KR20110070647A - Combined dissolved air flotation and submerged membrane device and method using waste air reuse and such device - Google Patents

Abstract

PURPOSE: Surplus air reusing water-treatment apparatus and method are provided to reduce the energy consumption for reducing the membrane contamination, and to improve the operational efficiency of the water-treatment apparatus. CONSTITUTION: A surplus air reusing water-treatment apparatus includes a dissolved air floating reaction tank(20), a dipping type membrane filtration device(30), and a returning pipe. A compressed air injection device(23) is installed on the returning pipe for injecting compressed air to circulating water supplied from the dipping type membrane filtration device to the returning pipe. An air-compression reaction-solid/liquid separation tank(24) is installed on the returning pipe for dissolving the compressed air in water.

Description

Combined Dissolved Air Flotation and Submerged Membrane Device and Method Using Waste Air Reuse and such Device}

The present invention relates to an integrated water treatment device of a dissolved air flotation device and an immersion type membrane filtration device for reuse of excess air, and a water treatment method using the same, and more particularly, to an immersion membrane filter device for surplus air generated in the dissolved air flotation device. The present invention relates to a water treatment apparatus and a water treatment method using the same, in which a dissolved air flotation apparatus and an immersion membrane filtration apparatus are integrally integrated to minimize membrane contamination of an immersion membrane and to reduce energy.

In water treatment or seawater desalination, suspended solids contained in raw water should be removed to meet water and drinking water standards. To this end, various methods for removing suspended particulate matter have been proposed, which can be largely classified into a method of settling and then removing the drug according to the characteristics of the suspended material and a method of floating by floating. In this method, sand filtration or membrane filtration is applied as a subsequent step.

Dissolved air flotation devices and membrane filtration processes have recently been applied as a pretreatment process for seawater desalination, and have been reported to effectively remove algae or oil components and particulate suspended solids contained in seawater.

Recently, due to the effects of algae in lake water or sea water, the efficiency of the conventionally applied precipitation process has decreased, and the dissolved air flotation method has been proposed as a new alternative. In the dissolved air floating method (DAF), when supersaturated water is depressurized under pressure, microbubbles are generated and rise while colliding with and colliding with colloidal substances in water to remove suspended solids in water. do. The dissolved air flotation method is known as an excellent technique for removing particles that have a very low specific gravity such as algae or bacteria and are difficult to settle.

On the other hand, the membrane filtration process is newly spreading as a replacement for the sand filtration process. The membrane filtration process uses fine pores (pores having a size of about 0.01 to 1 μm) on the surface to filter out particulate matter larger than the pores. That's how to handle it.

In order to use the dissolved air flotation method, the dissolved air for flotation should be present in the water and for this purpose, the compressed air must be dissolved in the water. For example, compressed air must be dissolved in water by injecting compressed air into the air compression reactor.

However, the dissolved air flotation method has a technical limitation in that compressed air cannot be dissolved in 100% of water. Therefore, more than 5% of the total compressed air injected into the water does not exist as floating treatment dissolved air, and is finally released to the outside meaninglessly. Although compressed air is expensive enough to be reported to cost approximately 50% of the total equipment operation cost, a significant amount of compressed air is not present as dissolved air in the water.

On the other hand, in case of membrane filtration device, as the operation continues, membrane fouling progresses on the surface of the membrane, which affects the operation. Therefore, a physical backwashing process is required to prevent this, and periodic backwashing using water or air is required. Because of the increase in membrane fouling, there is a problem in that operation efficiency and energy cost increase.

The present invention has been made to solve the above problems, in the water treatment apparatus used in the pretreatment process required for the water treatment and desalination process, dissolved air flotation device (specifically dissolved air flotation reaction tank) and immersion membrane filter device It is an object of the present invention to provide a device that can reduce energy saving and membrane fouling by applying a site-saving effect by applying the integrated to the membrane and applying the excess air from the dissolved air flotation device to the membrane filtration device.

In the present invention, in order to achieve the above object, dissolved air floating made up of a water tank to supply the water containing the dissolved air to react with the fine air bubbles generated when the supersaturated dissolved air is decompressed and the contaminant particles in the influent water to rise. A reactor; An immersion membrane filtration apparatus comprising a water tank having an immersion module for removing fine particles contained in the primary treated water subjected to the flotation of contaminants in the dissolved air flotation reaction tank; A conveying pipe for conveying part of the secondary treated water discharged from the submerged membrane filtration device to a dissolved air flotation reactor and circulating it; The conveying pipe is a compressed air injection device for injecting compressed air into the circulating water supplied to the conveying pipe of the secondary treated water discharged from the immersion membrane filtration device, and the dissolved air flotation reaction tank with the compressed air injection device An air compression reaction-gas-liquid separation tank disposed therein, wherein the compressed air injected by the compressed air injecting device is dissolved in water and dissolved air is processed; The submerged membrane filtration device is provided with an air discharger for injecting air for cleaning the submerged module; An air supply pipe 34 is communicated between the air compression reaction-gas liquid separation tank and the air discharge unit, so that excess air that is not dissolved in water in the air compression reaction-gas liquid separation tank is supplied to the air discharge port through the air supply pipe. There is provided a surplus air reuse water treatment device having a structure that is used for washing to remove membrane contamination of the immersion module.

In addition, in the present invention, as a means for achieving the object, by supplying the water containing the dissolved air to the dissolved air flotation reaction tank consisting of a water tank, the air bubbles and the contaminant particles of the inflow water are generated by the supersaturated dissolved air decompression reaction to rise To remove; By the immersion membrane filtration apparatus consisting of a water tank having an immersion module, to remove the fine particles contained in the primary treated water subjected to the contaminant flotation treatment in the dissolved air flotation reaction tank; Some of the secondary treated water discharged from the submerged membrane filtration apparatus are circulated by being returned to the dissolved air flotation reactor by a return pipe; Installing a compressed air injecting device in the conveying pipe and injecting the compressed air into the circulating water supplied to the conveying pipe of the secondary treated water discharged from the submerged membrane filtering device; Arranging an air compression reaction-gas separation tank between the dissolved air flotation reaction tank and the compressed air injection device so that the compressed air injected by the compressed air injection device is dissolved in water to become dissolved air; The submerged membrane filtration apparatus is provided with an air discharger for injecting air for washing the submerged module, and installed in such a manner that an air supply pipe is communicated between the air compression reaction-gas-liquid separation tank and the air discharger, and the air compression reaction- In the gas-liquid separation tank, the surplus air reused water treatment method is provided by supplying surplus air to the air discharger by the air supply pipe to use the excess air for washing to remove the membrane contamination of the immersion type module. .

In the present invention as described above, and a chemical mixing tank for injecting and mixing the chemicals into the inflow water so that the chemicals can be injected before the inlet water is supplied to the dissolved air floating reaction tank; An upper scum remover may be further provided to remove the scum that floats in the dissolved air flotation reaction tank, and the tank of the immersion type membrane filtration device may be integrally coupled to the side of the tank of the dissolved air flotation reaction tank.

According to the present invention, since the surplus air remaining in the water of the compressed air, which is not dissolved in the water, is supplied to the immersion module, that is, the membrane filtration device, and reused for washing the membrane, the dissolved air cannot be made out of the energy used for forming the dissolved air. The lost energy is recycled as energy for reducing membrane fouling in the present invention. Therefore, it is possible to reduce the energy consumption that is consumed for the membrane fouling to reduce the energy cost, the effect of increasing the operating efficiency and energy utilization efficiency of the entire water treatment device.

In addition, in the water treatment system for surplus air reuse according to the present invention, the dissolved air flotation reaction tank and the submerged membrane filtration device may be integrally formed. Area reduction effect can be obtained.

Hereinafter, referring to the drawings, an integrated dissolved air flotation device and an immersion membrane filtration device for reuse of excess air according to an embodiment of the present invention will be described in detail. 1 is a block diagram of an excess air reuse water treatment apparatus according to an embodiment of the present invention.

As shown in Figure 1, the excess air reuse water treatment apparatus according to an embodiment of the present invention, chemical mixing tank 10, dissolved air flotation reaction tank 20, immersion membrane filtration device 30, circulation pump 22 ) And an air compression reaction-gas-liquid separation tank 24.

The chemical mixing tank 10 may be provided as needed to inject the chemical into the influent to mix with the influent so that the flotation of contaminants on the influent can be effectively performed. The chemical mixing tank 10 may be provided with a chemical injector (not shown) and an agitator 11 to mix the chemical and the influent.

The dissolved air flotation reaction tank 20 is a water tank that allows the air bubbles reacted with the fine air bubbles generated while the supersaturated dissolved air is decompressed and floated to react. Are sequentially removed by (21). The sludge precipitated without being floated is discharged separately. For this purpose, although not shown in the drawing, a sludge discharge port may be formed in the lower portion of the dissolved air flotation reactor 20. Since the dissolved air flotation reactor 20 itself is well known, detailed description thereof will be omitted.

The immersion membrane filtration device 30 is composed of a water tank having an immersion module 32, the fine particles contained in the primary treatment water that is subjected to the flotation of the contaminant in the dissolved air flotation reaction tank (20) It is removed by the immersion module 32. In the drawing, reference numeral 33 denotes a membrane filtration suction provided to generate pressure for sucking the primary treated water introduced into the water tank of the submerged membrane filtration device 30 to pass through the immersed module 32. Pump 33. The condensate concentrates that have not passed through the immersion module 32 are discharged from the immersion membrane filtration apparatus 30 to the outside.

The secondary treated water is safely discharged while passing through the submerged module 32 of the submerged membrane filtration device 30, and some of the secondary treated water is dissolved again through the return pipe 26. It is returned to the floating reaction tank 20 and circulated. The conveying pipe (26) includes a circulation pump (22) for circulating some of the secondary treated water to the dissolved air flotation reaction tank (20), and circulated water conveyed through the conveying pipe (26) to the circulating water. There is a compressed air injection device 23 for injecting. In addition, an air compression reaction-gas-liquid separation tank 24 exists in the conveying pipe 26 subsequent to the circulation pump 22 and the compressed air injection device 23. In the drawing, reference numeral 27 denotes a compressed air control valve 27 for injecting compressed air from the compressed air injection device 23 into the conveying pipe 26.

On the other hand, in the present invention, the submerged membrane filtration device 30 is provided with an air discharger 31 for injecting air for washing the submerged module 32, the air compression reaction-gas liquid separation tank 24 And an air supply pipe 34 communicates with the air discharge unit 31. In the figure, the member number 35 is a surplus air discharge valve 35 for controlling the surplus air supply to the air supply pipe 34 by opening and closing the air supply pipe (34).

In the configuration of the present invention as described above, the secondary treatment while the first treatment water is subjected to the flotation treatment of contaminants in the dissolved air flotation reaction tank 20 while passing through the immersion module 32 of the immersion membrane filtration device 30 A portion of the secondary treated water that has passed through the immersion module 32 is supplied to the conveying pipe 26 without being discharged. The conveying pipe 26 is provided with a compressed air injection device 23 to inject the compressed air into the circulating water supplied to the conveying pipe (26). At the rear of the compressed air injector 23, an air compression reaction-gas-liquid separation tank 24 is positioned in the conveying pipe 26. In the air compression reaction-gas-liquid separation tank 24, the compressed air injection apparatus 23 is provided. The compressed air injected by the melt is dissolved in the water and proceeds to the dissolved air. The circulating water containing the dissolved air is supplied to the dissolved air flotation reaction tank 20 to float the contaminant particles of the inflow water while generating fine air bubbles as mentioned above.

At this time, the excess air that is not dissolved in the water is separated into the space above the water surface in the air compression reaction-gas-liquid separation tank 24, and is provided in the submerged membrane filtration device 30 through the air supply pipe 25 It is supplied to the air discharger (32) is used for washing to remove the membrane fouling of the immersion type module (32). That is, by using the surplus air supplied through the air supply pipe 34 to vibrate the immersion module 32 or directly spray on the membrane surface to remove contaminants formed on the membrane surface of the immersion module 32 will be. In order to generate vibration of the immersion type module 32 by surplus air, the surplus air discharge valve 35 may be opened and closed periodically.

As described above, in the present invention, the surplus air remaining in the compressed air without being dissolved in water is supplied to the immersion module 32, that is, the membrane filtration device, and reused for washing the membrane. That is, in the present invention, the energy that has been discarded without making dissolved air among the energy used for forming the dissolved air is recycled as energy for reducing membrane fouling. Therefore, it is possible to reduce the energy consumption that is consumed for the membrane fouling to reduce the energy cost, the effect of increasing the operating efficiency and energy utilization efficiency of the entire water treatment device.

On the other hand, in the excess air reuse water treatment apparatus according to the present invention, it is preferable to integrally constitute the dissolved air floating reaction tank 20 and the immersion membrane filtration device 30 integrally. That is, it is advantageous to combine the water tank of the immersion type membrane filtration device 30 in the dissolved air floating reaction tank 20 to the side adjacent to make one device. In this way, by configuring a single device, an area reduction effect can be obtained, and the device can be simplified.

1 is a block diagram of an excess air reuse water treatment apparatus according to an embodiment of the present invention

Description of the main parts of the drawing

10: chemical mixing tank 20: dissolved air flotation reactor

30: submerged membrane filtration device

Claims (4)

A dissolved air floating reaction tank (20) comprising a water tank for supplying water containing dissolved air to react with fine air bubbles generated when the supersaturated dissolved air is decompressed and contaminant particles in the influent water to float; An immersion type membrane filtration device (30) consisting of a water tank having an immersion module (32) for removing fine particles contained in the primary treated water subjected to the flotation treatment of contaminants in the dissolved air flotation reaction tank (20); ; And a conveying pipe 26 for conveying and circulating a part of the secondary treated water discharged from the submerged membrane filtration device 30 to the dissolved air flotation reactor 20; The conveying pipe 26, the compressed air injection device 23 for injecting compressed air into the circulating water supplied to the conveying pipe 26 of the secondary treated water discharged from the immersion membrane filtration device 30, and the The air compression reaction-gas-liquid powder disposed between the dissolved air flotation reactor 20 and the compressed air injected by the compressed air injection device 23 is melted in water to become dissolved air. A lyso 24 is provided; The submerged membrane filtration device 30 is provided with an air discharger 31 for injecting air for cleaning the submerged module 32; Air supply pipe 34 is communicated between the air compression reaction-gas-liquid separation tank 24 and the air discharge unit 31, the air that is not dissolved in the water in the air compression reaction-gas-liquid separation tank 24 is surplus Is supplied to the air discharger through the air supply pipe (34) has a structure that is used for washing to remove the membrane fouling of the immersion type module 32, characterized in that the excess air reuse water treatment apparatus. The method of claim 1, A chemical mixing tank 10 for injecting and mixing the chemicals into the inflow water so that the chemicals can be injected before the inflow water is supplied to the dissolved air floating reaction tank 20; The surplus air reuse water treatment apparatus, characterized in that the upper scum remover 21 for removing the scum floating in the dissolved air flotation reactor 20 is further provided. The method according to claim 1 or 2, The water tank of the submerged membrane filtration device 30 is integrally coupled to the side surface of the water tank of the dissolved air flotation reaction tank 20. Supplying the water containing the dissolved air to the dissolved air flotation reaction tank (20) consisting of a tank to remove and float by reacting the fine air bubbles generated while the supersaturated dissolved air is decompressed and contaminant particles of the influent water; The fine particles contained in the primary treated water subjected to the contaminant flotation treatment in the dissolved air flotation reactor 20 by the immersion membrane filtration device 30 composed of a water tank having an immersion module 32. Remove; Some of the secondary treated water discharged from the submerged membrane filtration device 30 is returned to the dissolved air flotation reactor 20 by the return pipe 26 for circulation; Installing a compressed air injecting device (23) in the conveying pipe (26) to inject compressed air into the circulating water supplied to the conveying pipe (26) of the secondary treated water discharged from the submerged membrane filtration device (30);  An air compression reaction-gas separation tank 24 is disposed between the dissolved air flotation reactor 20 and the compressed air injection device 23, and the compressed air injected by the compressed air injection device 23 is dissolved in water to dissolve the air. To proceed with the process; The submerged membrane filtration device 30 is provided with an air discharger 31 for injecting air for washing the submerged module 32, and the air compression reaction-gas-liquid separation tank 24 and the air discharger 31. The air supply pipe 34 is installed to communicate with each other, and the excess air that is not dissolved in the water in the air compression reaction-gas-liquid separation tank 24 is supplied to the air discharger 32 by the air supply pipe 34. Surplus air reuse water treatment method, characterized in that used for washing to remove the membrane fouling of the immersion type module (32).

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