KR20130063751A - Anti-fouling device in a membrane filtration process - Google Patents

Abstract

PURPOSE: A fouling reduction apparatus in a membrane filtration process is provided to remove fouling by a fouling side being scratched with silica particles supplied as fouling removal particles, and to be able to reduce TMP(Trans-Membrane Pressure) without performing the CIP(Cleaning In Place) during continuous operation as the differential pressure falls down by the removed fouling cross section. CONSTITUTION: A fouling reduction apparatus in a membrane filtration process comprises a source water tank, a membrane module(20) and a particle storage tank. The membrane module purifies the source water supplied from the source water tank through a pump and ejects the water. The particle storage tank supplies fouling removal particles(24) to a source water supply line between the pump and the membrane module. When the TMP rises in the membrane module, the source water is supplied to the membrane module, and fouling removal particles in the particle storage tank are simultaneously supplied to the membrane module to remove the contaminated fouling within the membrane module.

Description

Anti-fouling device in a membrane filtration process

The present invention relates to an apparatus for reducing fouling in a membrane filtration process. More specifically, by injecting silica particles into the rear end of the influent, physically removing fouling in the ceramic membrane, TMP can be reduced without performing CIP during continuous operation. Can be. In addition, the used silica can be recovered by adding a screening process at a later stage, and the water using silica relates to a fouling reduction device in the membrane filtration process that can be branched and recycled back into a raw water tank or a particle storage tank.

Conventional methods of coagulation, sedimentation, sand filtration, etc. have been widely used in general water treatment methods until recently, but it is difficult to completely remove the taste, odor, and dissolved organic substances technically. Therefore, the need for advanced water treatment facilities is emphasized, and an ozone and activated carbon process may be added to the rear stage.

However, even with ozone activated carbon, it is difficult to completely remove trace harmful substances and organic substances. Therefore, the importance of the membrane filtration process that can solve the problems of the existing water treatment methods worldwide is increasingly recognized.

The membrane filtration process makes pores smaller than the size of organic matter, and contaminants having a size larger than that of organic matter pass through the membrane to produce clean water. These membranes can be classified into organic and inorganic membranes.

Types of organic membranes include microfilters, ultrafilters, nanofilters, reverse osmosis filters, and can be classified into pore sizes.

In addition, there is a ceramic filter in the inorganic membrane, but the mechanical strength is stronger than that of the general organic membrane, the chemical stability is excellent, and there is no film degradation. In addition, the recovery rate (98% or more) is superior to the organic membrane, and the amount of permeated water is 2 to 3 times or more. In addition, the membrane life is more than 15 years, more than twice the organic film, high hydrophilicity and permeability, and can be recycled as a ceramic raw material even after use. Such a ceramic film has various advantages and can be utilized as a water treatment process to replace an organic film.

However, even the organic film or the inorganic film may have various problems in the actual process. In particular, fouling phenomena occurring on the surface of the membrane deteriorate the function of the membrane, and the water quality of the permeate is not assured reliably, and economical costs are high.

In general, fouling on the heat transfer surface is one of the causes of greatly reducing the efficiency of the manufacturing process and the boiler equipment, and different materials (silica, calcium carbonate, calcium sulfate, microorganism, carbon, etc.) contained in the heat medium are different. It is a phenomenon in which crystals are formed by reacting with a component or changing the dissolution conditions according to the temperature change during heat exchange to deposit or scale on the heat exchanger side.

The scale formed in this way acts as the largest thermal resistance of the total thermal resistance, causing enormous energy loss, and the friction coefficient is increased by the scale formed at the cross section of the pipe, and the pressure loss is generated in the heat exchange system. Disruption of operation is a serious detrimental factor to equipment life and energy efficiency.

On the other hand, one of the biggest problems of the water purification process using a membrane is that membrane fouling (fouling) is a biofouling phenomenon that is proliferated by attaching organic matter or microorganisms to the surface of the filter over time Inorganic fouling or scaling caused by agglomeration and precipitation of minerals in water occurs.

Such fouling is recognized as a factor having resistance on the surface of the membrane to increase the transmembrane pressure (Trans-Membrane Pressure, TMP), there is a problem that can not guarantee the stability of the purified water in addition to the decrease in the filtered water production.

In addition, the number of cleaning in place (CIP) is increased due to the contaminants may cause a cost problem in the secondary contamination of the cleaning agent or the operation of the CIP.

Membrane contamination that can occur during operation of the membrane system includes crystalline contamination (scaling by inorganic matter, inorganic precipitation due to excess of dissolved products), organic contamination (decomposition of decomposed humic acid, oil, grease), particulate matter, Colloidal contamination (clay, silt, particulate corrosive, silica precipitation), microbial contamination (biofouling, microbial adhesion and concentration, biofilm formation).

In case of inorganic membrane contamination caused by crystalline or colloidal contamination, removal of membrane contamination by physical pretreatment such as coagulation precipitation is considered to be easier to control than biological membrane contamination. In case of membrane fouling, it is difficult to control biofouling by the pretreatment process, which is the most common method of membrane fouling control. Therefore, in order to solve this problem, various methods, such as using ozone, using ultraviolet light, using chlorine, have been proposed.

The method using ozone has no residual effect of ozone, which is likely to cause secondary pollution, is expensive to process, is difficult to treat large volumes, and has a problem of corrosion of a tank, that is, a tank housing by ozone.

Ultraviolet rays can inactivate microorganisms or break organic chemical bonds to remove contaminants. However, ultraviolet rays are the same as ozone and have no residual effect. In addition, since UV process requires high power, economical and large molecular weight organic material is decomposed into organic material with low molecular weight, so that the small molecular weight organic material is adversely affected by microbial food. There is this.

In addition, the use of chlorine is the most common and widely known disinfectant, but when used in organic film pretreatment, chlorine itself has a large oxidation power, which can damage the organic film. In this case, it is necessary to add a process to neutralize chlorine in front of the separator to remove residual chlorine to prevent damage to the membrane. Care should also be taken when using chlorine because it combines with toxic substances in water to produce highly toxic disinfection byproducts that are difficult to control.

Recently, a method of performing water treatment using plasma pulses has been developed, but there is a cost burden due to a power supply for generating pulse power, and in terms of efficiency, it is less usable than other disinfection processes. .

Moreover, in most prior art, fouling inhibitor or CIP is performed to reduce fouling. However, this method has a problem that continuous operation is impossible because the driving is stopped for a while.

Korea Patent Registration No. 10-0704421 (2007.3.30) Korean Patent Publication No. 2011-45847 (2011.05.04) Korea Patent Registration No. 10-1035511 (2011.05.12) Korean Patent Registration No. 10-1068205 (2011.09.21) Korean Patent Publication No. 2005-102872 (2005.10.27) Korean Patent Registration No. 10-0688715 (2007.02.22)

The present invention has been made to solve the above problems, by spraying silica particles on the rear end of the influent to remove fouling in the membrane, fouling in the membrane filtration process that can reduce the TMP without performing CIP during continuous operation A ring reducing device is provided, and the silica used for fouling removal is not used once and discarded, but the entire silica can be recovered by adding a screening process to the rear stage. In this way, the cost of using silica can be reduced and the operating cost can be reduced by continuous operation without stopping the membrane filtration process. Accordingly, it is an object of the present invention to provide a fouling reducing apparatus that can utilize these advantages.

According to an aspect of the present invention, the present invention is a fouling reduction device in the membrane filtration process, the raw water tank for storing the raw water to be purified, and the raw water stored in the raw water tank is supplied from the raw water tank through a pump Membrane module for discharging the raw water and then discharged, and a particle storage tank for supplying the fouling removal particles to the raw water supply line between the pump and the membrane module, the membrane module is raised when the TMP is raised in the membrane module Simultaneously with the supply of raw water to the membrane, fouling-removing particles of the particle storage tank can be supplied to the membrane module to remove fouling in the membrane module.

The present invention may further include a screening screen for filtering fouling particles and fouling particles used in the membrane module.

Water from which the particulate matter is removed from the screen portion can be sent to the raw water tank and the particle storage tank.

At this time, the water is removed from the screen portion is separated from the particulate matter sent to the raw water tank is supplied to the particle storage tank can be adjusted to the water level of the particle storage tank.

The membrane of the membrane module is a ceramic membrane, and the fouling removing particles are silica particles.

It is preferable that a silica particle is 100 micrometers or more.

According to an embodiment of the present invention, the fouling surface is scratched and removed by silica particles supplied as fouling removing particles, and the differential pressure drops as much as the removed fouling section, thereby reducing TMP without performing CIP during continuous operation. Has the effect.

1 is a process chart showing the configuration and process of a fouling reducing apparatus in a membrane filtration process according to a preferred embodiment of the present invention.
FIG. 2 is a conceptual diagram illustrating the principle of fouling removal of the apparatus of FIG. 1.

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

1 shows the configuration and process of a fouling reducing apparatus in a membrane filtration process according to a preferred embodiment of the present invention.

As shown in FIG. 1, the fouling reducing device in the membrane filtration process of the present invention transfers raw water stored in a raw water tank 10 storing raw water to be purified to a membrane module 20 through a pump 30. Supply, purify and discharge.

The film of the film module 20 (hereinafter referred to as a ceramic film module) is preferably a ceramic film. This is because, in the case of the organic film, the fouling removing particles themselves may damage the film, but since the ceramic film is excellent in durability, no film damage occurs.

A valve 2 is attached to the raw water supply line 12 between the raw water tank 10 and the pump 30 to control the supply of raw water, and the raw water supply line between the pump 30 and the ceramic membrane module 20 ( 12) Particularly, the rear end of the influent water is connected to the particle supply line 42 supplied from the particle storage tank 40 for storing the fouling removal particles. A valve 4 is also attached to the particle supply line 42 to control the supply of the fouling removing particles.

As described above, the fouling reducing device in the membrane filtration process of the present invention uses silica particles as the fouling removing particles. In this way, by introducing a cube-shaped silica particle spiking device having a cube shape of 100 μm or more at the rear end of the influent, even if the TMP of the membrane module 20 increases during operation, fouling contaminated with the membrane can be physically removed at a high flow rate.

When the silica particles as the fouling removing particles are pulverized to less than 100 µm, the silica particles may be agglomerated by the electrostatic force and van der Waals force of the particles, which may cause colloidal fouling. It is important not to grind the silica particles to adhere to the ceramic film and cause fouling.

Also, as a fouling removing particle, the induction of charge is an important consideration, but the silica particles do not adhere to the surface of the ceramic film due to the electrostatic repulsive force by flowing particles charged with the same charge as the fouling surface into the influent, thereby fouling. The removed particles do not foul again.

Accordingly, when the trans-membrane pressure (TMP) increases in the ceramic membrane module 20, the valve 4 of the particle supply line 42 for supplying the fouling removing particles is opened to convert the silica particles into the ceramic membrane. The module 20 is supplied with raw water to remove fouling at the same time.

The used silica particles and fouling particles separated from the ceramic film surface are sent to the screen portion 50 installed in the screen line 52 between the ceramic membrane module 20 and the raw water tank 10, and the screen portion 50 Is filtered through screening. The valve 6 is also attached to the screen line 52 between the ceramic membrane module 20 and the screen portion 50 to control the amount of screening and at the same time the raw water to the screen line 52 when not spraying silica. To control the inflow.

Meanwhile, the water from which the particulate matter is removed from the screen unit 50 is sent back to the raw water tank 10 through the screen line 52.

Meanwhile, a branch line 54 connected to the particle storage tank 40 is branched from the screen line 52 between the screen unit 50 and the raw water tank 10, and a valve 8 is attached to the branch line 54. Control the amount of water supplied to the particle storage tank (40).

When the water level of the particle storage tank 40 is low, the valve 8 is opened to branch water 54 to supply the particle storage tank 40 with the particulate matter removed from the screen unit 50 to the particle storage tank 40. By adjusting the water level of the particle storage tank 40.

In addition, a recovery line 62 having a valve 9 is connected between the ceramic membrane module 20 and the raw water tank 10, so that the fouling is not removed from the ceramic membrane module 20. ) To recycle the raw water, at which time the valve 6 of the screen line 52 is closed.

As shown in FIG. 2, a cross section of the ceramic membrane module 20 in which fouling is performed by the fouling reducing device in the membrane filtration process of the present invention configured as described above is illustrated in FIG. 2. The fouling surface 22 is scratched and removed by the silica particles 24 supplied through), and the differential pressure drops slightly as much as the fouling removing section 26.

As described above, the fouling reducing device in the membrane filtration process of the present invention can reduce the TMP without performing CIP during continuous operation.

Although specific embodiments of the present invention have been described above, these are merely examples, and the present invention is not limited thereto and should be construed as having the broadest scope in accordance with the basic idea disclosed herein. Those skilled in the art can change the material, size, etc. of each component according to the application field, it is possible to implement the pattern of the shape not shown by combining or replacing the disclosed embodiments, but this is also not departing from the scope of the present invention. In addition, those skilled in the art can easily change or modify the disclosed embodiments based on the present specification, it is apparent that such changes or modifications are included in the scope of the present invention.

2,4,6,8,9 Valve 10: Raw water tank
12: raw water supply line 20: ceramic membrane module
22: fouling surface 24: silica particles
26: fouling cross section 30: pump
40: particle storage tank 42: particle supply line
50: screen portion 52: screen line
54: branch line 62: recovery line

Claims (6)

As fouling reduction device in membrane filtration process,
A raw water tank for storing raw water to be purified;
A membrane module for discharging raw water stored in the raw water tank after purifying raw water supplied from the raw water tank through a pump;
Includes a particle storage tank for supplying the fouling removal particles to the raw water supply line between the pump and the membrane module,
When the TMP rises in the membrane module, at the same time as the supply of raw water to the membrane module, the fouling removal particles of the particle storage tank are supplied to the membrane module to remove contaminating fouling in the membrane module.
Fouling reduction device in membrane filtration process.
The method of claim 1,
The fouling removing particles and the fouling particles used in the membrane module further comprise a screening screening filter.
Fouling reduction device in membrane filtration process.
3. The method of claim 2,
Water from which the particulate matter is removed from the screen unit is sent to the raw water tank and the particle storage tank.
Fouling reduction device in membrane filtration process.
The method of claim 3, wherein
Water from which the particulate matter sent to the raw water tank is removed from the screen unit is branched and supplied to the particle storage tank to adjust the level of the particle storage tank.
Fouling reduction device in membrane filtration process.
The method of claim 1,
The membrane of the membrane module is a ceramic membrane, the fouling removing particles are characterized in that the silica particles
Fouling reduction device in membrane filtration process.
The method of claim 5, wherein
The silica particles are characterized in that more than 100㎛
Fouling reduction device in membrane filtration process.

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