JP2000005575A - System and method for membrane life monitoring - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a system and method by which the membrane life can be monitored easily and in real time and furthermore, a water treating device and method having the above system or method. SOLUTION: A water treating device 1 is provided with a raw water tank 10, a circulating line 3 connected to the raw water tank 10, treating lines 4 branched from the circulating line 3, treated water tanks 11 connected to the treating lines 4, and a membrane life monitoring system 2. The membrane life monitoring system 2 is provided with a first sampling line 6, a second sampling line 7, and a detector 9. The detector 9 searches for a removing rate of silica on membrane modules 8.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a system and method for monitoring the life of a membrane, and more particularly to a water treatment apparatus and method.

[0002]

2. Description of the Related Art In a water treatment apparatus such as a water purification apparatus using a membrane, the membrane deteriorates in a microscopic part as it is used, and in addition, pressure is applied to the membrane, so that the raw water is moved to the treated water side. It is known that the probability of leakage increases over time.

In such a water treatment apparatus, conventionally,
The life of the membrane is monitored by measuring the differential pressure of a pressure gauge attached to the front and rear of the membrane or by measuring the amount of water taken by the apparatus to maintain the quality of the treated water. In addition, the quality of the treated water is maintained by periodically replacing the membrane, and further by examining the presence or absence of viable bacteria, endotoxin, and the like in the treated water.

However, in the former two methods, it is difficult to detect a minute abnormality such as a film leak. For this reason,
Substances to be removed by the membrane may leak to the treated water side.

[0005] In addition, it takes a considerably long time (eg, one hour) to test for the presence of live bacteria, endotoxin, and the like.
It is difficult to monitor the film life in real time.

[0006] In particular, in water quality control at the subsequent stage of a water-for-injection or ultrapure water production apparatus using a membrane, there is no means to detect the degradation of the membrane because there is no substance to be quantified.

[0007]

SUMMARY OF THE INVENTION It is an object of the present invention to provide a system and method for easily and real-time monitoring of membrane life, and a water treatment apparatus and method having the system or method.

[0008]

This and other objects are achieved by the present invention which is defined below as (1) to (17).

(1) In a membrane life monitoring system for monitoring a membrane life of a membrane for removing a predetermined substance from water, an indicator substance in the water upstream and downstream of the membrane installed in the middle of the flow path of the water. A film life monitoring system, comprising: a detection device for detecting and comparing the concentrations of the respective components.

(2) In a membrane life monitoring system for monitoring a membrane life of a membrane for removing a predetermined substance from water, a first system for sampling water upstream of the membrane installed in the middle of a flow path of water. A sampling line, a second sampling line for sampling water on the downstream side of the membrane installed in the middle of the flow path of water, and a concentration of the indicator substance in water obtained from the first sampling line and the second A film life monitoring system comprising: a detection device that detects the concentration of an indicator substance in water obtained from two sampling lines and compares the concentrations.

(3) The film life monitoring system according to (1) or (2), wherein the detection device has a function of obtaining a removal rate of the indicator substance.

(4) The film life monitoring system according to any one of (1) to (3), which has a function of recording the concentration of the indicator substance and / or the removal rate of the indicator substance.

(5) When the concentration of the indicator substance exceeds a predetermined threshold value and / or when the removal rate of the indicator substance falls below a predetermined threshold value, the film life deteriorates. The film life monitoring system according to any one of the above (1) to (4), which has a function of issuing a warning.

(6) The film according to any one of (1) to (5), wherein the concentration or removal rate of the indicator substance has a correlation with the removal rate of the substance to be removed by the film. Life monitoring system.

(7) The film life monitoring system according to any one of (1) to (6), wherein the indicator substance is silica.

(8) The membrane life monitoring system according to any one of (1) to (7), wherein the membrane is a reverse osmosis membrane or an ultrafiltration membrane.

(9) A water treatment apparatus for treating water using a membrane capable of removing a predetermined substance from water, comprising the membrane life monitoring system according to any one of the above (1) to (8). A water treatment apparatus characterized by the above-mentioned.

(10) a raw water tank for storing raw water, a circulation line connected to the raw water tank, and a membrane for removing a predetermined substance from the raw water flowing through the circulation line;
A treated water tank installed downstream of the membrane for storing water treated by the membrane, and a membrane life monitoring system according to any one of the above (1) to (9). Water treatment equipment.

(11) In a film life monitoring method for monitoring a film life of a film for removing a predetermined substance from water, a concentration of an indicator substance in water before and after the treatment with the film is detected, and the concentration of the indicator substance is measured based on the detected concentrations. A film life monitoring method comprising: obtaining a removal rate of an indicator substance; and detecting a film life based on the removal rate.

(12) The method for monitoring the life of a membrane according to the above (11), wherein the life of the membrane is continuously monitored during the treatment of the water.

(13) When the concentration of the indicator substance exceeds a predetermined threshold value and / or when the removal rate of the indicator substance falls below a predetermined threshold value, the film life deteriorates. The film life monitoring method according to the above (11) or (12), wherein a warning is issued as a result.

(14) The film lifetime according to any of (11) to (13) above, wherein the concentration or removal rate of the indicator substance has a correlation with the removal rate of the substance to be removed by the film. Monitoring method.

(15) The method according to any one of the above (11) to (14), wherein the indicator substance is silica.

(16) The method according to any one of the above (11) to (15), wherein the membrane is a reverse osmosis membrane or an ultrafiltration membrane.

(17) A water treatment method, wherein water is treated while performing the membrane life monitoring method according to any one of (11) to (16).

[0026]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described based on preferred embodiments shown in the accompanying drawings.

FIG. 1 is a circuit diagram showing an embodiment of the water treatment apparatus of the present invention. As shown in FIG. 1, the water treatment device 1
A raw water tank 10, a circulation line 3 connected to the raw water tank 10, a treatment line 4 branched from the circulation line 3, and a treated water tank 11 connected to the treatment line 4.
And a film life monitoring system 2 of the present invention.

Hereinafter, each of these components will be described. Both ends of the circulation line 3 are connected to the raw water tank 1 respectively.
Connected to 0. The circulation line 3 is a raw water tank 1
This is for supplying water (hereinafter, referred to as “raw water”) stored in the membrane module 8 to the membrane module 8. The water that has not passed through the membrane module 8 goes around the circulation line 3 and returns to the raw water tank 10 again, so that the raw water circulates between the raw water tank 10 and the circulation line 3. Has become.

The raw water tank 10 stores raw water to be supplied to the circulation line 3. In this case, the raw water tank 10
Is preferably sealed to prevent contamination of the raw water.

The raw water is preferably water at the stage of dechlorination or purification in order to protect the membrane from oxidizing substances such as chlorine. As such water, for example, purified water equipment,
Examples include a pure water production apparatus or a pretreatment apparatus thereof, a raw water filter, a raw water reverse osmosis (raw water RO) apparatus, an ion exchange resin, an ultrafiltration (UF) apparatus, and water treated with sodium sulfite.

A pump 31 is provided in the middle of the circulation line 3. The pump 31 circulates the raw water between the circulation line 3 and the raw water tank 10.

The treatment line 4 removes substances to be removed contained in the raw water, and removes the treated water (hereinafter, referred to as “treatment water”).
(Referred to as “treated water”).

The three processing lines 4 are connected in parallel in the middle of the circulation line 3. In the middle or at the upstream end of the processing line 4, a membrane module 8 containing a membrane described later is installed, respectively. In the processing line 4, a valve (electromagnetic valve) 4 is provided upstream of the membrane module 8.
1 is installed.

The valve 41 has a function of opening and closing the processing line 4 in response to, for example, a control signal of a detection device 9 described later. In addition, about the details of the membrane module 8,
It will be described later.

The treated water tank 11 is for storing treated water treated in the treatment line 4.

Hereinafter, the side of the circulation line 3 across the membrane module 8 is referred to as “upstream”, and the side of the treated water tank 11 is referred to as “downstream”.

Hereinafter, the membrane module 8 will be described.
The membrane module 8 removes substances to be removed (hereinafter referred to as “removed substances”) contained in the raw water. Thereby, the outflow of the removed substance from the upstream side to the downstream side of the membrane module 8 is prevented.

The membrane module 8 is filled with a predetermined membrane. This film has the ability to remove the removal substances contained in the raw water.

The type of the membrane is not particularly limited as long as the substance to be removed can be removed. For example, a membrane filter such as a reverse osmosis membrane (RO membrane), an ultrafiltration membrane (UF membrane), and a dialysis membrane is preferable. Are listed.

The film may have an ion removing ability. In this case, from the viewpoint of efficiently removing ions, the ion removal ability is preferably 90% or more.

The material of the reverse osmosis membrane is not particularly limited as long as the substance to be removed can be removed, and examples thereof include a cellulosic polymer, polyester, polyamide, polyacrylonitrile, polyether, polyvinyl alcohol, and a composite membrane thereof. Is mentioned.

The pore diameter of the reverse osmosis membrane is not particularly limited as long as the substance to be removed can be effectively removed.
It is preferably about 100 nm.

The material of the ultrafiltration membrane is not particularly limited as long as the substance to be removed can be removed.
Examples thereof include polyolefin, fluorine-based polymer, polyether sulfone, polyacrylonitrile, polyamide, ceramic, and a composite film thereof.

The pore size of the ultrafiltration membrane is not particularly limited as long as the substance to be removed can be effectively removed.
It is preferably about 100 nm.

Examples of the removing substance include endotoxin, live bacteria, ions, high molecular compounds, low molecular organic compounds,
Organic and inorganic fine particles are exemplified.

The membrane area per unit capacity of the membrane module 8 is not particularly limited, and is, for example, 150 to 20,000 m ² / m
^{About 3} are used.

A predetermined pressure is applied to the membrane module 8 by the differential pressure between the upstream side and the downstream side. This pressure is not particularly limited as long as it is a pressure capable of exerting the processing capability of the membrane. For example, when the membrane is a reverse osmosis membrane, the pressure is 5 to 5.
100 kg / cm ² or so, in the case of the ultrafiltration membrane is 1-5 kg / cm ²
It is preferred that it is about.

The flow rate of the raw water flowing to the membrane module 8 varies depending on the type and performance of the membrane.
It is used at about 2,000 to 20,000 mL / min.

Hereinafter, the film life monitoring system 2 will be described. The film life monitoring system 2 includes a first sampling line 6, a second sampling line 7, and a detection device 9.

The first sampling line 6 has a function of sampling (sampling) raw water on the upstream side of the membrane module 8 and supplying it to the detecting device 9. The upstream end of the first sampling line is connected in the middle of the circulation line 3, and the downstream end is connected to the detection device 9.

The second sampling line 7 has a function of sampling (collecting) treated water on the downstream side of the membrane module 8 and supplying it to the detecting device 9. The upstream end of the second sampling line is connected to each downstream side of the membrane module 8 in the processing line 4, and the downstream end is connected to the detection device 9.

In the middle of the first sampling line 6 and each second sampling line 7, a valve (electromagnetic valve)
61 and a valve (electromagnetic valve) 71 are provided.

The valves 61 and 71 open and close to control the supply of the raw water and the treated water to the detecting device 9.

The detecting device 9 includes the first sampling line 6
And the indicator substance in the raw water or the treated water supplied from the second sampling line 7.

The detecting device 9 has a recorder 91. The indicator substance refers to a substance that has a correlation with the removal rate or the permeation amount (leak amount) of the removal substance, and can determine the film life using the substance as an index.

That is, when the film of the membrane module 8 reaches the end of its service life and the film deteriorates, the removal rate of the indicator substance decreases, and the indicator substance leaks to the downstream side of the membrane module 8. A large amount of the indicator substance is detected downstream of. Therefore, the life of the membrane can be monitored by detecting the concentration of the indicator substance on the downstream side of the membrane module 8. In this case, the amount of the indicator substance on the upstream side may fluctuate somewhat, so that the film life can be more accurately determined by comparing the concentrations of the indicator substances in the raw water and the treated water, or determining the removal rate from them. Can be monitored.

As the indicator substance, for example, when the substance to be removed is endotoxin or viable bacteria, a silicon compound is preferable. Among them, silica is particularly preferred. This is because, among the silicon compounds, silica is present in a large amount and its concentration can be easily measured. Therefore, when silica is used as the indicator substance, the film life can be easily monitored in real time (continuously).

As described above, if the indicator substance can be easily detected by the detector 9, the life of the film can be measured in real time (continuously).
It becomes possible to monitor. Then, by monitoring the membrane life in real time, when the membrane is deteriorated and reaches the end of its life, the supply of the raw water to the membrane module 8 having reached the end of its life is stopped, and the membrane module 8 is quickly stopped. Can be exchanged for a new one,
Injection water production equipment and the like can safely treat raw water.

The detection method of the indicator substance by the detector 9 is preferably a detection method suitable for the indicator substance, and examples thereof include an optical method, an electrochemical method, and a colorimetric method.

The detection of the indicator substance may be performed at regular intervals (intermittently) or continuously according to the state of the film.

Further, it is preferable that the detecting device 9 has a function of comparing the detected concentrations of the indicator substances of the raw water and the treated water. In particular, it is more preferable that the detection device 9 has a function of obtaining the removal rate of the indicator substance of the membrane module 8 based on the detected concentrations of the indicator substance and the treated water. This is because the amount of the indicator substance on the upstream side may fluctuate somewhat, and therefore, by comparing the values of the two or determining the removal rate, the film life can be more accurately monitored. For example, a predetermined threshold value is provided, the obtained removal rate is compared with the threshold value, and when the removal rate is lower than the threshold value, the film is deteriorated, and it is determined that the life has been reached. It is possible to monitor the film life.

The recorder 91 has, for example, the concentration of the indicator substance,
Data such as the removal rate of the indicator substance can be recorded (stored). From these records, it is possible to predict the future film life. For example, when the silica removal rate is less than 60%, the possibility of endotoxin leakage increases, and therefore, it is possible to predict the time of the membrane life by performing a trend analysis on the silica removal rate.

The recorder 91 may have a function of displaying recorded data on a display or printing out the data.

When the concentration of the indicator substance exceeds a predetermined threshold value or when the removal rate of the indicator substance falls below the predetermined threshold value, the detection device 9 deteriorates the film and shortens its life. Judge that it has reached. This threshold value is empirically determined in consideration of the safety of the treated water and the like.

It is preferable that the detecting device 9 has a function (warning means) for issuing a warning when the film is judged to be "life". This makes it possible to more quickly detect that the life of the film has been reached.

This warning is for reminding that the film has reached the end of its life. The warning method is not particularly limited as long as it can be recognized that the film has reached the end of its life, and examples thereof include a method using visual expression, a method using audio expression, and a combination thereof.
The visual expression includes, for example, display on a display and lighting of a warning lamp, and the audio expression includes, for example, emitting a sound to that effect from a speaker or sounding a buzzer.

Further, the detection device 9 is provided for detecting that the film reaches the end of its life when the concentration of the index substance exceeds a predetermined threshold value or when the removal rate of the index substance falls below the predetermined threshold value. It is preferable to control the supply of the raw water to the membrane module 8 having the membrane that has reached the end of its life or to stop the operation of the water treatment apparatus 1 (stop the circulation of the raw water). This makes it possible to automatically stop the supply of the raw water to the membrane that has reached the end of its life, and it is possible to quickly prevent the substance to be removed from leaking into the treated water.

Note that these controls may be performed by a microcomputer built in the detection device 9 or by a computer such as a personal computer connected to the outside.

Hereinafter, the operation of the water treatment apparatus 1 of the present invention will be described. The raw water stored in the raw water tank 10 is
The circulation in the circulation line 3 is performed by the operation of the pump 31.

A part of the raw water flowing in the circulation line 3
It flows to the processing line 4. In this case, each valve 41 is set to a predetermined opening.

In the treatment line 4, when the raw water passes through the membrane of the membrane module 8, the substance to be removed is removed. Then, the treated water that has passed through the membrane is stored in the treated water tank 11.

On the other hand, when the valve 61 of the first sampling line 6 is opened at a predetermined opening, a part of the raw water is supplied from the circulation line 3 to the detection device 9 through the first sampling line 6.

When the valve 71 of the second sampling line 7 is opened at a predetermined opening, a part of the processing water from the processing line 4 is supplied to the detection device 9 through the second sampling line 7.

The detection device 9 detects the concentrations of the indicator substances in the raw water and the treated water in the treatment line 4, respectively.

Further, in the detecting device 9, the removal rate of the indicator substance for each membrane module 8 is obtained from the detected concentrations of the indicator substance in the raw water and the treated water. This is obtained, for example, by dividing the difference between the concentration of the indicator substance in the raw water and the concentration of the indicator substance in each processing line by the concentration of the indicator substance in the raw water.

Next, the detection device 9 determines whether or not the film has deteriorated and the life has been reached based on the obtained removal rate (or concentration) of the indicator substance of the film. This is performed by comparing the removal rate of the indicator substance of the film with a predetermined threshold value measured in advance. That is, when the removal rate of the indicator substance of the film is equal to or more than a predetermined threshold value, the film is determined to be normal, and when it is less than the threshold value, it is determined that the film has reached the end of its life. .

When the detection device 9 determines that the film has reached the end of its life, it issues a warning. At the same time, the detection device 9 outputs a control signal to that effect so as to close the valve 41 in the treatment line 4 to which the membrane whose life has reached belongs or to stop the operation of the entire water treatment device 1.
This operation may be performed manually.

As described above, the life of the membrane can be quickly recognized by monitoring the removal rate of the indicator substance preferably in real time during the processing in the membrane module 8.

Then, the membrane module 8 whose membrane has reached the end of its life
Is replaced with a new one and the processing is continued.

As described above, according to the present invention, it is possible to detect the film life and monitor the film life by detecting the concentration of the indicator substance of the water treated by the film (treated water).

In particular, by detecting the concentration of the indicator substance on the upstream side and the downstream side of the membrane, respectively, and determining the removal rate of the indicator substance by the membrane, the life of the membrane can be monitored more accurately.

When the concentration of the indicator substance exceeds a predetermined threshold value or the removal rate of the indicator substance falls below the predetermined threshold value, a warning is issued to notify that the film has reached the end of its life. Can be easily detected.

Further, when a silicon compound is used as an indicator, there is a correlation between the removal rate of the silicon compound and the removal rate of endotoxin, so that the presence or absence of endotoxin leak can be easily detected. Become.

Among them, silica is particularly preferred. This is because, among silicon compounds, the amount of silica is large and the measurement is easy. In addition, the endotoxin test usually requires one hour or more, whereas silica can be measured in real time, so that using silica as an index makes it possible to measure the film life in real time.

Further, the present invention can be carried out in the process of using a membrane at an intermediate stage when treating water. This makes it possible to process the raw water more safely without waste.

The present invention is not limited to the embodiment shown in FIG. For example, the number of the membrane modules 8 does not need to be three as shown in FIG.
A plurality other than three may be used. In this case, it is preferable to provide a plurality of membrane modules 8 from the viewpoint of efficient water treatment.

In the circulation line 3, the raw water may not be circulated. Further, the end of the circulation line 6 itself may be connected to a membrane module, a distiller, or the like.

For example, when the concentration of the indicator substance in the raw material water is known (when the concentration is stable), the monitoring of the membrane life is performed by opening the valve 71 and closing the valve 61, The detection may be performed by detecting the concentration of the indicator substance of No. 4.

Further, the detecting device 9 does not need to be installed via a sampling line, and may be installed in-line in a pipe, for example.

Further, the water used in the present invention does not need to be purified water, and may be, for example, tap water.

[0091]

The present invention will be described below in more detail with reference to specific examples.

As a water treatment device, a pyrogen-free water production device as shown in FIG. 1 was manufactured. Raw water was obtained by the following method.

[1] Tap water was treated with a raw water filter (manufactured by Organo Corporation) to remove solids. The pore size of such a filter was 1 μm and the flow rate was 10 m ³ / h.

[2] Next, the water treated in [1] is
It was treated with a pure water production apparatus (manufactured by Organo Corporation) to remove ions. The flow rate of such a device was 10 m ³ / h.

[0095] Raw water was obtained through the above steps [1] and [2]. This raw water was supplied to a raw water tank, and treated with a reverse osmosis membrane (a module incorporating a reverse osmosis membrane) as a pyrogen-free water production apparatus.

The capacity of the raw water tank was 10 m ³ , and the diameter of the pipe in the circulation line was 63.5 mm.

The flow rate by the pump is 7 m ³ / hour,
The pressure was 40 kg / cm ² . The material of the membrane of the module incorporating the reverse osmosis membrane was a synthetic polymer composite membrane (manufactured by Nitto Denko Corporation). Then, three of these modules were installed in parallel with the circulation line.

Then, the raw water in the circulation line and the treated water in each reverse osmosis membrane were collected from the first sampling line and the second sampling line, respectively, and the silica concentration was measured with a silica concentration detector (7028 silica meter manufactured by Nikkiso Co., Ltd.). The concentration was detected and measured, and the removal rate of silica was determined for each module.

The measurement range was 0 to 1000 ppb, and the measurement interval was 5 minutes. In addition, in order to examine the correlation between the removal rate of silica and the removal rate of endotoxin, endotoxin in water (treated water) after passing through a reverse osmosis membrane was actually measured.

The endotoxin was measured with a toxinometer (manufactured by Wako Pure Chemical Industries, Ltd.) using a turbidimetric method using the turbidity of the LAL reagent (Wako Pure Chemical ES-II) as an index.

Table 1 shows the concentration of silica and the change over time in the removal rate for each module.

When endotoxin was actually measured and its concentration was higher than a predetermined value (30 mEu / mL), an X mark was given at a corresponding place in Table 1, and a circle mark was given when it was lower than the predetermined value. .

[0103]

[Table 1]

As shown in the results in Table 1, it was found that there is a correlation between the removal rate of silica and the removal rate of endotoxin. In particular, it was found that when the silica removal rate was lower than 60% (threshold value), the possibility of endotoxin leakage was high. Therefore, it is possible to determine the replacement time of the module by monitoring the silica removal rate and using the removal rate of 60% as a threshold to determine the reduction in the life of the reverse osmosis membrane.

[0105]

As described above, according to the present invention, the life of a film can be monitored easily and in real time.

Further, by obtaining the removal rate of the indicator substance and using this as an index of the film life, it is possible to monitor the film life more accurately.

[Brief description of the drawings]

FIG. 1 is a circuit diagram showing an embodiment of a water treatment apparatus of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Water treatment apparatus 2 Membrane life monitoring system 3 Circulation line 31 Pump 4 Processing line 41 Valve 6 First sampling line 61 Valve 7 Second sampling line 71 Valve 8 Membrane module 9 Detector 91 Recorder 10 Raw material water tank 11 Treated water tank

Claims (10)

[Claims] 1. A membrane life monitoring system for monitoring a membrane life of a membrane for removing a predetermined substance from water, comprising: an indicator substance in water upstream and downstream of the membrane installed in the middle of a water flow path. A film life monitoring system comprising a detection device for detecting and comparing concentrations. 2. The film life monitoring system according to claim 1, wherein the detection device has a function of obtaining a removal rate of the indicator substance. 3. When the concentration of the indicator substance exceeds a predetermined threshold value and / or when the removal rate of the indicator substance falls below a predetermined threshold value, the film life is deteriorated. 3. The film lifetime monitoring system according to claim 1, further comprising a function of issuing a warning. 4. The film life monitoring system according to claim 1, wherein said indicator substance is silica. 5. The system according to claim 1, wherein the membrane is a reverse osmosis membrane or an ultrafiltration membrane. 6. A film life monitoring method for monitoring a film life of a film for removing a predetermined substance from water, comprising: detecting a concentration of an indicator substance in water before and after treatment with the film; A film life monitoring method comprising: obtaining a material removal rate; and detecting a film life based on the removal rate. 7. The method according to claim 6, wherein the life of the membrane is continuously monitored during the treatment of the water. 8. When the concentration of the indicator substance exceeds a predetermined threshold value and / or when the removal rate of the indicator substance falls below a predetermined threshold value, the life of the film is deteriorated. 8. The method for monitoring the life of a membrane according to claim 6, wherein a warning is issued as: 9. The method according to claim 6, wherein the indicator substance is silica. 10. The method for monitoring the life of a membrane according to claim 6, wherein the membrane is a reverse osmosis membrane or an ultrafiltration membrane.