KR100881629B1 - Apparatus for purifying sewage using micro porous hollow fiber membrane - Google Patents

Abstract

An apparatus for purifying sewage using micro porous hollow fiber membrane is provided to vibrate a micro porous hollow fiber membrane upward and downward in order to remove contaminant adhered to a micro pore of the micro porous hollow fiber membrane. An apparatus for purifying sewage using micro porous hollow fiber membrane comprises the following units. A aeration tank(100) stores sewage. A pair of module props(500) are formed to face toward a lower part of the aeration tank. A module fixing grooves(510) are formed on the module props at some distance. A spring(520) is inserted into the module fixing grooves. A spring plate(522) is formed on the spring.

Description

Wastewater treatment apparatus using hollow fiber membrane {Apparatus for purifying sewage using micro porous hollow fiber membrane}

The present invention relates to a wastewater treatment apparatus for purifying and treating sewage or wastewater, and more particularly, to a wastewater treatment apparatus using a hollow fiber membrane having excellent treatment efficiency while quickly and simply removing contaminants adhering to a hollow fiber membrane module. will be.

Hollow fiber membrane module uses a hollow fiber membrane, which is a thin fiber with a myriad of small micropores on the surface, and uses a hollow fiber membrane to exclude materials larger than the micropore size from the multicomponent liquid mixed with various materials. It means a device that can selectively recover only small substances.

In general, the hollow fiber membrane module has been widely used in the field of ultrafiltration and precision filtration such as sterile water, drinking water production, etc., and recently, advanced treatment in sewage terminal treatment, advanced treatment in small scale septic tanks, suspended solids in industrial wastewater. It is actively applied in various fields such as removal, treatment of heavy and high concentration organic wastewater, treatment of industrial water and household water, as well as recovery of process materials in production processes of food, automobile and steel industries.

When the hollow fiber membrane module is immersed in the aeration tank of biological wastewater treatment process in which the concentration of suspended solids and microorganisms is kept above a certain amount in relation to the various uses of the hollow fiber membrane module, the treated water quality is always maintained regardless of the degree of microbial precipitation. Good maintenance costs less chemicals and glass management costs, microorganisms in the aeration tank can be made at high concentrations, and the ability to cope with changes in influent concentration is excellent. As the sedimentation tank for liquid separation is unnecessary, there is a significant advantage such as less land area required for the installation of the facility. Therefore, studies on the hollow fiber membrane module for treating the high concentration of wastewater have been continuously conducted.

When the hollow fiber membrane module is directly immersed in the wastewater with high concentration of suspended solids and filtered, the suspended solids accumulate on the membrane surface or between the membranes and the flow path is mixed. Is generated. Therefore, in order to filter wastewater with a high concentration of suspended solids for a long time, the structure of the hollow fiber membrane module should have a structure capable of suppressing intermembrane blockage, and in addition, aeration or air turbulence may be formed at the bottom of the membrane module. Or by shaking the hollow fiber membranes with ultrasonic waves or vibrations, to keep the suspended solids accumulated on the surface or between the membranes.

Here, the method of forming the turbulence by aeration of air at the bottom of the module is the most adopted because it has advantages in terms of cost or cleaning effect.

Briefly describing the structure of aeration of air at the bottom of the module, dozens of hollow fiber membrane modules are installed in the aeration tank at regular intervals, and then form an air pipe from the ground air pump to the bottom of the hollow fiber membrane module (the bottom of the aeration tank). In addition, continuous air flows from the bottom of the aeration bottom into the aeration tank by the operation of the air pump, causing the air to rise by buoyancy, causing turbulence to continuously shake off the contaminants stuck to the micropores of the hollow fiber membranes.

If the amount of air flowing from the air pipe into the aeration tank is high and the pressure is high, the effect of removing the contaminants adhering to the micropores of the hollow fiber membrane is high, but the air above a certain amount and the air above a certain pressure have an adverse effect on the activity of microorganisms. Increasing the amount of air or increasing the pressure of air limits the removal of contaminants.

On the other hand, the hollow fiber membrane module installed in the aeration tank is fixed to the fixing member by inserting the hollow fiber membrane into the fixing member at the top and bottom. Therefore, when installed in the aeration tank, the lower fixing member is fixed below the aeration tank, and then the upper fixing member is fixed to the aeration tank top.

When dozens of hollow fiber membrane modules are installed in the aeration tank, wastewater flows into the aeration tank and used for a certain period of time. Thus, the hollow fiber membrane module may be damaged by various factors. At this time, the hollow fiber membrane module should be replaced, but it is not easy to replace because it is immersed in the aeration tank full of waste water.

In order to facilitate replacement work, the handle may be formed and lifted by forceps, etc., but the hollow fiber membrane having the upper and lower ends of the hollow fiber membrane 10 as the upper fixing member 20 and the lower fixing member 30 as shown in FIG. The module is very inconvenient because there is no structural strength up and down. In other words, the aeration tank should be lifted using a mechanical device, and then the hollow fiber membrane module should be installed and then replaced. That is, the replacement of the hollow fiber membrane module is very inconvenient.

The present invention is to solve the problems described above, to improve the homeostasis and processing efficiency of the device by being able to quickly and continuously remove the contaminants adhering to the hollow fiber membrane module.

The present invention is to install the hollow fiber membrane module in the aeration tank in order to achieve the above object in the wastewater treatment apparatus using a hollow fiber membrane to treat the wastewater introduced into the aeration tank while blowing air through the air pump, the wastewater is stored inflow Aeration tank; A pair of module supports formed to face the lower portion of the aeration tank; A plurality of module fixing grooves formed on the module support at regular intervals; A spring inserted into the module fixing groove; A spring plate formed on the spring; Module catching grooves formed at regular intervals on the aeration tank; A hollow fiber membrane module inserted between the module fixing groove and the module catching groove, and having a catching protrusion to be inserted into the module catching groove and moved up and down on both sides of the module; And installed in the aeration tank, to provide a wastewater treatment apparatus using a hollow fiber membrane, characterized in that made; including an air pipe for ejecting air from the lower portion of the hollow fiber membrane module.

According to the present invention, because the hollow fiber membrane module vibrates up and down, the contaminants stuck to the micropores of the hollow fiber membrane are removed from the air by aeration of the hollow fiber membrane module by removing the hollow fiber membrane module continuously up and down. Better remove contaminants

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

2 and 3, the wastewater treatment apparatus according to the present invention may store the wastewater and includes an aeration tank 100 in which aerobic microorganisms may inhabit.

The aeration tank is generally made of cement concrete or metal, but in the present invention, a metal aeration tank having a relatively light weight and easy management is used.

The wastewater treatment device can be made with only one aeration tank 100, but can be installed on a large scale by installing several to several hundreds in a predetermined space.

The aeration tank consists of a cube or cuboid that is approximately 1 to 2 meters wide and 1 to 2 meters high because wastewater flows in and is stored and microorganisms need to inhabit.

The aeration tank 100 is provided with a hollow fiber membrane module 200 to separate the purified water into the introduced waste water. The hollow fiber membrane module 200 bundles the hollow fiber membrane 210 in bundles of several hundreds to thousands, and fixes the hollow fiber membrane 210 at the upper and lower ends in proportion to the height of the aeration tank 100. That is, the upper fixing member 220 for fixing the upper end of the hollow fiber membrane 210 and the lower fixing member 230 for fixing the lower end of the hollow fiber membrane 210, the upper fixing member 220 and the lower fixing member ( It consists of a left fixing member 240 and the right fixing member 250 to connect the 230 integrally from the left and right.

The upper fixing member 220 has a flow path formed therein, and an end portion of the hollow fiber membrane 210 is in communication with the flow path, and one side of the upper fixing member 220 has a suction port 222 communicating with the flow path. Inlet 222 is a suction pump is connected to extract the purified water from the waste water of the aeration tank 100 through the inlet 222.

One side of the upper fixing member 220 occurs when the hollow fiber membrane module 200 is installed for replacement or maintenance in a state where the handle 224 is installed for easy lifting. A handle is formed in the handle so that it can be easily lifted out through tongs or a mechanical device.

Inside the aeration tank 100, the module support 500 is formed to face each other in the horizontal direction, the module support 500 is a module of the form corresponding to both cross-sections of the upper fixing member 220 and the lower fixing member 230 A plurality of fixing grooves 510 are formed at regular intervals along the module support.

The spring 520 is inserted into the module fixing groove 510 to be elastically supported when the hollow fiber membrane module is installed so that the waste water in the aeration tank can be interlocked with a predetermined distance up and down when flowed by air pressure. A cushion member 530 such as rubber is inserted into the center of the spring 520, and the cushion member 530 is formed only to about 50 to 90% of the height of the spring. This is to facilitate the vibration by the repulsive force of the spring at the beginning of the vibration to prevent excessive rolling in the late vibration.

The spring plate 522 is formed on the spring 520 so that the load is dispersed and balanced when the load of the hollow fiber membrane module is applied, and the side end of the spring plate 522 is caught by the module fixing groove 510 to hold the spring 520. When the spring plate 522 is moved up and down together, it can be guided without leaving the module fixing groove 510 completely.

The upper end of the aeration tank 100 is formed with a module locking groove 610 corresponding to the module fixing groove 510 to fix the hollow fiber membrane module 200. Module locking groove 610 is formed long up and down.

Both side ends of the upper fixing member 220 is inserted into the module engaging groove 610 is formed to protrude the engaging projection 226 when the hollow fiber membrane module 200 is vibrated up and down.

An air pipe 300 is installed in the aeration tank 100, and an air distribution pipe 310 is formed at an end of the air pipe 300. Waste water of the aeration tank 100 is decomposed by the microorganisms, the microorganisms are mostly aerobic microorganisms to provide sufficient air to increase the treatment efficiency. In addition, when the purified water is inhaled through the hollow fiber membrane, contaminants are easily blocked by blocking the micropores of the hollow fiber membrane 210. If not properly removed, the wastewater treatment efficiency drops rapidly. Therefore, air is blown to remove the contaminants that cling to the micropores, causing turbulence in the wastewater.

Removing the contaminants adhering to the micropores of the hollow fiber membrane 210 is one of the biggest factors that determine the efficiency of the waste water treatment apparatus. Therefore, the end of the air pipe 300 is located in the lower portion of the hollow fiber membrane module 200 to supply through the air distribution pipe 310 is formed with a plurality of air holes to cause turbulence throughout the waste water to shake off the pollutants.

Referring to the operation of the wastewater treatment apparatus according to the present invention configured as described above are as follows.

The wastewater treatment apparatus is installed at a specific place where household wastewater or industrial wastewater is collected. First, the aeration tank 100 is installed, and the hollow fiber membrane module 200 is installed in the aeration tank 100. Since the groove corresponding to the cross section of the hollow fiber membrane module 200 is formed in the aeration tank 100, the hollow fiber membrane module 200 is inserted one by one from the top.

The air pipe 300 is integrally installed on one side of the aeration tank 100 by welding or bolting, and connected to the air pump, respectively.

After the hollow fiber membrane module 200 is installed, the suction port 222 formed on the upper fixing member 220 is connected to the suction pump.

When the aeration tank 100 is installed as described above, and the wastewater flows into the aeration tank 100 while the air pipe 300 and the hollow fiber membrane module 200 are installed in the aeration tank 100, contaminants are decomposed by aerobic microorganisms. Is purified.

Purified water generates negative pressure in the hollow fiber membrane 210 through the suction port 222 by the operation of the suction pump, the purified water is sucked through the micropores of the hollow fiber membrane 210. Contaminants adhere to the micropores of the hollow fiber membrane 210 as a repetitive process of inhaling the purified water. At this time, the waste water is ejected through the air distribution pipe 310 installed to extend to the lower portion of the hollow fiber membrane module 200. It causes turbulence in and shakes off contaminants stuck to the micropores of the hollow fiber membrane 210.

At this time, the air is ejected, causing turbulence in the waste water and simultaneously pushing up the hollow fiber membrane module 200 by air pressure, the hollow fiber membrane module 200 is temporarily lifted slightly and vibrates in a repeated operation of falling down by its own weight. In addition, as shown in FIG. 4, the cushion member 530 is formed at the center of the spring 520, so that the hollow fiber membrane module 200 excessively decreases its speed when the user descends more than a predetermined distance when laying down by its own weight. To prevent rolling.

If the waste water treatment apparatus is used for a long time, some of the hollow fiber membrane modules 200 may be damaged or unusable due to various factors. At this time, the hollow fiber membrane module 200 should be replaced. Since the handle 224 is installed on the upper portion of the hollow fiber membrane module 200, the handle 224 without lifting the aeration tank 100 or removing the waste water of the aeration tank. If you lift and lift the damaged hollow fiber membrane module 200 is to be inserted, the new hollow fiber membrane module 200 is plugged in.

Without the left fixing member 240 and the right fixing member 250 formed on the left and right sides of the hollow fiber membrane module 200, when the hollow fiber membrane module 200 is inserted, the hollow fiber membrane module 200 is bent due to buoyancy of waste water. Therefore, unless you lift the aeration tank 100 or remove the waste water, it is difficult to replace, since the left fixing member 240 and the right fixing member 250 are firmly supported, they can be simply plugged in.

1 is a schematic view of the conventional hollow fiber membrane module.

2 is a perspective view of a wastewater treatment apparatus according to an embodiment of the present invention.

3 is a cross-sectional view of a wastewater treatment apparatus according to an embodiment of the present invention.

4 is a cross-sectional view of an essential part of a wastewater treatment apparatus according to another embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

100: aeration tank 200: hollow fiber membrane module

210: hollow fiber membrane 220: upper fixing member

226: jamming

230: lower fixing member 240: left fixing member

250: right fixing member 300: air pipe

310: air distribution pipe 500: module support

510: module fixing groove 520: spring

522: spring plate 530: cushion member

610: module locking groove

Claims (2)

In the wastewater treatment apparatus using a hollow fiber membrane that installs a hollow fiber membrane module in the aeration tank to treat the wastewater introduced into the aeration tank while ejecting air through the air pump, Aeration tank in which waste water is introduced and stored; A pair of module supports formed to face the lower portion of the aeration tank; A plurality of module fixing grooves formed on the module support at regular intervals; A spring inserted into the module fixing groove; A spring plate formed on the spring; Module catching grooves formed at regular intervals on the aeration tank; A hollow fiber membrane module inserted between the module fixing groove and the module catching groove, and having a catching protrusion to be inserted into the module catching groove and moved up and down on both sides of the module; And Is installed in the aeration tank, the wastewater treatment apparatus using a hollow fiber membrane, characterized in that it comprises a; air pipe for ejecting air from the lower portion of the hollow fiber membrane module. The method of claim 1, Waste water treatment apparatus using a hollow fiber membrane, characterized in that the cushion member is inserted into the center of the spring.

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