KR20190048270A - Double inclined plate for collecting microorganisms granule and apparatus usnig it - Google Patents

Abstract

The present invention relates to an apparatus for recovering microbial granule, which precipitates and recovers microbial granules having a gas pocket in a wastewater treatment apparatus using granular microorganisms. The apparatus of the present invention comprises: a treatment tank (10) having an inflow water pipe (11) and an outflow water pipe (12) installed on an upper part thereof, and having a granule recovery pipe (13) for recovering microbial granule precipitated in a bottom surface (14); and a plurality of double inclined plates (20) installed at a predetermined interval on the upper part of the treatment tank (10), and including an ascending inclined surface (21) and a descending inclined surface (22) to allow inflow water to continuously ascend and descend. According to the present invention, additional maintenance costs can be reduced by utilizing a dual inclined plate fixed and installed without supplying an additional power source, and the efficiency of recovering microorganisms can be greatly increased by improving a precipitation rate of microbe granule.

Description

Technical Field [0001] The present invention relates to a double inclined plate for microbial granulation and a microbial granule recovery apparatus using the same,

The present invention relates to an apparatus for recovering microbial granules in a wastewater treatment apparatus using granular microorganisms.

In a variety of bioreactor processes, granules are useful microbial masses that maintain a certain amount or more in the bioreactor. Such a bioreaction process is not only an anaerobic deammonia reaction (anammox) for nitrogen wastewater treatment, but also a bioreactor in which a gravimetric microorganism predominates.

In general, anaerobic microorganisms are slower in growth and more sensitive to environmental factors than aerobic microorganisms. Therefore, microbiological loss prevention technology is needed to maintain stable process efficiency.

Conventional methods for recovering microorganisms for preventing microbial loss include a carrier immobilization method, a cyclone utilization method, and a natural sedimentation method.

First, the carrier immobilization method is a method in which a microorganism is immobilized on a carrier and is propagated or naturally formed granules are recovered and returned to the inside of the reactor. When immobilized on a carrier, a screen can be installed on the front side of the outflow pipe to prevent loss of the fluid. However, such a carrier immobilizing method is easy to recover, but there is a fear that an additional cost is incurred in the preparation and immobilization of the carrier, and the anammox bacteria that can not be immobilized on the carrier may be lost.

Next, in the method of recovering granule using cyclone, there is a disadvantage that an additional power ratio for operating a cyclone for sorting substances according to the specific gravity is generated, and a specific gravity of anammus granule is similar to that of water.

Next, the natural sedimentation method has a disadvantage that sedimentation is not easy because it contains nitrogen gas generated by anammox bacteria in the granule.

Korean Registered Patent No. 10-1450772 (issued October 16, 2014) Korean Registered Patent No. 10-0564993 (2006. 03. 28. Announcement) Korean Patent No. 10-1272016 (Announcement of Mar. 10, 2013)

Disclosure of Invention Technical Problem [8] To solve the above-described problems, the present invention provides a micro slurry for microbial granulation for removing precipitated microbial granules from a microbial granule having a nitrogen gas pocket therein and returning the recovered microbial granules to the reaction tank, And an object of the present invention is to provide a microorganism granule recovery device using the same.

In order to solve the above-described problems, the present invention provides a double slant plate for microbial granulation, comprising: a microbial granule having a plurality of microbial granules arranged at a predetermined interval on an upper part of a treatment tank for collecting and recovering microbial granules having gas pockets contained in inflow water; And is provided with an ascending slope surface (21) and a descending slope surface (22) so as to continuously raise and lower the inflow water.

Preferably, the microbial granules are microbial masses used in the anaerobic deammonia reaction for treating nitrogen wastewater.

Preferably, a plurality of protrusions (23, 24) are formed on the surface of at least one of the ascending slope (21) and the descending slope (22) to protrude in the flow direction of the inflow water so as to collide with the gas pocket do.

At this time, the protrusions 23 and 24 are staggered with respect to the flow direction of the inflow water so as to increase the collision frequency of the gas pocket.

The apparatus may further include a partition wall portion 30 extended to a lower portion of the body where the ascending slope 21 and the descending slope 22 are formed and spaced apart from the bottom surface 14 of the treatment tank 10 .

Preferably, upward sloping upward sloping surfaces 43 and 44 are formed on both sides of the lower portion of the body on which the ascending sloping surface 21 and the descending sloping surface 22 are formed.

A microbial granule recovery apparatus for recovering microbial granules having a gas pocket contained in inflow water by sinking the microbial granules comprises an inflow water pipe (11) and an effluent water pipe (12) A treatment tank (10) provided with a granule recovery pipe (13) for recovering microbial granules settled on the bottom surface (14); And a plurality of double swash plates (20) provided at an upper portion of the treatment tank (10) with a predetermined gap therebetween and having an ascending slope (21) and a descending slope (22) so that the inflow water is continuously lifted and lowered; And a control unit.

Preferably, the microbial granules are microbial masses used in the anaerobic deammonia reaction for treating nitrogen wastewater.

Preferably, each of the double swash plates 20 further includes a partition wall 30 extending downwardly from each of the double swash plates 20 and spaced apart from the bottom surface of the treatment tank 10.

Preferably, the bottom surface of the treatment tank 10 is formed to be inclined downward toward the granule recovery pipe 13, and the partition wall portions 30 have a downward length as they are relatively closer to the granule recovery pipe 13 And is formed to be long.

Preferably, the treatment tank 10 is installed in a partitioned space at the upper part of a microbial reactor having an agitator, and the inflow water pipe 11 is configured to introduce a reaction solution and a microbial granule into the microbial reactor, The pipeline 12 is connected to the effluent line of the microorganism reaction tank and the granule recovery pipe 13 is connected to the lower portion of the microorganism reaction tank.

Preferably, the treatment tank 10 is disposed apart from the microbial reaction tank, and the inflow water pipe 11 is connected to the outflow pipe of the microbial reaction tank, and the granule recovery pipe 13 is connected to the microbial reaction tank And a return line for re-supplying the microbial granules.

The present invention has the following effects.

First, the maintenance cost can be greatly reduced by using a fixed double slant plate without additional power source.

Second, the double slope plate can increase the sedimentation rate of the microbial granules and greatly improve the microbial recovery efficiency.

Third, the microbial granule recovery tank can be installed in connection with the inside of the microbial reactor, and the influence of the temperature change, which is a major factor affecting the biological reaction, can be blocked.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a sectional view showing a treatment tank provided with a double swash plate according to an embodiment of the present invention; FIG.
2 is a plan view of Fig.
3 is a perspective view showing a protrusion formed on an ascending slope constituting a double swash plate;
4 is a perspective view showing a protrusion formed on an ascending slope constituting a double swash plate;
5 is a front view of a dual swash plate according to another embodiment of the present invention.

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

As shown in FIGS. 1 and 2, the apparatus for recovering microorganism granules according to the present invention mainly comprises a treatment tank 10 for recovering microbial granules and a plurality of double swash plates 20 installed on the upper side of the treatment tank 10.

The treatment tank 10 includes an inflow water pipe 11 connected to an outflow pipe of a microorganism reaction tank (not shown), an effluent pipe 12 for discharging the supernatant in which the microorganism granules are precipitated, And a granule recovery pipe (13) for recovering the granules.

The microbial reaction tank (not shown) may be equipped with a stirrer to increase the reaction efficiency as a space where the microbial reaction takes place. The treatment tank 10 constituting the present invention is constituted such that a rectangular space is defined on the upper surface of the microbial reaction tank so that the reaction liquid and the microbial granules flow into the inflow water pipe 11 of the treatment tank 10, (12) may be connected to the effluent line of the microbial reaction tank, and the granule recovery pipe (13) may be connected to the transfer pipe leading to the lower portion of the microbial reaction tank.

By disposing the treatment tank 10 in the microorganism reaction tank as described above, it is possible not only to improve the treatment space efficiency but also to prevent the influence on the temperature change, which is a major factor affecting the biological reaction.

On the other hand, as described above, the treatment tank 10 may not be provided on the upper portion of the microorganism reaction tank but may be provided in a separate space adjacent to the microorganism reaction tank. In this case, the inflow water pipe 11 is connected to the outflow pipe of the microbial reaction tank. The granule recovery pipe 13 may be configured as a return line for re-feeding the microbial granules back into the microbial reactor.

A plurality of double swash plates (20) for microbial granulation with gas pockets are provided at predetermined intervals in the direction of flow of the inflow water. Respectively.

The microbial granules are applicable not only to a mass of microbial communities used in an anaerobic deammoniation reaction for treating nitrogen wastewater but to granule type microbes having gas pockets.

Specifically, the double swash plate 20 includes the ascending slope 21 and the descending slope 22 so that the inflow and outflow of the inflow water are continuously performed.

At this time, as shown in FIGS. 3 and 4, a plurality of protrusions 23 (not shown) protruding from the surface of at least one of the ascending slope 21 and the descending slope 22 , 24 are formed. The protrusions 23 and 24 may have various shapes such as a cylinder, a triangular prism, and a square prism. The protrusions 23 and 24 collide with the gas pocket to function to sink the microbial granules by removing gas pockets of the microbial granules.

The protrusions 23 and 24 may be formed of a plurality of rows and / or columns, and are preferably staggered with respect to the flow direction of the inflow water so as to increase the frequency of collision of gas pockets.

The gas pocket removing efficiency can be further improved by providing the ultrasonic wave applying means in at least one of the above-mentioned elevation slope 21, the downward slope 22, and the protrusions 23 and 24.

The apparatus further includes a partition wall portion 30 extending to a lower portion of the body where the ascending slope 21 and the descending slope 22 are formed and spaced apart from the bottom surface of the treatment tank 10.

The partition wall 30 functions to improve the sedimentation efficiency by increasing the residence time of the microbial granules having the a-pocket in the treatment tank 10.

In order to improve the recovery efficiency of the sedimented microbial granules, the bottom surface 14 of the treatment tank 10 is formed to be inclined downward toward the granule recovery pipe 13.

The partition wall portions 30 are formed to have a longer downward length in the vicinity of the granule recovery pipe 13 so as to be closer to the bottom surface 14 of the treatment tank 10, It is desirable to increase the residence time.

The double swash plate 40 according to another embodiment of the present invention is as shown in Fig.

There is a difference in that upward sloping upward sloping surfaces 43 and 44 are formed on both sides of the lower portion of the body on which the ascending sloping surface 41 and the descending sloping surface 42 are formed in comparison with the double swash plate 20 of the above- These upward inclined surfaces 43 and 44 function to smoothly float the microbial granules having gas pockets without stagnation in the lower part of the body.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken in conjunction with the language of the present invention.

10: Treatment tank 11: Influent piping
12: Effluent piping 13: Grinding rate recovery piping
14: bottom surface 20, 40: double swash plate
21, 41: ascending / descending slope 22, 42: descending slope
23, 24: projecting portion 30: partition wall portion
43, 44: upward slope

Claims (12)

A double slanting plate for microbial granulation as set forth in claim 1, wherein a plurality of microbial granules are disposed at a predetermined interval above a treatment tank (10) for collecting and recovering microbial granules having gas pockets contained in inflow water,
And a descending slope (21) and a descending slope (22) are provided on the upper part of the treatment tank (10) to continuously raise and lower the inflow water. The method according to claim 1,
Wherein the microbial granule is a microbial community mass used in an anaerobic deammonia reaction for nitrogen wastewater treatment. The method according to claim 1,
Wherein a plurality of projections (23, 24) are formed on the surface of at least one of the ascending slope (21) and the descending slope (22) so as to protrude in the flow direction of the inflow water so as to collide with the gas pocket Double reciprocating swash plate. The method of claim 3,
Wherein the protrusions (23, 24) are staggered with respect to the flow direction of the inflow water so as to increase the frequency of collision of gas pockets. The method according to claim 1,
And a partition wall portion 30 extending from the bottom of the body where the ascending slope 21 and the descending slope 22 are formed and spaced apart from the bottom surface 14 of the treatment tank 10 A double slurry for microbial granulation. The method according to claim 1,
Wherein upward sloping upward inclined surfaces (43, 44) are formed to both sides of the lower portion of the body on which the ascending slopes (21) and the descending slopes (22) are formed. CLAIMS 1. A microorganism granule collection device for withdrawing microbial granules having a gas pocket contained in an influent,
A treatment tank 10 provided with an inflow water pipe 11 and an effluent water pipe 12 at an upper portion thereof and a granule recovery pipe 13 for recovering microbial granules settled on the bottom surface 14; And
A plurality of double swash plates 20 provided at an upper portion of the treatment tank 10 at predetermined intervals and having a rising slope 21 and a falling slope 22 so that the inflow and outflow of the inflow water are continuously performed; Wherein the microbial granule collection device comprises: 8. The method of claim 7,
Wherein the microbial granule is a microbial community mass used in an anaerobic deammonia reaction for nitrogen wastewater treatment. 8. The method of claim 7,
Further comprising a partition wall (30) extending downwardly from each of the double swash plates (20) and spaced apart from a bottom surface of the treatment tank (10). 9. The method of claim 8,
The bottom surface of the treatment tank (10) is formed to be inclined downward toward the granule recovery pipe (13)
Wherein the partition wall portions (30) are formed to have a longer length downward as they are relatively closer to the granule recovery pipe (13). 8. The method of claim 7,
The treatment tank 10 is installed in a partitioned space in the upper part of the microorganism reaction tank having an agitator,
The inflow water pipe (11) is configured such that a reaction liquid and a microbial granule are introduced into the microbial reaction tank,
The effluent pipe (12) is connected to an effluent line of the microbial reaction tank,
Wherein the granule recovery pipe (13) is connected to the lower portion of the microorganism reaction tank. 8. The method of claim 7,
The treatment tank (10) is disposed apart from the microorganism reaction tank,
The inflow water pipe (11) is connected to an outflow pipe of the microorganism reaction tank,
Wherein the granule recovery pipe (13) comprises a return line for re-supplying the microbial granules to the microbial reaction tank.

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