KR101544407B1 - Method for preventing fouling of reverse osmosis membrane - Google Patents

Abstract

The present invention relates to a method for reducing fouling of a reverse osmosis membrane, and more particularly, to a method for reducing fouling of a reverse osmosis membrane, and more particularly, to a method for reducing fouling of a reverse osmosis membrane, which comprises separating an influent water into treated water and concentrated water using a reverse osmosis membrane having a pressure- ; And removing the contamination of the surface of the separation membrane by removing the pressure of the concentrated water line while maintaining the separation step.
According to the fouling reduction method of the reverse osmosis membrane of the present invention, the flow of the surface of the reverse osmosis membrane is maintained to prevent the damage of the reverse osmosis membrane, and the surface of the reverse osmosis membrane, which is generated when the pressure of the concentrated water line is intermittently released It is possible to safely and promptly reduce contaminants formed on the surface of the separation membrane due to the increase of the fluidity and the osmotic pressure from the treated water to the concentrated water.

Description

TECHNICAL FIELD [0001] The present invention relates to a method for reducing fouling of a reverse osmosis membrane,

The present invention relates to a method for reducing fouling in a reverse osmosis membrane, and more particularly, to a method for reducing fouling in a reverse osmosis membrane, To a method for reducing surface contamination.

In general, filtration methods using separators are most often used for reuse or desalination of sewage, wastewater and seawater. Examples of the filtration method include micro filtration, ultrafiltration, nano filtration, and reverse osmosis. The filtration methods may be used alone or in combination Can be used.

Among these, reverse osmosis filtration is the most widely used technique recently with the development of membrane technology, and only reverse osmosis filtration can remove both ions and organic substances in water. Reverse osmosis membrane used for reverse osmosis filtration is widely used because it is easy to install and compatible with various company products since the size of membrane and pressure vessel are standardized.

However, due to the use of the separation membrane, contaminants accumulate on the surface of the separation membrane, thereby causing clogging of the separation membrane, that is, fouling, shortening the life of the separation membrane, .

Accordingly, various methods have been proposed to prevent or remove the contamination on the surface of the separation membrane, and conventionally, mainly backwashing is performed, that is, pressure is applied in the opposite direction to the flow of the filtered treatment water, CIP (Chemical Cleaning In Place) methods have been used to remove pollutants and wash them with chemicals.

The backwashing method can be applied to a separation membrane having pores such as microfiltration or ultrafiltration. However, when a semi-permeable membrane such as polyamide or cellulose acetate, such as a reverse osmosis separation membrane, is used, Therefore, if reverse pressure is applied to the membrane, a polymer membrane layer coated with a semipermeable membrane is liberated, which is not applicable because it damages the entire membrane.

Therefore, most of the reverse osmosis membranes are subjected to chemical cleaning in place (CIP) method. Among known CIP methods, there are citric acid and oxalic acid cleaning methods for cleaning minerals without damaging the reverse osmosis membrane, and there is an alkali cleaning method which is mainly used for cleaning organic materials. As the solution used in the alkali washing method, a method of mixing caustic soda with a surfactant is generally used. When the CIP method is used, the cleansing effect of the separator is excellent. However, when cleaning is performed, a large amount of chemical substance is required to be used, and it takes a long time for cleaning. As the frequency of cleaning is increased, the surface of the reverse osmosis membrane is damaged Therefore, it is necessary to minimize cleaning as much as possible.

In addition, U.S. Patent Application Publication No. 2012-0318737A1 discloses a technique of periodically applying a pressure pulse to prevent membrane contamination. However, such periodic pressure changes are applied to the reverse osmosis membrane irrespective of the osmotic pressure of the influent water The possibility of damaging the movable pump or the reverse osmosis membrane is rather large, and the maintenance and management of the process can not be stably performed.

Accordingly, when a technique capable of effectively reducing fouling without damaging the RO membrane is provided, it is expected that the present invention can be effectively applied to related fields.

Accordingly, one aspect of the present invention is to provide a method for reducing fouling of a reverse osmosis membrane capable of rapidly removing contaminants without causing damage to the reverse osmosis membrane.

According to an aspect of the present invention, there is provided a method for separating influent water into treated water and concentrated water using a reverse osmosis membrane having a pressure control unit in a concentrated water line to maintain a pressure higher than osmotic pressure; And removing the contamination of the surface of the separation membrane by removing the pressure of the concentrated water line while maintaining the separation step.

The pressure of the concentrated water line is preferably eliminated by opening a pressure control unit provided in the concentrated water line.

Preferably, the pressure control part is a pressure control valve.

It is preferable that the pressure of the concentrated water line is eliminated once during the period of 1 to 30 days.

It is preferable that the pressure of the concentrated water line is canceled when the pressure of the inflow water rises by 20% or more from the pressure during normal operation.

It is preferable that the time for which the pressure of the concentrated water line is maintained is 0.1 to 10 minutes per one time.

The influent water is preferably selected from the group consisting of sewage, wastewater and seawater.

According to the fouling reduction method of the reverse osmosis membrane of the present invention, the flow of the surface of the reverse osmosis membrane is maintained to prevent the damage of the reverse osmosis membrane, and the surface of the reverse osmosis membrane, which is generated when the pressure of the concentrated water line is intermittently released It is possible to safely and promptly reduce contaminants formed on the surface of the separation membrane due to the increase of the fluidity and the osmotic pressure from the treated water to the concentrated water.

1 schematically illustrates the structure of an exemplary reverse osmosis membrane and a conceptual diagram of the related apparatus.
FIG. 2 shows the operation result (a) of the reverse osmosis membrane by the general method and the operation result (b) of the reverse osmosis membrane to which the method of the present invention is applied.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, the embodiments of the present invention can be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below.

First, the configuration of the reverse osmosis membrane to which the fouling reduction method of the present invention is applied and the process of separating influent water using the same are as shown in FIG.

1, the inflow water 1 to be treated is supplied through the inflow pump 2 and the high-pressure pump 3 for maintaining the pressure higher than the osmotic pressure, and while the pressure gauge 4 installed on the inflow water side is checked, Flows into the pressure vessel (5) and is supplied to the separation membrane module (6).

The influent water 1 is separated into treated water and concentrated water in the separation membrane module 6 and discharged through the treated water line 10 and the concentrated water line 13 respectively. And is regulated by the pressure control valve 11 installed. In the pressure vessel 5, a plurality of separation membrane modules 6 are arranged in series, and spacers 8 may be provided at the ends. In each module, the filtered water is discharged along the treatment water line 10 through the treatment water tube 7, and the discharged treatment water can be monitored by the flow meter 9 for its throughput.

The reverse osmosis separation membrane is generally operated by adjusting the pressure control valve 11 installed in the concentrated water line 13 in order to keep the flow rate of the treated water constant. In this case, as shown in FIGS. 2A and 2B, the flow rate (flux) passing through the separation membrane in the pressure vessel 5 gradually decreases in the longitudinal direction, The osmotic pressure of the solution remaining in the solution permeates the solution gradually increases. If the operation is continued in such a situation, the surface of the reverse osmosis membrane gradually becomes contaminated. As a result, the operating pressure gradually increases. Further, if the osmotic pressure membrane exceeds the safe limit pressure, the surface of the membrane should be cleaned.

In the conventional method, the CIP process is performed using a chemical agent. After the CIP process is performed, the pressure and the flow rate are restored. However, during this process, the production of the process water must be stopped, It is getting faster and eventually it is necessary to replace the membrane.

According to the present invention, by relieving the pressure of the line of concentrated water (13), a large amount of water can instantly escape through the line of concentrated water (13), thereby reducing the contamination of the surface of the osmotic pressure separation membrane The osmotic pressure is generated toward the concentrated water line, and natural backwashing is enabled, thereby providing a method of remarkably reducing separation membrane contamination.

More specifically, the present invention provides a method for reducing fouling of a reverse osmosis membrane, comprising: separating influent water into treated water and concentrated water using a reverse osmosis membrane having a pressure control unit in a concentrated water line to maintain a pressure higher than osmotic pressure; And removing the contamination of the surface of the separation membrane by releasing the pressure of the concentrated water line while maintaining the separation step.

The pressure of the concentrated water line can be eliminated by opening the pressure control unit provided in the concentrated water line. That is, in order to separate the inflow water by the reverse osmosis membrane, a pressure higher than the osmotic pressure must be maintained. Therefore, a pump capable of applying a high pressure to the inflow water side is provided. .

The pressure control unit may be a pressure control valve. The pressure control valve may be provided with a signal by using a timer or a program for controlling the process to relieve the pressure, or a pressure gauge of the inflow line may be monitored. The pressure can be relieved by adjusting the control valve. As a result, a large amount of water instantaneously escapes into the concentrated water line, thereby reducing contamination on the surface of the separation membrane and causing osmotic pressure toward the concentrated water line in the treated water line, thereby enabling natural backwashing.

In the present invention, the pressure relieving cycle of the concentrated water line may be varied depending on a situation in which the system is installed and operated, such as several minutes, several hours, and several days. For example, the pressure of the concentrated water line may range from 1 hour to 30 days It can be resolved once.

If the pressure is relieved more than once per hour frequently, separation membrane contamination can be prevented. However, since the production time of the treated water is reduced and a large amount of untreated water is discharged, it is inefficient, The effect of the present invention may not be sufficiently obtained if it is performed in an excessively long period less than once per day, so that it is preferable to operate the period within the scope of the present invention as described above.

More preferably, the pressure of the concentrated water line is reduced once or twice a day. However, as the dissolved solids concentration of the influent water to be used in the osmotic pressure separation membrane is higher, the pressure is more relieved more frequently, and as the dissolved solids concentration is lower, The period is preferably extended.

In order to implement such periodic pressure relief, a signal can be applied to the pressure control valve to add a system in which the pressure control valve can be driven to the reverse osmosis membrane, and more conveniently, the timer 12 The pressure control valve is opened to relieve the pressure according to a predetermined time interval, and the pressure control valve is closed again after a predetermined time interval elapses.

On the other hand, it is also possible to monitor the pressure installed in the inflow water line so that the pressure control valve is automatically adjusted when the pressure exceeds a predetermined pressure. For example, a timer can be softly operated in a PLC (Programmable Logic Controller) or an HMI (Human Machine Interface), which is recently used to control the separation membrane, and the signal can be delivered to the valve. have.

In this case, it is preferable that the pressure of the concentrated water line is eliminated when the pressure of the inflow water rises by 20% or more from the pressure during normal operation.

That is, the osmotic pressure may vary depending on the salt concentration of various influent water. However, if the pressure of the influent water is not relieved even when the pressure of the influent water rises by 20% or more based on the pressure during normal operation, Which may cause semi-permanent separation membrane contamination problems. As a result, there is a problem that the cleaning period of the chemical is advanced, which lowers the economical efficiency of the entire process, shortens the replacement cycle of the separation membrane, and reduces the production amount of the produced water.

It is preferable that the time for which the pressure of the concentrated water line is maintained is 0.1 to 10 minutes per one time. If the time for which the pressure of the concentrated water line is maintained is less than 0.1 minute per one hour, there is a problem that the contamination on the surface of the osmotic pressure separation membrane is not sufficiently removed, and the time during which the pressure relieving of the concentrated water line is maintained is 10 minutes , The production time of the treated water is reduced and a large amount of untreated water is discharged, which is inefficient.

The inflow water to which the present invention can be applied may be selected from the group consisting of sewage, wastewater and seawater, but is not limited thereto, and any kind of inflow water applicable to the reverse osmosis membrane can be applied.

The flux of the treated water at the time of operation of the reverse osmosis membrane is gradually decreased along the longitudinal direction of the pressure vessel and the flow rate to the right side of the surface of the osmotic membrane is maintained at a constant rate. According to the present invention, As shown in the upper part, the flux is formed by the difference of the osmotic pressure between the treated water and the inflow water during the pressure relieving period, and the flux is inversely proportional to the longitudinal direction. Since the surface of the surface of the reverse osmosis membrane is rapidly backwashed and the pressure of the surface is higher than that of the normal operation, the organic and inorganic contaminants attached to the surface of the reverse osmosis membrane can be rapidly separated and removed into the concentrated water line .

2 (a) and 2 (b), the flow rate of the treated water and the pressure variation pattern applied to the separation membrane in the case of chemical cleaning by a known method are shown. When the pressure of the osmotic pressure membrane is increased to some extent, it is necessary to remove the contamination through chemical cleaning such as CIP. As a result, it is confirmed that the cycle required for cleaning is gradually accelerated.

In the case of FIG. 2 (b) in which the fouling reduction method of the present invention is applied to the reverse osmosis membrane of the present invention, the rate at which the pressure increases with time can be remarkably reduced, have. Further, since the chemical cleaning cycle is extended, the flow rate discharged through the concentrated water can be reduced, so that the overall process maintenance cost can be reduced and the production amount of treated water can be increased.

The method of reducing fouling of the reverse osmosis membrane of the present invention has an advantage that it can be implemented without a device requiring installation.

Hereinafter, the present invention will be described more specifically by way of specific examples. The following examples are provided to aid understanding of the present invention, and the scope of the present invention is not limited thereto.

< Example >

Example  One

In order to confirm the effect of the fouling reduction method of the reverse osmosis membrane according to the present invention, a wastewater reuse pilot plant system using a reverse osmosis membrane was installed on wastewater generated in a steel mill, Also, by applying the fouling reduction method of the reverse osmosis membrane according to the present invention, a process of obtaining a production volume of 100 tons per day by using the reverse osmosis membrane for 3 months was operated. The results of running the process under these conditions are shown in Table 1 below.

Comparative Example  One

Except that the method of reducing fouling of the reverse osmosis membrane according to the present invention was not applied, the process of obtaining the production water by using the reverse osmosis membrane for 3 months under the same condition as in Example 1 was operated. The results of operating the process under these conditions are shown in Table 1 below.

Experimental Example  1: Pilot plant ( Pilot Plant ) Operation result

Table 1 shows the results of running the process using the osmotic pressure membrane according to the conditions described in Example 1 and Comparative Example 1.

Comparative Example 1 Example 1 Application period 3 months 3 months Influent Iron wastewater effluent Iron wastewater effluent Total incoming volume 11,200 tons 10,300 tons Total processed quantity 6700 tons 6800 tons Recovery rate 59.8% 66% Number of drug rinses 7 times 3rd time Pressure relief cycle 0 2 times / day Average operating pressure 16.8 kgf / cm ² 14.2 kgf / cm ²

As shown in Table 1, it can be seen that Example 1 is increased in terms of the total treated amount, and the recovery rate is also increased by about 6.2%.

In addition, it was confirmed that the number of cleaning times of the drug decreased from 7 times in the case of Comparative Example 1 to 3 times in the case of Example 1, thereby increasing the overall operating time and increasing the recovery rate.

The pressure relief period applied in Example 1 was twice per day, and in this case, the average pressure applied to the influent line was kept low, and very good results were obtained.

Fig. 2 (b) shows the results of the present invention. Fig. 2 (a) shows the results obtained when the osmotic membrane separation membrane was operated by a normal osmotic membrane separation method. In other words, the flux and the linear velocity in the longitudinal direction are indicated by arrow lengths. Arrows pointing upward indicate the state in which the treated water is produced, and arrows pointing down indicate that natural backwashing occurs due to osmotic pressure.

2A and 2B show the pressure change and the treated water flow rate at the middle and lower ends. In the case where the operation is performed while the flow rate of the treated water is kept constant and the present invention is applied, In the case of FIG. 2 (b), it is confirmed that the intermittent pressure relief is continuously applied and the period of time required for chemical cleaning is remarkably extended.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be obvious to those of ordinary skill in the art.

<Notation of Government Patent Research Projects>

[Assignment number] GT-11-B-02-003-2

[Ministry of Environment] Ministry of Environment

[Project name] Wastewater advanced treatment technology development project (Ministry of Environment Global top environmental technology development project)

[Project title] Development of concentrate water treatment process for high quality of effluent water quality of steel wastewater and standardization of core process of reusable water

[Organizer] Pohang Institute of Science and Technology

[Research period] (2011.8.1 ~ 2016.4.30)

I submit it to the KIPO as above.

1. Raw Water
2. Feed Pump
3. High Pressure Pump
4. Inlet Pressure Gauge
5. Pressure Vessel
6. Reverse osmosis membrane module (RO membrane module)
7. Treatment Tube (Permeate Tube)
8. Spacer
9. Processed water flowmeter (Permeate Flowmeter)
10. Permeate
11. Pressure Control Valve (Control Valve or On-Off Valve)
12. Timer
13. Concentrate

Claims (7)

Separating the influent water into the treated water and the concentrated water by using the reverse osmosis membrane having the pressure control unit in the concentrated water line to maintain the pressure higher than the osmotic pressure; And
Removing the contamination of the surface of the separation membrane by releasing the pressure of the concentrated water line by opening the pressure control unit while maintaining the separation step,
The pressure of the concentrated water line is relieved once or twice a day,
Wherein the time during which the pressure of the concentrated water line is maintained is 0.1 to 10 minutes per one time.
delete The method of claim 1, wherein the pressure control unit is a pressure control valve.
delete The method of claim 1, wherein the pressure of the concentrated water line is eliminated when the pressure of the inflow water is increased by 20% or more from the pressure during normal operation.
delete The method of claim 1, wherein the influent water is selected from the group consisting of sewage, wastewater, and seawater.

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