KR20150133394A - Reverse osmosis membrane module-specific osmotic backwash system - Google Patents

Abstract

The present invention relates to a reverse osmosis membrane module-specific osmotic backwash system. The reverse osmosis membrane module-specific osmotic backwash system for washing a plurality of modules which are in a train of a reverse osmosis membrane comprises: a plurality of high concentration cleaning solution valves installed on a front end of each module to receive raw water, and for supplying the received raw water to each module as a high concentration solution for osmotic cleaning or blocking the received water; a plurality of low concentration cleaning solution valves installed on a rear end of each module, and re-supplying production water generated from each module to each module as a low concentration solution for osmotic cleaning or blocking the production water; a plurality of raw water valves installed on a front end of each module, and supplying raw water which is compressed by a pump to each module or blocking the raw water; and a plurality of discharge valves for discharging a high concentration foreign material discharge solution including pollutants removed by an osmosis phenomenon between the high concentration solution for osmotic cleaning and the low concentration solution for osmotic cleaning from each module. Accordingly, pollutants of a membrane can be discharged as a high concentration foreign material discharge solution by an osmosis phenomenon between a high concentration solution for osmotic cleaning and a low concentration solution for osmotic cleaning from a corresponding module by controlling supply of the high concentration solution for osmotic cleaning for each module through the valves.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a reverse osmosis membrane module reverse osmosis membrane module,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an osmotic backwash system for each reverse osmosis membrane module, and more particularly, to an osmosis backwash system for each module in a train or a group of modules in which several modules are collected to remove contaminants accumulated on a membrane surface And an osmotic backwash system for each reverse osmosis membrane module.

In general, the reverse osmosis membrane can remove salts, organic and inorganic contaminants, viruses, bacteria, heavy metals, etc. using a reverse osmosis membrane which is a microfiltration membrane capable of selectively permeating a specific component. It is attracting attention as a high value-added material in the water treatment industry such as seawater desalination, pure water and ultrapure water, and recycling of wastewater.

PCT Application Publication No. WO 2004/062774 relates to an osmotic pressure cleaning system in which high pressure and high concentration of concentrated water are injected into the feed side of an operating reverse osmosis membrane module and diluted water is pressurized into the production water, Lt; RTI ID = 0.0 > feed-side < / RTI > Thus, membrane surface contaminants formed in the reverse osmosis process can be removed by an osmotic solvent.

Korean Patent No. 10-0987294 relates to a method for osmotic cleaning of a high pressure membrane filtration process and a high pressure membrane filtration apparatus using the same, wherein a high concentration solution of 10,000 to 100,000 mg / L having an inlet pressure of 0 to 3 bar and a filtration product The membrane surface contaminants can be removed by the osmotic solvent using the osmotic pressure difference of the water.

Conventional membrane osmotic backwashing technology requires a separate power unit for the injection of the high concentration solution used in the osmotic backwash and stops the operation of the high pressure pump during the osmotic backwash process, Can be reduced.

PCT Application Publication No. WO 2004/062774 Korean Patent No. 10-0987294

In an embodiment of the present invention, a valve for controlling inflow of highly concentrated solution for osmotic washing and a source of compressed water is installed in each module, and the reverse osmosis membrane module for removing contaminants of the membrane for each module in the train through osmosis phenomenon Cleaning system.

Among the embodiments, the osmotic backwash system for each reverse osmosis membrane module is an osmotic backwash system for each reverse osmosis membrane module for cleaning a plurality of modules in a train of reverse osmosis membranes, A plurality of washing high concentration solution valves for supplying or blocking each of the modules with the high concentration solution for osmotic washing received, and the production water generated from each module installed at each rear end of the module is supplied to the module with low concentration solution for osmotic washing A plurality of wash water low-concentration solution valves for supplying or shutting off, a plurality of raw water valves installed at the front ends of the modules for supplying or blocking raw water compressed by the pump to each of the modules, And the contamination removed by the osmosis phenomenon between the low concentration solution for osmotic washing And a plurality of discharge valve for discharging the foreign material generated in the concentrated water discharge high-concentration solution, and reverse osmosis processes, including quality.

In one embodiment, it may further comprise an input for receiving a wash command that includes information about the module to be cleaned.

In one embodiment, the control unit further includes a control unit for controlling opening / closing of the corresponding cleaning high concentration solution valve, opening / closing of the corresponding cleaning low concentration solution valve, opening / closing of the corresponding raw water valve, and opening / closing of the corresponding discharge valve in accordance with the cleaning command inputted to the input unit can do.

In one embodiment, the controller may further include a memory unit that stores a plurality of valve control data corresponding to each module to be cleaned.

In one embodiment, the control unit can check the module information to be cleaned from the cleaning command input to the input unit, and read the valve control data corresponding to the identified module information from the memory unit.

The control unit generates opening / closing control data for controlling the opening / closing operation of the valve in accordance with the read valve control data, and outputs the opening / closing control data to the washing high concentration solution valve, the washing low concentration solution valve, Closing the high-concentration solution valve for cleaning, opening / closing the low-concentration solution valve for cleaning, opening / closing the raw water valve, and opening / closing the discharge valve.

In one embodiment, the control unit includes first control data for controlling opening and closing of the cleaning high concentration solution valve, second control data for controlling opening and closing of the cleaning low concentration solution valve, and third control data for controlling opening and closing of the raw water valve. Control data and fourth control data for controlling the opening and closing of the discharge valve.

In one embodiment, the information processing apparatus may further include a display unit for displaying information on a module to be cleaned, input from the input unit, and a process of controlling the corresponding module by the control unit.

The osmosis backwash system according to an embodiment of the present invention controls the supply of the high concentration solution for osmosis cleaning for each module through the valve, and the osmosis wash between the high concentration solution for osmosis washing and the low concentration solution for osmosis washing The contaminants on the surface of the membrane are removed and the contaminants can be discharged to the foreign matter-releasing high-concentration solution.

1 is a block diagram illustrating an osmotic backwash system for each reverse osmosis membrane module per reverse osmosis membrane module according to an embodiment of the present invention.
2 is a view illustrating a process of washing the first module with the osmotic backwash system according to the reverse osmosis membrane module shown in Fig.
FIG. 3A is a diagram illustrating fluid flow in a module that is washed with an osmotic backwash system per reverse osmosis membrane module in FIG.
FIG. 3B is a view illustrating fluid flow of a module that is not cleaned by the osmotic backwash system according to the reverse osmosis membrane module in FIG. 1; FIG.

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. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

FIG. 1 is a schematic view illustrating osmotic backwashing of each reverse osmosis membrane module according to an embodiment of the present invention. FIG. 2 is a view illustrating a process of washing the first module by osmosis backwashing by the reverse osmosis membrane module shown in FIG. Is an embodiment to be described.

1 and 2, an osmotic backwash system 100 for each reverse osmosis membrane module is used to clean a plurality of modules within a train of reverse osmosis membranes and includes a high concentration solution valve 110 for cleaning, A low-concentration solution valve 120, a discharge valve 130, and a raw water valve 140.

The washing high concentration solution valve 110 is separately installed in the front end of each module (the front end is the input part for supplying the raw water to each module), and the raw water is supplied and supplied to the module by the high concentration solution 200 for osmotic washing Can be blocked. A plurality of high concentration solution flushing solution valves 110 are installed so as to match the number of cleaning unit modules, and when the high concentration solution valve 110 for cleaning installed at the front end of each module is opened, And when the washing high concentration solution valve 110 installed at the front end of each of the modules is closed, supply of the high concentration solution 200 for osmosis washing to the module can be blocked.

The cleaning high concentration solution valve 110 may be opened or closed according to the first control data for controlling the valve opening and closing operations of the controller 160. The cleaning high concentration solution valve 110 is installed at each front end of the module Opening and closing can be controlled for each valve.

In one embodiment, the washing high concentration solution valve 110 installed at the front end of the first module is referred to as a first cleaning high concentration solution valve 111, and the cleaning high concentration solution valve 110 installed at the front end of the second module, The high concentration solution valve 112 for cleaning and the high concentration solution valve 110 for cleaning installed at the front end of the third module are referred to as the third high concentration solution valve 113 for cleaning. When the operator inputs a cleaning command for the module to the input unit 150 in order to clean the first module, the control unit 160 opens the first cleaning high concentration solution valve 111 according to the cleaning command input from the input unit 150 And generates control data for closing the second cleaning high concentration solution valve 112 and the third cleaning high concentration solution valve 113 to supply only the first module with the osmotic cleaning high concentration solution 200 .

The cleaning low-concentration solution valve 120 is separately installed at each rear end of the module (the rear end is a portion for discharging the product water from each module), and the product water 400 generated in each module is supplied to the low- ). ≪ / RTI >

The cleaning low concentration solution valve 120 is provided with a washing low concentration solution flow control valve 120 for regulating the flow rate when the production water 400 generated in each module is supplied again to the low concentration solution 500 for osmotic washing, And a production water discharging valve 120 for discharging the production water 400 produced in the washing machine 100 to the outside, and one washing low concentration solution flow control valve 120 and one production water discharging valve 120 Can be installed.

The low concentration solution valve 120 for cleaning allows the production water 400 produced by each module to be supplied to the module by the low concentration solution 500 for osmotic washing when the cleaning low concentration solution flow rate control valve is opened, When the flow control valve is closed, production water 400 produced by each module can be prevented from being supplied to the module by the low concentration solution 500 for osmotic cleaning. When the production water discharge valve is opened, the washing low concentration solution valve 120 causes the production water 400 produced in each module to be discharged to the outside for the next process. When the production water discharge valve is closed, The water 400 can be prevented from being discharged to the outside.

In one embodiment, the osmotic backwash system 100 for each reverse osmosis membrane module may omit the production water discharge valve of the cleaning low concentration solution valve 120, or omit the production water discharge valve and the cleaning low concentration solution flow control valve The cleaning low concentration solution valve can also be opened. In this case, as the osmotic backwashing process proceeds while the production water pipe is full due to the reverse osmosis process operation, the low concentration solution for osmotic cleaning is produced in the osmotic backwashing process. The air can be generated inside the tube and prevented from flowing into the module when the tube is not in a full-blown state.

The cleaning low concentration solution valve 120 may be opened or closed according to the second control data generated by the controller 160. The cleaning low concentration solution valve 120 may be opened or closed for each valve installed at the rear end of each module Lt; / RTI >

In one embodiment, the valve 120 provided at the downstream end of the first module to regulate the flow rate of the osmotic cleaning low concentration solution when the produced water 400 is re-supplied to the low concentration solution for osmotic cleaning, A valve 120 for controlling the flow rate of the low concentration solution for osmotic cleaning when the low concentration solution flow rate control valve 121 and the production water 400 provided at the downstream end of the second module are supplied again to the low concentration solution for osmotic cleaning A valve for controlling the flow rate of the low concentration solution for the osmotic cleaning when the second washing low concentration solution flow rate control valve 123 and the product water 400 provided at the rear stage of the third module are re- 120 is referred to as a third cleaning low concentration solution flow rate control valve 125. A valve 120 provided downstream of the first module for discharging the produced water 400 is connected to a first produced water discharge valve 122 and a valve 120 provided at the rear end of the second module for discharging the produced water 400 The second production water discharge valve 124 and the valve 120 provided at the rear end of the third module for discharging the production water 400 are referred to as a third production water discharge valve 126.

When the operator inputs a cleaning command for the module to the input unit 150 in order to clean the first module, the control unit 160 stops production of the production number 400 of the first module and stops the production of the second module and the third module Some of the water 400 may be discharged to the outside for the next process while the remaining part of the water 400 may flow to the production water pipe of the first module by the pressure of the production water branch pipe to be used as the low concentration solution 500 for osmotic washing.

The control unit 160 generates control data for opening the first cleaning low concentration solution flow rate regulating valve 121 in accordance with the cleaning instruction input to the input unit 150 and controls the second cleaning low concentration solution flow rate regulating valve 123 and The control data for closing the third cleaning low concentration solution flow rate control valve 125 may be generated so that the low concentration solution 500 for osmosis cleaning is supplied only to the first module.

The control unit 160 generates control data for closing the first production water discharge valve 122 and generates control data for opening the second production water discharge valve 124 and the third production water discharge valve 126, 2 and the third module may be discharged to the production water reservoir or the next process.

The discharge valve 130 is installed at the downstream end of each module and is connected to the concentrated solution generated from each module or the high concentration solution 200 for osmotic cleaning supplied to the module from the high concentration solution valve 110 for cleaning and the low concentration solution valve 120 The foreign matter discharge high concentration solution 600 containing contaminants of the membrane removed by the osmotic action between the low concentration solution 500 for osmotic washing supplied to the module in FIG.

The discharge valve 130 includes a concentrated water discharge valve 130 for discharging the concentrated water generated in each module during the reverse osmosis process operation and a foreign matter discharge device for discharging a high concentration solution discharged from each module in the osmosis back washing. A single concentrated water discharge valve 130 and a single foreign matter discharge high concentration solution discharge valve 130 may be installed in each module.

When the concentrated water discharge valve is opened in the discharge valve 130 installed at the rear end of the module, the concentrated water generated in each module during the reverse osmosis process operation can be discharged through an energy recovery device (ERD) When the valve is closed, the concentrated water generated in each module can be prevented from being discharged. When the foreign matter discharge high concentration solution discharge valve is opened out of the discharge valve 130 installed at the rear end of the module, the high concentration solution discharged from each module during the osmosis back washing can be discharged to the outside, and the high concentration solution Can be prevented from being discharged to the outside.

The discharge valve 130 may be opened or closed according to the fourth control data generated by the controller 160. The discharge valve 130 may be opened or closed for each valve installed at the rear end of each module.

In one embodiment, the valve 130 installed at the downstream end of the first module for discharging the foreign substance-discharging high-concentration solution is called a first foreign substance discharging high-concentration solution discharging valve 131, The valve 130 for allowing the high concentration solution to be discharged is connected to the second foreign matter discharge high concentration solution discharge valve 133 and the valve 130 provided at the rear end of the third module for discharging the foreign matter discharge high concentration solution is called the third Foreign matter discharge high concentration solution discharge valve 135 ". A valve 130 disposed at the rear end of the first module for discharging the concentrated water is referred to as a first concentrated water discharge valve 132 and a valve 130 provided at a rear end of the second module for discharging the concentrated water, The discharge valve 134 and the valve 130 disposed at the rear end of the third module for discharging the concentrated water are referred to as a third concentrated water discharge valve 133.

When the operator inputs a cleaning command for the module to the input unit 150 in order to clean the first module, the control unit 160 causes the concentrated water discharge of the first module to stop and the foreign matter discharge high concentration solution to be discharged from the first module , And the discharge of the concentrated water of the second module and the third module can be continued.

The control unit 160 generates control data for opening the first foreign substance discharge high concentration solution valve 131 in accordance with the cleaning command inputted to the input unit 150 and controls the second foreign matter discharge high concentration solution valve 133 and the third foreign matter discharge The control data for closing the high concentration solution valve 135 may be generated so that the foreign matter discharge high concentration solution 600 is discharged only in the first module.

The control unit 160 generates control data for closing the first concentrated water discharge valve 132 and generates control data for opening the second concentrated water discharge valve 134 and the third concentrated water discharge valve 136, 2 and the third module can be discharged through the energy recovery device.

The osmosis backwash system 100 for each reverse osmosis membrane module may further include a raw water valve 140, an input unit 150, a control unit 160, a memory unit 170, and a display unit 180.

The raw water valve 140 may be separately provided at a front end of each module (the front end is an input part for supplying raw water to each module) to supply or shut off the raw water compressed by the pump to each module, The production water 400 can be produced through reverse osmosis. When the raw water valve 140 installed at the front end of the module is opened, the raw water valve 140 can be supplied to the module, and the raw water valve 140 installed at the front end of the module is closed The compressed raw water can be prevented from being supplied to the corresponding module.

The raw water valve 140 can be opened or closed according to the third control data generated by the controller 160. The raw water valve 140 can be controlled to be opened or closed for each corresponding valve installed at the front end of each module.

The raw water valve 140 installed at the front end of the first module is referred to as a first raw water valve 141 and the raw water valve 140 provided at the front end of the second module may be referred to as a second raw water valve 142, The raw water valve 140 provided at the front end is referred to as a third raw water valve 143.

The control unit 160 controls the first water valve 141 to close the first raw water valve 141 in response to a cleaning command input to the input unit 150, And to generate control data for opening the second raw water valve 142 and the third raw water valve 143 so that the compressed raw water is supplied only to the second module and the third module.

The input unit 150 allows a worker to input a cleaning command including information on a module to be cleaned, and the controller 160 can identify a module to be cleaned from a cleaning command input to the input unit 150.

The control unit 160 can control the opening and closing of the cleaning high concentration solution valve 110 and the opening and closing of the cleaning low concentration solution valve 120 in accordance with the cleaning instruction inputted to the input unit 150, Closing of the raw water valve 140 can be controlled and the opening and closing of the raw water valve 140 can be controlled.

The control unit 160 can check the module information to be cleaned according to the cleaning command input to the input unit 150 and read the valve control data corresponding to the identified module information from the memory unit 170. [

For example, when the cleaning module input to the input unit 150 is the first module, the control unit 160 opens the first cleaning high concentration solution valve 111 of the first module, The high concentration solution valve 112 for cleaning and the high concentration solution valve 113 for the third cleaning of the cleaning solution high concentration solution valve 110 are read out from the memory part 170 storing the valve control data for closing the high concentration solution valve 112, Can be controlled.

The controller 160 closes the first raw water valve 141 of the first module and opens the second raw water valve 142 of the second module and the third raw water valve 143 of the third module, And controls the corresponding raw water valve 140 by reading the data from the memory unit 170 storing the data.

The controller 160 controls the flow rate of the first osmotic cleaning fluid for the second osmotic cleaning of the second module, the valve control data for opening the first osmotic cleaning low-concentration solution flow rate control valve 121 of the first module and closing the first production water discharge valve 122, The valve control data for closing the low concentration solution flow regulation valve 123 and opening the second production water discharge valve 124 and the third module for the third osmotic cleaning low concentration solution flow rate control valve 125 are closed and the third production The low concentration solution valve 120 for cleaning can be controlled by reading the memory unit 170 storing the valve control data for opening the water discharge valve 126.

The controller 160 controls the first module to discharge the first foreign matter discharge high concentration solution discharge valve 131 and the first concentrated water discharge valve 132 to close the valve control data, The valve 133 closes and the second concentrated water discharge valve 134 opens and the third foreign matter discharge high concentration solution discharge valve 135 of the third module is closed and the third concentrated water discharge valve 136 is closed, The control unit 160 can read the memory unit 170 storing the valve control data for opening the discharge valve 130 and control the discharge valve 130.

The control unit 160 can generate the first control data for controlling the opening and closing of the cleaning high concentration solution valve 110 and the second control data for controlling the opening and closing of the cleaning low concentration solution valve 120 Third control data for controlling the opening and closing of the raw water valve 140 and fourth control data for controlling the opening and closing of the discharge valve 130 can be generated.

The control unit 160 may transmit the module information to be input to the input unit 150 and the process of controlling the corresponding module to the display unit 180.

The memory unit 170 stores valve control data corresponding to each module to be cleaned and the control unit 160 reads the valve control data corresponding to the module information input to the input unit 150 from the memory unit 170 .

The memory unit 170 stores valve control data for opening or closing the high concentration solution valve 110 for cleaning, The valve control data relating to the opening and closing of the low concentration solution valve 120 and the valve control data relating to the opening and closing of the raw water valve 140 can be stored.

For example, the memory unit 170 may be configured to open the first cleaning high concentration solution valve 111 of the first module, to open the second cleaning high concentration solution valve 112 of the second module, When the cleaning high concentration solution valve 113 is to be closed, the valve control data for controlling the first cleaning high concentration solution valve 111, the valve control data for controlling the second cleaning high concentration solution valve 112, The control unit 160 provides valve control data for controlling the high concentration solution valve 113 for use.

The display unit 180 may display information on the module to be cleaned inputted from the input unit 150 and a process of controlling the corresponding module by the controller 160. At this time, You can see the information on the module you entered and the control process of the module.

FIG. 3A is a view for explaining fluid flow of a module to be washed with an osmosis backwashing system for each reverse osmosis membrane module in FIG. 1, and FIG. 3B is a view for explaining a flow of a module Fig.

3A and 3B, the osmotic backwash system 100 for each reverse osmosis membrane module includes a washing high concentration solution valve 110 for supplying or blocking the raw water 200 to the high concentration solution 200 for osmotic washing, Connect separately to the front of the module. At this time, only a few modules among a number of modules in one train can enter the cleaning stage.

The osmosis backwash system 100 for each reverse osmosis membrane module opens the raw water valve 140 to supply the compressed raw water to the module. When the raw water valve 140 is closed, the compressed raw water is not supplied to the module do. The raw water valve 140 leading to the module which has entered the washing step in the compressed raw water pipe from the same compression pump 300 is closed and the remaining module is opened when the raw water valve 140 is opened for normal operation, The pressure exerted on the driving module may be further increased. This can induce an increase in the flux of the remaining normal operation module, thereby compensating for the amount of production water that can not be produced by the module that has entered the cleaning step.

The reverse osmosis membrane module reverse osmosis membrane module 100 uses the same production number 400 for each train and the in-train module in which the low concentration solution valve 120 for cleaning is installed. The production water outlet can be used as an inlet for a low concentration solution 500 for osmotic washing and when a production water outlet 400 is applied to a module having two or more outlets, one of the production water outlets can be used as an osmosis washing low concentration solution 500 inlet Roll can be used. At this time, no power unit is required, and when the module in which the low concentration solution valve 120 for cleaning is opened is supplied to the low concentration solution 500 for osmotic washing, And the high concentration solution for osmotic washing may generate osmosis phenomenon, so that the foreign matter discharging high concentration solution 600 including the contaminant of the filtered membrane may be discharged through the discharge valve 130.

In one embodiment, the osmotic backwash system 100 for each reverse osmosis membrane module is configured such that when the module high-concentration solution valve 110 is opened and the raw water valve 140 is closed, Module. The low concentration solution 500 for osmotic cleaning supplied to the module is continuously supplied and the solvent of the osmotic cleaning low concentration solution 500 moves to the high concentration solution 200 for osmotic cleaning by the osmosis phenomenon and the foreign substance including the contaminant of the membrane The discharged high concentration solution 600 may be discharged through the discharge valve 130. [

In another embodiment, the osmotic backwash system 100 for each reverse osmosis membrane module is configured such that when the high concentration solution valve 110 for cleaning the module is closed and the raw water valve 140 is opened, the compressed raw water is supplied to the module . At this time, the reverse osmotic pressure is generated by the pressure of the compressed raw water, the solvent of the compressed raw water moves to the production water 400, the produced water 400 is discharged to the outside for the next process, Lt; / RTI >

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the present invention as defined by the following claims It can be understood that

100: reverse osmosis membrane reverse osmosis system
110: High-concentration solution valve for cleaning
120: Low-concentration solution valve for cleaning
130: discharge valve
140: raw water valve
150:
160:
170:
180:

Claims (8)

An osmotic backwash system for a reverse osmosis membrane module for cleaning a plurality of modules within a train of reverse osmosis membranes,
A plurality of cleaning high concentration solution valves installed at respective front ends of the modules to supply raw water and supply or block each of the modules with high concentration solution for osmotic cleaning;
A plurality of cleaning low-concentration solution valves installed at respective rear ends of the module to supply or shut off the production water produced in each module to the module with a low concentration solution for osmotic cleaning;
A plurality of raw water valves installed at respective front ends of the modules to supply or block the raw water compressed by the pump to each of the modules; And
And a plurality of discharge valves for discharging the foreign matter discharge high concentration solution including the contaminants removed by the osmosis phenomenon between the high concentration solution for osmotic cleaning and the low concentration solution for osmotic cleaning in the module and the concentrated water generated in the reverse osmosis process Wherein the reverse osmosis membrane module is a reverse osmosis membrane.
The method according to claim 1,
Further comprising an input for receiving a wash command including information about the module to be cleaned.
3. The method of claim 2,
And a control unit for controlling the opening and closing of the high concentration solution valve for cleaning, the opening and closing of the low concentration solution valve for cleaning, the opening and closing of the corresponding raw water valve, and the opening and closing of the corresponding discharge valve in accordance with the cleaning command inputted to the input unit Reverse osmosis membrane reverse osmosis reverse osmosis system.
The method of claim 3,
Further comprising a memory for storing a plurality of valve control data corresponding to each module to be cleaned.
5. The apparatus of claim 4, wherein the control unit
Wherein the control unit checks the module information to be cleaned from the cleaning command input to the input unit and reads the valve control data corresponding to the identified module information from the memory unit.
6. The apparatus of claim 5, wherein the control unit
Closing control data for controlling the opening and closing operation of the valve according to the read valve control data to apply the opening and closing control data to the cleaning high concentration solution valve, the cleaning low concentration solution valve, the raw water valve and the discharge valve And controls the opening and closing of the washing high concentration solution valve, the opening and closing of the washing low concentration solution valve, the opening and closing of the raw water valve, and the opening and closing of the discharge valve.
7. The apparatus of claim 6, wherein the control unit
First control data for controlling opening and closing of the cleaning high-concentration solution valve;
Second control data for controlling opening and closing of the cleaning low-concentration solution valve;
Third control data for controlling opening and closing of the raw water valve; And
And fourth control data for controlling the opening and closing of the discharge valve is generated in the reverse osmosis membrane module.
The method of claim 3,
Further comprising a display unit for displaying information on a module to be cleaned inputted from the input unit and a process of controlling the module by the controller, on the screen.

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