KR101410910B1 - Apparatus for cleaning Reverse osmosis membrane module and Method of cleaning the device - Google Patents

Abstract

The present invention relates to an apparatus and a method for washing a reverse osmosis membrane module. The washing apparatus comprises: a washing tank for accommodating washing liquid; a supersonic wave generator for exerting supersonic waves into the washing tank; a circulation pipe having one end part connected to the concentrate outlet of the membrane module; and a vacuum pump installed on the circulation pipe and sucking foam which is generated by the washing liquid and the supersonic waves into the membrane module by exerting negative pressure into the membrane module. The apparatus and method for washing a reverse osmosis membrane module according to the present invention effectively wash even objects that are so severely contaminated that the objects cannot be recycled via general methods by a complex washing method in which vacuum pressure, ultrasonic waves, and osmotic pressure are applied. Therefore, the objects can be made to have performance similar to the performance of a new product and discarded membrane modules can be collected to be reused. In addition, the apparatus for washing a reverse osmosis module can be used without burden as washing time is very short and a small amount of wastewater is generated by washing, thus generating little environmental load.

Description

TECHNICAL FIELD [0001] The present invention relates to a reverse osmosis membrane module cleaning apparatus and a cleaning method,

The present invention relates to a cleaning device and a cleaning method of a (NF, RO) membrane module.

There are a wide variety of purifiers for purifying water contaminated with various contaminants or impurities, and most purifiers have membranes for filtering contaminants.

The membrane may be classified into MF (Micro Filtration: 0.03 to 10 micron), UF (Ultra Filtration: 0.02 to 0.1 micron), NF (Nano filtration: 0.001 micron) and the like depending on the size of the filtration particles. Hollow fiber, Tubla, Spiral wound, Plate and frame are used.

In particular, since the NF has a very fine structure, it can filter not only all the particulate matter contained in water, various viruses, but also inorganic substances and organic substances dissolved in water, so that the reverse osmosis type desalination apparatus .

However, when the MF or UF is contaminated with contaminants, it can be easily cleaned by a back washing method and is used without any difficulty in recycling. However, NF is a nano- Because it is 1mm / 1mm unit, it is difficult to back wash and it is necessary to perform chemical cleaning using chemical cleaning solution.

In order to perform such a chemical cleaning, it is necessary to carry out a quite complicated and complicated process using the cleaning solution recommended by the manufacturer of the membrane with the use guidelines specified. If the recommended cleaning solution does not accurately operate the cleaning concentration, the cleaning time, and the cleaning combination, the cleaning efficiency is significantly lowered, and even if the cleaning is performed, the membrane is easily clogged again to advance the cleaning cycle. It is necessary to discard it at an early stage.

The problem is that the purge process is rarely carried out in accordance with the above-mentioned guidelines. Although it is possible at the level of a large corporation having the capital, technology and professional personnel for the purification treatment, it is a reality that the above-mentioned purification treatment is not carried out according to the manual at the water treatment facilities of small and medium size.

In the case of water treatment in the case of small to medium-sized water treatment, it is almost impossible to make proper meandance because of lack of skilled manpower or technology. For example, most of the membrane module is used up to the end. Since most of the membrane modules thus discarded have already missed the washable period, satisfactory cleaning can not be expected even if they are cleaned according to the above cleaning manual. Membrane modules thus discarded are becoming an urgent problem in terms of resource recycling and industrial waste generation.

On the other hand, Korean Patent Registration No. 1206618 discloses a reverse osmosis membrane cleaning apparatus comprising a pretreatment unit, a pump, a reverse osmosis unit, a cleaning liquid supply unit, and a monitor unit. The cleaning device monitors the pressure and flow rate change of the reverse osmosis part of the monitor and the removal rate of the salt in real time, thereby causing the cleaning liquid supply part to inject the cleaning liquid when the salt removal rate drops, for example.

However, such a cleaning device has a configuration such as automatically injecting a cleaning liquid, but has a disadvantage in that the cleaning efficiency of the membrane module in the reverse osmosis part is poor. In order to obtain a satisfactory cleaning effect, the cleaning liquid must be continuously circulated for one to three days, for example. The cleaning operation can not be performed while circulating the cleaning liquid.

In order to solve the above problems, the present invention employs a complex cleaning method in which a vacuum pressure, an ultrasonic wave, and an osmotic pressure are simultaneously applied, so that objects that are so contaminated that they can not be recycled in a normal manner are effectively cleaned, So that it is possible to collect membrane modules that have already been disposed of and to reuse them as much as possible. Also, since the cleaning time is very short and the generation amount of wastewater due to washing is small, there is no environmental load. And a reverse osmosis membrane module cleaning apparatus and method.

In accordance with an aspect of the present invention, there is provided a reverse osmosis membrane module cleaning apparatus comprising a membrane for purifying water by passing water from the outside, an RO water outlet for discharging RO water through the membrane, A cleaning tank for cleaning the reverse osmosis membrane module having a concentrated water outlet for discharging water that has not passed through the membrane, the cleaning tank providing a cleaning space for cleaning the membrane module and containing a cleaning solution; An ultrasonic generator mounted on the cleaning tank and applying ultrasonic waves to the inside of the cleaning tank during cleaning; A circulation tube having one end connected to the concentrated water outlet of the membrane module and the other end opened to the inside of the washing tub; And a vacuum pump installed in the circulation pipe and applying negative pressure to the membrane module to suck bubbles generated by the cleaning liquid and the ultrasonic waves into the inside of the membrane module and returning the bubbles to the cleaning tank through a circulation pipe.

The cleaning apparatus may further include: Wherein the RO water storage tank is connected to the RO water outlet of the membrane module via the first RO water supply pipe, the first RO water supply pipe is connected to the RO water supply pipe, And an RO water valve for introducing the RO number into the interior of the membrane module and allowing the RO number to pass through the membrane by the action of osmotic pressure and to back up the membrane.

In addition, the cleaning apparatus includes: An alkaline cleaning liquid storage tank for storing an alkaline cleaning liquid supplied to the cleaning tank via an alkaline cleaning liquid supply pipe opened and closed by a valve; Further comprising an acid cleaning liquid reservoir for receiving acid cleaning liquid supplied to the cleaning tank via an acid cleaning liquid supply pipe opened and closed by a valve, wherein the RO water stored in the RO water storage tank is connected to a second RO water supply pipe To the cleaning tank.

In order to achieve the above object, the reverse osmosis membrane module cleaning apparatus of the present invention comprises a membrane for purifying the water by passing the water introduced from the outside, and an RO water outlet for discharging the RO water passing through the membrane, An alkaline washing tank for receiving an alkaline washing liquid from the outside and providing a space for alkaline washing of the membrane module, a washing tank for washing the reverse osmosis membrane module, An ultrasonic wave generator mounted on the cleaning tank and generating ultrasonic waves during cleaning; a circulation tube having one end connected to the concentrated water outlet of the membrane module and the other end opened to the inside of the alkali cleaning tank; and a negative pressure And the bubbles generated by the ultrasonic wave and the alkaline cleaning liquid An alkaline cleaning section including a vacuum pump through a circulation pipe sends back twos alkali washing and then sucked into the inside of the lane module; An ultrasonic generator mounted on the pickling tank and generating ultrasonic waves during cleaning; and a condenser connected to the concentrated water outlet of the membrane module, wherein the pickling tank is provided with an acid pickling solution supplied from outside to provide a space for pickling the membrane module, And the other end is opened to the inside of the pickling trough, and a negative pressure is applied to the membrane module in a state where it is installed in the circulation tube and the bubble generated by the pickling solution and the ultrasonic wave is sucked into the inside of the membrane module, A pickling unit having a vacuum pump for returning the picked-up picked-up picked-up product to the picked-up condition; An RO water washing tank for receiving the RO water, which is purified water by a separate membrane module, for containing the membrane module; an ultrasonic generator installed in the RO washing tank and for applying ultrasonic waves to the RO washing tank; A circulation tube connected to the outlet of the membrane module and connected to the discharge port and opened to the inside of the RO washing and washing tub; and a bubble generated by the RO number and the ultrasonic wave is sucked into the membrane module by applying a negative pressure in the membrane module, And an RO washing unit having a vacuum pump for returning the RO washing water to the RO washing tank through the circulation pipe.

Also, the RO water storage tank is connected to the RO water outlet of the membrane module through the first RO water supply pipe, and the RO water is guided into the first RO water supply pipe to the inside of the membrane module, And an RO water valve for passing back the membrane.

In order to accomplish the above object, the reverse osmosis membrane cleaning method of the present invention comprises a membrane for purifying by passing water introduced from the outside, a RO water outlet for discharging RO water passing through the membrane, , A reverse osmotic membrane module having a concentrated water outlet for discharging water that has not passed through the membrane, wherein the membrane module to be cleaned is immersed in RO water purified by a separate membrane module to wet the membrane Wow; After the immersion step, the membrane module is set in a washing tank containing a washing liquid, negative pressure is applied to the concentrated water outlet, the washing liquid is sucked into the membrane module, the washing liquid passes through the membrane module, A cleaning liquid circulating step for removing the cleaning liquid; An ultrasonic wave generating step of applying ultrasonic waves to the cleaning liquid during the cleaning liquid circulation step; A backwashing step of directing the RO number purified by the separate membrane module to the RO water outlet of the membrane module after the rinse solution circulation step is completed to allow the RO number to pass through the membrane by osmotic action and to reverse the membrane; And a step of rinsing the membrane module after completion of the backwashing step to a RO number purified by a separate membrane module.

In order to accomplish the above object, the reverse osmosis membrane cleaning method of the present invention comprises a membrane for purifying by passing water introduced from the outside, a RO water outlet for discharging RO water passing through the membrane, , A reverse osmotic membrane module having a concentrated water outlet for discharging water that has not passed through the membrane, wherein the membrane module to be cleaned is immersed in RO water purified by a separate membrane module to wet the membrane Wow; The membrane module having been subjected to the immersion step is put in an alkali washing tank containing an alkaline washing liquid and a negative pressure is applied to the concentrated water outlet so that the alkaline washing liquid is sucked into the membrane module and the alkaline washing liquid is sucked into the inside of the membrane module An ultrasonic wave generating step of applying ultrasonic waves to the alkaline cleaning liquid to form bubbles in the primary alkaline cleaning liquid circulating step and the primary alkaline cleaning liquid circulating step to be performed simultaneously with the primary alkaline cleaning liquid circulating step; And a backwashing step of directing the RO number purified by the separate membrane module to the RO water outlet of the membrane module so that the RO number passes through the membrane by osmotic action and backs up the membrane; The membrane module having been subjected to the first-order step is set in a pickling bath containing a pickling solution, and negative pressure is applied to the concentrated water outlet to suck the pickling solution into the inside of the membrane module, The ultrasonic wave generating step of applying ultrasonic waves to the acid cleaning liquid to form bubbles; and a second membrane module, after the acid washing liquid circulating step, Guiding the RO number purified by the membrane separation module to an RO water outlet of the membrane module, the RO number passing through the membrane by osmotic action and backwashing the membrane; Characterized in that the step of rinsing the membrane module after completion of the second-order step is carried out with a RO number purified by a separate membrane module.

In addition, a step performed between the second step and the rinsing step may include a step of applying a negative pressure to the concentrated water outlet in a state in which the membrane module having undergone the second-leveling step is put in an alkaline cleaning tank containing an alkaline cleaning liquid A second alkaline cleaning liquid circulating step of sucking the alkaline cleaning liquid into the inside of the membrane module to allow the alkaline cleaning liquid to pass through the inside of the membrane module and a step of performing ultrasonic waves in the alkaline cleaning liquid during the second alkaline cleaning liquid circulating step, And an RO washing step of introducing the RO water purified by the separate membrane module to the RO water outlet of the membrane module after the secondary alkaline cleaning liquid circulation process is completed and the RO number passing through the membrane by osmotic action And a third-order step including a backwash process for backwashing the membrane is further included It is gong.

Since the reverse osmosis membrane module cleaning apparatus and cleaning method of the present invention as described above employs a complex cleaning method that simultaneously applies a vacuum pressure, an ultrasonic wave, and an osmotic pressure, It is possible to collect the already discarded membrane module and to reuse it as much as possible, and the cleaning time is very short, and the amount of wastewater generated by washing is small, so that the environmental load is almost There is no need to feel free to use.

1 is a view showing the overall structure of a reverse osmosis membrane module cleaning apparatus according to a first embodiment of the present invention.
FIG. 2 is a block diagram illustrating a membrane module cleaning method using the reverse osmosis membrane module cleaning apparatus shown in FIG. 1. Referring to FIG.
3 is a diagram illustrating the overall structure of a reverse osmosis membrane module cleaning apparatus according to a second embodiment of the present invention.
4 is a block diagram showing a membrane module cleaning method using the cleaning device shown in FIG.
5 is a diagram showing the overall structure of a reverse osmosis membrane module cleaning apparatus according to a third embodiment of the present invention.
FIG. 6 is a block diagram for explaining a membrane module cleaning method using the cleaning device shown in FIG.

Hereinafter, one embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

The present invention has a membrane for purifying by passing water introduced from the outside, and has a RO water outlet at one side thereof for discharging RO water passing through the membrane, and a concentrated water outlet for discharging water not passing through the membrane To an apparatus and method for cleaning a reverse osmosis membrane module.

FIG. 1 is a view showing the overall structure of a reverse osmosis membrane module cleaning apparatus 11 according to a first embodiment of the present invention. FIG. 2 is a schematic view of the reverse osmosis membrane module cleaning apparatus 11 shown in FIG. FIG. 2 is a block diagram illustrating a membrane module cleaning method.

Basically, the reverse osmosis membrane module washing apparatus 11 according to the first embodiment is composed of an alkali washing section 61, a pickling section 65, and an RO washing and washing section 63. The alkali cleaning section 61, the pickling section 65, and the RO washable section 63 are configured to be parallel and independent of each other.

Particularly, in the membrane module cleaning method in this embodiment, one membrane module 33 (as shown in the figure) is attached to the RO washable portion 63, the alkali cleaning portion 61, 65, an alkali cleaning section 61, and an RO washable section 63 sequentially.

The alkali cleaning section 61 includes an alkaline cleaning liquid storage tank 15 for storing an alkaline cleaning liquid 15a and an alkaline cleaning tank 31 disposed at a lower altitude than the alkaline cleaning liquid storage tank 15.

The alkaline cleaning liquid storage tank 15 is a container for storing the alkali cleaning liquid 15a supplied from the outside and includes a stirring motor 19 and a rotor 21. The agitation motor 19 agitates the alkaline cleaning liquid 15a through the rotor 21 to prevent deposits.

The alkaline cleaning liquid storage tank 15 is provided with a temperature control unit 17. The temperature controller 17 serves to maintain the alkaline cleaning liquid 15a within a predetermined temperature range. The temperature realized by the temperature regulating part 17 is about 20 캜 to 30 캜.

The alkaline cleaning liquid 15a may be at least one selected from the group consisting of NaOH, TSP, Sodium Triphosphate (SHP), Sodium Hexa Meta Phosphate (SHMP), Ethylene Diamine Tetra Acetic Acid- , And sodium dodecyl sulfate (SDS), dissolved in a separately prepared RO water.

In the present description, the RO number refers to water purified through a separate reverse osmosis membrane module, and this water will be referred to as RO number in the future.

When all of the above components are used together, 0.01 to 0.1 wt% of sodium hydroxide, 0.01 to 0.5 wt% of EDTA, 0 to 0.5 wt% of TSP, STP, SHMP, 0 to 0.6 wt% of SDS, .

Reference numeral 15b denotes a drain valve for draining precipitates precipitated in the alkaline cleaning liquid reservoir 15.

The alkali cleaning tank 31 is a tank in which the alkali cleaning liquid 15a is stored, and accommodates the membrane module 33 to be processed therein. The size of the alkali washing tub 31 is such that the level of the alkali washing liquid 15a can be higher than that of the membrane module 33 while the membrane module 33 is accommodated. A drain valve 31a is also provided in the lower part of the alkali washing tank 31. [

In particular, an ultrasonic wave generator 45 is provided on the lower side of the alkali cleaning tank 31. The ultrasonic wave generator 45 operates by electric power supplied from the outside to apply ultrasonic waves to the inside of the alkali washing tank 31. The frequency of the ultrasonic wave outputted from the ultrasonic wave generator 45 is about 40 KHz to 60 KHz. The output of the ultrasonic wave generator varies depending on the size of the membrane module 33 to be processed.

The ultrasonic wave output from the ultrasonic wave generator 45 is transmitted to the alkaline cleaning liquid 15a to generate fine bubbles in the alkaline cleaning liquid 15a. The bubbles are sucked into the membrane module 33 during operation of a vacuum pump 43 to be described later, and blow out from the membrane module to remove contaminants from the membrane. This will be described later.

Circulating tubes 25a and 25b are provided on the side of the alkaline cleaning tank 31. [ The circulation pipes 25a and 25b are connected to each other in the longitudinal direction and serve as passages for extracting the cleaning liquid 15a from the inside of the alkali cleaning tank 31 to the outside and returning the cleaning liquid to the outside.

The circulation pipes 25a and 25b are connected to the silicone hose 38 connected to the concentrated water outlet 33b of the membrane module 33 to be cleaned and the silicone hose 38 connected to the silicone hose 38 through the quick coupler 36 A first circulation pipe 25a and a second circulation pipe 25b having one end connected to the first circulation pipe 25a and the other end drawn into the alkaline cleaning tank 31. [ The quick coupler 36 is a known connecting member that is very easy to fasten and separate.

The first circulation pipe 25a is provided with a pressure gauge 39, a vacuum pump 43, a flow meter 41, a circulation valve 25c and a drain valve 25d. The pressure gauge 39 serves to check the pressure of the alkali cleaning liquid 15a passing through the first circulation pipe 25a and to inform the outside of the pressure of the alkali cleaning liquid 15a. The flow meter 41 displays the flow rate of the alkali cleaning liquid 15a do.

The vacuum pump 43 sucks up the alkaline cleaning liquid 15a through the concentrated water outlet 33b. That is, when the vacuum pump 43 is operated, a negative pressure is formed on the upstream side of the vacuum pump 43 to suck up the alkaline cleaning liquid 15a. The suction pressure of the vacuum pump 43 is about -0.9 kgf / cm2 to -1 kgf / cm2. However, the sign (-) at the suction pressure means a negative pressure.

The power of the vacuum pump 43 depends on the size of the membrane module 33 to be processed, and may be, for example, larger than the above range.

The circulation valve 25c is a valve that opens and closes the first circulation pipe 25a and is opened when the vacuum pump 43 is operated and is shut off when the vacuum pump 43 is not operated. The drain valve 25d serves to drain the circulating alkaline cleaning liquid 15a from the first circulation pipe 25a.

A strainer 27 and a cartridge filter 29 are sequentially installed in the second circulation pipe 25b. The strainer 27 serves to filter out particles having a size of about 0.3 mm, which may be mixed with the alkali cleaning liquid 15a. The cartridge filter 29 also filters particles of the order of 10 microns.

When the vacuum pump 43 is operated by connecting the silicone hose 38 to the concentrated water outlet 33b with the circulation valve 25c opened and the drain valve 25d shut off, 31 are sucked into the inside of the membrane module 33 and circulated.

The alkali cleaning liquid 15a sucked into the membrane module 33 comes into contact with the membrane built in the membrane module 33 and dissolves or removes some organic substances attached to the membrane. Particularly, the alkaline cleaning liquid 15a sucks up by the negative pressure and then collects at one point, that is, the concentrated water outlet 33b and exits to the outside, so that it rises up to the constituent corners inside the membrane module 33,

Reference numeral 23 denotes an alkaline cleaning liquid supply pipe. One end of the alkaline cleaning liquid supply pipe 23 is fixed to the alkaline cleaning liquid storage tank 15 and the other end is connected to the second circulation pipe 25b. The alkaline cleaning liquid 15a stored in the alkaline cleaning liquid reservoir 15 is supplied to the alkaline cleaning bath 31 through the alkaline cleaning liquid supply pipe 23 and the second circulation pipe 25b. It goes without saying that the alkaline cleaning liquid supply pipe 23 may be directly connected to the alkaline cleaning tank 31 as the case may be.

A silicone hose 37 is connected to the RO water outlet 33a of the membrane module 33. The silicone hose 37 is connected to the first RO water supply pipe 46 through a quick coupler 35 as a hose made of a flexible material.

The first RO water supply pipe 46 is opened and closed by the RO water valve 46a as a passage for guiding the RO water 13a stored in the RO water storage tank 13 to the membrane module 33. [ The RO water 13a stored in the RO water storage tank 13 flows downward through the opened RO valve 46a and is supplied to the membrane module 33 via the silicone hose 37. [

The RO water valve 46a is shut off when the vacuum pump 43 is operated and is opened after the circulation of the alkali cleaning liquid 15a by the vacuum pump 43 is completed, (33).

The RO water 13a sent to the membrane module 33 passes through a membrane (not shown) inside the membrane module 33 by an osmotic action and is attached to the membrane (disassembled by the action of the alkaline cleaning liquid) After the contaminants are separated from the surface of the membrane, they are mixed with the alkaline cleaning liquid 15a. That is, the membrane is back washed.

The RO water storage tank 13 is a tank for separately storing and storing the RO water 13a through a supply pipe 13c and has a valve 13b at a lower portion thereof. It is a matter of course that the RO number 13a is supplied when the valve 13b is opened.

The pickling section 65 includes a pickling solution storage tank 47 for storing the pickling solution 47a and a pickling vessel 51 connected to the pickling solution storage tank 47 through the pickling solution supply pipe 49 do.

Most of the structure of the pickling portion 65 is the same as the structure of the alkali cleansing portion 61 described above, and the same members having the same function are given the same reference numerals, and a repeated description thereof will be omitted.

The acid washing liquid reservoir 47 has a drain valve 47b at a lower portion thereof for containing acid pickling liquid 47a supplied from the outside. The drain valve 47b is a passage through which the precipitate settled in the pickling solution storage tank 47 is taken out to the outside.

The temperature control unit 17 is provided on the side of the acid washing liquid reservoir 47. The temperature regulator 17 maintains the acid cleaning liquid 47a at 20 캜 to 30 캜.

In addition, the agitation motor 19 and the rotor 21 provided in the acid washing liquid reservoir 47 prevent sedimentation of the mixture contained in the acid washing liquid.

The pickling solution 47a is obtained by mixing one or more selected from among hydrochloric acid, hydrochloric acid, citric acid, EDTA-2Na, and SDS, or all or all of them, into RO water. (0.1 to 0.1% by weight), citric acid (0 to 1% by weight), EDTA-2Na (0 to 0.5% by weight), SDS 0.2% by weight).

The pickling tank 51 receives the pickling solution 47a supplied from the pickling solution storage tank 47 and performs cleaning of the membrane module 33 therein.

The pickling vessel 51 is provided with a drain valve 51a, and the ultrasonic generator 45 is provided below the pickling vessel 51. The ultrasonic wave generator 45 operates when the vacuum pump 43 operates to apply ultrasonic waves to the acid cleaning liquid. As described above, fine bubbles are generated inside the acid cleaning liquid 47a by the action of the ultrasonic wave generator 45. [

The circulation pipes 25a and 25b are mounted on the side of the pickling vessel 51. [ The circulation pipes 25a and 25b circulate acid pickling liquid 47a during operation of the vacuum pump 43 so that acid pickling liquid is sucked into the inside of the membrane module 33. [

The circulation pipes 25a and 25b are connected to the silicone hose 38 through the silicone hose 38 and the quick coupler 36 which are connected to the concentrated water outlet 33b of the membrane module 33, And a second circulation pipe 25b, one end of which is fixed to the first circulation pipe 25a and the other end of which is fixed to the acid washing liquid reservoir 47 by being inserted and fixed.

The first circulation path 25a is provided with a pressure gauge 39, a vacuum pump 43 and a flow meter 41. The strainer 27 and the cartridge filter 29 are mounted on the second circulation pipe 25b.

The acid cleaning liquid supply pipe 49 for guiding the acid cleaning liquid 47a of the acid cleaning liquid reservoir 47 to the pickling tank 51 has an upper end that is fixed to the acid cleaning liquid reservoir 47, And is connected to the circulation pipe 25b. Therefore, the pickling liquid 47a is supplied to the pickling vessel 51 through the pickling liquid supply pipe 49 and the second circulation pipe 25b through the supply valve 49a.

The RO water outlet 33a of the membrane module 33 set in the pickling tank 51 receives the RO water 13a through the first RO water supply pipe 46 and the silicone hose 37. [ At this time, the RO water valve 46a of the first RO water supply pipe 46 is closed when the pickling solution 47a is circulated and is opened after the circulation is completed, so that the RO water 13a is supplied to the membrane module 33 .

The RO washing unit 63 includes an RO water storage tank 13 in which the RO water storage 13a is stored and an RO storage tank 13 in the RO water storage tank 13, And an RO water washing tank 59 supplied with water 13a.

The RO water storage tank 13 is a part of the RO washable section 63 serving also as a supply source for supplying the RO water 13a to the alkali washing tank 31 and the pickling tank 51. The RO number 13a filled in the RO water storage tank 13 is water purified by a separate normally operating membrane module (not shown).

The RO washing and washing tank 59 is a space in which an immersion step 101 and a rinsing step 115 to be described later proceed and has an ultrasonic wave generator 45 at the lower part thereof. The circulation pipes 25a and 25b are also located on the side of the RO water washing tank 59.

The circulation pipes 25a and 25b are provided with a silicone hose 38 fixed to the concentrated water outlet 33b of the membrane module 33 and a second circulation pipe 36 connected to the silicone hose 38 by a quick coupler 36. [ And a second circulation pipe 25b connected to the first purifying pipe 25a and the other end being connected to the RO rinsing tank 59.

A pressure gauge 39, a vacuum pump 43 and a flow meter 41 are mounted on the first circulation pipe 25a and a strainer 27 and a cartridge filter 29 are installed on the second circulation pipe 25b. As shown above.

The RO water 13a stored in the RO water storage tank 13 is supplied to the RO water wash tank 59 through the second RO water supply pipe 44. [ The second RO water supply pipe 44 can be opened and closed by a valve 44a.

The RO water outlet 33a of the membrane module 33 is supplied with the RO water 13a through the silicone hose 37 and the first RO water supply pipe 46.

The silicone hoses 37 and 38 connected to the RO water discharge port 33a and the concentrated water discharge port 33b of the membrane module 33 to be cleaned are connected to the quick couplers 35 and 36 And the first circulation pipe 25a through the first RO water supply pipe 46 and the first circulation pipe 25a, the movement of the quick couplers 35 and 36 is very simple.

It is very easy to install the membrane module 33 in the RO washing / washing tank 59 to the alkali washing tank 31 or the alkaline washing tank 31 to the pickling tank 51 or vice versa.

The cleaning method of the reverse osmosis membrane module 33 according to the first embodiment having the above-described structure includes the immersion step 101, the first-order step 103, the first-difference transfer step 105, A second difference transmission step 109, a third order adjustment step 111, a third difference transmission step 113 and a rinsing step 115. The first difference transmission step 107, the second difference transmission step 109, the third difference transmission step 111,

The immersing step 101 is a process of setting a membrane module 33 to be purified in the RO washing and washing tank 59 and immersing the RO membrane in RO water to wet an inner membrane (not shown).

Since the reverse osmosis membrane to be cleaned is left in a discarded state or is discarded, most of the moisture is evaporated and dried, so that the immersion step 101 is first carried out to make a hygroscopic state. The time of the immersion step (101) is variable depending on the state of the membrane module (33).

In order to perform the immersion step 101, the membrane module 33 is vertically placed in the RO water washing tank 59 and is submerged in the RO water, and then the quick couplers 35 and 36 are filled.

In this state, the valve 44a is shut off, the circulation valve 25c is opened, and the vacuum pump 43 is driven. When the vacuum pump 43 is driven, the RO water 13a in the RO flushing tank 59 is sucked into the membrane module 33 through the membrane module 33, Returning to the RO water washing tank 59 via the first circulation pipe 38, the first circulation pipe 25a and the second circulation pipe 25b.

At this time, the flow rate of the RO number is controlled to be not more than 0.1 m / sec by adjusting the vacuum pump 43 and the circulation valve 25c. The flow time of the RO water is adjusted to about 20 minutes to 1 hour and the water temperature is maintained at about 45 ° C. Through the above process, the membrane inside the membrane module 33 comes into contact with the RO number and becomes wet.

Particularly, during the circulation process, the ultrasonic wave generator 45 is driven to transmit ultrasonic waves into the RO water to form minute bubbles by the ultrasonic waves in the RO water 13a. The fine bubbles flow into the membrane module 33 together with the RO water 13a and flow upward, and micro-bubbles are applied to the contaminants attached to the membrane. In addition to being wetted with water, the contaminants are subjected to minute stimulation by air bubbles, which weakens the adhesion state to the surface of the membrane.

After completion of the flow of the washing liquid, the ultrasound generating unit 45 may be stopped and the RO valve 46a may be opened to guide the pure RO water into the membrane module 33.

When the immersion step 101 is completed, the membrane module 33 is transferred to the alkali washing tank 31 through the first-difference transfer step 102, and then the first cleaning step 103 is performed in the alkali cleaning part 61 do.

The primary cleaning step 103 includes a primary alkali cleaning liquid circulating step 103a, an ultrasonic wave generating step 103b and a backwashing step 103c.

It goes without saying that the membrane module 33 after immersion is taken out of the RO water washing tank 59 and transferred to the alkaline washing tank 31 before proceeding to the first-level washing step 103 in earnest. Setting it here means that the membrane module 33 is arranged vertically in the alkaline cleaning bath 31 and is immersed in the alkaline cleaning solution 15a, and then the quick couplers 35 and 36 are filled.

The primary alkali cleaning liquid circulation process 103a for driving the vacuum pump 43 and the ultrasonic wave generating unit 45 are performed while the supply valve 23a and the drain valve 25d are closed, The ultrasonic wave generating step 103b is operated.

When the vacuum pump 43 is driven, the alkaline cleaning liquid 15a is sucked into the membrane module 33, passes through the membrane module 33, and then passes through the silicone hose 38, the first circulation pipe 25a, , The second circulation pipe (25b) is returned to the alkali washing tank (31).

When the ultrasonic wave generator 45 is operated, minute bubbles are generated in the alkaline cleaning liquid 15c. The bubbles are sucked into the interior of the membrane module 33 together with the alkaline cleaning liquid 15a and flow upward to blow up the alkaline cleaning liquid 15c against the contaminants deposited on the surface of the membrane.

When the bubble bursts, the space occupied by the bubble instantaneously opens, and the alkaline cleaning liquid 15c fills the space to generate physical energy. When the bubble bursts between the contaminant and the membrane, The energy is transmitted in the direction of making. This is reminiscent of a known air bubble washer.

The contaminants separated from the membrane module 33 through the above process are caught by the strainer 27 and the cartridge filter 29 and collected later.

During the primary alkaline cleaning liquid circulation step 103a, the flow rate of the alkali cleaning liquid passing through the membrane module 33 is maintained at 0.1 m / sec or less, and the circulation of the cleaning liquid proceeds for 30 minutes to 1 hour. It is needless to say that the flow rate of the alkaline cleaning liquid 15a can be controlled by controlling the vacuum pump 43 and the circulation valve 25c.

The backwashing step 103c, which is performed after the first alkaline cleaning liquid circulation step 103a is completed, is a process of inducing and injecting the RO water into the membrane module 33. That is, the RO water valve 46a is opened to supply the RO water in the RO water storage tank 13 to the membrane module 33 through the first RO water supply pipe 46 and the silicone hose 37.

The number of ROs supplied to the membrane module 33 is shifted from the inner surface to the outer surface of the membrane by the osmotic action and pushes out contaminants deposited on the outer surface of the membrane to back wash. The contaminants are treated in the alkaline cleaning liquid 15a so that the organic matter is somewhat dissolved or already cloudy, and is somewhat separated from the membrane through this backwashing process.

The membrane module 33 is transferred from the alkali washing tank 31 to the pickling tank 51 through the two-stage transferring step 105 and then the second ordering step 107 is carried out do.

The secondary determining step 107 includes an acid washing liquid circulating step 107a, an ultrasonic wave generating step 107b, and a backwashing step 107c.

The acid pickling cyclic process 107a is a process of circulating the pickling solution 47a by operating the vacuum pump 43 with the membrane module 33 set on the pickling vessel 51. [ At this time, the flow rate of the pickling liquid 47a may be 0.1 m / sec or less and the circulation time may be about 30 minutes to 60 minutes.

The ultrasonic wave generating step 107b is a process of operating the ultrasonic wave generating part 45 to form bubbles in the acid washing liquid 47a.

Through the acid pickling process 107a and the ultrasonic wave generating process 107b, the pickling solution 47a containing fine bubbles passes through the membrane module 33 and removes the inorganic substances therein. The operation principle and function of the bubble are the same as those in the first-order mode.

The inorganic contaminants separated or removed from the membrane module (33) are filtered by the strainer (27) and the cartridge filter (29) and collected later.

If the acid washing liquid 47a is sufficiently circulated, the vacuum pump 43 and the ultrasonic wave generator 45 are stopped, and the RO water valve 46a is opened to backwash the membrane with the RO water 13a.

The RO water introduced into the membrane module 33 via the first RO water supply pipe 46 moves from the inner side to the outer side of the membrane due to the osmosis phenomenon and peels off the contaminants and backwashes the membrane. The backwashing using this osmosis phenomenon is also the same as the first washing.

If the second leveling step 107 is completed, the membrane module 33 is moved back to the alkali washing tank 31 from the pickling tank 51 through the three-stage transferring step 109, ).

The tertiary determination step 111 includes a secondary alkali cleaning liquid circulating step 111a, an ultrasonic wave generating step 111b and a backwashing step 111c, do.

If the secondary alkali cleaning of the membrane module 33 is performed by the third ordering step 111, the membrane module 33 is removed from the alkali washing tank 31 through the fourth difference transfer step 113, After transferring to the tank 59, the rinsing step 115 is continued.

The rinsing step 115 is a process of finally rinsing the membrane module 33 in the RO water 13a atmosphere with the membrane module 33 having been subjected to the 1,2,3 washing step set on the RO water washing tank 59, And proceeds in the same manner as the immersion step (101).

That is, the rinsing step 115 includes an RO water circulation step 115a for circulating the RO number by operating the vacuum pump 43, and an ultrasonic wave generation part 45 to operate to form bubbles in the RO water 13a An ultrasonic wave generating step 115b for performing ultrasonic waves, and a backwashing 115c after the RO water circulation is completed.

The RO number circulation process 115a circulates the RO number 13a so that the RO number passes through the inside of the membrane module 33. The number of ROs passing through the inside of the membrane module is controlled by the amount of RO Or acid cleaning solution or other impurities.

 In addition, the backwash process 115c is the last step of backwashing the contaminants that may remain finely in the membrane module 33.

FIG. 3 is a view showing the overall structure of a reverse osmosis membrane module cleaning apparatus according to a second embodiment of the present invention, and FIG. 4 is a block diagram showing a membrane module cleaning method using the cleaning apparatus shown in FIG. 3 .

Hereinafter, the same reference numerals as those of the above-mentioned reference numerals denote the same members having the same functions, and the same process will not be described again.

3, the membrane module washing apparatus 11 according to the second embodiment has the alkaline washing tank 31, the RO washing tank 59, and the pickling tank 51 in the first embodiment Is integrated into the integrated cleaning tank 53 of the first embodiment.

The integrated washing tank 53 has a drain valve 53a at the lower portion as a space where the precipitation process, the first, second and third cleaning processes, and the rinsing process are performed.

The drain valve 53a discharges the used cleaning liquid or RO water to the outside. That is, this is a passage through which the RO water used for newly filling the alkali cleaning liquid 15a is taken out, or the alkali cleaning liquid is discharged before the acid cleaning liquid 47a is filled for acid cleaning after the alkali cleaning is finished. Likewise, it is a passage for removing the acid cleaning solution or the alkaline cleaning solution to newly fill the RO number.

Since the drain valve 53a can be used to replace the cleaning liquid or the RO water, it is possible to exert a sufficient function through the single complex cleaning liquid 55a.

The cleaning method using the membrane module cleaning apparatus according to the second embodiment having the above-described configuration starts with an immersion step (101). As described above, the immersion step (101) is a process in which the membrane module to be treated is immersed in RO water in a state of being set in the integrated cleaning tank (53) and soaked in water. In order to carry out the immersion step 101, it is needless to say that the complex cleaning tank 23 is pre-filled with the RO number 13a.

If the immersion step 101 is completed, an alkaline cleaning liquid supply step 117 is performed. The alkaline cleaning liquid supply step 117 opens the drain valve 53a to completely discharge the used RO water 13a and opens the supply valve 23a to supply the alkaline cleaning liquid 15a ).

If a sufficient amount of the alkaline cleaning liquid 15a is supplied to the integrated cleaning tank 53 through the alkaline cleaning liquid supply step 117, the first-level cleaning step 103 is performed.

Thereafter, the first cleaning step 103 is terminated and then the acid cleaning supply step 119 is continued. The acid cleaning supply step 119 is a process of opening the drain valve 53a and discharging the used alkaline cleaning liquid 15a from the integrated cleaning tank 53 and filling the site with the acid cleaning liquid 47a.

It goes without saying that the supply valve 23a and the valve 44a are shut off and the supply valve 49a of the acid cleaning liquid supply pipe 49 is opened for this purpose. The pickling solution 47a stored in the pickling solution storage tank 47 is supplied to the integrated cleaning tank 53 via the pickling solution supply pipe 49.

After the acid pickling solution is supplied through the acid pickling solution supplying step 119, the secondary pickling 107 is performed.

When the secondary cleaning 107 is completed, the alkali cleaning liquid supply step 121 is continued. The alkaline cleaning liquid supply step 121 is a step of discharging the used acid cleaning liquid from the integrated cleaning tank 53 and receiving the alkaline cleaning liquid 15a again. The alkaline cleaning liquid supply step 121 is the same as the alkaline cleaning liquid supply step 117 performed before the first-order cleaning step 103.

After the alkaline cleaning liquid supply step 121 is completed, the third-level cleaning step 111 and the RO water supply step 123 are performed in order.

The RO water supplying step 123 is a process of discharging the alkaline cleaning liquid from the integrated cleaning tank 53 and then filling a new RO number.

If the RO number 13a is supplied to the integrated cleaning tank 53 through the RO water supply step 123, the rinsing step 115 is performed and the entire process is completed.

5 is a view showing the overall structure of a reverse osmosis membrane module cleaning apparatus according to a third embodiment of the present invention. FIG. 6 is a view for explaining a membrane module cleaning method using the cleaning apparatus shown in FIG. Block diagram.

The membrane module washing apparatus according to the third embodiment is a type in which only one composite washing liquid 55a is used without separately using acid pickling liquid and alkali washing liquid. The composite cleaning liquid 55a is a mixture of a chelate, sodium hydroxide, and a surfactant in RO water. The composite cleaning liquid 55a can remove organic contaminants, inorganic contaminants, particulate contaminants, and microorganisms in the membrane module 33 .

The reverse osmosis membrane module cleaning apparatus according to the third embodiment includes an RO water storage tank 13 for storing the RO water 13a, a complex cleaning liquid storage tank 55 containing the complex cleaning liquid 55a, And a cleaning tank 53.

It is a matter of course that the reverse osmosis membrane module 33 to be processed is placed in the integrated washing tank 53. The combined wash liquid reservoir 55 is connected to the second circulation pipe 25b through the composite cleaning liquid supply pipe 57 and the RO water storage tank 13 is connected to the second RO water supply pipe 44 through the second circulation pipe 25b .

In addition, the RO water outlet 33a of the membrane module 33 can receive the RO number through the first RO water supply pipe 46.

The cleaning method according to the third embodiment having the above-described configuration starts with the immersion step 101. The immersion step (101) has been described with reference to FIG.

After the immersion step 101, a complex cleaning liquid supply step 131 is performed. The complex cleaning liquid supply step 131 is a process of discharging the RO water from the integrated cleaning tank 53 and replenishing the composite cleaning liquid 55a.

If the complex cleaning liquid supply step 131 is completed, a complex cleaning step 133 is performed. The complex cleaning step 133 is for removing contaminants from the interior of the membrane module 33 by using a complex cleaning liquid and includes a complex washing liquid circulating step 133a, an ultrasonic wave generating step 133b, and a backwashing step 133c. Lt; / RTI >

The composite cleaning liquid circulating process 133a is a process of circulating the composite cleaning liquid 55a by driving the vacuum pump 43. The combined cleaning liquid circulating process 133a and the acid washing liquid circulating process 107a It goes on in the same way.

The ultrasonic wave generating process 133b is a process of forming fine bubbles by applying ultrasonic waves to the inside of the complex cleaning liquid 55a. The bubbles are sucked into the interior of the membrane module 33 together with the composite cleaning liquid to perform the above-mentioned function.

The backwashing process 133c is a process of opening the RO valve 46a and inducing the RO number into the membrane module 33 while the vacuum pump 43 is stopped, The membrane is backwashed through osmosis. The backwashing process 133c is performed in the same manner as the first, second, and third washback processes.

If the complex cleaning step 133 is completed, the RO water supply 123 and the rinsing step 115 are performed and the entire process is completed.

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, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

11: Cleaning device 13: RO water storage tank 13a: RO number
13b: valve 13c: supply pipe 15: alkaline cleaning liquid storage tank
15a: Alkali cleaning liquid 15b: Drain valve 17: Temperature control unit
19: Stirring motor 21: Rotor 23: Alkali cleaning liquid supply pipe
23a: supply valve 25a: first circulation pipe 25b: second circulation pipe
25c: circulation valve 25d: drain valve 27: strainer
29: Cartridge filter 31: Alkali cleaning tank 31a: Drain valve
33: membrane module 33a: RO water outlet 33b: concentrated water outlet
35, 36: Quick coupler 37, 38: Silicone hose 39: Pressure gauge
41: Flow meter 43: Vacuum pump 44: Second RO water supply pipe
44a: valve 45: ultrasonic wave generator 46: first RO water supply pipe
46a: RO water valve 47: Acid cleaning liquid reservoir 47a: Acid cleaning liquid
47b: drain valve 49: acid cleaning liquid supply pipe 49a: supply valve
51: Pickling tank 51a: Drain valve 53: Integrated cleaning tank
53a: drain valve 55: complex cleaning liquid storage tank 55a: composite cleaning liquid
57: Combined cleaning liquid supply pipe 59: RO flushing tank 61:
63: RO Washing Service 65: Picking Service

Claims (8)

A reverse osmosis membrane module having a membrane for purifying by passing water flowing from the outside and having a RO water outlet at one side thereof for discharging RO water through the membrane and a concentrated water outlet for discharging water not passing through the membrane; For example,
An alkaline cleaning bath which provides a cleaning space for cleaning the membrane module and accommodates an alkaline cleaning liquid;
An ultrasonic wave generator installed in the alkaline cleaning bath and applying ultrasonic waves to the inside of the cleaning bath when cleaning;
A circulation pipe having one end connected to the concentrated water outlet of the membrane module and the other end opened to the interior of the alkali cleaning tank; And
A vacuum pump installed in the circulation pipe and applying negative pressure to the membrane module to suck bubbles generated by the alkali cleaning liquid and the ultrasonic waves into the inside of the membrane module and returning the bubbles to the alkali washing tank through a circulation tube;
Wherein the reverse osmosis membrane module cleaning apparatus comprises: The method according to claim 1,
The cleaning apparatus includes:
Further comprising an RO water reservoir for receiving RO water that is water purified by a separate membrane module,
The RO water storage tank is connected to the RO water outlet of the membrane module via the first RO water supply pipe,
In the first RO water supply pipe,
And an RO water valve for guiding the RO number to the inside of the membrane module and allowing the RO number to pass through the membrane by the action of osmotic pressure and to back up the membrane. 3. The method of claim 2,
The cleaning apparatus includes:
An alkaline cleaning liquid storage tank for storing an alkaline cleaning liquid supplied to the alkaline cleaning tank via an alkaline cleaning liquid supply pipe opened and closed by a valve;
Further comprising an acid cleaning liquid reservoir for containing an acid cleaning liquid supplied to the pickling tank via an acid cleaning liquid supply pipe opened and closed by a valve,
Wherein the RO number stored in the RO water storage tank is supplied to the RO washing tank via the second RO water supply pipe opened and closed by a valve. A reverse osmosis membrane module having a membrane for purifying by passing water flowing from the outside and having a RO water outlet at one side thereof for discharging RO water through the membrane and a concentrated water outlet for discharging water not passing through the membrane; For example,
An alkali washing tank provided with an alkali washing liquid from outside to provide a space for washing the membrane module with alkali; an ultrasonic wave generator installed in the alkali washing tank and generating ultrasonic waves during cleaning; and an end connected to a concentrated water outlet of the membrane module And the other end is opened to the inside of the alkali cleaning tank, and a negative pressure is applied to the membrane module in a state where it is installed in the circulation pipe, the bubbles generated by the alkali cleaning solution and the ultrasonic wave are sucked into the inside of the membrane module, An alkaline cleaning unit having a vacuum pump for returning the cleaning liquid to an alkali cleaning tank;
A pickling tank for receiving a pickling solution from outside and providing a space for pickling the membrane module; an ultrasonic generator mounted on the pickling tank for generating ultrasonic waves during cleaning; And the other end is opened to the interior of the pickling hood; and a vacuum pump for applying negative pressure to the membrane module in a state where the circulation pipe is installed and sucking bubbles generated by the pickling solution and the ultrasonic waves into the membrane module, A pickling section having a vacuum pump for returning the pickled tanks to the pickling tanks;
An RO washing water cleaning tank for receiving the RO water as purified water by a separate membrane module and containing the membrane module, an ultrasonic wave generator for applying ultrasonic waves to the RO washing water washing tank, A circulation pipe connected to the water discharge port and having the other end opened to the inside of the RO rinsing tank; and a circulation pipe installed in the circulation pipe to apply a negative pressure to the membrane module to suck bubbles generated by the RO number and the ultrasonic waves into the membrane module And an RO washing unit having a vacuum pump for returning the RO washing water to the RO washing tank through the after-circulation pipe. 5. The method of claim 4,
The cleaning apparatus includes:
Further comprising an RO water reservoir for receiving RO water that is water purified by a separate membrane module,
The RO water storage tank is connected to the RO water outlet of the membrane module via the first RO water supply pipe,
In the first RO water supply pipe,
And an RO water valve for guiding the RO number to the inside of the membrane module and allowing the RO number to pass through the membrane by the action of osmotic pressure and to back up the membrane. A reverse osmosis membrane module having a membrane for purifying by passing water flowing from the outside and having a RO water outlet at one side thereof for discharging RO water through the membrane and a concentrated water outlet for discharging water not passing through the membrane; For example,
Immersing the membrane module to be cleaned in a RO number purified by a separate membrane module to wet the membrane;
After the immersion step, the membrane module is set in an alkaline cleaning bath containing an alkaline cleaning solution, negative pressure is applied to the concentrated water outlet, the alkaline cleaning solution is sucked into the membrane module, and the alkaline cleaning solution is supplied to the membrane module A cleaning liquid circulating step through which the pollutant is removed;
An ultrasonic wave generating step of applying ultrasonic waves to the cleaning liquid in the cleaning liquid circulation step;
A backwashing step of directing the RO number purified by the separate membrane module to the RO water outlet of the membrane module after the rinse solution circulation step is completed to allow the RO number to pass through the membrane by osmotic action and to reverse the membrane;
And a rinse step of rinsing the membrane module after the backwash step with a RO number purified by a separate membrane module. A reverse osmosis membrane module having a membrane for purifying by passing water flowing from the outside and having a RO water outlet at one side thereof for discharging RO water through the membrane and a concentrated water outlet for discharging water not passing through the membrane; For example,
Immersing the membrane module to be cleaned in a RO number purified by a separate membrane module to wet the membrane;
The membrane module having been subjected to the immersion step is put in an alkali washing tank containing an alkaline washing liquid and a negative pressure is applied to the concentrated water outlet so that the alkaline washing liquid is sucked into the membrane module and the alkaline washing liquid is sucked into the inside of the membrane module An ultrasonic wave generating step of applying ultrasonic waves to the alkaline cleaning liquid to form bubbles in the primary alkaline cleaning liquid circulating step and the primary alkaline cleaning liquid circulating step to be performed simultaneously with the primary alkaline cleaning liquid circulating step; And a backwashing step of directing the RO number purified by the separate membrane module to the RO water outlet of the membrane module so that the RO number passes through the membrane by osmotic action and backs up the membrane;
The membrane module having been subjected to the first-order step is set in a pickling bath containing a pickling solution, and negative pressure is applied to the concentrated water outlet to suck the pickling solution into the inside of the membrane module, The ultrasonic wave generating step of applying ultrasonic waves to the acid cleaning liquid to form bubbles; and a second membrane module, after the acid washing liquid circulating step, Guiding the RO number purified by the membrane separation module to an RO water outlet of the membrane module, the RO number passing through the membrane by osmotic action and backwashing the membrane;
And a rinsing step of rinsing the membrane module after completion of the second-leveling step with a RO number purified by a separate membrane module. 8. The method of claim 7,
The step of performing the step between the second-ordering step and the rinsing step,
The membrane module having been subjected to the second-leveling step is put in an alkaline cleaning bath containing an alkaline cleaning solution, and a negative pressure is applied to the concentrated water outlet to suck the alkaline cleaning solution into the membrane module, And an ultrasonic wave generating step of ultrasonic wave generation by applying an ultrasonic wave to the alkali cleaning liquid as a process to be carried out together with the secondary alkaline cleaning liquid circulation step and an ultrasonic wave generation step in which the secondary alkaline cleaning liquid circulation step is completed Followed by a backwash step of directing the RO number purified by the separate membrane module to the RO water outlet of the membrane module to allow the RO number to pass through the membrane by osmotic action and to reverse the membrane Wherein the reverse osmosis membrane module cleaning method comprises the steps of:

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