JP2013240762A - Reverse osmosis membrane filtration system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a reverse osmosis membrane filtration system capable of eliminating a biofilm.SOLUTION: A reverse osmosis membrane filtration system includes: a reverse osmosis membrane treatment means 8 having a reverse osmosis membrane for producing fresh water by filtering taken seawater; a pH adjusting agent injection means 9 for injecting a pH adjusting agent for adjusting a pH of the taken seawater into the taken seawater at a position in front of where the taken seawater is supplied to the reverse osmosis membrane treatment means 8; a cleaning agent injection means 10 for injecting a degrading agent for degrading a component of a biofilm generated on a surface of the reverse osmosis membrane into the taken seawater; and an a bactericide injection means 11 for injecting a bactericide for sterilizing a microorganism protected by the biofilm into the taken seawater.

Description

  The present invention relates to a reverse osmosis membrane filtration system.

  In recent years, the application of seawater desalination technology using membranes has increased. The reverse osmosis membrane method applies a pressure more than twice the osmotic pressure of seawater (approximately 2.5 MPa) to a reverse osmosis membrane made of materials such as cellulose and polyamide, and allows salt to permeate water without permeating the membrane. As a result, fresh water can be obtained.

  In the reverse osmosis membrane method, after taking seawater, first, sand and organic substances are removed by a method such as sand filtration. At this time, most of the microorganisms are removed at the same time. And the ion in seawater is isolate | separated with a reverse osmosis membrane, and fresh water is obtained. At this time, magnesium, calcium, carbonate ions, and sulfate ions in seawater are the main causes, and scale is deposited in the plant, and a biofilm is formed by microorganisms and their metabolites. When these adhere and deposit on the surface of the reverse osmosis membrane, the reverse osmosis membrane is clogged, so-called fouling occurs. Fouling causes a decrease in the treatment flux and salt rejection due to the reverse osmosis membrane, and it is necessary to increase the power of the high-pressure pump and increase the frequency of replacement of the membrane module in order to secure a predetermined amount of water and water quality. .

  Among the causes of fouling, as countermeasures to the scale of inorganic components, pH control of seawater (maintains low pH by acid), injection of scale inhibitors (such as carboxylic acid polymers), and water quality control in the pretreatment process Application of UF membranes (ultrafiltration membranes) with smaller openings and smaller openings. As a result of these measures, fouling due to inorganic components in the reverse osmosis membrane filtration plant tends to be suppressed. As fouling due to inorganic components has been reduced, fouling due to biofilms has been cited as the next issue.

  In biofilms, microorganisms in seawater adhere to reverse osmosis membrane surfaces and the surface of lattice-like spacers arranged between the membranes in a spiral membrane, and these are extra cellular polysaccharides (EPS). It is formed in a form in which a plurality of microorganisms coexist. The biofilm provides an environment in which microorganisms can stably survive and serves as a protective film against a bactericide added to seawater.

  As means for suppressing biofouling, removal of microorganisms (introduction of a UF membrane or the like), control of raw water quality (adsorption / decomposition of organic substances), and the like have been proposed. However, mixing of microorganisms into the reverse osmosis membrane module having the reverse osmosis membrane occurs due to the passage of the UF membrane or the invasion of microorganisms from the outside. Further, it is technically and costly difficult to remove organic substances to a sufficiently low concentration. In addition, it is pointed out that microorganisms actively produce and accumulate polysaccharides in an oligotrophic state with little organic matter and nutrients to improve their surrounding environment. Therefore, in the current reverse osmosis membrane filtration plant, injection of a bactericide as a measure for suppressing biofilm production, and injection of an acid / alkali agent as a measure for suppressing formation of inorganic scale and washing, respectively. Is actually.

  Under such circumstances, in recent years, the operation of operations such as addition of bactericides, chemical cleaning, and pretreatment for the purpose of preventing biofouling of the reverse osmosis membrane module of the reverse osmosis membrane filtration unit is highly reliable and sensitive. The invention described in Patent Document 1 has been proposed for the purpose of providing a reverse osmosis membrane filtration plant operation method and a reverse osmosis membrane filtration plant which can be carried out rationally, quickly and simply.

  This Patent Document 1 relates to a method for operating a reverse osmosis membrane filtration plant having a raw water intake part, a pretreatment part, and a reverse osmosis membrane filtration part having a reverse osmosis membrane module in this order. The biofilm-forming substrate is placed under conditions where feed water and / or reverse osmosis membrane non-permeate water is allowed to flow at a linear velocity equal to the non-permeate water velocity in the reverse osmosis membrane module of the reverse osmosis membrane filtration unit. The invention of evaluating the amount of biofilm on the biofilm-forming substrate once a day to every six months and controlling the operation method of the reverse osmosis membrane filtration plant based on the evaluation result. Have been described. In addition, as a control of the operation method of the reverse osmosis membrane filtration plant, it is described that the biofilm-forming substrate is treated under the same control conditions, which is control of sterilization conditions or cleaning conditions of the reverse osmosis membrane filtration unit. ing.

  In Patent Document 1, chelating agents such as sodium hydroxide and ethylenediamine-4-acetic acid (EDTA), surfactants, and salts such as 2-methyl-4-isothiazolin-3-one are used as cleaning agents. As a disinfectant, 2-methyl-4-isothiazolin-3-one, 5-chloro-2-methyl-4-isothiazolin-3-one, acid, silver ions, etc. are used. ing.

  Moreover, in this patent document 1, in the reverse osmosis membrane filtration plant which has a reverse osmosis membrane filtration part which has a raw | natural water intake part, a pre-processing part, and a reverse osmosis membrane module in this order, it is the first reverse osmosis in a reverse osmosis membrane filtration part. Connected downstream of the pipe and a pipe through which the feed water branched from the upstream from the membrane module flows and / or a pipe through which the reverse osmosis membrane non-permeated water branches from the reverse osmosis membrane module in the reverse osmosis membrane filtration section. And a flow rate regulating valve connected upstream or downstream of the water flow container. The reverse osmosis membrane used in the reverse osmosis membrane filtration unit is provided in the water flow container. The invention describes that the material is accommodated under flowing water at a linear velocity equal to the non-permeate water linear velocity in the reverse osmosis membrane module of the reverse osmosis membrane filtration unit.

International Publication No. 2008/038575 Pamphlet

As described above, the invention described in Patent Document 1 calculates the appropriate amount of the bactericidal agent or cleaning agent based on the amount of biofilm on the biofilm-forming substrate, and injects each independently. .
However, as mentioned above, since biofilms have EPS, it is difficult to effectively sterilize microorganisms in biofilms simply by optimizing the amount of bactericides. A large amount of disinfectant was required to try. In order to effectively sterilize microorganisms in the biofilm, it is necessary to remove the biofilm.

  This invention is made | formed in view of such a situation, and makes it a subject to provide the reverse osmosis membrane filtration system which can remove a biofilm.

  In order to solve the above problems, the present invention provides a reverse osmosis membrane treatment means having a reverse osmosis membrane for producing fresh water by filtering the taken seawater, and supplying the taken seawater to the reverse osmosis membrane treatment means. In the previous position, the pH adjusting agent injection means for injecting the pH adjusting agent for adjusting the pH of the intake seawater into the intake seawater, and the biofilm components generated on the surface of the reverse osmosis membrane are decomposed. Cleaning agent injection means for injecting the decomposing agent into the taken-in seawater; and bactericide-injecting means for injecting the disinfectant for sterilizing the microorganisms protected by the biofilm into the taken-up seawater. Provided.

  ADVANTAGE OF THE INVENTION According to this invention, the reverse osmosis membrane filtration system which can remove a biofilm can be provided.

It is a block diagram which shows the structure of the reverse osmosis membrane filtration system S which concerns on 1st Embodiment. It is a block diagram which shows the structure of the reverse osmosis membrane filtration system S which concerns on 3rd Embodiment. It is a flowchart which shows the control flow in 3rd Embodiment.

DESCRIPTION OF EMBODIMENTS Hereinafter, modes (embodiments) for carrying out the present invention will be described in detail with reference to the drawings as appropriate.
<First Embodiment>
(Main components of the reverse osmosis membrane filtration system according to the first embodiment)
FIG. 1 is a block diagram showing a configuration of a reverse osmosis membrane filtration system S according to the first embodiment.
As shown in FIG. 1, the reverse osmosis membrane filtration system S according to the first embodiment includes, as main components, water intake means 1, raw water sterilization means 3, scale inhibitor injection means in the order of taking seawater and processing it. 4, flocculant injection means 5, pretreatment means 2, reducing agent injection means 7, pretreatment water adjustment tank 6, reverse osmosis membrane treatment means 8, fresh water adjustment tank 14, alkaline agent injection means 15, mineral injection means 16, fresh water Sterilization means 17 is provided.

  And in the reverse osmosis membrane filtration system S which concerns on this 1st Embodiment, between the pretreatment water adjustment tank 6 and the reverse osmosis membrane treatment means 8, pH adjuster injection means 9, the cleaning agent injection means 10, and a disinfectant An injection means 11 is provided. The reverse osmosis membrane filtration system S operates the pH adjusting agent injection means 9, the cleaning agent injection means 10 and the bactericidal agent injection means 11 periodically or by checking the operation state of the reverse osmosis membrane treatment means 8 to perform reverse osmosis. The biofilm generated on the membrane is removed and the microorganisms that produce it are sterilized. Details will be described later.

Each of these constituent elements of the reverse osmosis membrane filtration system S is connected to the control means 13 and is controlled by the control means 13 to perform a predetermined operation. The operation control in the present invention will be described in detail later.
The raw water sterilization unit 3, the scale inhibitor injection unit 4, and the flocculant injection unit 5 may be provided between the water intake unit 1 and the pretreatment unit 2, and the arrangement order thereof is not limited thereto.
Moreover, the alkaline agent injection | pouring means 15, the mineral injection | pouring means 16, and the fresh water sterilization means 17 should just be provided after the fresh water adjustment tank 14, and the arrangement | positioning order is not limited to this.
Hereinafter, each above-mentioned component is demonstrated along the order which reverse osmosis membrane filtration system S takes in seawater and desalinates.

(Water intake means)
The water intake means 1 is equipment for taking seawater from the sea or from the ground into which seawater penetrates and taking it into the pretreatment means 2. The water intake means 1 has a pump P1 in a path (pipe) leading to the pretreatment means 2, and takes in seawater with an appropriate pressure by the pump P1 and takes it into the pretreatment means 2.

(Raw water sterilization means, scale inhibitor injection means, flocculant injection means)
Raw water sterilization means 3, scale inhibitor injection means 4 and coagulant injection means 5 are provided between water intake means 1 and pretreatment means 2.
The raw water sterilization means 3 sterilizes microorganisms in the taken seawater (the taken seawater is also called “raw water” or the like). The raw water sterilization means 3 performs sterilization by injecting a bactericide into the raw water. As the disinfectant, for example, sodium hypochlorite solution, calcium hypochlorite solution, electric field chlorine, chloramine, and the like can be used. Among these, the use of a sodium hypochlorite solution is preferable because it can inactivate and sterilize microorganisms in the raw water and suppress propagation and biofilm formation in the system.
In addition, the sterilization by the raw water sterilization means 3 can be performed by other means such as irradiating seawater with ultraviolet rays or radiation.

  The scale inhibitor injection means 4 injects a chemical (a scale inhibitor) for preventing the generation of scale into the taken-in seawater. As the scale inhibitor, for example, a polymer such as a sulfuric acid solution, acrylic acid, maleic acid, and a copolymer salt of 2-hydroxyethyl methacrylate can be used. Among these, the use of a sulfuric acid solution is preferable because alkaline earth metals such as magnesium, calcium, and strontium contained in raw water can be prevented from depositing as carbonate or sulfate scales. These salts have sufficiently high solubility if the pH is adjusted to about 6. Therefore, when the pH of the raw water is adjusted to about 6, it is possible to prevent precipitation in the system piping, pump, reverse osmosis membrane and the like.

The flocculant injection means 5 injects the flocculant for the purpose of improving the particle removal performance in the pretreatment means 2 described later into the taken-in seawater. As the flocculant, for example, synthetic polymers such as ferric chloride, polyaluminum chloride, and polyacrylic acid can be used. If such a flocculant is used, it will combine with the particles in the raw water to form larger particle size (floc).
In a general reverse osmosis membrane filtration system, quality control of raw water supplied to a reverse osmosis membrane is performed using an index called SDI (Silt density index). In a general reverse osmosis membrane filtration system, the SDI is maintained at about 2, and it may be maintained at the same level in the present invention. Since the microorganisms in the sea water are about several μm in size, most of them are removed by the pretreatment means 2. Note that the floc removal performance of the pretreatment means 2 depends on the aperture of the film applied thereto.

(Pretreatment means)
The pretreatment means 2 removes flocs contained in the raw water as described above. As the pretreatment means 2, for example, sand filtration, flotation separation, ultrafiltration, and microfiltration can be applied. Flock and the like filtered by the pretreatment means 2 are discarded as sludge.

(Reducing agent injection means)
The pretreated water treated by the pretreatment means 2 is sent to the pretreated water adjustment tank 6. A reducing agent injection means 7 is provided between the pretreatment means 2 and the pretreatment water adjustment tank 6. The reducing agent injection means 7 injects SBS (sodium bisulfite, NaHSO ₃ ) or the like into the pretreated water to reduce hypochlorite ions injected by the raw water sterilization means 3. Thereby, when the material of the reverse osmosis membrane used in the reverse osmosis membrane treatment means 8 is polyamide or the like, it is possible to prevent the membrane from being oxidized by hypochlorite ions and reducing the ion rejection rate. it can. In addition, as a result, the redox potential of the pretreatment water injected into the reverse osmosis membrane treatment means 8 is set to 100 mV vs. It can be about Ag / AgCl, and the pH can be about 6.

(Pretreatment water adjustment tank)
The pretreatment water adjustment tank 6 has a purpose of refining raw water to a necessary level so as not to impose a load on each downstream means / process. The adjustment of the pretreatment water can be appropriately terminated depending on the degree of contamination of the raw water.

  A high pressure pump P <b> 2 is provided between the pretreatment water adjustment tank 6 and the reverse osmosis membrane treatment means 8. The high-pressure pump P2 supplies pretreatment water from the pretreatment water adjustment tank 6 to the reverse osmosis membrane treatment means 8 at an appropriate pressure. The pressure of the high-pressure pump P2 can be set to 4 to 8 MPa, for example. With such a pressure, the reverse osmosis membrane treatment means 8 can appropriately perform the treatment. As the high-pressure pump P2, any pump can be used as long as it can be used for the reverse osmosis membrane treatment.

(Reverse osmosis membrane treatment means)
The reverse osmosis membrane treatment means 8 produces fresh water by filtering (desalting) pretreated water, which is seawater taken, through a reverse osmosis membrane. The reverse osmosis membrane processing means 8 can be implemented by a reverse osmosis membrane module having a reverse osmosis membrane.

  Here, the reverse osmosis membrane has many pores with a size of approximately 2 nm or less and allows water in the supplied seawater (pretreated water) to pass through, but permeates components other than water such as chloride ions. This refers to a semipermeable membrane that is not allowed. As the reverse osmosis membrane, both a flat membrane type and a hollow fiber type can be used. The reverse osmosis membrane includes a so-called nanofiltration membrane and a loose reverse osmosis membrane. The reverse osmosis membrane is preferably made of a polymer material such as cellulose acetate polymer, polyamide, polyester, polyimide, pinyl polymer, polyvinyl alcohol, polysulfone. A reverse osmosis membrane having a thickness of about 10 μm to 1 mm can be used.

  The reverse osmosis membrane module refers to a module provided with the above-described reverse osmosis membrane in a housing. As the reverse osmosis membrane module, for example, a spiral type module, a hollow fiber type module, a tubular type module, or a plate and frame type module can be used.

  Fresh water produced by filtration (desalting treatment) by the reverse osmosis membrane treatment means 8 is sent to the fresh water adjustment tank 14, and seawater from which moisture has been removed to increase the salt concentration is referred to as waste water (hereinafter referred to as concentrated waste water). ) And then discharged.

(Fresh water adjustment tank)
The fresh water adjustment tank 14 temporarily stores fresh water produced by the reverse osmosis membrane treatment means 8 and adjusts the amount of water.

(Alkaline agent injection means, mineral injection means, fresh water sterilization means)
The fresh water adjusted in the fresh water adjustment tank 14 is sent out of the fresh water adjustment tank 14 by the pump P3. Note that fresh water adjusted in the fresh water adjustment tank 14 has a low pH and a low concentration of minerals such as calcium. Therefore, the alkali agent injection | pouring means 15 and the mineral injection | pouring means 16 are provided after the fresh water adjustment tank 14, and a sodium hydroxide solution and calcium carbonate are added from each means, for example. Further, since the bactericide such as sodium hypochlorite added by the raw water sterilization means 3 has been removed by the reverse osmosis membrane treatment means 8, the fresh water sterilization means 17 is maintained so that the disinfection effect can be maintained up to the end of the water supply. By adding a bactericidal agent such as a chlorine agent. The fresh water that meets the standards for drinking water manufactured in this way is transported to the required place by piping or by being packed in a tank or the like, and is drunk.

The reverse osmosis membrane filtration system S produces fresh water from seawater as described above. Then, as described above, the reverse osmosis membrane filtration system S periodically or at the time when the reverse osmosis membrane treatment means 8 is operated, the pH adjusting agent injection means 9, the cleaning agent injection means 10, and the bactericide injection means. 11 is operated, the biofilm generated in the reverse osmosis membrane treatment means 8 is removed, and the microorganisms that produce the biofilm are sterilized.
Hereinafter, the removal of the biofilm by these is demonstrated.

(PH adjuster injection means, cleaning agent injection means, bactericidal agent injection means)
The pH adjusting agent injection means 9, the cleaning agent injection means 10 and the bactericide injection means 11 are provided between the pretreatment water adjustment tank 6 and the reverse osmosis membrane treatment means 8.
The pH adjuster injection means 9, the cleaning agent injection means 10 and the bactericidal agent injection means 11 do not operate during normal operation (during manufacture) of producing fresh water from seawater, and it is determined that the reverse osmosis membrane needs to be cleaned and sterilized. Work on a regular basis. The pH adjusting agent injection means 9, the cleaning agent injection means 10 and the bactericidal agent injection means 11 are each provided with a pump (not shown), and the respective chemicals are supplied to the pretreated water by the pump. A flow meter for measuring the flow rate of the drug is provided on the path to these pumps and pretreatment water, and the flow rate (process flow rate) of the drug measured thereby is input to the control means 13. . The control means 13 calculates the injection amount of each drug by multiplying the concentration and the treatment flow rate for each drug, and controls the injection amount by increasing / decreasing or stopping the supply amount by the pump. .

  The pH adjuster injection means 9 supplies an alkaline agent, for example, a pH adjuster such as a sodium hydroxide solution, to the pretreated water. By adjusting the pH of the pretreatment water by the pH adjusting agent injection means 9, it is possible to efficiently perform the cleaning by the cleaning agent injection means 10 performed later. The pH adjusting agent injection means 9 may adjust the pH of the pretreatment water to be near neutral, for example, about pH 6.5 to 7.5, but is not limited to this, and the characteristics of the cleaning agent (for example, The pH can be appropriately changed depending on the optimum pH of the enzyme used.

  The cleaning agent injection means 10 supplies a cleaning agent for cleaning the biofilm grown on the surface of the reverse osmosis membrane to the pretreatment water. The cleaning agent is not particularly limited as long as it is a component that can decompose or dissolve the biofilm. Biofilm components are complex, such as polysaccharides, proteins, and lipids, but the ratio of polysaccharides and proteins is high. Therefore, as the cleaning agent, enzymes that decompose these are preferable, and for example, cellulase, amylase, and protease are preferable. Moreover, you may add the lipase which decomposes | disassembles fat.

  The sterilizing agent injection means 11 supplies a sterilizing agent for sterilizing microorganisms in the biofilm to the pretreated water. The bactericidal agent is preferably one that can sterilize microorganisms in the biofilm and has little deterioration of the reverse osmosis membrane. For example, 2,2-dibromo-3-nitrilopropionamide (DBNPA), sodium hydroxide solution, and the like can be applied.

(PH meter, control means)
The pH meter 12 is provided immediately before the reverse osmosis membrane treatment means 8 and measures the change in the pH of the pretreatment water by the pH adjuster injection means 9. The measured value measured by the pH meter 12 is output to the control means 13. Based on the measured value, the control means 13 controls the injection amount of the pH adjusting agent as described later. As the pH meter 12, any commercially available product that can measure pH can be applied.

  The control means 13 is connected to the pH meter 12 and the pH adjusting agent injection means 9, the cleaning agent injection means 10 and the sterilizing agent injection means 11 described above. The control means 13 is connected to the above-described means and other means not shown and described, and appropriately controls each means during fresh water production. A commercially available computer or the like can be applied to the control means 13.

(Removal and sterilization of reverse osmosis biofilm)
The reverse osmosis membrane filtration system S according to the first embodiment having the configuration described above removes the biofilm from the reverse osmosis membrane and sterilizes the microorganisms protected thereby (hereinafter referred to as “washing”).・ It may be called “sterilization operation”.
The washing and sterilization operation in the reverse osmosis membrane filtration system S according to the first embodiment interrupts the fresh water production process by the reverse osmosis membrane filtration system S periodically or triggered by the operating state of the reverse osmosis membrane treatment means 8. And implement.

  Specifically, first, when the pH measured by the pH meter 12 exceeds a predetermined value set in advance, a switching signal is output from the control means 13 to the valve V1. The valve V1 is a so-called three-way valve and normally sends fresh water produced by the reverse osmosis membrane treatment means 8 to the fresh water adjustment tank 14, but is discharged from the reverse osmosis membrane treatment means 8 by switching the connection. It is provided so that it can merge with concentrated wastewater. Therefore, when the switching signal described above is input, the valve V1 switches so that the water desalinated by the reverse osmosis membrane treatment means 8 merges with the concentrated waste water.

  When the connection destination of the valve V1 is switched, the control means 13 outputs a start signal to the pH adjuster injection means 9. The pH adjuster injecting means 9 to which the start signal is inputted injects the pH adjuster into the pretreated water, and the value of the pH meter 12 at the stage of flowing into the reverse osmosis membrane treatment means 8 is neutral, preferably pH 6. Adjust to a range of 5 to 7.5. As described above, this is intended to make the pretreated water, which is acidified by the scale inhibitor injection means 4 and becomes acidic, substantially neutral. Thereby, degradation of the biofilm by the cleaning agent (enzyme) is caused to act more effectively.

  When the pH falls within a predetermined range (pH 6.5 to 7.5), the control unit 13 outputs a start signal to the cleaning agent injection unit 10. The cleaning agent injection means 10 to which the start signal is input injects the cleaning agent into the pretreated water. Detergents break down some of the substances produced by microorganisms through metabolism, such as biofilm polysaccharides and proteins. Detergent injection conditions (eg, injection volume and / or injection time) depend on the amount and type of biofilm. For this reason, the amount of biofilm produced in the cycle in which the biofilm of the reverse osmosis membrane is removed and sterilized and the degradation characteristics by the enzyme are investigated in advance, and injection conditions (for example, injection volume and / or injection time) are set. It is preferable that the cleaning agent is injected based on such injection conditions.

  The triggers for starting biofilm removal and sterilization of reverse osmosis membranes include reverse osmosis membrane permeation flux, reverse osmosis membrane transmembrane pressure, reverse osmosis membrane flow resistance (inflow point and concentrated wastewater outflow). The boundary value of each index of salt rejection rate, or a combination of these is registered in the control means 13 and can be executed when deviating from this boundary value.

  When the cleaning agent injection satisfies the predetermined injection condition, the control unit 13 outputs a stop signal to the pH adjusting agent injection unit 9 and the cleaning agent injection unit 10. The pH adjusting agent injection means 9 and the cleaning agent injection means 10 to which the stop signal is input stop the injection of the pH adjusting agent and the injection of the cleaning agent, respectively.

  Next, the control means 13 outputs a start signal to the bactericide injection means 11. The sterilizing agent injection means 11 to which the start signal is input injects the sterilizing agent into the pretreated water. The sterilant injection conditions (eg, injection amount and / or injection time) depend on the type of sterilant, biofilm cleaning conditions, biofilm residue, and reverse osmosis membrane degradation. Therefore, the sterilization performance after the cleaning operation is investigated in advance, the injection conditions (for example, the injection amount and / or the injection time) for obtaining a predetermined sterilization effect are determined and registered in the control means 13, and the injection conditions It is preferable to inject a bactericide on the basis of

  When the injection of the sterilizing agent satisfies the injection conditions, the control unit 13 outputs a stop signal to the sterilizing agent injection unit 11. The sterilizing agent injection means 11 to which the stop signal is input stops the sterilizing agent injection.

  When the injection of the sterilizing agent by the sterilizing agent injection unit 11 is stopped, the control unit 13 outputs a return signal to the valve V1. The valve V1 to which the return signal is input switches the connection destination from the concentrated waste water side to the fresh water adjustment tank 14 and restarts the reverse osmosis membrane treatment for fresh water production.

When the biofilm is removed and sterilized in this manner, the sterilization treatment is performed after the EPS acting as a protective film for microorganisms is decomposed with the cleaning agent, so that the sterilizing effect of the sterilizing agent can be enhanced.
Moreover, since the bactericidal effect is improved, microorganisms remaining on the surface of the reverse osmosis membrane are reduced as compared with the conventional method, and re-formation of the biofilm after the treatment can be suppressed. Thereby, biofouling does not occur for a long period of time, and it is possible to prevent an increase in the amount of electric power of the high-pressure pump that maintains a predetermined flux, or to reduce the frequency of replacement of the reverse osmosis membrane module.
In addition, since the water quality and / or biofilm status in the reverse osmosis membrane module is measured with a measuring instrument and the amount of drug injected is controlled based on the results, the biofilm can be removed to a predetermined level each time. A stable reverse osmosis membrane treatment operation can be realized.

Second Embodiment
(Main components of the reverse osmosis membrane filtration system according to the second embodiment)
The reverse osmosis membrane filtration system S according to the second embodiment has substantially the same configuration as that of the first embodiment, but is not shown by the control means 13 installed before and after the high-pressure pump P2 and the reverse osmosis membrane treatment means 8. It is different in that a valve is provided and operated to remove and sterilize the biofilm of the reverse osmosis membrane.
In the reverse osmosis membrane filtration system S according to the second embodiment, the biofilm of the reverse osmosis membrane is removed and sterilized as follows.

(Removal and sterilization of reverse osmosis biofilm)
The inside of the reverse osmosis membrane module at the time of fresh water production is in a high pressure state of about 5 MPa. In the second embodiment, the control means 13 is operated so as to supply pretreated water (taken seawater) to the reverse osmosis membrane treatment means 8 (reverse osmosis membrane module) at a lower pressure than when fresh water is produced when the cleaning agent is injected. Control. That is, the pressure of the high-pressure pump P2 and / or the opening of the valve (not shown) is controlled. The pressure in the reverse osmosis membrane module at the time of injecting the cleaning agent is ½ or less, preferably 1 MPa or less, during fresh water production. At this time, as the pressure in the reverse osmosis membrane module is reduced, the flow rate of the pretreatment water containing the cleaning liquid is also reduced. This flow rate varies depending on how pressure is applied (that is, the pressure setting of the high-pressure pump P2 and / or the opening of the valve (not shown)), the structure of the reverse osmosis membrane module, and the state of biofilm generation. It is 1/2 or less, preferably 1/10 or less of the supply flow rate of seawater.

  Next, the control means 13 controls the operation of supplying the pretreated water to the reverse osmosis membrane treatment means 8 at a pressure higher than that during the production of fresh water when the sterilizing agent is injected. That is, the pressure of the high pressure pump P2 is controlled. At the time of sterilization operation, the pressure in the reverse osmosis membrane module and the flow rate of the pretreatment water containing the sterilizing agent are at least larger than those at the time of the washing operation, preferably higher than at the time of fresh water production. The control means 13 controls the pressure of P2 and / or the opening of the valve (not shown).

  By such pressure and flow rate control during the cleaning operation, the action of the cleaning agent and the bactericidal agent on the biofilm changes. By decreasing the flow rate, the enzyme as a cleaning agent has a longer residence time in the vicinity of the biofilm. In addition, the decrease in the flow rate inside the reverse osmosis membrane module eliminates uneven flow due to the spacer, and facilitates the supply of the enzyme to the flow retention part (that is, the region where biofilm formation is likely to occur) due to the diffusion effect. It becomes.

  On the other hand, the biofilm produced | generated in the state of the high pressure at the time of freshwater manufacture contains the water | moisture content equivalent to an equivalent pressure inside. In order to obtain a pressure equilibrium when the pressure at the time of injecting the cleaning agent is reduced, a part of the water in the biofilm is released out of the biofilm. Since high pressure is applied at the time of injection, moisture enters the biofilm from the outside in order to rebalance the pressure. At this time, since the bactericidal agent also enters at the same time, the bactericidal agent reaches the center of the biofilm.

Furthermore, the increase in the flow rate of the pretreatment water when starting the sterilization process causes a change in flow rate in the flow path inside the reverse osmosis membrane module. Therefore, shear force is generated in the biofilm due to water flow, and peeling of the biofilm whose strength has been reduced by the cleaning agent from the substrate (reverse osmosis membrane or spacer) can be promoted.
When the cleaning / sterilization operation is completed, the reverse osmosis membrane treatment for fresh water production is resumed in the same manner as in the first embodiment.

  When the biofilm is removed and sterilized in this manner, in addition to the effects described in the first embodiment, the supply of the cleaning agent to the staying portion in the reverse osmosis membrane module is promoted. The effect can be improved. In addition, since the bactericidal agent is introduced into the center of the biofilm, the procedure described in the first embodiment can also be effective against microorganisms that have been in a region where the bactericidal effect is not sufficient.

In order to obtain a greater effect, the osmotic pressure difference inside and outside the biofilm is used. That is, in order to drain water from the biofilm by a washing operation, it is better that the external salt concentration is high. Therefore, for example, concentrated waste water discharged from the reverse osmosis membrane treatment means 8 may be used. Conversely, in the sterilization step, water is introduced into the biofilm, and therefore, for example, fresh water having a lower osmotic pressure than seawater may be used.
Furthermore, since a physical action due to a shearing force due to a change in flow velocity is added, the removal of the biofilm is promoted more than the case of only the chemical action by the enzyme.

<Third Embodiment>
(Main components of the reverse osmosis membrane filtration system according to the third embodiment)
FIG. 2 is a block diagram showing a configuration of a reverse osmosis membrane filtration system S according to the third embodiment.
As shown in FIG. 2, in the reverse osmosis membrane filtration system S according to the third embodiment, the reverse osmosis membrane treatment means 8 is provided with a measurement means 21 that measures the amount of biofilm and outputs it to the control means 13. This is different from the first embodiment.

  In the third embodiment, the control unit 13 includes the pH adjustment agent injection unit 9, the cleaning agent injection unit 10, and the bactericide injection unit based on the measurement result measured by the measurement unit 21 together with the measurement value of the pH meter 12. 11 is controlled. That is, in the third embodiment, the measured value measured by the measuring means 21 is used for starting the cleaning / sterilizing operation, setting the cleaning agent injection condition, and / or the sterilizing agent injection condition.

  In addition, as the measurement means 21, the differential pressure gauge which measures the pressure difference inside and outside the reverse osmosis membrane processing means 8 can be mentioned. Moreover, as the measurement means 21, optical apparatuses, such as a camera, a microscope, and a spectrometer which observe the state of a biofilm, can also be mentioned. These optical instruments are also preferably used in combination with a flow cell or the like. Further, as the measuring means 21, a measuring instrument such as HPLC capable of measuring an inhibitor (autoinducer) of quorum sensing can be cited. These will be described in detail later. FIG. 2 shows an example in which a differential pressure gauge that measures the pressure difference inside and outside the reverse osmosis membrane treatment means 8 is used as the measurement means 21.

  As shown in FIG. 2, the differential pressure in the third embodiment corresponds to the flow resistance of the reverse osmosis membrane (the differential pressure between the inflow point and the concentrated wastewater outflow point). Although the differential pressure gauge may be installed only in one reverse osmosis membrane module, it is preferable to install the differential pressure gauge in a plurality of reverse osmosis membrane modules and use an average value or a maximum value. This is because the reverse osmosis membrane modules are arranged in various ways, such as in series or divided (arrangement where the number of modules increases toward the downstream side), and thus the state of biofilm formation differs for each reverse osmosis membrane module.

  In the reverse osmosis membrane filtration system S according to the third embodiment in which a differential pressure gauge is provided as the measuring means 21, the biofilm of the reverse osmosis membrane is removed and sterilized as follows.

(Removal and sterilization of reverse osmosis biofilm)
FIG. 3 is a flowchart showing a control flow in the third embodiment.
As in the first embodiment, the control means 13 first switches the connection of the valve V1 so that the fresh water produced by the reverse osmosis membrane treatment means 8 and the concentrated wastewater discharged from the reverse osmosis membrane treatment means 8 Let them merge (see FIG. 2).

Next, as shown in FIG. 3, the control means 13 outputs a start signal to the pH adjusting agent injection means 9 in step S301.
The pH adjusting agent injecting means 9 to which the start signal is input starts injecting the pH adjusting agent into the pretreated water sent from the pretreated water adjusting tank 6 toward the reverse osmosis membrane treating means 8 by the high pressure pump P2.

Next, in step S302, it is determined whether the pH measured by the pH meter 12 is within a predetermined range (for example, pH 6.5 to 7.5) registered in the control means 13.
If the pH is not within the predetermined range registered in the control means 13 (No in step S302), the injection amount is adjusted by continuing the injection of the pH adjusting agent in step S303. For this adjustment, general PID control can be applied.

  If the pH measured by the pH meter 12 is within the predetermined range registered in the control means 13 in step S302 (Yes in step S302), the process proceeds to step S304. In step S <b> 304, the measuring unit 21 acquires an initial value of the differential pressure ΔP and outputs it to the control unit 13. Note that the initial value of the differential pressure ΔP indicates the initial state of the biofilm before washing.

  The control means 13 to which the initial value of the differential pressure ΔP is input outputs a start signal toward the cleaning agent injection means 10 in step S305. The cleaning agent injection means 10 to which the start signal is input starts injecting the cleaning agent into the pretreated water.

  The upper limit (t0) of the cleaning agent injection time is registered in advance in the control means 13, and in step S306, the actual cleaning agent injection time is compared with t0 registered in advance (cleaning agent injection time> t0).

  When the cleaning agent injection time is shorter than t0 (No in step S306), the control unit 13 proceeds to step S307 and confirms whether the differential pressure ΔP is smaller than the set value ΔP0 (ΔP <ΔP0). The set value ΔP0 is a reference value for the differential pressure ΔP at a predetermined flow rate in a reverse osmosis membrane that has been sufficiently washed. Therefore, when the actually measured differential pressure ΔP is larger than the set value ΔP0 (No in step S307), it indicates that the amount of biofilm attached on the reverse osmosis membrane is large. Therefore, the process returns to step S306 again and the injection of the cleaning agent is continued.

  When the cleaning agent injection time becomes longer than t0 (Yes in Step S306) and when the set value ΔP0 becomes larger than the differential pressure ΔP (Yes in Step S307), the control means 13 proceeds to Step S308 and adjusts the pH. A stop signal is output toward the agent injection means 9 and the cleaning agent injection means 10. The pH adjusting agent injection means 9 and the cleaning agent injection means 10 to which the stop signal is input stop the injection of the respective drugs.

  When the injection of the pH adjusting agent and the cleaning agent is stopped, the process proceeds to step S309, and the control means 13 again outputs a remeasurement signal for measuring the differential pressure ΔP toward the measurement means 21. The measuring means 21 to which the re-measurement signal is inputted measures the differential pressure ΔP again and outputs the measured value to the control means 13. The control means 13 to which the measured value of the differential pressure ΔP that has been measured again is input proceeds to step S310 and calculates the injection condition of the bactericide.

When the differential pressure ΔP is equal to or less than the set value ΔP0, the disinfectant injection conditions (for example, the injection amount and / or the injection time) set in the control means 13 in advance may be used.
On the other hand, when the differential pressure ΔP is larger than the set value ΔP0, the injection condition is calculated as a function of (ΔP−ΔP0). The function is obtained using, for example, A × (ΔP−ΔP0) ⁿ + B as the injection amount of the bactericide. Here, A, B, and n are constants. The constant A is a constant for determining the injection amount of the necessary bactericide with respect to the net adhesion amount of the biofilm. The constant B is a constant for considering in advance the amount of disinfectant consumed by seawater. When the constant B is insufficient, the bactericidal agent is consumed by organic substances, inorganic substances, or microorganisms contained in the seawater, and a substantial amount of the bactericidal agent reaching the biofilm is insufficient.

  These constants need to be adjusted according to the quality of seawater, the specifications of the reverse osmosis membrane module, and the type of disinfectant. As the value of B, for example, an injection amount obtained by adding a bactericide to the target seawater and measuring the concentration of the bactericide that works effectively after a predetermined time may be used as B. That is, the consumption of the disinfectant by seawater is measured, and the obtained injection amount may be used as B. Since the quality of seawater changes throughout the year, it is desirable to update the value of B every month, for example.

  Further, the value of A needs to be determined in consideration of the bactericidal effect on microorganisms in the biofilm. For example, a biofilm obtained when reverse osmosis membrane treatment is performed on the target seawater, a bactericidal agent is added thereto, and a bactericidal effect after a predetermined time, that is, living microorganisms and death It is only necessary to measure the number of microorganisms in use and use this value. Since the properties of the biofilm also change, it is preferable to reset the value of A according to the increasing speed of the differential pressure ΔP after the washing / sterilizing operation.

  The value of n is preferably n = 3/2 in order to convert the differential pressure ΔP depending on the cross-sectional area of the channel into the volume of the biofilm that needs to be sterilized.

  When the sterilizing agent injection conditions are calculated in step S310, the process proceeds to step S311 to inject the sterilizing agent into the pretreatment water from the control unit 13 toward the sterilizing agent injecting unit 11 with an injection amount based on the calculation result. Output a start signal. The sterilizing agent injecting means 11 to which the start signal is input injects the sterilizing agent of the injection amount based on the calculation result into the pretreated water.

  In the next step S312, the control means 13 confirms whether the injection amount of the bactericide is within the range of the bactericide injection conditions. When the injection condition of the sterilizing agent is not satisfied (No in Step S312), the control unit 13 outputs a continuation signal for continuously injecting the sterilizing agent toward the sterilizing agent injection unit 11. The sterilizing agent injection means 11 to which the continuation signal is input continuously injects the sterilizing agent into the pretreated water.

  In step S312, the control unit 13 outputs a stop signal to the sterilizing agent injection unit 11 when the injection amount of the sterilizing agent satisfies the sterilizing agent injection condition (Yes in step S312). The sterilizing agent injection means 11 to which the stop signal is input stops the sterilizing agent injection.

  In the reverse osmosis membrane filtration system S according to the third embodiment in which a differential pressure gauge is provided as the measuring means 21, the biofilm of the reverse osmosis membrane is removed and sterilized by controlling as described above.

In the third embodiment, the injection amount of the bactericide is controlled, but the injection time is changed with the concentration of the bactericide constant, or the CT value (that is, the injection amount and / or the injection time of the bactericide) is used as an index. The function using the differential pressure ΔP may be changed so that the injection conditions are set as follows. Even when the differential pressure ΔP is equal to or less than the set value ΔP0, an appropriate function can be set to determine the cleaning agent injection conditions.
In addition, although the injection | pouring time of a cleaning agent or a disinfectant changes with effects of each chemical | medical agent, it is desirable to implement each in the range for 30 minutes to 6 hours.

  When the biofilm is removed and sterilized in this manner, in addition to the effects described in the first embodiment, the sterilizing agent that reflects the actual cleaning result can be injected, so that the number of living microorganisms is reduced and Reformation of the film can be suppressed. In addition, since appropriate amounts of the cleaning agent and the bactericidal agent can be injected by the differential pressure ΔP, the drug cost can be optimized.

In the third embodiment, a differential pressure gauge is used as the measuring means 21. However, as described above, for example, a flow cell and a measuring device capable of optically measuring the state of biofilm generation can be used. .
When using a flow cell, it connects so that the same seawater as the reverse osmosis membrane processing means 8 may flow in. The internal structure of the cell is constructed so as to reproduce the spacer structure and flow velocity inside the reverse osmosis membrane module.
In addition, when the flow cell is made of an optically transparent material, for example, the state of the biofilm can be observed using optical equipment such as a camera, a microscope, and a spectrometer, thereby evaluating the amount of the biofilm, It can also be measured.
When using a camera image, the ratio (area ratio) of the biofilm to the image can be calculated by image processing. The value calculated in this way can be used similarly to the case of the differential pressure ΔP. Further, the absorbance measured value by the spectrometer can be used similarly to the case of the differential pressure ΔP.

  As another measuring means 21, for example, there is an auto inducer measuring instrument used for quorum sensing between microorganisms. Quorum sensing is a mechanism that senses the density of microorganisms of the same or different types and controls the production of substances accordingly. An auto inducer is a substance used for information transmission between microorganisms. When this concentration reaches a predetermined value, a function of a specific gene is activated. Autoinducers vary depending on the microorganism, but include AHL (Acylate Homoserine Lactone, acylated homoserine lactone) and DKP (diketopiperazines).

  As a measuring method of AHL, there are a method using a reporter strain and a thin layer chromatography multi-layer method. Since the concentration of the autoinducer reflects the number of microorganisms and the state of biofilm formation, input information for controlling the cleaning / sterilization operation by the control means 13 as in the above-described differential pressure and optical measurement methods. Can be used as

A method for quantifying AHL using a reporter strain is introduced, for example, in “Introduction to Biofilm” (Nichikagiren). Using a reporter strain in which the AHL synthesis gene is disrupted, a protein (R protein) that binds to AHL from the outside is overexpressed.
And AHL is detectable by producing purple pigment | dye as a response of R protein with respect to AHL. In addition, the structure and quantification of AHL can be performed by conducting analysis using a reporter strain after developing the bacteria using thin layer chromatography.
Specific examples of reporter strains include Agrobacterium tumefaciens A136 (pCF218) (pCF372) and Chromobacterium violaceum CV026.

  There are also inhibitors (quorum sensing inhibitors) that inhibit quorum sensing. This inhibitor has no biofilm cleaning effect or microbial bactericidal effect, but injection of the inhibitor can suppress the progression of the biofilm growth process involving quorum sensing.

  Therefore, an injection means for injecting a quorum sensing inhibitor is provided, and when the autoinducer concentration exceeds a predetermined concentration, the quorum sensing inhibitor is continuously or intermittently injected. You can also. As such a quorum sensing inhibitor, for example, AHL lactonase, AHL acylase and the like can be applied. The means for injecting the quorum sensing inhibitor is preferably between the reducing agent injection means 7 and the high-pressure pump P2.

  With such a configuration, in addition to the effects described in the first embodiment, since the growth of biofilm can be suppressed while continuing the operation of freshwater production, when the growth rate of the biofilm is specifically fast However, a planned operation (fresh water production and washing / sterilization operation) based on the water demand can be performed.

<Fourth embodiment>
(Main components of the reverse osmosis membrane filtration system according to the fourth embodiment)
The fourth embodiment has the same configuration as the first to third embodiments, but the cleaning agent injection mode is changed (not shown). The contents will be described below.

  As an internal structure of the reverse osmosis membrane, a spacer having a network structure with a pitch of several mm to several cm is inserted. The spacer functions to prevent contact between the reverse osmosis membranes and to prevent occurrence of a short circuit flow and uneven distribution of concentration in the module. However, flow velocity distributions occur within individual meshes. The stay portion of the flow generated by the spacer is easy for microorganisms to adhere to and hardly peels off due to shearing force, so that the biofilm easily grows.

  Therefore, in this 4th Embodiment, the structure which supplies the enzyme which is a washing | cleaning agent efficiently to this residence part is employ | adopted. Specifically, the cleaning agent is supplied in the form of particles. These particles are a mixture of an enzyme, which is a cleaning agent, and a sugar, and preferably have a structure in which the sugar covers the enzyme. The particles can be obtained by dissolving or diffusing enzymes and sugars in water, spraying the solution or slurry, or evaporating water in the air. The particle size of the particles depends on the concentration of each substance in the water and the size of the droplets to be sprayed, but in order to be injected as a cleaning agent, the diameter is 50 μm or less, preferably 5 μm or less.

  In the case of an enzyme that can be present in water, it is formed as a mixture with sugar in the particle production method described above. On the other hand, an enzyme of a kind existing as an individual in water evaporates water from a state in which the enzyme is covered with a sugar solution, and thus is in a form covered with sugar. Such particles are made into a slurry immediately before the injection of the cleaning agent and injected into the pretreatment water.

  According to such an aspect, in addition to the effects described in the first embodiment, the particles of the cleaning agent can be retained or adsorbed on the portion where the retention is caused by the spacer in the reverse osmosis membrane module. The cleaning effect can be further improved.

As mentioned above, although the content of this invention was demonstrated in detail by embodiment which implements this invention, this invention is not limited to an above-described content, Various modifications are included. For example, the above-described embodiment has been described in detail for easy understanding of the present invention, and is not necessarily limited to one having all the configurations described. Further, a part of the configuration of one embodiment can be replaced with the configuration of another embodiment, and the configuration of another embodiment can be added to the configuration of one embodiment. In addition, it is possible to add, delete, and replace other configurations for a part of the configuration of each embodiment.
Each of the above-described configurations, functions, processing units, processing means, and the like may be realized by hardware by designing a part or all of them with, for example, an integrated circuit. Each of the above-described configurations, functions, and the like may be realized by software by the processor interpreting and executing a program that realizes each function. Information such as programs, tables, and files for realizing each function can be stored in a recording device such as a memory, a hard disk, an SSD (Solid State Drive), or a recording medium such as an IC card, an SD card, or a DVD.
Further, the control lines and information lines indicate what is considered necessary for the explanation, and not all the control lines and information lines on the product are necessarily shown. Actually, it may be considered that almost all the components are connected to each other.

S reverse osmosis membrane filtration system 8 reverse osmosis membrane treatment means 9 pH adjusting agent injection means 10 cleaning agent injection means 11 bactericidal agent injection means

Claims (8)

A reverse osmosis membrane treatment means having a reverse osmosis membrane for producing fresh water by filtering the taken seawater;
In a position before supplying the taken seawater to the reverse osmosis membrane treatment means,
PH adjusting agent injection means for injecting a pH adjusting agent for adjusting the pH of the taken-in seawater into the taken-up seawater;
Cleaning agent injection means for injecting a decomposing agent for decomposing biofilm components generated on the surface of the reverse osmosis membrane into the taken-in seawater;
A bactericidal agent injection means for injecting a bactericidal agent for sterilizing microorganisms protected by the biofilm into the taken-in seawater;
A reverse osmosis membrane filtration system characterized by comprising: The reverse osmosis membrane filtration system according to claim 1,
Connected to the pH adjusting agent injection means, the cleaning agent injection means, and the sterilizing agent injection means, and controls the injection amount of the pH adjusting agent, the injection amount of the cleaning agent, and the injection amount of the sterilizing agent, respectively. Control means to
The control means injects the cleaning agent while injecting the pH adjusting agent so that the pH falls within a preset range, and after the injection of the pH adjusting agent and the cleaning agent is completed, the sterilization is performed. A reverse osmosis membrane filtration system characterized by performing operation control for injecting the agent. The reverse osmosis membrane filtration system according to claim 1,
The pH adjusting agent injection means, the cleaning agent injection means, and the sterilizing agent injection means are connected, and the injection amount of the pH adjusting agent, the injection amount of the cleaning agent, and the injection amount of the 8 sterilizing agent, respectively. Control means for controlling,
The control means supplies the drawn seawater to the reverse osmosis membrane treatment means at a pressure lower than that at the time of fresh water production when the cleaning agent is injected, and the reverse osmosis at a pressure higher than that at the time of fresh water production when the sterilizing agent is injected. A reverse osmosis membrane filtration system which performs operation control to supply the taken seawater to the membrane treatment means. The reverse osmosis membrane filtration system according to claim 3,
The reverse osmosis membrane filtration system, wherein the pressure of water supplied to the reverse osmosis membrane treatment means at the time of injection of the cleaning agent is ½ or less of that in fresh water production. The reverse osmosis membrane filtration system according to claim 3,
The reverse osmosis membrane filtration system, wherein the pressure of water supplied to the reverse osmosis membrane treatment means when the cleaning agent is injected is 1 MPa or less. The reverse osmosis membrane filtration system according to claim 1,
Connected to the pH adjusting agent injection means, the cleaning agent injection means, and the sterilizing agent injection means, and controls the injection amount of the pH adjusting agent, the injection amount of the cleaning agent, and the injection amount of the sterilizing agent, respectively. Control means to
The control means supplies the drawn seawater to the reverse osmosis membrane at a flow rate lower than that at the time of fresh water production when the cleaning agent is injected, and supplies the reverse osmosis membrane to the reverse osmosis membrane at a flow rate higher than that at the time of fresh water production when the sterilizer is injected. A reverse osmosis membrane filtration system characterized by performing operation control for controlling to supply water. The reverse osmosis membrane filtration system according to any one of claims 2 to 6,
Measuring means for measuring the amount of the biofilm and outputting to the control means,
The control means, from the measurement value input from the biofilm amount measurement means, start of injection of the cleaning agent, start of injection of the sterilizing material, determination of injection conditions of the cleaning agent, and injection conditions of the sterilizing agent A reverse osmosis membrane filtration system, wherein at least one of the determinations is made. The reverse osmosis membrane filtration system according to claim 7,
The reverse osmosis membrane filtration system, wherein the measurement object by the measurement means is any one of a differential pressure, a camera, a microscope, a spectrometer, and a quorum sensing inhibitor.

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