjustment tank in order to adjust the cleaning liquid having a predetermined chemical concentration, which increases the size of the equipment. was there. In particular, since reverse osmosis modules usually have a large number of reverse osmosis modules arranged in parallel and use a wide area, it is necessary to make the equipment used for washing as small as possible in order to avoid using a wider area. There is.
In addition, when stirring in the tank is insufficient and a cleaning liquid having a high chemical concentration is adjusted locally, the chemical resistance of the reverse osmosis membrane may cause deterioration of the membrane.
Further, when the soil component of the osmotic membrane is a dissolved component that dissolves in the cleaning liquid, or when it is a component that circulates together with the cleaning liquid as a suspension, the soil component circulates with the cleaning liquid and the cleaning ability decreases.

  Therefore, in view of the problems of the prior art, the present invention adjusts the chemical concentration of the cleaning liquid so that the tank does not need to be provided and the equipment is not enlarged and the reverse osmosis membrane is not deteriorated due to the cleaning liquid. It is an object of the present invention to provide a cleaning method and apparatus for a reverse osmosis membrane module which can be used and the dirt component of the reverse osmosis membrane does not circulate with the cleaning liquid.

In order to solve the above problems, in the present invention,
An inlet-side retention section which is connected to the raw water supply port of each of a plurality of adjacent reverse osmosis membrane module, and an outlet-side retaining portion coupled to the concentrated water outlet respectively adjacent the plurality of reverse osmosis membrane module people comprising, the The side staying part and the inlet side staying part are connected by a circulation line, and an on-off valve is provided on the raw water supply part side upstream of the inlet side staying part to stop the supply of raw water to the inlet side staying part. In the method of cleaning a reverse osmosis membrane module device configured to send permeate obtained by separating raw water with a reverse osmosis membrane module to a permeate tank through an outlet side retention part
While stopping the supply of raw water to the inlet side retaining part by the raw water on-off valve, by driving the circulation pump, the part of the permeate permeate tank, the circulation than the outlet-side retaining part Circulate in the order of the inlet side retention part, the reverse osmosis membrane module and the outlet side retention part of the reverse osmosis membrane module via the line , and introduce a predetermined amount of the cleaning chemical into the circulating water, The cleaning liquid is adjusted.

By circulating water and introducing a predetermined amount of cleaning chemical into the water, the water and the cleaning chemical are mixed by circulation, and a cleaning liquid that is an aqueous solution of a predetermined concentration of cleaning chemical can be prepared. During the circulation, stagnation of the circulating water occurs in the inlet-side stagnation part and the outlet-side stagnation part, so that water and cleaning chemicals can be mixed by circulation.
This eliminates the need for large-scale equipment such as tanks, so it is possible to reduce the size of equipment for cleaning reverse osmosis membrane modules. As a result, less cleaning chemicals are required.

In addition, the concentration of the cleaning chemical in the circulating water or a physical property value that fluctuates corresponding to the concentration of the cleaning chemical is detected, and when the detected value exceeds a predetermined value, the flow rate of the cleaning chemical introduced is reduced. The introduction of the cleaning chemical is stopped or reduced.
Examples of physical property values that vary in accordance with the concentration of the cleaning chemical include pH when the cleaning chemical is acid (HCl) or alkali (NaOH), and the cleaning chemical is an oxidizing agent (H ₂ O ₂ ). Includes an oxidation-reduction potential (ORP) and UV when the cleaning chemical is a chemical having fluorescence or absorption.
The predetermined value is determined according to the chemical resistance of the membrane of the reverse osmosis module, the type of cleaning chemical, and the like, and is set to a value that does not deteriorate the membrane within the reference value.

  As a result, the concentration of the cleaning chemical is locally increased during the circulation, and when the detected value exceeds a predetermined value, the introduction flow rate of the cleaning chemical to the circulation line is reduced or the introduction is stopped. Further, it is possible to prevent the concentration of the cleaning chemical from being increased, and it is possible to prevent the cleaning liquid having a high concentration of cleaning chemical from being locally introduced into the reverse vibration membrane module and deteriorating the membrane.

The cleaning chemical is an acid or an alkali, and the physical property value is a hydrogen ion concentration (pH).
Acids or alkalis change pH as the cleaning chemical concentration changes. pH follows changes in concentration with high accuracy, and a pH meter for measuring pH is inexpensive and has a simple structure. Therefore, changes in chemical concentration can be detected with high accuracy at low cost.

Moreover, the volumetric flow F _w of water are the circulation, the volumetric flow rate F _c of cleaning agent to be introduced into the water that the circulation, the volume ratio of water and cleaning agent quantity in said cleaning liquid V _{w /} V _{When it is set as c} , it sets so that the following (1) Formula may be materialized.
_{F c / F w <V c} / V w ··· (1)

  By satisfying (1), it is possible to avoid a high concentration of chemical at the position where the cleaning chemical is introduced into the circulating water, and the high concentration cleaning liquid is placed in the reverse osmosis membrane module. It is possible to prevent the film from flowing and causing deterioration of the film.

In addition, as an apparatus invention for solving the problem,
An inlet-side retention section which is connected to the raw water supply port of each of a plurality of adjacent reverse osmosis membrane module, and an outlet-side retaining portion coupled to the concentrated water outlet respectively adjacent the plurality of reverse osmosis membrane module people comprising, the The outlet side staying part and the inlet side staying part are connected by a circulation line, and an open / close valve is provided on the raw water supply part side upstream of the inlet side staying part to stop the supply of raw water to the inlet side staying part, A reverse osmosis membrane module cleaning device configured to send permeate obtained by separating raw water in each reverse osmosis membrane module to a permeate tank through an outlet side retention portion, wherein the outlet side retention portion an inlet-side retaining portion between the circulation connected circulate pump that said interposed in the circulation, but was, means for introducing a cleaning agent into the circulation line, the provided and,
Wherein the supply of raw water to the inlet side retaining portion in a state of stopping the raw water on-off valve, by driving the circulation pump, the part of the permeate from the permeate tank, said from the outlet-side retaining part inlet side accumulating section via the circulation line, with circulating in the order of the reverse osmosis membrane module interior and outlet retention portion, the cleaning agent is introduced a predetermined amount of water that the circulation, by adjusting the cleaning solution It is characterized by.

  A detecting means for detecting a concentration of the cleaning chemical in the circulating water or a physical property value that varies in accordance with the concentration of the cleaning chemical; and when the detected value exceeds a predetermined value, A control device for reducing the introduction flow rate or stopping the introduction of the cleaning chemical is provided.

  Further, the cleaning chemical is acid or alkali, and the detection means is a hydrogen ion concentration meter (pH meter).

Further, the circulation line, characterized in that interposed means for removing dirt component in the washing liquid.
Examples of means for removing the soil component include a filter and an adsorbent.
Thereby, it is possible to prevent the dirt component removed from the reverse osmosis membrane module by the cleaning liquid from circulating with the cleaning liquid and reducing the cleaning ability of the cleaning liquid.

  As described above, according to the present invention, the chemical concentration of the cleaning liquid can be adjusted so that the reverse osmosis membrane is not deteriorated due to the cleaning liquid without increasing the size of the equipment because there is no need to provide a tank. It is possible to provide a method and apparatus for cleaning a reverse osmosis membrane module in which dirt components of the reverse osmosis membrane do not circulate with the cleaning liquid.

  Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the drawings. However, the dimensions, materials, shapes, relative arrangements, and the like of the components described in this embodiment are not intended to limit the scope of the present invention unless otherwise specified, but are merely illustrative examples. Not too much.

FIG. 1 is a configuration diagram illustrating a reverse osmosis membrane module and a cleaning device thereof according to Embodiment 1, and FIG. 2 is a configuration diagram around a reverse osmosis membrane module.
First, operation during the production of pure water will be described.
In FIG. 1, 1 is raw water such as seawater, 2 is a reverse osmosis membrane module, 3 is permeate, 4 is a permeate tank, and 5 is concentrated water.
In FIG. 1, raw water 1 such as seawater is pressurized to a pressure at which water and impurities can be separated by a reverse osmosis membrane module 2, which will be described later, by a boosting pump (not shown) and sent to the reverse osmosis membrane module 2. The reverse osmosis membrane module 2 is configured by forming a reverse osmosis membrane made of, for example, cellulose acetate or polyamide into a hollow fiber type or a spiral type, and storing the raw water 1 in the reverse osmosis membrane by a reverse osmosis action. Is separated into permeated water 3 that has passed through the reverse osmosis membrane and concentrated water 5 in which the impurity concentration is increased without passing through the reverse osmosis membrane. The permeate 3 is stored in the permeate tank 4 as pure water, and the concentrated water 5 is discharged to the outside.

Moreover, as shown by 2a, 2b, 2c, 2d, and 2e in FIG. 2, not only one reverse osmosis membrane module 2, but a plurality are arranged in parallel. In FIG. 2, five reverse osmosis membrane modules are arranged side by side, but the number of reverse osmosis membrane modules arranged in parallel and the direction of arrangement are not particularly limited, and several tens of reverse osmosis modules are arranged vertically. Sometimes placed side by side.
As described above, when a plurality of reverse osmosis membrane modules 2a to 2e are arranged in parallel, the raw water 1 is introduced into the inlet header 21 provided at the inlet portion of the reverse osmosis membrane modules 2a to 2e. 21 to the reverse osmosis membrane modules 2a to 2e. The permeated water 3 obtained by separating the raw water by the reverse osmosis membrane modules 2 a to 2 e is introduced into the outlet header 23 and then sent to the permeated water tank 4. Further, the concentrated water 5 obtained in each of the reverse osmosis membrane modules 2a to 2e is introduced into the concentrated liquid header 22 and then discharged to the outside.

Next, cleaning of the reverse osmosis membrane module 2 will be described.
The reverse osmosis membrane module is cleaned with chemicals such as acid or alkali according to the contamination of the membrane. Depending on the state of contamination of the film, after the acid cleaning, further alkali cleaning may be performed.
In FIG. 1, 8 is a cleaning chemical such as acid or alkali, 9 is a cleaning chemical pump for introducing the cleaning chemical 8 into a circulation line 10 to be described later, and 10 is a circulation line for circulating a cleaning liquid which is an aqueous solution of a predetermined concentration of cleaning chemical, Reference numeral 11 denotes a cleaning liquid pump for circulating the cleaning liquid, and reference numeral 6 denotes cleaning permeate introduced from the permeate tank 4 into the circulation line. The circulation line 10 is connected to the inlet header 21 and the outlet header 22 as shown in FIG.

When the reverse osmosis membrane module 2 is washed, first, the permeate stored in the permeate tank 4 in a state where supply of the raw water 1 to the reverse osmosis membrane modules 2a to 2e, that is, supply to the inlet side retention portion 21, is stopped is performed. A part of water is supplied into the circulation line 10 as the permeated water 6 for cleaning, and the cleaning liquid pump 11 is activated to circulate the circulation line 10. Thereby, the permeating water for cleaning circulates in the order of the cleaning liquid pump 11 → the inlet side retention part 21 → the reverse osmosis membrane modules 2 a to 2 e → the outlet side retention part 23 → the cleaning liquid pump 11. In addition, since it is necessary to prevent the permeating water for washing from flowing to the permeate tank 4 side, the outlet side (retention part) of each reverse osmosis membrane module 2a to 2e, that is, the reverse osmosis membrane modules 2a to 2e. A valve (not shown) is preferably provided between the outlet head 23 and the outlet head 23, and the valve is closed during cleaning.

  Further, while the cleaning permeated water is circulated, the cleaning chemical 8 is continuously introduced into the circulation line 10 by the cleaning chemical pump 9 until a predetermined amount is reached, and then the introduction is stopped. The predetermined amount for introducing the cleaning chemical 8 is necessary for the ratio of the amount of the cleaning chemical 8 introduced into the circulation line 10 and the amount of the permeating water 6 for cleaning to clean the reverse osmosis membrane modules 2a to 2e. The amount should be the same as the ratio of cleaning chemical to water in a clean cleaning solution.

Moreover, the the volumetric flow F _w of the cleaning permeate circulating in the circulation line 10, the relationship between the volumetric flow F _c of cleaning agent to be introduced into the circulation line 10, for cleaning in the final required washing liquid When the volume ratio of the permeated water amount and the cleaning chemical amount is V _w / V _c , the volume flow rates F _w and F _c are set so that the following expression (1) is satisfied.
_{F c / F w <V c} / V w ··· (1)
By satisfying (1), it is possible to avoid a high concentration of the chemical at the position where the cleaning chemical is introduced into the circulating permeating water for circulation. It is possible to prevent the membrane from being deteriorated by flowing into the module.
Here, the volume flow rates _Fw and _Fc are adjusted, for example, by providing a flow meter on the discharge side of the cleaning liquid pump 11 and the cleaning chemical pump 9, and the strokes of the cleaning liquid pump 11 and the cleaning chemical pump 9 according to the detected value by the flow meter. The flow rate adjustment valve opening may be adjusted by providing a separate flow rate adjustment valve. However, in order to reduce the size of the entire facility, It is preferable to select the capacity of the cleaning chemical pump 9 and the piping diameter of the circulation line 10 and the line for introducing the cleaning chemical so that no flow meter is provided. For example, the pump capacity and the pipe diameter are selected so that the expression (1) is established when the cleaning liquid pump 11 and the cleaning chemical pump 9 are operated at their rated values.

In this way, by introducing a predetermined amount of cleaning chemical into the permeating water for cleaning while circulating a predetermined amount of the permeating water for cleaning, the permeating water for cleaning and the cleaning chemical are mixed by circulation, It becomes a cleaning solution of concentration. In the present invention, since the circulation line 10 is connected to the inlet header 21 and the concentrate header 22 as shown in FIG. 2, the inlet header 21 and the concentrate header 22 serve as a retention portion, and the permeate for washing by circulation. And cleaning chemicals can be mixed.
Then, the reverse osmosis membrane modules 2a to 2e can be cleaned by continuing the circulation after the cleaning permeate and the cleaning chemical are mixed to form a cleaning liquid.

  This eliminates the need for large equipment such as a tank, so the reverse osmosis membrane module can be cleaned with a small equipment, and since the tank is not required, the circulation flow rate is reduced by the amount of tank storage compared to the case where a tank is required. Therefore, the amount of cleaning chemicals required may be small.

FIG. 3 is a configuration diagram illustrating the reverse osmosis membrane module and the cleaning device thereof according to the second embodiment.
The same reference numerals as those in FIG. 1 denote the same items, and the sensor 14 and its accessories are the same as in the first example, and therefore, the description of the same parts as those in the first example is omitted.

In the second embodiment, the sensor 14 is provided on the discharge side of the cleaning liquid pump 9 in the circulation line 10. The sensor 14 detects a cleaning chemical concentration in the cleaning liquid or a physical property value that varies in accordance with the concentration.
For example, when alkali (NaOH) is used as a cleaning chemical to clean organic matter in the reverse osmosis membrane module 2, the pH changes in response to the cleaning chemical concentration change in the cleaning liquid. It can be. In addition, when acid (HCl) is used as a cleaning chemical to clean metal (FeOH ₃ ) dirt in the reverse osmosis membrane module 2, it responds to changes in the concentration of cleaning chemicals in the cleaning liquid in the same manner as when alkali is used as the cleaning liquid. Since the pH changes, the sensor 14 can be a pH meter. When the cleaning chemical is an oxidizing agent (H ₂ O ₂ ), the sensor 14 is an oxidation-reduction potential (ORP) sensor. When the cleaning chemical is a fluorescent or absorbing chemical, the sensor 14 is a UV meter. Can do.

Further, when the concentration of the cleaning chemical in the cleaning liquid in the circulation line 10 locally increases and the detection value by the sensor 14 exceeds a predetermined reference value, the pump 9 is stopped and the introduction of the cleaning chemical into the circulation line is stopped. Control to do.
Accordingly, it is possible to prevent the cleaning chemical concentration from further increasing, and it is possible to suppress the deterioration of the membrane due to the local introduction of the cleaning liquid having a high cleaning chemical concentration into the reverse osmosis membrane module 2. Further, the same effect can be obtained by reducing the cleaning chemical introduction flow rate by lowering the pump stroke instead of stopping the cleaning chemical pump 9.
Further, when the detection value by the sensor 14 exceeds the predetermined reference value, the same effect can be obtained if the flow rate of the cleaning chemical introduced into the circulation line 10 is reduced or stopped. A flow rate adjusting valve may be provided, and control may be performed so as to adjust the opening degree of the flow rate adjusting valve when the value detected by the sensor 14 exceeds the reference value.

The reference value that serves as a reference for reducing or stopping the flow rate of the cleaning chemical introduced into the circulation line 10 is determined by the chemical resistance of the reverse osmosis module membrane, the type of cleaning chemical, and the like. The value is set so as not to deteriorate.
When the cleaning chemical is alkali (NaOH) and a polyamide film is used and a pH meter is used as the sensor 14, the reference value can be set to, for example, pH = 12. If exceeded, the flow rate of the cleaning chemical introduced into the circulation line 10 is lowered or stopped.
Further, when a cleaning chemical is an acid (HCl) and a cellulose acetate film is used and a pH meter is used as the sensor 14, the reference value can be set to, for example, pH = 1. When it is less than 1, the flow rate of the cleaning chemical introduced into the circulation line 10 is lowered or stopped.

FIG. 4 is a configuration diagram illustrating the reverse osmosis membrane module and the cleaning device thereof according to the third embodiment.
The same reference numerals as those in FIG. 1 denote the same components, and the same parts as those in the first embodiment except that the filter 13 is provided.

In the third embodiment, a filter 13 is provided in the circulation line 10. When the dirt component in the reverse osmosis membrane module 2 is removed with the cleaning liquid, the dirt component may circulate in the circulation line 10 together with the cleaning liquid to reduce the cleaning ability of the cleaning liquid. Since it can be removed by a filter, cleaning can be performed without circulating dirt and thus without reducing the cleaning ability of the cleaning liquid.
Further, when the dirt component does not dissolve in the cleaning liquid, it is sufficient to provide the filter 13. However, if the dirt component dissolves in the cleaning liquid, the filter 13 may not be able to remove the dirt component. It is better to remove the dirt component using an adsorbent instead of the vessel 13, and the filter 13 and the adsorbent are arranged in series in the circulation line 10 to remove the dirt component that is soluble in the cleaning liquid and the insoluble dirt component. You may make it do.

  Since there is no need to install a tank, the chemical concentration of the cleaning solution can be adjusted so that the reverse osmosis membrane does not deteriorate due to the cleaning solution without increasing the size of the equipment. It can be used as a cleaning method and apparatus for a reverse osmosis membrane module that does not circulate.

It is a block diagram which shows the reverse osmosis membrane module which concerns on Example 1, and its washing | cleaning apparatus. It is a block diagram around a reverse osmosis membrane module. It is a block diagram which shows the reverse osmosis membrane module which concerns on Example 2, and its washing | cleaning apparatus. It is a block diagram which shows the reverse osmosis membrane module which concerns on Example 3, and its washing | cleaning apparatus. It is a block diagram which shows the reverse osmosis membrane module which concerns on a prior art, and its washing | cleaning apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Raw water 2 Reverse osmosis membrane module 3 Permeated water 4 Permeated water tank 5 Concentrated water 8 Cleaning chemicals 10 Circulation line 11 Cleaning liquid pump 13 Filter 14 Sensor 21 Inlet header (raw water retention part)
22 Concentrate header (concentrated water retention part)
23 Exit header

Claims (8)

An inlet-side retention section which is connected to the raw water supply port of each of a plurality of adjacent reverse osmosis membrane module, and an outlet-side retaining portion coupled to the concentrated water outlet respectively adjacent the plurality of reverse osmosis membrane module people comprising, the The outlet side staying part and the inlet side staying part are connected by a circulation line, and an open / close valve is provided on the raw water supply part side upstream of the inlet side staying part to stop the supply of raw water to the inlet side staying part, In the method for cleaning a reverse osmosis membrane module device configured to send permeate obtained by separating raw water in each reverse osmosis membrane module to a permeate tank via an outlet side retention part
Supply of raw water to the inlet side retaining part in a state of being stopped by the raw water on-off valve, by driving the circulation pump, the part of the permeate permeate tank via the circulation line cleaning fluid The cleaning solution is prepared by circulating the inlet side staying part, the reverse osmosis membrane module inside and the module outlet side staying part in order from the pump , and introducing a predetermined amount of the cleaning chemical into the circulating water. The reverse osmosis membrane module cleaning method. Detecting the concentration of the cleaning chemical in the circulating water or the physical property value that fluctuates corresponding to the concentration of the cleaning chemical;
2. The method of cleaning a reverse osmosis membrane module according to claim 1, wherein when the detected value exceeds a predetermined value, the flow rate of the cleaning chemical introduced is decreased or the introduction of the cleaning chemical is stopped.   The method for cleaning a reverse osmosis membrane module according to claim 2, wherein the cleaning chemical is an acid or an alkali, and the physical property value is a hydrogen ion concentration (pH). The volume flow rate F _w of the circulating water, the volume flow rate F _c of the cleaning chemical introduced into the circulating water, and the volume ratio of the water amount and the cleaning chemical amount in the cleaning liquid are expressed as V _w / V _c . The reverse osmosis membrane module cleaning method according to any one of claims 1 to 3, wherein the following equation (1) is set to satisfy:
_{F c / F w <V c} / V w ··· (1) An inlet-side retention section which is connected to the raw water supply port of each of a plurality of adjacent reverse osmosis membrane module, and an outlet-side retaining portion coupled to the concentrated water outlet respectively adjacent the plurality of reverse osmosis membrane module people comprising, the A side retention part and an inlet side retention part are connected via a circulation line, and an open / close valve is provided on the raw water supply part side upstream of the inlet side retention part to stop the supply of raw water to the inlet side retention part, Furthermore, the reverse osmosis membrane module cleaning device is configured to send permeate obtained by separating raw water in each reverse osmosis membrane module to a permeate tank through a side retention part , wherein the reverse osmosis membrane module an outlet-side retaining portion and the inlet-side retaining portion between the circulation pump, which is interposed in the circulation Kan was circulated connected, means for introducing a cleaning agent into the circulation line, the provided for,
Supply of raw water to the inlet side retaining part in a state of being stopped by the raw water on-off valve, by driving the circulation pump, the part of the permeate from the permeate tank via the circulation line The cleaning liquid is circulated in order from the cleaning liquid pump to the inlet side retention part, the reverse osmosis membrane module inside and the reverse osmosis membrane module outlet side retention part, and a predetermined amount of the cleaning chemical is introduced into the circulating water to adjust the cleaning liquid. A cleaning device for a reverse osmosis membrane module. Detecting means for detecting a concentration of the cleaning chemical in the circulating water or a physical property value that varies in accordance with the concentration of the cleaning chemical;
6. The reverse osmosis membrane module according to claim 5, further comprising a control device that reduces the flow rate of the cleaning chemical introduced or stops the introduction of the cleaning chemical when the detected value exceeds a predetermined value. Cleaning equipment.   7. The reverse osmosis membrane module cleaning apparatus according to claim 6, wherein the cleaning chemical is an acid or an alkali, and the detection means is a hydrogen ion concentration meter (pH meter). 6. The reverse osmosis membrane module cleaning apparatus according to claim 5 , wherein means for removing dirt components in the cleaning liquid is interposed in the circulation line.

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