KR101328570B1 - Apparatus for Supplying Cleaning Water of membrane - Google Patents

Abstract

The present invention (a) raw water storage tank 12, the raw water supply is provided with an inlet pump 14 connected to the raw water storage tank; (b) Bubble generation, which is installed at the rear end of the raw water supply unit and manufactures the washing water in which the micro-nano bubble is mixed, including the pressure tank 20 in which the submerged bubble generator 21 and the tubular bubble generator 23 are mounted. part; (c) a washing water supply unit installed at a rear end of the bubble generating unit and including a header 30 for supplying raw water mixed with micro-nanobubbles; And (e) a control unit including a control unit 40 for controlling the operation of the raw water supply unit, the bubble generating unit, and the washing water supply unit, and a use thereof.
Membrane washing water supply apparatus according to the present invention can supply the colloidal washing water in which the ultra-fine bubbles are dissolved at low energy to the membrane during the filtration process while maintaining the concentration at the time of the first manufacturing, the concentration polarization and membrane contamination formed in the membrane In addition to improving the separation efficiency of the membrane, it is also possible to extend the life of the membrane and at the same time reduce the amount of the cleaning agent has the effect of reducing the management and maintenance costs.

Description

Apparatus for Supplying Cleaning Water of membrane

The present invention relates to an apparatus for producing washing water in which micronanobubbles are mixed using two kinds of generators including a tubular microbubble generator and a submerged nanobubble generator, and a use thereof.

In general, membrane filtration apparatus for filtering water using a membrane member such as a hollow fiber membrane is widely used in various fields because its structure is simpler and energy, space, power consumption, etc. are reduced compared to other filtration apparatuses. . However, such a membrane filtration device has a structure in which raw water including contaminants passes through the membrane member, and the contaminants adhere to the membrane member, and the permeate filtered out to the opposite side of the membrane member is discharged. Since the amount of contaminants adhered to the member increases, and the pressure of raw water for passing the membrane member increases due to the adhesion of such contaminants, the membrane cleaning operation periodically removes the contaminants adhered to the membrane member. This should be done.

Membrane cleaning is mainly divided into a physical cleaning operation in which the filtered permeate is returned to the membrane member to shake off contaminants and a chemical cleaning operation in which the cleaning liquid is contacted with the membrane member to remove the contaminants.

Conventional filtration equipment performs cleaning by periodically performing a physical cleaning operation, stopping the filtration device only when necessary, immersing the membrane member in the chemical cleaning liquid, or repeatedly passing the cleaning liquid through the membrane member. Doing.

However, only the method of removing contaminants through strong backflow of permeate has a problem that physical cleaning of contaminants adhering to the periphery of micropores present in the membrane member is not sufficiently performed. Since it proceeds directly by the operator in the judgment, it takes a lot of time and the occurrence of safety accidents, such as the worker is in contact with the chemical cleaner or the cleaning liquid is a frequent disadvantage. As such, when a long time is required for the cleaning operation, since the filtration process cannot be performed during the corresponding time, the throughput per hour is greatly reduced, and since the worker must always wait for the cleaning operation to proceed, there is a problem in that manpower consumption is increased and the processing cost is also increased. In addition, flocculants (drugs), detergents, and fibrous media used in this process cause the generation of secondary pollutants for the contamination of raw water, and the consumables in the system reduce the treatment efficiency of UF or RO membranes when sewage is reused, and reduce the load. There is a problem to increase.

In addition, the conventional membrane filtration device is stopped when the raw water is insufficient or the filtered permeate is sufficient, at which time the contaminated raw water is stopped in contact with the membrane member, if this time passes, contamination of the membrane member If the operation is resumed by acceleration, there is a disadvantage in that it cannot exhibit sufficient filtration performance.

Microbubbles, on the other hand, are generally microscopic bubbles of less than 2 mm, whereas milky microbubbles that have a diameter of less than 50 μm and cause a chain reaction of bonding, cleavage, and rupture in a short period of 1 s. It is characterized by being reduced to nanobubble by pressure to generate various energy and extinguish. The rising speed is slower than normal bubbles bursting up to the surface and bursting, and it is maintained for several minutes or hours. In addition, nano bubbles are characterized by dispersing and dissolving in the upper, middle and lower layers of water with a diameter of less than 1 μm, and exist for several months.

The microbubble is subjected to a high pressure of 4.2 to 6.3 kg / cm2 for 10 to 30 seconds using a Henry's law that the solubility of the gas dissolved in water increases with increasing pressure. This can be caused by a sudden pressure drop of, 40 KHz ultrasonic wave, high sound pressure of 140 db and instantaneous high temperature of 4000 ~ 6000 degrees during the extinction process, and generate negative ions by the levard effect.

Accordingly, the present inventors have made diligent efforts to solve the problems of the prior art by incorporating the micro-nanobubble technology. As a result, the micro-nanobubble is mixed using two kinds of generators including a tubular microbubble generator and a submerged nanobubble generator. When fabricating a device for preparing the clean water and washing the membrane by using the same, the membrane cleaning cycle and the amount of chemicals used can be reduced to extend the membrane life, reduce the maintenance cost of the membrane and improve the membrane separation efficiency. This invention was completed.

SUMMARY OF THE INVENTION An object of the present invention is to provide an apparatus and a use for producing washing water in which micronanobuble is mixed using two kinds of generators including a tubular bubble generator and a submerged bubble generator.

In order to achieve the above object, the present invention (a) raw water storage tank 12, the raw water supply provided with an inlet pump 14 connected to the raw water storage tank; (b) Bubble generation, which is installed at the rear end of the raw water supply unit and manufactures the washing water in which the micro-nano bubble is mixed, including the pressure tank 20 in which the submerged bubble generator 21 and the tubular bubble generator 23 are mounted. part; (c) a washing water supply unit installed at a rear end of the bubble generating unit and including a header 30 for supplying raw water mixed with micro-nanobubbles; And (e) a controller including a control unit 40 for controlling the operation of the raw water supply unit, the bubble generating unit, and the washing water supply unit.

The present invention also provides a raw water supply step (S1) to be transported into the pressure tank 20 while the cleaning chemical is mixed with the raw water; When the raw water is filled in the pressure tank 20, the raw water is transferred to the tubular bubble generator 23 through the inlet 26, and microbubbles are applied to the raw water by using the gas supplied by the circulation pump 24. Bubble generation step (S2) to be mixed, and to discharge into the pressure tank 20 through the diffuser (25); When raw water is filled in the pressure tank 20, bubbles generated in the submerged bubble generator 21, which are installed in the diffuser 25 of the tubular bubble generator 23, are generated in the submerged bubble generator 21. Is released to the end of), the micro-nanobubble generation step (S3) is mixed with the microbubble produced in the step S2; And washing water supplying step for cleaning the membrane using the washing water supply device for washing the membrane, the washing water supplying step (S4) of supplying the raw water mixed with the micro nanobubbles to the washing target membrane through the header 30. Provide a process.

Membrane washing water supply apparatus according to the present invention can supply the colloidal washing water in which the ultra-fine bubbles are dissolved at low energy to the membrane during the filtration process while maintaining the concentration at the time of the first manufacturing, the concentration polarization and membrane contamination formed in the membrane In addition to improving the separation efficiency of the membrane, it is also possible to extend the life of the membrane and at the same time reduce the amount of the cleaning agent has the effect of reducing the management and maintenance costs.

1 is a schematic diagram of a washing water supply device for washing a membrane.
2 is a front view of the washing water supply device for washing the membrane.
3 is a cross-sectional view of the washing water supply device for washing the membrane (A: top view; B: front view; C: side view; D: right side view).
4 is a cross-sectional view of the tubular bubble generator.
5 is a front view of the submerged bubble generator (brush type).
6 is a front view of a submerged bubble generator (impeller type).
Figure 7 is a view of the installation site of the membrane washing water supply apparatus of the present invention (A
: Installation of membrane cleaning device is completed. B: Completed installation of membrane cleaning device; C: inlet pump 14; D: dry motor 22; E: cleaning agent reservoir 10; F: circulation pump 24).
8 is a pilot test result showing the membrane washing efficiency using the washing water supplied by the membrane washing water advanced device of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, configurations and effects according to preferred embodiments of the present invention will be described in detail with reference to the drawings.

Conventional filtration equipment performs cleaning by periodically performing a physical cleaning operation, stopping the filtration device only when necessary, immersing the membrane member in the chemical cleaning liquid, or repeatedly passing the cleaning liquid through the membrane member. Doing. However, only the method of removing contaminants through strong backflow of permeate has a problem that physical cleaning of contaminants adhering to the periphery of micropores present in the membrane member is not sufficiently performed. Since it proceeds directly by the operator in the judgment, it takes a lot of time and the occurrence of safety accidents, such as the worker is in contact with the chemical cleaner or the cleaning liquid is a frequent disadvantage.

Accordingly, the present inventors have diligently tried to solve the problems of the prior art by incorporating the micro-nanobubble technology. As a result, the micro-nanobubble is mixed using two kinds of generators including a tubular microbubble generator and a submerged nanobubble generator. It was confirmed that the apparatus for preparing the washed water, and the membrane washing using the same, can improve the efficiency of using the UF filter and FO filter, and completed the present invention.

The present invention in one aspect, the present invention (a) raw water storage tank 12, the raw water supply unit is provided with an inlet pump 14 connected to the raw water storage tank; (b) a bubble generating unit which is installed at a rear end of the raw water supply unit and manufactures raw water in which micro-nano bubbles are mixed, including a pressure tank 20 in which a submerged bubble generator 21 and a pipe-type bubble generator 23 are mounted; ; (c) a washing water supply unit installed at a rear end of the bubble generating unit, the washing water supply unit including a header 30 to supply the washing water mixed with the micro nanobubbles; And (e) a control unit including an apparatus 40 for controlling the operation of the raw water supply unit, the bubble generating unit, and the washing water supply unit, wherein the tubular bubble generator 23 has an outer lower portion of the pressure tank 20. Mounted in, the submerged bubble generator 21 is powered by a server motor 22 mounted on the upper outer surface of the pressure tank 20, the diffuser 25 of the tubular bubble generator and the The terminal of the submersible bubble generator 21 relates to a washing water supply device for membrane cleaning, characterized in that the end is provided adjacent to each other.

In the apparatus of the present invention, the micro-nanobuble is mixed with raw water and used for washing the membrane. The raw water may be sewage treatment water, but is not limited thereto.

In addition, since the raw water introduced into the pressure tank 20 may be in a state in which cleaning chemicals are mixed, in the present invention, the terms 'raw water' and 'cleaning liquid' or 'clean water' are used in the same meaning.

The apparatus according to the present invention is provided with a cleaning chemicals storage tank (10), the cleaning chemicals outlet on the top of the storage tank, and includes a control pump (11), supplying the cleaning chemicals through the pipe connected to the raw water storage tank (12) Characterized in that it further comprises a cleaning chemicals supply.

In the apparatus of the present invention, the bubble generator produces micronanobubbles. In addition, in the apparatus of the present invention, the washing chemical is mixed with raw water of 1 ppm to 5 ppm, and micronanobubles may be mixed to prepare washing water.

In the apparatus of the present invention, the cleaning chemical outlet may be installed at the front or rear end of the raw water storage tank, preferably in the apparatus of the present invention, the raw water storage tank 12 is the raw water inlet pipe is fastened to one side of the upper, A supply pipe for supplying raw water to the inflow pump 14 is provided on the other side of the lower, characterized in that the one side of the supply pipe is provided with a pipe formed from the cleaning chemical outlet.

The pipe formed from the cleaning chemical outlet is fastened to one side of the supply pipe, the raw water and the cleaning chemical are mixed on the supply pipe, it can be supplied to the pressure tank by the inlet pump.

The raw water storage tank 12 may be designed in a tower shape, but is not limited thereto.

The inlet pipe supplies the raw water introduced by the inlet pump 14 to the pressure tank 20.

In the apparatus of the present invention, the pressure tank 20 is further provided with a raw water inlet, a washing water discharge port, and an air vent 27 to which a supply pipe for supplying raw water from the inflow pump 14 is fastened. .

In the apparatus of the present invention, the tubular bubble generator 23 mounted below the pressure tank 20 is provided inside the pressure tank 20, and the raw water stays inside the pressure tank 20 to inundate the water. Piping for supplying raw water through the inlet port 26, the circulation pump 24 for supplying gas, and the end of the bubble supply pipe formed from the bubble generator 23 to the diffuser 25 is provided so that the raw water is immersed in It is characterized in that the configuration.

As shown in FIG. 4, the tubular bubble generator 23 has a plurality of rotatable protrusions formed therein to supply washing water containing fine bubbles.

In the apparatus of the present invention, the submerged bubble generator 21 may be equipped with an impeller or brush type generator according to the structure of the bubble generator.
Since the generator of the brush type (FIG. 5) has a structure in which the housing and the suction impeller 213 are omitted in the impeller type (FIG. 6), the brush is in direct contact with the raw water in the pressure tank 20. In the impeller type, the raw water is supplied from the vacuum suction port 212 provided at the upper part of the impeller by the vacuum force generated while the suction impeller 213 rotates to generate bubbles by contacting the raw water in the generator.

In the apparatus of the present invention, the impeller-type submerged bubble generator, as shown in Figure 6, (i) a vacuum suction port (212) in which the raw water in the pressure tank 20 flows into the generator; (ii) a suction impeller 213 causing a vacuum inside the generator; (iii) nanowires 218 creating bubbles; (iv) Distribute 1 (216) to refine the bubble; (v) Dispense 2 220 to refine the bubble; And (vi) a gas inlet 211, and when the hollow shaft is rotated by the dry motor 22, the suction impeller 213 rotates, whereby a vacuum is applied to the generator. As raw water flows in and moves to the bottom of the generator, nanobubbles are generated by the nanowires 218 and finally discharged to the pressure tank through the distributor 2 220.

delete

In the device of the present invention the brush can be made of nanowires.

delete

In the apparatus of the present invention, the end of the submerged bubble generator 21 is installed in proximity to the diffuser 25 of the tubular bubble generator 23, and in the case of an impeller type submerged generator, the distributor 2 ( 220), in the case of a brush-type submerged generator is characterized in that the brush (226).

In the apparatus of the present invention, one to five pairs of bubble generators composed of the submerged bubble generator 21 and the tubular bubble generator 23 may be mounted to the pressure tank 20, and preferably three pairs may be mounted. Can be.

When two or more pairs of bubble generators including the tubular bubble generator and the submerged bubble generator are mounted in the pressure tank 20, they may be separated into the partition wall 28 of the perforated surface inside the pressure tank 20.

In the apparatus of the present invention, the control unit may include a device for controlling the operation of the raw water inlet, the inlet pump, the bubble generator, and the washing water supply unit, by monitoring the flow rate, water level, temperature, pressure, etc. of the device It can be electrically connected to the inlet pump, the bubble generator, and the driving means of the supply unit to control the operation.

In another aspect, the present invention, while the cleaning chemicals are mixed with the raw water, raw water supply step (S1) for transferring into the pressure tank (20); When the raw water is filled in the pressure tank 20, the raw water is transferred to the tubular bubble generator 23 through the inlet 26, and microbubbles are applied to the raw water by using the gas supplied by the circulation pump 24. Bubble generation step (S2) to be mixed, and to discharge into the pressure tank 20 through the diffuser (25); When raw water is filled in the pressure tank 20, bubbles generated in the submerged bubble generator 21, which are installed in the diffuser 25 of the tubular bubble generator 23, are generated in the submerged bubble generator 21. Is released to the end of), the micro-nanobubble generation step (S3) is mixed with the microbubble produced in the step S2; And washing water supplying step for cleaning the membrane using the washing water supply device for washing the membrane, the washing water supplying step (S4) of supplying the raw water mixed with the micro nanobubbles to the washing target membrane through the header 30. It is about process.

In the manufacturing process of the present invention, the cleaning chemicals may be introduced into the pipe quantitatively when the inflow pump is operated, the amount of the cleaning chemicals may be 1 ppm to 5 ppm depending on the contamination of the membrane, but is not limited thereto.

In the manufacturing process of the present invention, the level sensor manages the level of raw water in the pressure tank 20, and checks the discharge of the internal air, the air discharge is continued in the process of generating micro-nano bubble.

When the raw water is filled in the pressure tank 20, the submerged bubble generator rotates at 0 to 30,000 rpm in the vertical direction to generate nanobubbles, and the circulating pump 24 of the tubular bubble generator operates to supply gas quantitatively. And, the micro-nano bubble generated through the diffuser is supplied into the pressure tank (20). The gas may be ozone, oxygen or air, but is not limited thereto.

In the manufacturing process of the present invention, the residence time of the raw water in the pressure tank in the S2 and S3 is 1 minute to 5 minutes, the raw water in which the micro-nano bubble is mixed is supplied to the header 30, the header 30 The supplied washing water is discharged from the header 30 at a discharge pressure of 2.5 kg / cm ² and supplied to the washing water for the UF membrane and the RO membrane.

Example  One: Micro Nano Bubble  Filter cleaning effect of mixed washing water

In order to compare the cleansing water supplied to the apparatus of the present invention and the membrane cleaning effect by the conventional chemical treatment method, a 10-week pilot test was conducted on the ASF pretreatment system. The amount of is 280 ml, the amount of cleaning chemicals introduced by the conventional method is 410 ml, the amount of chemicals used is reduced by about 50%, and the number of cleanings is also reduced by 42%. It was confirmed (FIG. 8).

Unless otherwise defined in the technical and scientific terms used in the present invention, those having ordinary skill in the art to which the present invention pertains generally have the meanings that are commonly understood, and the gist of the present invention in the following description and the accompanying drawings. Descriptions of well-known functions and configurations that may unnecessarily blur are omitted.

10: cleaning chemical reservoir 11: control pump
12: raw water storage tank 13: cleaning chemical outlet
14: inflow pump
20: pressure tank 21: submerged nanobubble generator
22: dry motor 23: tubular microbubble generator
24: circulation pump 25: diffuser
26: inlet 27: air vent
30: header 40: controller
211: gas inlet 212: vacuum inlet
213: suction impeller 214: hollow shaft inlet
215: Venturi Hall 216: Distributor 1
217: nanohollow shaft 218: nanowire
219: micromesh 220: Distributor 2
221: motor base 222: shaft
223: housing 224: collar
225: cover 226: brush
231: protrusion

Claims (13)

(a) a raw water supply unit including a raw water storage tank 12 and an inflow pump 14 connected to the raw water storage tank;
(b) Bubble generation, which is installed at the rear end of the raw water supply unit and manufactures the washing water in which the micro-nano bubble is mixed, including the pressure tank 20 in which the submerged bubble generator 21 and the tubular bubble generator 23 are mounted. part;
(c) a washing water supply unit installed at a rear end of the bubble generating unit and including a header 30 for supplying raw water mixed with micro-nanobubbles; And
(e) a control unit including an apparatus 40 for controlling the operation of the raw water supply unit, the bubble generation unit, and the washing water supply unit,
The tubular bubble generator 23 is mounted on the outer lower portion of the pressure tank 20, and the submerged bubble generator 21 is provided by a server motor 22 mounted on the upper outer surface of the pressure tank 20. Receiving power, membrane unit washing machine, characterized in that the diffuser (25) of the tubular bubble generator and the end of the submerged bubble generator 21 is installed adjacent to each other.
According to claim 1, wherein the cleaning chemicals storage tank 10, the cleaning chemicals discharge port is provided on the upper portion of the reservoir, and includes a control pump (11), washing through the pipe connected to the raw water storage tank (12) Washing water supply device for membrane cleaning, characterized in that the cleaning chemicals supply unit for supplying the chemicals further included.
According to claim 2, wherein the raw water storage tank 12 is the raw water inlet pipe is fastened to one side, the supply pipe for supplying raw water to the inlet pump 14 is provided on the other side of the lower, Washing water supply device for membrane cleaning, characterized in that the one side is provided with a pipe formed from the cleaning chemical outlet.
According to claim 1, wherein the pressure tank 20 is characterized in that it further comprises a raw water inlet, the washing water discharge port and the air vent 27 to which the supply pipe for supplying the raw water from the inlet pump 14 is fastened. Membrane washing water supply for cleaning.
According to claim 1, The tubular bubble generator 23 is a pipe for supplying raw water through the inlet 26 provided in the pressure tank 20, the circulation pump 24 for supplying gas, and the bubble Membrane cleaning water supply device, characterized in that consisting of an acid pipe (25) provided at the end of the pipe to supply and immersed in raw water.
The washing water supply device for membrane cleaning according to claim 1, wherein the submerged bubble generator is an impeller type or a brush type.
delete The terminal of the submerged bubble generator 21 is installed in proximity to the diffuser 25 of the tubular bubble generator 23, and is a distributor 2 (220) or a brush (226). Membrane washing | cleaning water supply apparatus.
2. The cleaning solution supply according to claim 1, wherein one to five pairs of bubble generators comprising the submerged bubble generator 21 and the tubular bubble generator 23 are mounted in the pressure tank 20. Device.
10. The method of claim 9, wherein when the two or more pairs of bubble generators consisting of the tubular bubble generator and submerged bubble generator are mounted in the pressure tank 20, the partition wall 28 of the perforated surface inside the pressure tank 20. Membrane washing water supply apparatus, characterized in that the separation.
Claim 1 to 6 and 8 to 10 of the membrane washing cleaning water production process using the supply of any one of the following comprising:
While the cleaning chemicals are mixed with the raw water, the raw water supply step (S1) for transferring into the pressure tank 20;
When the raw water is filled in the pressure tank 20, the raw water is transferred to the tubular bubble generator 23 through the inlet 26, and microbubbles are applied to the raw water by using the gas supplied by the circulation pump 24. Bubble generation step (S2) to be mixed, and to discharge into the pressure tank 20 through the diffuser (25);
When raw water is filled in the pressure tank 20, bubbles generated in the submerged bubble generator 21, which are installed in the diffuser 25 of the tubular bubble generator 23, are generated in the submerged bubble generator 21. Is released to the end of), the micro-nanobubble generation step (S3) is mixed with the microbubble produced in the step S2; And
Membrane washing water supply step (S4) for supplying the raw water mixed with the micro-nanobuble to the membrane to be washed through the header (30).
12. The process of claim 11, wherein the residence time of the washing water in the pressure tank in the bubble generation step of S2 and S3 is 1 minute to 5 minutes.
12. The process of claim 11, wherein the gas is oxygen, ozone or air.

Images