KR20140050979A - A backwash method for a reverse osmosis membrane and a system for the same - Google Patents

Abstract

According to one embodiment of the present invention, a method for backwashing of a reverse osmosis membrane includes a washing process of washing a second reverse osmosis membrane included in a second module by bypassing some or total of a second influent while supplying a first influent treated by a first module including a first reverse osmosis membrane to the influent of the second module. The method for backwashing of a reverse osmosis membrane enables washing of a reverse osmosis membrane without stopping the whole process of water treatment, maintains processing quantities of a module not performing washing process to maintain the processing quantities of the total system as well as performs the washing process of the reverse osmosis membrane without separately and excessively inserting highly concentrated salt water; thus, additional contamination in concentrated water due to slat water does not occur and washing reverse osmosis membrane can be processed without a structural change in the water treatment system. [Reference numerals] (AA) Raw water tank; (BB,CC,DD) Sensor; (EE) Process water tub; (FF) Drug tank

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a backwashing method for a reverse osmosis membrane,

The present invention relates to a reverse osmosis membrane back-washing method and system thereof, and it is possible to perform reverse osmosis membrane cleaning without stopping the water treatment process without using a high concentration of salt water. Also, even when the reverse osmosis membrane is washed, A reverse osmosis membrane back-washing method, and a system therefor.

Membrane refers to a membrane capable of separating a specific component selectively from a mixture. The membrane is classified into a porous membrane, a nonporous membrane, a symmetric membrane and an asymmetric membrane depending on the structure. , Ultrafiltration, microfiltration membrane, and the like.

Reverse osmosis membrane is a membrane treatment method applied to water treatment in seawater desalination and wastewater treatment in the 1970s. When osmosis, a low concentration solution and a high concentration solution are divided into membranes selectively passing water only , A natural phenomenon in which water moves toward the high concentration solution in the low concentration solution). That is, when a pressure higher than the osmotic pressure is applied to the high concentration solution side, only water can pass through the separation membrane and pure water can be produced. This reverse osmosis membrane can be used for water treatment and purification.

However, since the reverse osmosis membrane is subjected to high pressure and water treatment, the mechanical strength must be excellent to withstand high pressure, and the chemical resistance to chlorine and dissolved salts must be good. Therefore, an aromatic polyamide composite membrane formed of an isolation layer or an active layer that maximizes the separation effect on a support layer having excellent mechanical strength as a material of a reverse osmosis membrane is most widely used, and an asymmetric cellulose acetate membrane may be used.

Meanwhile, in the water treatment using the reverse osmosis membrane, the reverse osmosis membrane cleaning process is required according to the water quality and the operation time of the treated water, and conventionally, in order to perform such washing, a salt solution of the cavity is flowed in the inflow water line under the continuous operation condition, However, since it is an indispensable treatment to inject a high concentration of saline solution, it is difficult to treat the concentrated water and it is difficult to recover the osmotic pressure inducing substance (US Pat. 2007/2046425).

An object of the present invention is to provide a reverse osmosis membrane backwashing method and system capable of cleaning a reverse osmosis membrane without stopping the operation of a water treatment process and applying the same while maintaining the flow rate of treated water treated in the entire system.

In order to accomplish the above object, a reverse osmosis membrane backwashing method according to an embodiment of the present invention includes supplying a first treated water treated by a first module including a first reverse osmosis membrane to a second influent of a second module, And washing the second reverse osmosis membrane included in the second module by bypassing a part or all of the second influent water.

And increasing the flow rate of the first process water to be processed in the first module to maintain the processing flow rate of the entire water treatment system including the first module and the second module.

The cleaning process may further include a pressure increasing process for improving the pressure of the rear end of the second module.

The cleaning process may further include a step of injecting a drug containing a descaler into the second influent water.

Further comprising the step of measuring the ion concentration of the first influent water flowing into the front end of the first module and predicting the amount of scale formed in the reverse osmosis membrane including the first RO and the second RO from the ion concentration .

The ion concentration of the second influent water flowing into the front end of the second module may be measured and the amount of the scale formed in the second reverse osmosis membrane may be predicted from the ion concentration to automatically determine whether the washing process is performed .

The quantity of the first treated water may be adjusted by using a high pressure pump located at the front end of the first module, a booster pump located at the rear end of the first module, or a combination thereof.

The reverse osmosis membrane backwashing system according to another embodiment of the present invention includes a first reverse osmosis membrane, a first influent water supply unit for supplying a first influent water to the first reverse osmosis membrane, and a second effluent water supply unit for discharging first treated water treated using the first reverse osmosis membrane And a first concentrated water discharging portion for discharging the first concentrated water, which is treated with the first reverse osmosis membrane and has concentrated contaminants, And a second treatment water outlet for discharging the second treated water treated by using the second reverse osmosis membrane and a second treatment water outlet for treating the second reverse osmosis membrane And a second concentrated water discharge unit for discharging the second concentrated water in which the pollutant is concentrated, wherein the first concentrated water discharge unit and the second influent water supply unit are connected to each other, 2 module further comprises a control unit for controlling a pressure applied to the second reverse osmosis membrane, wherein the control unit reduces the flow rate of the second influent water supplied to the second influent supply unit in the backwash mode, Is backwashed by the positive osmosis phenomenon.

The backwashing system may be to increase the flow rate of the first treated water processed in the first module when the controller is in the backwash mode to maintain the flow rate of the treated water processed in the entire backwash system.

The control unit may further include a bypass connected to the second inflow water supply unit and connected to one end of the second inflow water supply unit, and the bypass circuit may be configured to receive a part or all of the flow rate flowing into the second inflow water supply unit in the backwash mode .

The backwashing system of the reverse osmosis membrane may further include an ion measurement means at a front end of the first influent water supply portion of the first module, wherein the ion measurement means measures the ion content of the first influent water supplied to the first influent water supply portion And the degree of scale formed on the reverse osmosis membrane including the first and second reverse osmosis membranes may be predicted.

The reverse osmosis membrane back-washing system may further include a drug injector connected to the second module, wherein the drug injector is connected to the second influent water supply portion and includes a scale remover in a second influent water contacting the one surface of the second reverse osmosis membrane Or the like.

The reverse osmosis membrane back-washing system may further include a third module, wherein the third module includes a third reverse osmosis membrane, a third influent water supply unit for supplying a third influent water to the third reverse osmosis membrane, And a third concentrated water discharging portion for discharging the third concentrated water that has been treated with the third reverse osmosis membrane and has the pollutant concentrated therein, Wherein the controller is included in any one position selected from the group consisting of a front end of the module, a space between the first module and the second module, a rear end of the second module, and a combination thereof, 3 module to increase the flow rate of the third treated water to maintain the flow rate of the treated water to be treated in the entire backwash system.

The reverse osmosis membrane backwashing method and the reverse osmosis membrane backwashing system of the present invention can perform the reverse osmosis membrane cleaning process without injecting a large amount of high concentration brine separately, so that no additional contamination by the brine can be caused in the concentrated water. The reverse osmosis membrane can be cleaned without structural modification. In addition, the reverse osmosis membrane can be cleaned without stopping the whole process of the water treatment system, and the amount of the treated water of the module that is not cleaned can be controlled to maintain the treated amount of the whole system.

1 is a conceptual diagram illustrating a reverse osmosis membrane backwash system according to an embodiment of the present invention.
2 is a conceptual diagram illustrating a reverse osmosis membrane backwash system according to an embodiment of the present invention in which a third module is positioned between a first module and a second module.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Like parts are designated with like reference numerals throughout the specification.

The term including an ordinal number such as the first or second in the present invention can be used to describe various elements, but the constituent elements are not limited by the terms, For example.

&Quot; Shear " or " rear end " in the present invention is defined based on the flow of fluid entering the water treatment system or water treatment system, and is not limited to the case where it is directly in front of or immediately behind, And so on.

In the present invention, the term " connected " is used to mean not only a direct connection but also a connection between different components, unless otherwise specified.

A method of backwashing a reverse osmosis membrane according to an embodiment of the present invention is a method of backwashing a reverse osmosis membrane while maintaining the flow rate of treated water in a water treatment process using a reverse osmosis membrane composed of two or more stages .

The backwashing method of the reverse osmosis membrane may include supplying the first treated water processed by the first module including the first reverse osmosis membrane to the second influent water of the second module while bypassing some or all of the second influent water, And washing the second reverse osmosis membrane included in the second module. The washing process may be performed by reducing the flow rate of the second influent water supplied to the second reverse osmosis membrane, and then removing the second influent water supplied to the second reverse osmosis membrane and the second treatment water treated by the second osmosis membrane, Pressure is generated to cause backwash in the second reverse osmosis membrane, and the second reverse osmosis membrane is washed using the reverse osmosis membrane.

And increasing the flow rate of the first process water to be processed in the first module to maintain the processing flow rate of the entire water treatment system including the first module and the second module.

The second module including the second reverse osmosis membrane processes the second influent water having a high pollution load and a high scale-generating substance, so that the contamination degree of the second reverse osmosis membrane, which is generated because the concentration of the scale- . However, removal of the scale by conventional methods of injecting brine may make treatment of the concentrated water more difficult, it is difficult to recover the substance causing the osmotic pressure, and there is a limitation in operation in which the water treatment system must be temporarily stopped .

However, in the present invention, since there is a module that operates separately from a module including a reverse osmosis membrane in which scale occurs, it is possible to clean the reverse osmosis membrane without stopping the entire process of the water treatment system, The amount of processing of the system can be maintained. In addition, since the reverse osmosis membrane cleaning process can be performed without injecting high concentration of brine, the concentrated water can be prevented from further contamination by the brine, and the reverse osmosis membrane can be cleaned without any structural change in the water treatment system.

The washing process may further include a pressure increasing process for improving the pressure of the downstream end of the second module so that the pressure of the portion of the second reverse osmosis membrane contacting the second inflow water may be further lowered And backwashing of the reverse osmosis membrane can be performed more effectively.

The cleaning process may further include a step of injecting a drug containing a descaler into the second influent water. In the washing process, when the second reverse osmosis membrane is not sufficiently washed by bypassing a part or the whole of the second influent water, a chemical containing the descaler may be added. In this case, Can be minimized.

Also, the cleaning process may be performed by predicting the scale generation amount of the reverse osmosis membrane of each module. To this end, the backwashing method of the reverse osmosis membrane may include: measuring the ion concentration of the first influent water flowing into the front end of the first module, and measuring a concentration of the ion on the reverse osmosis membrane including the first reverse osmosis membrane and the second reverse osmosis membrane And a prediction process for predicting the amount of the prediction error. The cleaning process can be performed automatically or periodically taking into account the amount of scale expected through the prediction process, and it is possible to increase the lifetime of the reverse osmosis membrane by using the cleaning, and to provide a stable water treatment system Operation may be possible.

The washing process may include measuring an ion concentration of the second influent water flowing into a front end of the second module and estimating an amount of scale formed in the second ROEM from the ion concentration to automatically perform the washing process In this case, it is possible to increase the lifetime of the reverse osmosis membrane by performing the washing process automatically in consideration of the amount of scale to be generated, and to operate the water treatment system stably without stopping the operation.

The quantity of the first module first treated water may be adjusted by using a high pressure pump located at the front end of the first module, a pressure pump located at the rear end of the first module, or a combination thereof. That is, even when the cleaning process is performed, a high-pressure pump or a booster pump may be installed at the front end or the rear end of the module that is not subjected to the cleaning process, thereby increasing the flow rate of the treated water of the module , Whereby the flow rate of the pretreated water can be kept constant.

1 and 2 are conceptual views illustrating a reverse osmosis membrane reverse osmosis system according to an embodiment of the present invention. The reverse osmosis membrane backwash system according to another embodiment of the present invention will be described in more detail with reference to FIGS. 1 and 2. FIG.

The reverse osmosis membrane backwash system includes a first module 10 and a second module 20, wherein the first module 10 includes a first reverse osmosis membrane (not shown), a first reverse osmosis membrane A first treated water discharging portion 12 for discharging the first treated water treated using the first reverse osmosis membrane, and a second treated water discharging portion 12 treated by the first reverse osmosis membrane to concentrate the pollutant, 1 concentrated water discharging unit 13 for discharging the concentrated water and the second module 20 includes a second reverse osmosis membrane (not shown), a second influent water supplying unit 13 for supplying the second influent water to the second reverse osmosis membrane (21), a second treated water discharging portion (22) for discharging the second treated water treated using the second reverse osmosis membrane, and a second treated water discharging portion 2 concentrated water discharging portion 23, and the first concentrated water discharging portion 13 and the second inflow water supplying portion 21 are connected to each other directly or indirectly Including components.

The control unit 60 may further include a control unit 60 for controlling a pressure and a flow rate of the second reverse osmosis membrane at a front end of the second module 20, The flow rate of the second influent water supplied to the supply unit 21 is reduced, and the second reverse osmosis membrane is backwashed by the positive osmosis phenomenon.

The controller 60 can reduce the flow rate of the second influent water supplied to the second influent supply port when the backwashing system of the reverse osmosis membrane is in the backwashing mode, And the second reverse osmosis membrane can be backwashed by this normal pressure. That is, a positive osmosis phenomenon occurs due to the difference in the flow rate and concentration of the influent and treatment water contacting the second reverse osmosis membrane and the pressure applied to the second reverse osmosis membrane, thereby allowing the second reverse osmosis membrane to be backwashed.

In addition, the backwashing system may increase the flow rate of the first process water treated in the first module 10 when the controller 60 is in the backwash mode, Can be maintained. The increase in the first treated water flow rate may be achieved by utilizing a high pressure pump located at the front end of the first module 10, a booster pump located at the rear end of the first module 10, or both, The reverse osmosis membrane contained in each module can be backwashed while maintaining the flow rate of the treated water without stopping the entire water treatment system and it is possible to prevent or minimize the treatment with the high concentration brine have.

The control unit 60 further includes a bypass line 61 to which one end of the second inflow water supply unit 21 is connected and the bypass line 61 is connected to the second influent water A part or all of the flow rate flowing into the supply part 21 may be supplied. It is possible to wash the second reverse osmosis membrane included in the second module 20 without affecting the water treatment of the first module 10 by using the bypass circuit 61 included in the controller 60 have.

The backwash system of the reverse osmosis membrane may further include a chemical injection unit 71 connected to the second module 20 and the chemical injection unit 71 may be connected to the second inflow water supply unit 21 And the second influent water contacting the one surface of the second reverse osmosis membrane may be provided with a drug including a descaler. The descaling agent can be applied as an auxiliary role in the backwashing, and the efficiency of descaling in the backwashing process of the second reverse osmosis membrane can be improved.

Further, the second module 20 may further include a booster pump at its rear end, and the flow rate of the second influent water may be adjusted by the regulator 60 using the booster pump, The degree of the positive osmotic pressure can be controlled.

The backwash system of the reverse osmosis membrane may further include a third module (30).

The third module 30 includes a third reverse osmosis membrane (not shown), a third influent supply part 31 for supplying a third influent water to the third reverse osmosis membrane, a third treated water treated using the third reverse osmosis membrane And a third concentrated water discharging portion 33 for discharging the third concentrated water which has been treated with the third reverse osmosis membrane and has the pollutant concentrated therein, (30) may be any of a front end of the first module (10), a space between the first module (10) and the second module (20), a rear end of the second module (20) Can be included in one location.

If the backwashing system of the reverse osmosis membrane further includes the third module 30, the flow rate of the third treated water processed in the third module 30 in the backwash mode for backwashing the second reverse osmosis membrane So that the flow rate of the process water to be treated in the entire backwash system including the first to third modules can be maintained at a level equivalent to that in the case where the backwash mode is not used.

The backwash system of the reverse osmosis membrane is provided with an ion measuring means (not shown) on the front end of the first inflow water supply portion 11 of the first module 10, the front end of the second inflow water supply portion 21 of the second module 20, Quot; sensor ", the same applies hereinafter). The ion measuring means can measure the ion content of the influent water supplied to each module and predict the degree of contamination such as scales formed in the respective reverse osmosis membranes. Based on the prediction, it is possible to determine whether the reverse osmosis membrane included in each module is backwashed And such determination and backwashing may be accomplished by an automated system.

The reverse osmosis membrane backwash system of the present invention can be operated in two modes, an operation mode and a backwash mode. The operation mode can be operated in the same manner as water treatment in a water treatment system using a conventional reverse osmosis membrane, and the reverse osmosis membrane backwashing method of the present invention can be operated in the backwash mode.

That is, in a water treatment system including two or three or more modules, when the washing operation is required to any one of the two or three or more reverse osmosis membranes included in the water treatment system, the flow rate of the inflow water flowing into any one of the modules is controlled by the controller 60, So that the reverse osmosis membrane can be cleaned.

The reverse osmosis membrane backwashing system of the present invention can clean the reverse osmosis membrane without stopping the entire water treatment system, and can regulate the amount of water treated by the module that is not washed, thereby maintaining the throughput of the entire system. In addition, the reverse osmosis membrane can be cleaned without separately injecting a high concentration of brine, so that no additional contamination by the brine can be caused in the concentrated water, and the reverse osmosis membrane can be cleaned without any structural change in the water treatment system.

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, Of the right.

10: first module 11: first influent water supply part
12: first treated water discharging portion 13: first concentrated water discharging portion
20: second module 21: second influent water supply part
22: second treated water discharging portion 23: second concentrated water discharging portion
30: third module 31: third inflow water supply part
32: third treated water discharge part 33: third concentrated water discharge part
60: Adjustment part 61: Bypass
71:

Claims (13)

The first module including the first reverse osmosis membrane is supplied to the second influent water of the second module while bypassing a part or the whole of the second influent water, The washing process for washing the second reverse osmosis membrane
Wherein the reverse osmosis membrane backwashing method comprises: The method according to claim 1,
Wherein the flow rate of the first process water processed by the first module is increased to maintain the processing flow rate of the entire water treatment system including the first module and the second module. The method according to claim 1,
Wherein the cleaning step further includes a step-up step of increasing a pressure at a rear end of the second module. The method according to claim 1,
Wherein the washing step further comprises a step of injecting a drug containing a descaler into the second influent water. The method according to claim 1,
Measuring a concentration of ions in the first influent water flowing into the front end of the first module and predicting an amount of scale formed in the reverse osmosis membrane including the first and second reverse osmosis membranes from the ion concentration, , Reverse osmosis membrane reverse osmosis. The method according to claim 1,
Wherein an ion concentration of the second influent water flowing into a front end of the second module is measured and an amount of a scale formed in the second reverse osmosis membrane is predicted from the ion concentration to automatically determine whether or not to perform the washing process. Reverse osmosis membrane reverse osmosis. 3. The method of claim 2,
Wherein the quantity of the first treated water is adjusted by using a high pressure pump located at a front end of the first module, a booster pump located at a rear end of the first module, or a combination thereof. A first reverse osmosis membrane, a first influent water supply unit for supplying a first influent water to the first reverse osmosis membrane, a first treated water discharge unit discharging first treated water treated using the first reverse osmosis membrane, and a first reverse osmosis membrane A first module including a first concentrated water discharge portion for discharging a first concentrated water in which contaminants are concentrated; And
A second treatment water outlet for discharging the second treated water treated by using the second reverse osmosis membrane, and a second reverse osmosis membrane for treating the second reverse osmosis membrane, And a second concentrated water discharge portion for discharging the second concentrated water in which the pollutant is concentrated,
Wherein the first concentrated water discharge portion and the second influent water supply portion are connected to each other,
Further comprising an adjuster at a front end of the second module to adjust a pressure applied to the second reverse osmosis membrane,
Wherein the controller reduces the flow rate of the second influent water supplied to the second influent supply part in the backwash mode, and the second reverse osmosis membrane is backwashed by the positive osmosis phenomenon. 9. The method of claim 8,
Wherein the backwashing system increases the flow rate of the first treated water processed in the first module when the controller is in the backwash mode to maintain the flow rate of the treated water processed in the entire backwash system, Of the backwash system. 9. The method of claim 8,
The control unit may further include a bypass connected to one end of the second inflow water supply unit,
Wherein the bypass passage is supplied with a part or all of the flow rate flowing into the second inflow water supply section in the backwash mode. 9. The method of claim 8,
The backwashing system of the reverse osmosis membrane further comprises an ion measuring means at a front end of the first influent supply portion of the first module,
Wherein the ion measuring unit measures the ion content of the first influent water supplied to the first influent water supply unit and predicts the degree of scale formed in the reverse osmosis membrane including the first RO and the second RO, Cleaning system. 9. The method of claim 8,
Wherein the backwash system of the reverse osmosis membrane further comprises a medicine injector connected to the second module,
Wherein the chemical injection unit is connected to the second inflow water supply unit and provides the medicament including the scale remover to the second influent water that contacts the one surface of the second reverse osmosis membrane. 9. The method of claim 8,
Wherein the backwash system of the reverse osmosis membrane further comprises a third module,
The third module includes a third reverse osmosis membrane, a third influent water supply part for supplying the third influent water to the third reverse osmosis membrane, a third treated water discharge part for discharging the third treated water treated using the third reverse osmosis membrane, And a third concentrated water discharging portion for discharging the third concentrated water that has been treated with the third reverse osmosis membrane to concentrate the pollutant,
The third module is included in any one position selected from the group consisting of a front end of the first module, a space between the first module and the second module, a rear end of the second module, and a combination thereof,
Wherein the control unit increases the flow rate of the third process water processed in the third module to maintain the flow rate of the process water processed in the entire backwash system when the control unit is in the backwash mode.

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