KR101604017B1 - RO Membrane device and Counter Cross Current method for scale prevention for RO Membrane device - Google Patents

Abstract

The present invention relates to a raw milk infusion pump (100) having a plurality of raw water inflowing and facing each other; A plurality of filter membranes (200) arranged in parallel between the raw milk inlet (100) and the raw milk inlet (100); One end of which is connected to the raw milk feed inlet 100 and the other end of which is connected to the membrane filter 200 and which is disposed opposite to both ends of the membrane filter 200 to distribute the raw water supplied to the membrane filter 200 A water distribution pipe (300); A purified water discharge pipe 400 installed at one side of the membrane filter 200 to discharge purified water filtered by the membrane filter 200; The water supply pipe 300 and the purified water discharge pipe 400 are installed in the water separating pipe 300 and the purified water discharging pipe 400 so as to switch the supply direction of the raw water by selectively controlling the raw milk inflow pipe 100, A control unit 500; The present invention can reduce the maintenance and management cost of the water treatment apparatus and improve the water treatment efficiency by increasing the operation time of the water treatment apparatus by effectively removing the sludge and the foreign substances in the membrane filter by suggesting the AO membrane apparatus using the reverse- .

Description

TECHNICAL FIELD [0001] The present invention relates to an all-membrane device using reverse-directional crossing operation and a scale pollution prevention method using the same.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for separating a solvent and a solute using a reverse osmosis membrane, and more particularly, to an apparatus for separating a solvent and a solute using a reverse osmosis membrane, And to a scale pollution prevention method using the same.

Generally, the reverse osmotic filter (filter), which is a reverse osmosis membrane applied to a water treatment apparatus, is an expensive filter having a high filtration performance and should be regularly exchanged after performing a certain amount of water purification function.

The reverse osmosis membrane applied to the reverse osmosis type water treatment apparatus is composed of a support layer (thickness: about 50 μm) and an active layer (thickness: 0.2 to 0.8 μm) having a separating function and separates the solvent and the solute using reverse osmosis.

The reverse osmosis membrane's ability to remove foreign substances is excellent, but it is also prone to fouling and scaling.

In order to use the reverse osmosis system efficiently, it is necessary to optimize the performance of the membrane by reducing the foulants that affect the reverse osmosis membrane as much as possible.

The reverse osmosis membrane having the microfiltration function has to be contaminated or deteriorated depending on the quality of the raw water, the operation mode, conditions, etc., and it should be regularly cleaned or exchanged.

Therefore, extending the lifetime of the expensive reverse osmosis filter is essential to reduce water treatment operating costs, maintenance procedures and costs.

In order to extend the life of the reverse osmosis membrane and maintain its performance, various pretreatment and chemical treatments are performed at the previous stage of the reverse osmosis filter, and a certain level of filtered water is supplied to the reverse osmosis filter.

Generally, this pretreatment process consists of a combination of coagulation, clarification, filtration (A / C filter, micro filter), softener, degassifier and so on. And injecting necessary medicine for the purpose.

However, even when the pretreatment apparatus is operated, the scale of the reverse osmosis separation membrane is scaled by the high concentration of concentrated water flowing on the surface of the membrane.

In addition, Silt, colloidal substances, bacteria, and by-products that are corroded by Fe present in water are concentrated on the surface of the separation membrane, resulting in organic fouling.

If the performance of the separation membrane deteriorates due to the occurrence of scale failure or organic matter disruption, the production quantity is greatly affected.

 If the performance of the reverse osmosis membrane deteriorates due to fouling, it is necessary to clean (Clean In Place) or change the membrane to recover the function.

However, since it is necessary to invest time and money, it is necessary to maintain the optimization of the performance of the membrane and to manage the cleaning (CIP) cycle for the economical operation of the reverse osmosis equipment.

As described above, the conventional membrane-type separation membrane operation method in the forward direction (one-way flow) frequently causes scale fouling or organic fouling, which causes a problem of high cost of cleaning (CIP) and membrane replacement.

Therefore, it is necessary to develop a technology that can increase the cleaning cycle (CIP) and optimize the performance of the membrane to reduce the time and cost.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a water treatment apparatus and a water treatment apparatus which can effectively remove sludge and foreign matter from a separation membrane filter, And to improve the water treatment efficiency by increasing the operation time of the allo membrane device.

In order to solve the above-described problems, the present invention provides a raw milk infusion apparatus comprising: a raw milk infusion inlet (100) having a plurality of raw water flowing in opposite directions; A plurality of filter membranes (200) arranged in parallel between the raw milk inlet (100) and the raw milk inlet (100); One end of which is connected to the raw milk feed inlet 100 and the other end of which is connected to the membrane filter 200 and which is disposed opposite to both ends of the membrane filter 200 to distribute the raw water supplied to the membrane filter 200 A water distribution pipe (300); A purified water discharge pipe 400 installed at one side of the membrane filter 200 to discharge purified water filtered by the membrane filter 200; The water supply pipe 300 and the purified water discharge pipe 400 are installed in the water separating pipe 300 and the purified water discharging pipe 400 so as to switch the supply direction of the raw water by selectively controlling the raw milk inflow pipe 100, A control unit 500; This paper proposes an all - membrane device using reverse crossover operation.

Here, the membrane filter 200 may include a plurality of membrane members 210 having both ends connected to the water distribution pipe 300.

The membrane member 210 has a cylindrical case 211 having a predetermined inner space and both ends connected to the water distribution pipe 300 so that the central part of the inner space of the case 211 A membrane 213 which surrounds the tube 212 to purify the raw water and a membrane 213 which surrounds the tube 212. The membrane 213 has a plurality of through- (214) fixed to both ends of the case (211) so as to prevent it from being separated from the case (211).

The control unit 500 includes a plurality of electromagnetic valves 510 installed in the water distribution pipe 300 and the purified water discharge pipe 400 so as to control the direction of raw water passing through the membrane filter 200 Lt; / RTI >

In addition, a first connection pipe 110 having both ends communicated with the raw milk feed inlet 100 is installed at a front end between the raw milk feed inlet 100 and the raw milk feed inlet 100, 110 may be provided with an electronic valve 111.

One side of the raw milk inflow inlet 100 may be provided with a supplementary outflow pipe 120 connected to the water distribution pipe 300 to discharge concentrated water from the separation membrane filter 200.

A second connection pipe 130 is provided at a rear end between the auxiliary outlet pipe 120 and the auxiliary outlet pipe 120 so that both ends thereof communicate with the auxiliary outlet pipe 120, 130 may be provided with an electromagnetic valve 131.

In addition, a plurality of pumps 140 may be provided at one end of the raw milk inflow inlet 100 to pump the raw water to the raw milk inflow inlet 100 side.

In addition, the plurality of membrane filters 200 are provided in three units, and one of the units passes through the opposite direction, and the other two units can be purified while the raw water passes in the forward direction.

In addition, the separation membrane filter 200 through which the raw water passes in the reverse direction among the plurality of separation membrane filters 200 may be sequentially switched.

In order to solve the above-described problems, the present invention provides a method for controlling a water supply system, comprising: a first step of introducing raw water through a raw milk inflow inlet (100); A second step of controlling whether the electronic valve 510 provided in the controller 500 is opened or closed so that the raw water introduced through the raw milk inflow inlet 100 selectively passes through the plurality of separator filters 200 in the reverse or forward direction, Wow; And a third step of discharging the filtered purified water through the purified water discharge pipe (400) while passing through the membrane filter (200) in a reverse direction or a forward direction, and the second step is a step The method comprising the steps of alternately switching the direction through the membrane filter (200) of the membrane filter (200).

The present invention can effectively remove the sludge and foreign substances from the membrane filter while the operation of the water treatment apparatus is continued, thereby reducing the maintenance and management cost of the water treatment apparatus and increasing the water treatment efficiency by increasing the operation time of the water treatment apparatus There is an effect.

FIG. 1 is a perspective view showing the structure of an all-metal membrane apparatus using reverse crossover operation according to an embodiment of the present invention,
FIG. 2 is an exploded perspective view illustrating a structure of a membrane filter of an all-membrane device using reverse crossover operation according to an embodiment of the present invention,
FIG. 3 is an exploded perspective view showing a structure of the membrane filter of FIG. 2 in a state where the membrane is removed,
FIG. 4 is a schematic view schematically illustrating a connection relationship between respective parts of an all-metal membrane apparatus using reverse crossover operation according to an embodiment of the present invention,
FIG. 5 is a flowchart sequentially illustrating a method of preventing scale contamination using an all-membrane apparatus using reverse crossover operation according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view illustrating a structure of an all-metal membrane apparatus using a reverse-direction crossing operation according to an embodiment of the present invention. FIG. 2 is a cross-sectional view of a membrane filter of an all- FIG. 3 is an exploded perspective view showing a structure of the membrane filter of FIG. 2 in a state in which the membrane is removed. FIG. 4 is a cross-sectional view of the Alo membrane device using the reverse crossover operation according to an embodiment of the present invention. FIG. 5 is a flow chart sequentially illustrating a method of preventing scale contamination using an all-metal membrane apparatus using reverse crossover operation according to an embodiment of the present invention. FIG. to be.

As shown in these figures, the all-membrane device using the reverse-directional crossing operation according to the present invention includes a raw milk feed inlet 100 having raw water flowing therein and a plurality of raw milk feeds; A plurality of filter membranes (200) arranged in parallel between the raw milk inlet (100) and the raw milk inlet (100); One end of which is connected to the raw milk feed inlet 100 and the other end of which is connected to the membrane filter 200 and which is disposed opposite to both ends of the membrane filter 200 to distribute the raw water supplied to the membrane filter 200 A water distribution pipe (300); A purified water discharge pipe 400 installed at one side of the membrane filter 200 to discharge purified water filtered by the membrane filter 200; The water supply pipe 300 and the purified water discharge pipe 400 are installed in the water separating pipe 300 and the purified water discharging pipe 400 so as to switch the supply direction of the raw water by selectively controlling the raw milk inflow pipe 100, And a control unit 500.

One end of the raw milk inflow inlet 100 is provided with a pump 140 for introducing the raw water to the raw milk inflow inlet 100 side and the plurality of raw milk inflow inlet tubes 100 are arranged to face each other.

A first connection pipe 110 communicating with the raw milk inlet 100 is provided at a front end between the raw milk inlet 100 and the raw milk inlet 100 disposed opposite to each other, 110 may be provided with an electronic valve 111.

The first connection pipe 110 serves to control the direction of the raw water passing through the separation membrane filter 200 by connecting a plurality of raw milk inlet 100 and the raw milk inlet 100 with each other.

That is, when the raw water is allowed to pass through the membrane filter 200 in the forward direction, the raw water is directly supplied to the membrane filter 200 from the raw water inlet 100 connected to the low water source, and the raw water is supplied to the membrane filter 200 The raw water from the low-water source is supplied to the first filter 100 through the first connection pipe 100 so that the raw water can be supplied to the filter 200 through the raw milk inlet 100 disposed on the opposite side of the raw- (110) to the opposite side raw milk feed inlet (100).

A plurality of auxiliary outflow pipes 120 connected to the water distribution pipe 300 and having concentrated water discharged from the separation membrane filter 200 may be provided on one side of the raw milk inflow pipe 100 in parallel with the raw milk infusion pipe 100 .

After the raw water passes through the membrane filter 200 in the reverse direction and is purified, the purified water is passed through the purified water discharge pipe 400 when it is discharged to the outside. After the raw water passes through the membrane filter 200 in the forward direction, The purified water passes through the auxiliary outlet pipe 120 and is discharged to the outside.

A second connection pipe 130 is provided at the rear end between the auxiliary outlet pipe 120 and the auxiliary outlet pipe 120 so as to communicate with the auxiliary outlet pipe 120 at both ends thereof, It is preferable that an electronic valve 131 is provided.

Between the raw milk inlet 100 and the raw milk inlet 100, a separation membrane filter 200 capable of purifying the raw water flowing into the raw milk inlet 100 is provided as a plurality of units.

Here, the unit refers to a state in which the membrane filter 200 is constituted by a plurality of membrane members 210, so that a plurality of membrane members 210 are assembled into one membrane filter 200.

Therefore, the all-membrane apparatus using the reverse crossover operation according to an embodiment of the present invention is composed of three pre-processing meat (200) units.

The membrane filter 200 is installed so that its both ends are connected to the water distribution pipe 300 installed at a mutually opposing position of the raw milk inlet 100 so as to communicate with the raw milk inlet 100 to purify the raw water flowing thereinto do.

The membrane filter 200 includes a plurality of membrane members 210 connected at both ends to the water distribution pipe 300. The membrane members 210 are provided in a plurality of rows and columns to form one membrane filter 200) unit.

The membrane member 210 has a cylindrical case 211 having a predetermined inner space and both ends connected to the water distribution pipe 300 to penetrate the central region of the inner space of the case 211, A membrane 213 which is provided in the form of wrapping the tube 212 and has a plurality of through holes 212a formed therein and a membrane 213 for purifying the raw water and a membrane 213 for preventing the membrane 213 from being separated from the case 211 And a release preventing member 214 fixed to both ends of the case 211 so as to be movable.

The case 211 is a cylindrical member having an internal space formed therein, and both ends of the case 211 are formed so that raw water flows in or the purified water purified by the membrane 213 is discharged to the outside.

A tubular tube 212 having a plurality of through holes 212a formed in its outer surface through a central region of the case 211. The tubular tube 212 has a through hole 212a through which the purified water, 212a to the inside of the pipe tube 212 and then flows along the longitudinal direction of the pipe tube 212 to be discharged to the outside.

On both outer sides of the case 211, there is provided an inlet pipe 211a through which the purified water flows into one side along the longitudinal direction of the membrane member 210,

A membrane 213 is disposed on the outer surface of the pipe 212 so as to be wound in a spiral fashion to form a membrane of porous material having a predetermined length. Are inserted.

Separate sealing members 213a sealing the spacing space between the outer surface of the membrane 213 and the inner surface of the case 211 are provided on both circumferential surfaces of the membrane 213. The sealing member 213a is configured such that the raw water is bi- It is preferable that a triangular groove is formed along the circumferential direction in a central region thereof so that sealing can be performed even if it flows.

At both end portions of the pipe 212, a release preventing member 214 is inserted to prevent the membrane 213 from being released to the outside of the case 211 and is disposed on both open sides of the case 211.

The plurality of filter membranes 200 having such a configuration are provided in three units, one of which passes the raw water in the reverse direction and the other two units are purified while the raw water passes in the forward direction, The separator filter 200 through which the raw water passes in the reverse direction in the separator filter 200 can be sequentially switched.

When the concentration of raw water in the membrane 213 of the membrane filtration unit 200 is increased, such as a calcification component, due to the sequential switching of the direction in which the raw water passes through the membrane filter 200, foreign substances or sludge, It is possible to increase the operating time of the AlO membrane apparatus using the reverse crossover operation.

The water distribution pipe 300 is connected to a plurality of points of the raw water supply pipe 100 and distributes the raw water supplied through the raw water supply pipe 100 to the membrane filter 200 side.

The water distribution pipe 300 is disposed in a plurality of locations of the water supply pipe 100 facing each other and is connected to the water distribution pipe 300. The water distribution pipe 300 is divided into a plurality of branch pipes 310 Are disposed side by side.

The purified water discharge pipe 400 is provided at both outer sides of the raw water supply pipe 100 provided opposite to each other and serves as a passage through which the purified water purified by the membrane member 210 of the pre-treatment filtration unit 200 is discharged.

The purified water discharge pipe 400 provided at one side is connected to a plurality of the pre-filtration units 200, and the purified water that has been purified through the pre-filtration unit 200 can be discharged to the outside.

The control unit 500 may include a plurality of electromagnetic valves 510 installed in the water distribution pipe 300 and the purified water discharge pipe 400 so as to control the direction of the raw water passing through the membrane filter 200.

The electromagnetic valve 510 may be a solenoid valve or an actuator valve that is opened and closed electronically according to the user's intention, but the present invention is not limited thereto. Any type of valve would be sufficient.

The process of purifying the raw water using the all-membrane device using the reverse crossover operation according to an embodiment of the present invention having the above-described configuration is as follows.

First, the raw water of a low water source is introduced into the raw milk inlet 100 through the pump 140 and supplied to the membrane filter 200. When the raw water flows into the raw milk inlet 100, The open / closed states of the plurality of electronic valves are determined.

That is, the electromagnetic valve 510 provided on one of the plurality of water distribution pipes 300 installed on one side is opened and the electromagnetic valve 510 provided on the other two is closed, and the auxiliary outlet pipe 120 The electromagnetic valve 510 provided in any one of the electromagnetic valves 510 corresponding to the electromagnetic valve 510 is closed and the electromagnetic valve 510 installed at the other two valves is opened.

In addition, the electromagnetic valve 510 provided in any one of the plurality of water distribution pipes 300 installed on the other side is closed and the electromagnetic valve 510 provided in the remaining two valves is opened, and the auxiliary outlet pipe 120 The electromagnetic valve 510 provided in any one of the electromagnetic valve 510 corresponding to the electromagnetic valve 510 is opened and the electromagnetic valve 510 installed at the other two valves is closed.

In this state, the raw water flows in the reverse direction in one of the membrane filter units 200, and the raw water flows in the forward direction in the remaining two membrane filter units 200, and the raw water is purified through the membrane 213, Is introduced into the pipe tube 212 and then discharged to the outside through the purified water discharge pipe 400, thereby completing the water treatment.

When a certain period of time elapses after the purifying operation is performed in this state, the opening and closing states of the electromagnetic valves 510 provided in the water distribution pipe 300 and the auxiliary discharge pipe 120 installed at one side are reversely reversed, The opening and closing states of the electromagnetic valve 510 provided in the auxiliary outlet pipe 300 and the auxiliary outlet pipe 120 are reversed and the raw water is purified while the separation membrane filter 200 unit in which the raw water flows in the reverse direction is changed, .

As the process is repeatedly performed, the direction of the raw water passing through the membrane 213 of the pre-filter device 200 is sequentially changed when a predetermined time has elapsed, so that the sludge and foreign matter adhering to the membrane filter can be effectively removed, It is possible to reduce the maintenance and management cost of the Alo membrane device using the cross operation and increase the water treatment efficiency by increasing the operation time of the Alo membrane device using the reverse crossover operation.

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 or scope of the invention as defined in the appended claims. It is to be understood that both the technical idea and the technical spirit of the invention are included in the scope of the present invention.

100: raw milk inlet 110: first connector
111: Electronic valve 120: Auxiliary outlet pipe
130: Second connection pipe 131: Electronic valve
140: Pump 200: Membrane filter
210: membrane member 211: case
212: pipe tube 213: membrane
300: water distribution pipe 400: purified water discharge pipe

Claims (12)

A raw milk infusion inlet (100) having a plurality of raw water inflow and facing each other;
A plurality of filter membranes (200) arranged in parallel between the raw milk inlet (100) and the raw milk inlet (100);
One end of which is connected to the raw milk feed inlet 100 and the other end of which is connected to the membrane filter 200 and which is disposed opposite to both ends of the membrane filter 200 to distribute the raw water supplied to the membrane filter 200 A water distribution pipe (300);
A purified water discharge pipe 400 installed at one side of the membrane filter 200 to discharge purified water filtered by the membrane filter 200;
The water supply pipe 300 and the purified water discharge pipe 400 are installed in the water separating pipe 300 and the purified water discharging pipe 400 so as to switch the supply direction of the raw water by selectively controlling the raw milk inflow pipe 100, A control unit 500;
And the reverse-directional cross-operation is performed. The method according to claim 1,
Wherein the membrane filter (200) comprises a plurality of membrane members (210) connected at both ends to the water distribution pipe (300). 3. The method of claim 2,
The membrane member 210 has a cylindrical case 211 having a predetermined inner space and both ends connected to the water distribution pipe 300 to penetrate the central region of the inner space of the case 211 A membrane 213 which surrounds the tube 212 and purifies the raw water and a membrane 213 which is provided in the case 211 And a separation preventing member (214) fixed to both ends of the case (211) so as to prevent the separator (210) from being separated from the case (211). The method of claim 3,
And a sealing member 213a having a triangular groove extending along the circumferential direction is provided on the central region of the membrane 213 so that even if the raw water flows in both directions, Alo Membrane Device Using Reverse Crossover Operation. delete The method according to claim 1,
A first connection pipe 110 communicating with the raw milk inlet 100 is provided at a front end between the raw milk inlet 100 and the raw milk inlet 100, Characterized in that an electromagnetic valve (111) is provided in the reverse osmosis membrane. The method according to claim 1,
Wherein the auxiliary inflow pipe (120) is connected to one side of the raw milk inflow inlet (100) and connected to the water distribution pipe (300) to discharge the concentrated water remaining after the purification in the separation membrane filter (200) Alo Membrane Device Using Operation. 8. The method of claim 7,
A second connection pipe 130 having both ends connected to the auxiliary outlet pipe 120 is provided at the rear end between the auxiliary outlet pipe 120 and the auxiliary outlet pipe 120, Characterized in that an electromagnetic valve (131) is provided in the reverse osmosis membrane. The method according to any one of claims 1 to 4, 6 to 8,
And a plurality of pumps (140) for pumping raw water to the raw milk inlet (100) side is provided at one end of the raw milk feed inlet (100). 10. The method of claim 9,
Wherein the plurality of membrane filters (200) are provided in three units, one of which passes the raw water in the reverse direction and the other two units are purified while the raw water passes in the forward direction. Alo membrane device. 11. The method of claim 10,
Wherein the separation membrane filter (200) through which the raw water passes in the reverse direction among the plurality of separation membrane filters (200) is sequentially switched. 8. A method for preventing scale contamination using an all-membrane apparatus using reverse crossover operation according to any one of claims 1 to 4, and 6 to 8,
A first step of introducing raw water through the raw milk infusion inlet (100);
A second step of controlling whether the electronic valve 510 provided in the controller 500 is opened or closed so that the raw water introduced through the raw milk inflow inlet 100 selectively passes through the plurality of separator filters 200 in the reverse or forward direction, Wow;
A third step of switching the open / close state of the electromagnetic valve (510) provided in the controller (500) so as to switch the direction in which the raw water passes through the plurality of filter membranes (200) after a lapse of a predetermined time;
And a fourth step of discharging the filtered purified water through the purified water discharge pipe 400 while passing through the membrane filter 200 in the reverse or forward direction;
Wherein the reverse osmosis operation is performed in the reverse osmosis process.

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