KR100493646B1 - A way and a device to purify sewage,slop, and waste water by using a bed biofilm mehod and a pressure floataion - Google Patents

Abstract

end. The technical field to which the invention described in the claims belongs.

The present invention relates to a method and apparatus for treating sewage, sewage, and wastewater in combination with a biofilm method and a pressurized flotation method. In particular, the depth of the reaction tank is deep and the surface area is small, thereby greatly reducing the required area while maintaining the existing treatment volume ratio. There is no space limitation, and this reactor is characterized by reusing the treated water by combining the biofilm method and the pressure flotation method to improve the treatment efficiency.

I. The technical problem to be solved by the invention.

In the conventional method of treating sewage, sewage, and wastewater in combination with a biofilm method or a pressurized flotation method, a reaction tank designed to accommodate the capacity of the water to be treated is disposed on the surface of the area to be treated.

However, these reactors are usually calculated with a constant area and height, and thus require a large amount of area to process a certain amount of treated water. will be.

All. Summary of the Solution of the Invention.

Therefore, the present invention is to bury a deep-depth reaction tank formed vertically up and down to maintain the depth of the water to be treated in the basement of the treatment area to minimize the required area, and to form a biofilm in the reactor In the state of filling the carrier, pressurized water and the water to be treated to which the chemical for flocculation reaction and the compressed air are generated and the water to be treated are injected to the bottom of the reaction tank. Treatment of sewage, sewage, and wastewater in combination with a deep-depth biofilm method and a large-depth pressurized buoyancy method, including a treatment process that allows the physical and chemical treatments by pressurization flotation method to occur by flocculation and flotation of contaminants by chemicals and microbubbles. Way.

la. Important uses of the invention

Sewage, Sewage, Wastewater Treatment

Description

A method and apparatus for treating sewage, sewage, and wastewater in combination with a large-depth biofilm method and a pressurized buoyancy method with a depth depth {a way and a device to purify sewage, slop, and waste water by using a bed biofilm mehod and a pressure floataion}

The present invention relates to a method and apparatus for treating sewage, sewage, and wastewater incorporating a large depth biofilm method and a large depth pressurized flotation method. More specifically, the depth of the treatment area is deepened and the surface area is small while maintaining the existing treatment volume ratio. The required area is greatly reduced so that there is no space limitation, and the biofilm method and the pressure flotation method are applied to this treatment area to improve the treatment efficiency.

Conventionally, as a method of treating sewage, sewage, and wastewater, the biofilm treatment method in which microorganisms are combined is environmentally friendly and has excellent treatment efficiency, and is still widely used. However, when the concentration of influent is severely changed, the adaptability to sudden load changes is poor. In addition to the weak treatment efficiency, especially when toxic substances are introduced, the treatment efficiency is sharply lowered, and the effluent after biological treatment has a problem that it is difficult to reuse because the water quality of the treated water is not excellent.

Therefore, in order to overcome such a problem, a biofilm method using a carrier was developed to cope with a certain load variation, but these methods require at least one or more additional equipment such as a stirring tank, a mixing tank, and a precipitation degree. As a result, a new problem that requires a lot of land area has emerged.

Therefore, in Korea, which is sensitive to the required land area, the problem of dryness of rivers has begun to arise because the sources of pollutants are collected instead of directly from the source of pollutant sources. This is because upstream areas that do not flow because they are behind the streets may cause dryness due to reduced inflow.

Therefore, these dry streams have no choice but to lower the water level, which in turn leads to the rapid eutrophication of the rivers, and the rapid progress of the eutrophication promotes the water pollution of the rivers, causing water pollution as well as the source of odors, causing many complaints. It is done.

On the other hand, in the case of the pressurized buoyancy method in which the contaminants contained in the treated water are floated and removed by the microbubbles generated by injecting the pressurized water containing air into the treatment area, the contaminants are quickly floated. Although there is an advantage in that it can be removed, the energy consumption is large due to the input of air above a certain pressure in order to generate micro-bubbles, and the amount of chemical consumption according to the chemicals to form a floc of contaminants must be added. There is a problem that takes a lot of maintenance costs.

In addition, in the large-depth pressurization method, in which the depth of the treatment zone is deepened in order to save the required site, a release phenomenon is generated in which the bubbles generated at the bottom of the treatment zone rise, causing the floating speed to decrease or generated bubbles. Because it is extinguished, there is a problem that the treatment efficiency is significantly reduced.

Accordingly, the present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide a method and apparatus for treating sewage, sewage and wastewater, which can greatly reduce the required area and maximize the treatment efficiency. to be.

To this end, a deep-depth reaction tank formed up and down to maintain the depth of the water to be treated is buried deep from the ground surface of the area to be treated, and pressurized water and water to be treated are placed in the center of the reactor. Downward injection part is extended to the bottom of the reaction tank so that it can be injected to the bottom surface, and high pressure jet water is injected into the upper part of the pressurized water discharged through the downward injection part and the water to be treated in multiple stages depending on the depth, and the upper part and The downstream injection part is filled with a carrier for biofilm formation to maximize the treatment efficiency by combining the physical and chemical treatments by the biofilm method and the physical and chemical treatments by the pressure buoyancy method.

The present invention is a method for treating sewage, sewage, and wastewater by combining a biofilm method and a pressure flotation method while maintaining a high depth of water to be treated.

Hereinafter, the present invention will be described in more detail with reference to the following examples.

First, Figures 1 to 6 show an embodiment of the present invention, the large-depth reaction tank 10 is formed up and down to keep the depth of the water to be treated high from the ground surface of the processing region Buried deep to the basement, the downward injection portion 11 for injecting the pressurized water (1) and the water to be treated (2) to the bottom of the reaction tank in the inner center of the reactor 10 to the bottom installed downward injection By filling the carrier 12 for biofilm formation in the inside of the part 11 so that the advanced biological treatment by contact with the carrier 12 is performed, the pressurized water 1 discharged through the downward injection part 11. The microbubble 3 generated by the ascending through the upper portion (11a) formed on the outer side of the downward injection portion 11 to rise the flocculent (4) to perform the physical and chemical treatment by the pressure buoyancy method will be.

In this case, the downward injection portion 11 may be formed using a conventional material such as a pipe or a circular tube, but when formed using a filtration medium, the downward injection portion 11 may also play a role as a fixed-phase carrier to improve treatment efficiency. 2, it is possible to facilitate the generation of the micro-bubbles (3) by forming a proliferation-expansion type that changes the diameter depending on the depth as shown in Figure 2, wherein the use of an orifice or venturimeter to further generate the micro-bubbles Not only to facilitate but also to increase the disturbance to maintain the size of the micro-bubbles in a fine state.

       In addition, the carrier 12 may be filled in any form, such as a fluidized bed or a stationary bed, and when filled with a fluidized bed, a screen 14 may be formed at a predetermined portion of the downwardly injected portion 11 to move up and down. The storage of the upper carrier 12a should be possible, and when the fixed phase carrier 12b is filled, as shown in FIGS. 3 to 6, the lower injection unit 11 and the lower injection unit 11 are formed on the inner wall of the lower injection unit 11. It can be filled in various forms, such as vertically in the same direction or horizontally in the lateral direction. Especially, when the stationary bed carrier 12b is horizontally formed, clogging of the carrier by the backwashing device 13 is prevented. It should be prevented.

In addition, the upper portion (11a) is formed in a multi-stage injector 20 in several places by the depth of the fine to rise from the bottom of the reaction tank 10 by the high-pressure jetting water (6) injected through the injection device 20 By preventing the bubble 3 from being released, the size of the bubble can be maintained in a fine state, as well as preventing the bubble from being dissolved, and the treatment time can be shortened by increasing the floating speed of the fine bubble 3. To achieve the effect.

At this time, another reason for installing the injector 20 at various points for each depth is to increase the reaction rate with the contaminants that have not reacted in the deep portion.

In addition, the micro-bubbles (3) generated by the pressurized water (1) has an effect of aeration, by adjusting the injection of the pressurized water (1) at regular time intervals, the injection and stop of the pressurized water (1) repeatedly By making the reaction tank 10 also combines aerobic and anoxic state to increase the activity of various microorganisms to increase the treatment efficiency.

On the other hand, the reaction tank (10) is provided with a discharge water tank 15 to enable the temporary storage of the treated water (5) from which the flocculated aggregate (4) has been removed, the treated water (5) stored therein Is discharged as it is, or can be reused as pressurized water 1 and sprayed water 6 used in the treatment process of the present invention.

At this time, the aggregates (including sludge) 4 floating on the surface of the reaction tank 10 are sucked by the sludge suction device 30 provided separately and are removed after dehydration by the dewatering device 40. It is a method of treating phosphorous flotation, and pressurized water (1) includes compressed air supplied from the compressor (60) and chemicals supplied from the chemical tank (70), so that coagulation reaction by chemicals and oxygen injection by compressed air are possible. Of course it is.

Therefore, the present invention configured as described above can be embedded in the reaction tank 10 vertically up and down to deeply buried underground, so that the depth of the water to be treated can be formed deep while the surface area can be reduced, thereby minimizing the required area. The downward injection portion 11 is formed to extend to the bottom of the bottom of the reaction tank 10 so that the pressurized water 1 can be injected deep at a high pressure, and the microbubbles generated by the pressurized water are the upstream pipe 11a. By rising again through), by preventing the release of bubbles by the high-pressure water sprayed from the injection device 20 formed for each depth, as well as the rising speed can be increased to increase the removal efficiency of contaminants by the pressure buoyancy method. By incorporating the biological advanced treatment by the biofilm method in contact with the carrier 12 filled in the downward injection portion 11 can maximize the treatment efficiency A.

At this time, the micro-bubbles (3) generated from the pressurized water (1) injected through the downward injection portion 11 ascends through the upper portion (11a) and is converted into ultra-fine particles by the pressure gradually lowered depending on the water depth, the surface of the aggregates You can quickly injure up.

In addition, even when the treatment efficiency of the biofilm method decreases due to the change in load due to the shock of microorganisms, the water quality can be improved by physical and chemical treatments, so that the water quality of the effluent can be kept constant.

       7 and 8 illustrate still another embodiment of the present invention. The carrier 12 is formed on the upper portion 11a by the pressure portion floating method while passing through the downward injection portion 11. After the physical and chemical treatment is performed primarily, the treatment object 2 is raised through the upward portion 11a, and the advanced portion by biofilm method is brought into contact with the carrier 12 filled in the upward portion 11a. Can be made secondary.

       In this manner, the carrier 12 is formed on the downward injection portion 11 so that the advanced treatment is primarily performed by the biofilm method, and then the physical and chemical treatments are performed while rising through the upward portion 11a. It is another processing method for achieving the object of the present invention by forming only a method and a processing step sequence differently.

In addition, FIG. 9 shows a third embodiment of the present invention, in which two tanks of the reactor 10 are installed in series, and only one tank 12a is filled with the carrier 12 so that one tank of reactor 10a is provided. In the case of the biofilm, the advanced treatment is possible, and in another set of reactors 10b, the physical and chemical treatment is performed in parallel with the pressurization flotation method. It can be done sequentially.

In addition, the present invention can be formed in a modular form by forming a plurality of downward injection portion 11 formed with the carrier 12 in the reaction tank 10, as shown in Figure 11 and 12, this manner Is applicable when processing a large number of treatment targets.

       According to the present invention, by solving the necessity of a certain required area area, which is a disadvantage of the conventional biofilm method and the pressure injury method, it can be directly installed and processed in the area where pollution occurs, and the capacity of the module system can be easily expanded, and the sudden load change It is possible to solve the problems such as decrease in efficiency due to inadequate adaptation, decrease in efficiency due to toxic substances such as wastewater, shortage between treatment companies and energy cost reduction.

       In addition, it is expected to have side effects such as recycling of recycled water and prevention of dry weather due to direct discharge into the river due to the improvement of water quality due to the increase of treatment efficiency.

       1 is a process chart according to an embodiment of the present invention.

       2 is a processing step diagram of a state in which the downward injection portion is formed into a proliferation type.

       3 is a cross-sectional view in which the stationary phase carrier is vertically formed on the straight downward injection portion.

       Figure 4 is a cross-sectional view of the stationary phase carrier horizontally formed in the straight downward injection.

       5 is a cross-sectional view of the stationary phase carrier vertically formed in the proliferation-type downward injection.

       Figure 6 is a cross-sectional view of the stationary phase carrier horizontally formed in the proliferation-type downward injection.

       7 is a process chart according to another embodiment of the present invention.

       FIG. 8 is a process chart of a state in which the downward injection portion of FIG. 7 is formed into a proliferation expansion type. FIG.

       9 is a processing flowchart according to a third embodiment of the present invention.

       10 is a reaction state diagram of the micro-bubbles generated in the proliferation-type downward injection.

       Figure 11 is a longitudinal cross-sectional view of a reaction tank formed in a modular form applied to the present invention.

       Figure 12 is a cross-sectional view of a state in which the reactor is applied to the present invention in a modular form.

Explanation of symbols on the main parts of the drawing

1: pressurized water 2: water to be treated

3: microbubbles 4: aggregates

5: treated water 6: sprayed water

10: Reactor 11: Downstream Injection

11a: upper portion 12, 12a, 12b: carrier

13: backwash system 15: discharge channel

20: injection device 30: sludge suction device

40: dehydrator 50: compressor

60: chemical tank

Claims (9)

Pressurized water and the object to be treated are dissolved in the compressed air for the formation of chemicals and bubbles for the flocculation reaction in a state in which a carrier for forming a biofilm is filled in a reaction tank formed to be formed vertically up and down to maintain the depth of the water to be treated The water is injected to the bottom of the reaction tank, and the biological and advanced treatment by contact with the carrier, the coagulation reaction with the chemical by the pressurized water and the flotation effect of the flocculation by the microbubble are performed, and the physical and chemical treatment by the pressure flotation method is performed. A method of treating sewage, sewage, and wastewater using a large depth biofilm method and a large depth pressurized flotation method including a treatment process to make a large amount of water. The method of claim 1, wherein the pressurized water is repeatedly injected and stopped at predetermined time intervals so that the reaction tank is repeatedly formed in an aerobic state and an oxygen free state. Sewage, sewage, and wastewater treatment methods in parallel. The method for treating sewage, sewage, and wastewater according to claim 1, wherein a high-definition biofilm method and a deep-depth pressurized floatation method are injected in parallel into the reactor. 4. The sewage, sewage, and wastewater treatment according to claim 1 or 3, wherein the pressurized water and the high pressure jet water reuse the final treated water discharged after treatment. Way. Two reactors were installed in series to form the upper and lower sides so that the depth of the water to be treated can be kept high. One tank was filled with pressurized water in which chemicals and air were dissolved while a carrier for biofilm formation was filled. The water to be treated is injected to the bottom of the reaction tank, and only one pressurized water is injected to the bottom of the reaction tank so that the biological advanced treatment by the biofilm and the physical and chemical treatment by the pressure flotation are sequentially performed. A method for treating sewage, sewage, and wastewater using a large depth biofilm method and a large depth pressurization flotation method. It is formed up and down vertically and extends to the bottom, and is discharged through a downward injection portion 11 for injecting pressurized water and water to be treated, and a downward injection portion 11 to the outside of the downward injection portion 11. A carrier 12 for filling the inside of the reaction tank 10 having a double tube structure is capable of advanced processing by a biofilm method is formed, and an upward portion 11a is formed in which the pressurized water and the treatment target water rise. The sewage / sewage / wastewater treatment apparatus in which the high pressure jetting water injection device 20 is formed in the part 11a to prevent loosening of the micro bubbles, and combines a large depth biofilm method and a large depth pressurization method. 7. The apparatus for treating sewage, sewage, and wastewater according to claim 6, wherein the downward injection portion (11) is formed of a proliferation type of which a diameter changes with water depth. 8. The sewage and sewage of the deep-depth biofilm method and the large-depth pressurization buoyancy method according to claim 6 or 7, characterized in that the downward injection portion 11 is formed as a filtration medium so that the role of the fixed phase carrier is possible. Wastewater treatment device. 7. The apparatus for treating sewage, sewage, and wastewater according to claim 6, wherein the spraying device (20) is formed in the upper portion (11a) in multiple stages for each depth.