KR100626180B1 - Method and Apparatus for the Biological Wastewater Treatment - Google Patents

Abstract

As a method for biological purification of wastewater, wastewater and gas are injected into the reaction tank 1 in which microorganisms are cultured through an outer tube 8 and an inner tube 9 installed at the center of the two-phase nozzle 2, respectively. The upper nozzle 2 is submerged perpendicularly to the wastewater in the reactor 1.

The inner tube placed so that the gas enters the center of the two-phase nozzle 2 forms an open annular space and is surrounded by the outer tube into which the wastewater flows. The mixture of waste water and gas flows while being circulated in the reactor 1. The inner tube into which gas is injected into the two-phase nozzle 2 has a predetermined interval h to form an outlet of the outer tube into which waste water is injected. The outlet of the outer tube and its two-phase nozzle (2) have a certain distance (A) from the bottom (4) of the reactor (1), which interval is less than half the height (H) of the wastewater contained in the reactor (1). high.

Biological wastewater treatment, sewage, water treatment

Description

Apparatus and method for biological wastewater treatment {Method and Apparatus for the Biological Wastewater Treatment}

The present invention is a method for biological purification of wastewater, and the wastewater and gas are injected into a reactor containing microorganisms through a two-phase nozzle in which two tubes are fitted on the same central axis, and the nozzle is immersed perpendicularly to the wastewater of the reactor. In the outer circumference of the inner tube where the gas is injected in the center of the nozzle, the outer tube through which the waste water is injected is wrapped, and the mixture of waste water and gas flows while being circulated inside the reactor.

In biological purification of waste water, organic harmful substances are converted into harmless substances by the consumption of oxygen by microorganisms. The waste water is purified in the reaction tank while acid is added to the microbial-water mixture. At this time, the waste water and the gas are continuously injected into the reactor and the microbial-waste mixture is discharged. Herein, the gas refers to air or pure oxygen gas containing sufficient oxygen.

Wastewater contaminated with organic matter arises from living quarters and various industrial activities. Processes are known for removing dissolved organic compounds by aerobic methods using microorganisms to purify such waste water. Most of these processes take place in large aeration tanks. Disadvantages of these processes are, for example, a lot of exhaust gases, which are generally known for their high odors, noise, high investment and power costs, and large area requirements.

In addition, methods are known for purifying wastewater in high-cylinder tower tanks, similar to deep aeration (DE-Z "Chemie-Ingenieur-Technik" 54 (1982), Nr. 11, 939-952). Due to unfavorable hydrodynamic relationships and relatively poor mass transfer conditions due to bubbles, the volumetric loading rate, ie the ratio of COD measured by pollutants to the volume and time of day of the reactor, is low. The volume load ratio of the prior art amounts to about 1 kg / m 3 d. At this time, the diffuser is made separately at the bottom of each tower reactor, in which the power is consumed relatively high.

On the other hand, the process mentioned at the outset according to EP 0 130 499 B1 shows higher loadings in wastewater treatment. The volume loading rate is obtained up to 70 kg / m 3 d. Reactors used in this process are called reflux reactors. This reactor is a cylindrical tank placed on a vertical axis, and the induction pipes which are open at both sides are vertically installed inside. Waste water and gas are injected into the tubes lying on the same central axis of the two-phase nozzle and sent into the induction pipe. The inner tube used for injecting gas from the two-phase nozzle is placed inside the outer tube for injecting wastewater. And the inner tube through which gas is injected protrudes from the lower part of the outer tube. During operation of the reflux reactor, reflux flows around the induction pipe, where wastewater and gas are mixed. The advantages of this reflux flow are the relatively uniform flow of the two phases, and the flow of oxygen, which is required for wastewater purification, is well transferred from the gas to the water to dissolve. In this known process, the gas enters the induction pipe from above, forming at least once complete reflux and exiting the reactor. However, a large amount of energy is required to supply the injected wastewater to prevent the gas injected into the induction pipe from forming and raising the fine bubbles and to send it down like a reflux stream.

The present invention is to solve this problem, it is possible to further reduce the investment cost and energy consumption by further improving the conventional process shown.

 The present invention as a means for solving the above problems, in the two-phase nozzle, the inner tube to which gas is injected is terminated at a certain point inside the interval from the outlet of the outer tube into which waste water is injected, the outlet of the outer tube is a reaction tank There is a distance from the bottom, which is more than half the height of the waste water contained in the reactor.

In the present invention, the circulating waste water and the gas are injected into each other at least spatially separated from the two-phase nozzle, whereby the gas is first diffused in the two-phase nozzle because the gas is injected into the tube shorter than the outer tube. And when the mixture of wastewater and gas is ejected from the two-phase nozzle, impulse transfer occurs from the mixture ejected from the two-phase nozzle to the wastewater in the reactor, whereby the gas further diffuses very finely and Sent to my floor. The downward flowing fluid of the gas and wastewater mixture strikes the bottom of the reactor and rises to form a reflux stream so that the gas is very evenly distributed in the reactor. Thus, the process of the present invention does not require an induction tube and a diffusion device such as commonly used ring or membrane dispersers. This reactor can be constructed very simply because it has no special internal device. Therefore, construction costs are very low. In addition, the absence of these internal devices can also reduce energy consumption.

1 is a block diagram of an apparatus for carrying out a process according to the invention.

Figure 2 is a cross-sectional view showing a large two-phase nozzle according to the present invention.

FIG. 3 is a block diagram illustrating a device expanded than the device shown in FIG. 1; FIG.

 Referring to the preferred embodiment according to the present invention in detail with the accompanying drawings as follows.

First, Figure 1 shows the configuration of an apparatus for carrying out the process according to the invention, Figure 2 is a cross-sectional view showing a large two-phase nozzle, Figure 3 is an expanded view of the apparatus shown in Figure 1 .

As shown in the figure, one two-phase nozzle 2 is placed vertically in the reactor 1, and the precise structure of this nozzle is as shown in FIG. It is contained in the waste water of the reaction tank during the process operation in the reaction tank 1. At this time, the outlet 3 of the two-phase nozzle 2 is spaced apart from the bottom 4 of the reactor at a predetermined interval A, which is at least half of the height H of the wastewater in the reactor 1. to be. The gas and wastewater mixture ejected from the two-phase nozzle 2 in the direction of the arrow 5 flow in the form of a reflux flow 6 indicated by dotted lines in the reactor 1.                 

The waste water to be purified is injected from the inlet tube 7 into the outer tube 8, which end is projected into the reactor 1 and forms part of the two-phase nozzle 2. One inner tube (9) is the end is located in the two-phase nozzle (2) to inject the gas entering the gas inlet tube (10). A waste water circulation pipe 11 is connected out of the reactor 1, which is also connected to the outer pipe 8. Waste water flowing out of the reaction tank 1 along the waste water circulation pipe 11 is injected into the reaction tank 1 together with the new waste water by the pump 12 and circulated. Gas is injected from the blower 13 into the two-phase nozzle 2. The pump 12 and the blower 13 ensure that the mixture of gas and waste water is ejected from the two-phase nozzle 2 at a sufficient speed.

In the two-phase nozzle 2, the ends of the outer tube 8 and the inner tube 9 lie on each other on the same central axis. 2 shows the two-phase nozzle 2 in a specific form. The outer tube 8 surrounds the inner tube 9 into which gas is injected at predetermined intervals so that an annular gap naturally occurs, and wastewater can pass through the space. The outlet range of the outer tube 8 is appropriately reduced in diameter, which at the same time is the outlet of the two-phase nozzle 2. The inner diameter of the inner tube 9 is denoted by dG, while the inner diameter of the outer tube 8 is denoted by dF in the range of its outlet 3. The ratio of dG to dF ranges from about 0.6 to 0.9, with 0.75 being the most suitable. The inner tube 9 is enclosed in the outer tube 8, the end 14 of which has a distance h from the outlet end of the outer tube 8, which must be at least five times greater than dF. .

The process according to the invention is carried out for example as follows:                 

Waste water to be purified is injected into the outer tube (8), meets the wastewater flowing out of the waste water conveying pipe 11 connected from the reaction tank (1) is injected into the two-phase nozzle (2). At the same time, gas is injected into the two-phase nozzle 2 along the inner tube 9. This fluid is controlled by the pump 12 and the blower 13, respectively, so that at a sufficient rate the gas first diffuses in the two-phase nozzle 2. When a mixture of wastewater and gas is ejected from the two-phase nozzle 2, impulse transfer takes place from the mixture ejected from the two-phase nozzle 2 to the wastewater in the reactor 1 from the wastewater contained in the reactor 1. By this impulse transfer, the gas is further diffused very finely and moved down in the reactor 1.

The mixture of gas and wastewater descends downward and strikes the bottom 4 of the reactor 1 to rise to form a reflux stream 6 so that the gas is very uniformly dispersed in the reactor 1. And the purified waste water flows out along the discharge pipe 15, like microorganisms in the reaction tank (1). These wastewaters and microorganisms are not shown here, but are separated from each other in a sedimentation unit set up later. This microorganism is largely returned to the reaction tank 1 along the microbial conveying tube 16, and the remaining microorganisms are discharged to the excess sludge.

The outlet of the two-phase nozzle 2 is located above the wastewater of the reactor 1, as already mentioned above, located about two thirds of the height H of the wastewater from the bottom 4 of the reactor 1. In the reactor 1, the gas is dispersed more or less from the blower 13 depending on the height of the inlet of the two-phase nozzle 2. The amount of gas corresponding to the injected gas is discharged out of the reaction tank through the gas discharge pipe 17.

Since the ratio of the height and diameter of the reactor 1 and the velocity of the waste water and gas in the two-phase nozzle 2 should be kept at fixed values for hydrodynamic reasons and the construction height of the reactor is limited by the reasons for energy, In order to treat a large amount of waste water, several two-phase nozzles 2 are installed in a supply pipe corresponding to one reactor. For example, referring to FIG. 3, three two-phase nozzles 2 are shown. The installation of several two-phase nozzles (2) in one reactor (1) has a secondary advantage, which is more strongly due to the collision effect of liquid flows where the diffusion of injected gas strikes the bottom and collides with each other. Happens.

Claims (10)

Waste water and gas are injected into the reactor containing microorganisms through two-phase nozzles with two tubes fitted at the center. The nozzles are immersed perpendicularly to the wastewater contained in the reactor, and the inner tube into which gas from the two-phase nozzles is injected. Is surrounded by an outer tube into which the waste water is injected to form an annular space, in which the mixture of waste water and gas circulates in the reactor for the biological purification of the waste water flowing. The end of the inner tube (9) into which the gas of the two-phase nozzle (2) is injected is formed inside the predetermined distance (h) from the end of the outer tube (8) into which the waste water is injected, The outlet 3 of the outer tube 8 and the outlet of the two-phase nozzle 2 are formed to be spaced apart from the bottom 4 of the reactor 1 by a predetermined distance A, and the interval is wastewater in the reactor 1. Apparatus for biological wastewater treatment, characterized in that greater than half the height (H). The method of claim 1, The outlet of the outer tube (3) and the outlet of the two-phase nozzle (2) is located at about two-thirds of the height of the wastewater in the bottom (4) of the reactor (1). The method according to claim 1 or 2, The spacing h between the end 14 of the inner tube 9 and the outlet 3 of the outer tube 8 is at least five times larger than the inner diameter dF of the outer tube outlet portion. Device for wastewater treatment.       The method according to claim 1 or 2, The waste water is injected into the outer tube (8) of the two-phase nozzle (2) by the pump (12). The method according to claim 1 or 2, Apparatus for biological wastewater treatment, characterized in that the wastewater is injected into the outer tube (8) of the two-phase nozzle (2) with the wastewater flowing out from the reaction tank (1). The method of claim 1, Apparatus for biological wastewater treatment, characterized in that the gas is injected into the inner tube (9) of the two-phase nozzle (2) by the blower. The method according to claim 1 or 2, Apparatus for biological wastewater treatment comprising installing two or more two-phase nozzles (2) in one reactor. Waste water and gas are injected into the reactor containing microorganisms through two-phase nozzles with two tubes fitted at the center. The nozzles are immersed perpendicularly to the wastewater contained in the reactor, and the inner tube into which gas from the two-phase nozzles is injected. Is surrounded by an outer tube into which the waste water is injected to form an annular space, in which the mixture of waste water and gas circulates in the reactor for the biological purification of the waste water. An end portion of the inner tube (9) into which the gas of the two-phase nozzle (2) is injected is formed inward from the end of the outer tube (8) into which the waste water is injected a predetermined distance (h); The outlet 3 of the outer tube 8 and the outlet of the two-phase nozzle 2 are formed to be spaced apart from the bottom 4 of the reactor 1 by a predetermined distance A, and the interval is wastewater in the reactor 1. Is greater than half the height H of; The waste water is injected into the outer tube 8 of the two-phase nozzle 2 by a pump 12; The gas is injected into the inner tube (9) of the two-phase nozzle (2) by a blower. The method of claim 8, Wherein the outlet of the outer tube (3) and the outlet of the two-phase nozzle (2) lie at about two-thirds of the height of the wastewater at the bottom (4) of the reactor (1). The method of claim 8, The waste water is injected into the outer tube (8) of the two-phase nozzle (2) with the waste water flowing out from the reaction tank (1).

Images