KR0183432B1 - Treatment apparatus of anaerobic waste water - Google Patents

Abstract

The present invention relates to an anaerobic wastewater treatment apparatus, and more particularly, to install the separator horizontally in the wastewater treatment vessel reactor in several stages, and by using a medium having a specific gravity lighter than water to fix the microorganisms with excellent efficiency An anaerobic wastewater treatment apparatus capable of continuously removing organic matter.

Description

Anaerobic Wastewater Treatment System

1 is a schematic view showing an example of a conventional anaerobic wastewater treatment apparatus.

2 is a structural diagram schematically showing an anaerobic wastewater treatment apparatus in which a separator is installed according to the present invention.

* Explanation of symbols for main parts of the drawings

1, 11: wastewater inlet 2, 12: reactor

3, 13: treated water outlet 4, 14: gas collection pipe

5: separator 6, 16: media

17 slant plate 18 gas-liquid separator

The present invention relates to an anaerobic wastewater treatment apparatus, and more particularly, to install the separator horizontally in the wastewater treatment vessel reactor in several stages, and by using a medium having a specific gravity lighter than water to fix the microorganisms with excellent efficiency An anaerobic wastewater treatment apparatus capable of continuously removing organic matter.

In general, biological treatment methods are divided into anaerobic treatment and aerobic treatment. The aerobic treatment method generates a lot of sludge in the wastewater treatment, and in the case of high concentration wastewater, the wastewater should be diluted about 20 to 30 times, resulting in an excessive increase in the required capacity of the aeration tank, and the cost increase due to the large amount of dilution water. It is a problem.

Anaerobic treatment, another biological treatment, is used for the treatment of high concentrations of organic wastewater such as sugar wastewater, alcoholic beverages and food wastewater. Anaerobic treatment can treat high concentrations of wastewater, and methane gas can be obtained as a by-product.However, wastewater and active microorganisms must be sufficiently in contact with the wastewater treatment. There is a problem that the start-up time is long.

The most important factor in the anaerobic wastewater treatment method is sludge retention time in the reactor, and the sludge residence time in the reactor must be increased to allow sufficient contact between the wastewater and the active microorganism. As a method of extending the residence time of sludge in a reactor, there are a method of attaching and fixing microorganisms to a carrier and a method of using self-immobilization of a medium.

Examples of the method using the double adherent microorganism include an UAF (Upflow Unaerobic Filter) method and a thin film method. In the UAF method, about two-thirds of the reactor is filled with media to attach microorganisms to the reactor, and the wastewater is operated in an upflow manner. Another method, a thin film method, is similar to the above UAF method, and uses a tube having an inner diameter of 5 to 10 cm as a medium, and operates a wastewater in a downflow manner.

However, the method of using the fixed-phase microorganism media as described above is expensive, and there are various problems such as the pores of the media is closed when there is a lot of suspended matter in the influent. To solve this problem, the Upflow Anaerobic Sludge Blanket Process using self-immobilization of microorganisms has been developed. This method uses the principle of self-granulation of highly active microorganisms, and has excellent sedimentation and sludge. Less loss of, no mechanical agitation required. However, the above method has considerable difficulty in granulating the sludge naturally, and there is a risk that the sludge blanket layer is destroyed when wastewater having a low concentration of organic matter is introduced.

A solution developed to solve this problem is a fluidized bed or an expanded bed method. These methods use fine particles such as sand as a medium and operate the reactor in an upflow manner, but have good sedimentability and excellent microbial retention ability, but there is a problem in that it takes a considerable power cost to float and mix the particles.

In addition, the upflow filtration method, the fluidized bed, or the expanded bed method are difficult to operate the reactor because there is a difference in the optimum conditions for the reaction of microorganisms at each stage of organic decomposition, that is, hydrolysis, oxidation, and methane production. have.

Meanwhile, an example of a conventional anaerobic wastewater treatment apparatus is shown in FIG. 1 of the accompanying drawings. First, when the wastewater to be treated is introduced through the wastewater inlet 11, a sludge layer is formed in a predetermined amount, which is a reaction tank with an upflow flow. (12) As it moves upwards, it undergoes hydrolysis, oxidation, methane production, etc., and the generated methane gas is collected in the gas collecting tube 14, and the sludge falls back to the bottom of the reactor 12, which is a gas-solid. Via the separator 18 through the inclined plate 17. And, the upper portion of the reaction tank 12, the filter medium 14 is installed to serve to minimize the sludge outflow and the finally treated waste water is discharged through the treated water outlet (13). The conventional anaerobic wastewater treatment apparatus does not need a filter using the principle that the microorganism granulates itself, but since the sludge layer that removes most of the organic matter is not separated and becomes one, the environment inside the sludge layer may be unstable.

Therefore, the present inventors have conducted research to solve the difficulty of granulation of the anaerobic wastewater treatment device and the difficulty of reactor operation due to the difference of the optimum reaction conditions, and thus, the shape of the network that cannot pass the inside of the reactor The anaerobic wastewater treatment system was developed by dividing into two separation plates and filling polymer media with specific gravity lighter than water in the separated space.

An object of the present invention is to provide an anaerobic wastewater treatment apparatus which can easily granulate microorganisms and provide optimum reaction conditions for each wastewater treatment step and a wastewater treatment method using the same.

Hereinafter, the present invention will be described in detail.

The present invention provides an anaerobic wastewater treatment apparatus consisting of a wastewater inlet, a reaction tank, a treated water outlet, and a gas collecting pipe, wherein a separator is installed in a layered structure inside the reactor, and a polymer medium is placed inside each separated layer. It is characterized by that the filling is made about ~ 3/4.

The present invention will be described in more detail as follows.

The present invention relates to an anaerobic wastewater treatment apparatus provided with a separator plate, the anaerobic wastewater treatment apparatus of the present invention is as schematically shown in FIG.

When described in detail based on the accompanying drawings, the overall configuration consists of wastewater inlet (1), the reaction tank (2), the treated water outlet (3) and the gas collecting pipe (4) and the separation plate in a layered structure inside the reaction tank (2) (5) is provided and the filter medium 6 is filled in each separated layer.

The wastewater treatment mechanism occurring in the present invention is the same as the wastewater treatment mechanism in a general upflow anaerobic wastewater treatment apparatus, and the influent flows from the lower portion of the reactor 2 through the wastewater inlet 1 and gradually moves to the upper layer. It is hydrolyzed, oxidized and then subjected to acetate and methanogenesis. However, in the wastewater treatment apparatus in which the inside of the reactor is integrated as in the prior art, the wastewater moves through the upflow stream before each stage is completely progressed, and thus, sludge formation is not easy and microorganisms may occupy the dominant species at each stage. It was difficult to control the optimal condition of the.

Therefore, in the present invention, the separator 5 is installed inside the reactor 2 and the polymer filter 6 is filled in each layer. In the present invention, the separator is preferably in the form of a mesh made of polyethylene, polypropylene, nylon or polyester so that the polymer media filled in each layer does not pass and the treated water can move. It should be smaller than the size of the media (6) particles.

Polymeric media (6) that can be used in the present invention is a polyurethane-based media with a specific surface area of 95 ~ 150m ² / m ³ , so as to sufficiently extend the residence time of the microorganism in the reaction tank, specific gravity is preferably smaller than water 0.8-0.95, most preferably 5-50 mm in diameter.

Here, the specific surface area of the polymer medium is to be 95m ² / m ³ or more in order to improve the adhesion performance of the microorganism, particularly preferably the specific surface area is 95 ~ 150m ² / m ³ . In addition, if the specific gravity of the polymer media is heavier than water, it sinks in the reactor to reduce the efficiency of wastewater treatment. If the diameter is smaller than 5 mm, the diameter of the polymer media is 5 ~ It is preferable that it is 50 mm.

In this way, when the separation plate 5 is installed inside the reactor 2, the first separation plate is installed at a portion corresponding to 1/6 of the height of the entire reactor, and 1/12 to 1 / of the height of the entire reactor from the top thereof. Install 4 ~ 8 separator plates at equal intervals at 10 intervals.

Even at such intervals, the installation of the separator plate can sufficiently proceed each step from the inflow of the wastewater to the treatment. More specifically, the wastewater introduced through the wastewater inlet 1 is hydrolyzed in the lower layer. It is made, so that the hydrolysis from the bottom of the reactor is sufficiently made, and the layer to allow the microorganisms acting on the hydrolysis to occupy the dominant species.

Installing the separator as described above at a height of 1/6 from the bottom of the reactor is preferable because it can reduce the time for sufficient hydrolysis to occur, and the incoming waste water can be uniformly present in the reactor.

And 4-8 pieces of separator plates are installed in the upper part from the lowest part of the separating plate at the interval of 1 / 12-1 / 10 of the height of the whole reaction tank.

In the middle portion of the reaction tank separated by such a separator, acetic acid is finally produced at the site where the hydrolyzed treated water is moved upward in the lower layer to mainly oxidize the hydrolyzed substrate. The advantage that can be obtained by installing the separator as described above is that the dominant species acting on the oxidation of the substrate can sufficiently control the environment in which it grows, and there is sufficient time for such an action to occur.

In addition, the top of the reaction tank is a site where methanogenesis occurs, and the generated methane is collected in a gas collecting tube 4 installed at the upper part of the reaction tank and collected in a tank (not shown).

The reactor according to the present invention has a cylindrical shape, as shown in the accompanying drawings, and has an upper end in the form of a cone.

As described above, the separator is installed inside the reactor and the microbial media is filled to about 1/2 to 3/4. At this time, if the degree of filling of the microbial media is less than 1/2, there is a problem in that the treatment efficiency is lowered because the capacity of the microorganism is reduced. For example, when the gas exceeds 3/4, there is a problem that the fluid flow in the reactor is unstable due to excessive generation of gas.

The anaerobic wastewater treatment apparatus of the present invention can eliminate the difficulty in operating the reactor, and the microbial group acting on the reaction of each stage occupies the dominant species inside the stage, thereby maximizing the efficiency of the microorganisms acting on each reaction stage. can do. In addition, damage can be minimized in the event of an accident such as sludge particles in the reactor damaged by the impact during operation, it is possible to recover relatively quickly.

In addition, since the microorganism and the wastewater are mixed by the gas generated during the wastewater treatment reaction, there is no need for a special stirrer, thereby reducing the power cost.

In the wastewater treatment using the wastewater treatment apparatus of the present invention as described above, after 5 to 8 days have elapsed since the operation of the reactor was started, the microorganisms were attached to the media in the reactor, and after about 25 days had elapsed. The microbial membrane is sufficiently formed on the surface of the filter medium to allow steady operation.

The anaerobic wastewater treatment apparatus of the present invention is particularly useful for the treatment of wastewater, such as alcoholic wastewater, sugary wastewater or food wastewater.

Hereinafter, the present invention will be described in detail with reference to the following Examples, but the present invention is not limited by the Examples.

Example 1 and Comparative Example 1

Using the anaerobic wastewater treatment system according to the accompanying drawings, the organic matter load was 10kg COD / m ³ · D. Was measured. In the wastewater treatment apparatus of the present invention, the separator plate was made of a mesh type made of polyester, and each layer was filled with a specific surface area of 100 to 120 m ² / m ³ and a diameter of 5 to 10 mm. .

At this time, the period of microbial membrane formation in the media was given to 30 days, and the concentration of wastewater initially introduced was 2000 ppm. After the biofilm was formed, the concentration of the incoming wastewater to 10,000 ppm was given 45 days.

The results of the wastewater treatment in the same manner as above and the results of the wastewater treatment using the conventional anaerobic wastewater treatment apparatus as shown in FIG. 1 are compared. Are as shown in the following table.

From the results of the above table, the wastewater treatment using the anaerobic wastewater treatment device of the present invention, even if the concentration of the influent water is significantly changed than in the wastewater treatment using the conventional wastewater treatment device, the wastewater is uniformly removed with almost no change in the removal rate. It can be seen that processing.

Example 2 and Comparative Example 2

As shown in the following Table 2, a petrochemical wastewater having a COD concentration of 13,000 ppm was used as an initial inflow concentration of 3,200 ppm using a separator plate using a mesh screen between the same media as in Example 1 and a mesh-type screen made of nylon. Organic matter load 13kg COD / m Experiment with 50 days to raise to D.

The wastewater treatment in the same manner as described above is shown in Table 2 below.

On the other hand, the wastewater treatment using the conventional anaerobic wastewater treatment apparatus as shown in Figure 1 of the accompanying drawings in the same manner as in Example 2 as shown in Table 2 below.

As shown in Table 2, 13kg COD / m of organic matter load of petrochemical wastewater into the reactor in the steady state using the anaerobic wastewater treatment apparatus of the present invention. When applied in D, the removal rate was 81.3%, and it can be seen that it is superior to the wastewater treatment using the conventional anaerobic wastewater treatment apparatus.

Claims (1)

In the anaerobic wastewater treatment device comprising a wastewater inlet, a reaction tank, a treated water outlet, and a gas collecting pipe, and having a separator plate in a layered structure inside the reactor, a specific surface area of each separated layer is separated by a separator plate in the reactor. ~ 150m ² / m ^3, and a specific gravity of 0.8 ~ 0.95, anaerobic waste water treatment apparatus, it characterized in that the diameter is made by filling a polyurethane-based polymeric media than 5mm about 1/2 ~ 3/4.