KR101246500B1 - waste water treatment device using gas-lift anaerobic reactor - Google Patents

Abstract

The present invention relates to a wastewater treatment apparatus using a gas lift anaerobic microbial reactor, the gas-liquid separator 30 is installed in the gas circulation pipe 20 via the microbial reactor (10).
The gas-liquid separator 30 includes a water jacket 32 through which coolant is circulated, and a baffle 33 connected to the water jacket 32 protrudes into the gas-liquid separator 30.
Accordingly, when the circulating gas passing through the gas-liquid separator 30 contacts with the baffle 33, water is condensed and removed, thereby reducing the performance of the gas circulation pump 40 due to water.

Description

Waste water treatment device using gas-lift anaerobic microbial reactor

The present invention relates to a wastewater purification apparatus using an anaerobic microbial reactor, and more particularly, to a wastewater treatment apparatus equipped with a gas lift type reactor.

The anaerobic microbial reactor is a facility for purifying wastewater by using anaerobic metabolism of anaerobic microorganisms.

In the anaerobic microbial reactor, microorganisms are attached to media, carriers, thin films, etc., which are installed inside the reactor.

The present invention provides a gas lift anaerobic microbial reactor that is capable of efficiently removing moisture from the gas lift circulating gas to prevent the reduction and failure of the gas circulation pump and to easily discharge the water removed from the circulating gas to the outside of the apparatus. The purpose is to provide a wastewater treatment apparatus.

The present invention for achieving the above object,

Microbial reaction tank;

A gas circulation pipe passing through the microbial reaction tank;

A gas-liquid separator installed in the gas circulation pipe;

It includes.

In addition, a water jacket is installed in the gas-liquid separator,

The baffle connected to the water jacket is characterized in that the protrusion formed into the gas-liquid separator.

In addition, a condensation pin is formed on the baffle.

In addition, the baffle is characterized in that the end is installed inclined in a low state.

In addition, a water cooler is connected to the water jacket.

In addition, a cone-shaped portion is formed in the lower portion of the gas-liquid separator,

Condensate discharge pipe is formed at the end of the cone-shaped portion,

Opening valve is characterized in that the condensate discharge pipe is installed.

In addition, the inside of the baffle is characterized in that the guide plate for forming a cooling water circulation path is installed.

In addition, other gas-liquid separators same as the gas-liquid separator are further connected in series to the gas circulation pipe.

According to the present invention as described above,

By using the gas-liquid separator, water can be effectively removed from the circulating gas circulating in the gas lift microbial reactor, thereby preventing the performance and durability of the gas circulation pump due to water.

In addition, the temperature of the circulating gas is reduced when passing through the gas-liquid separator so that water condensation does not occur in the gas circulation pump, thereby preventing the performance and durability of the gas circulation pump due to moisture.

In addition, when using a dehumidifier filled with a dehumidifying agent in the container together with the gas-liquid separator, there is an advantage that the service life of the dehumidifier is extended.

In addition, there is an advantage to discharge the separated water through the gas-liquid separator to the outside of the device.

1 is a block diagram of a wastewater treatment apparatus according to the present invention,
Figure 2 is a modified embodiment of the gas-liquid separator is the main configuration of the present invention,
Figure 3 is another embodiment of the gas-liquid separator,
4 is a block diagram of the wastewater treatment apparatus of the present invention having a plurality of gas-liquid separators.

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

As shown in FIG. 1, the present invention provides a microbial reaction tank 10, a gas circulation pipe 20 passing through the microbial reaction tank 10, and a gas-liquid separator 30 installed in the gas circulation pipe 20. Include.

The microbial reaction tank 10 is a container closed to the outside is provided with media, carriers, thin films and the like attached to the microorganisms inside, the waste water inlet pipe 11 and the waste water discharge pipe 12 is provided with a whole waste water purification facility In the microbial reactor 10, wastewater is introduced from the facility before the wastewater is discharged to the facility after the purification operation.

The gas-liquid separator 30 has a cylindrical empty container shape, and a water jacket 32 surrounding the outer portion is installed, and a plurality of baffles 33 connected to the water jacket 32 are installed therein.

The baffle 33 protrudes into the gas-liquid separator 30, and the inside of the baffle 33 is empty so that the coolant may flow from the water jacket 32.

In addition, a plurality of condensation pins 34 protrude downward from the bottom surface of the baffle 33.

In addition, the lower portion of the gas-liquid separator 30 is formed in a cone shape (cone-shaped portion; 35), the condensate discharge pipe (35a) is connected to the lower end of the cone-shaped portion 35, opening and closing to the condensate discharge pipe (35a) The valve 36 is installed.

The on-off valve 36 may be manually operated as well as automatically operated by a control signal generated from a control unit of the wastewater treatment facility.

Meanwhile, a water cooler 37 is connected to the water jacket 32.

The water inlet pipe 37a of the water cooler 37 is connected to the lower portion of the water jacket 32, and the water discharge pipe 37b is connected to the upper portion of the water jacket 32.

The water inlet pipe 37a is provided with a cooling water pump 38 for cooling water circulation.

Therefore, the coolant discharged from the water cooler 37 is repeatedly cooled in the water cooler 37 while circulating a path returning to the water cooler 37 via the water jacket 32, and thus the water jacket (32) The cooling water inside maintains a low temperature state in which water can be condensed from the circulating gas.

On the other hand, the circulating gas discharged from the microbial reaction tank 10 is introduced into the lower portion of the gas-liquid separator 30 along the gas circulation pipe 20 to pass through the inside of the gas-liquid separator 30 and then discharged upward.

The circulating gas includes a large amount of water while passing through the microbial reaction tank 10, and the circulating gas contacts the baffle 33 while passing through the gas-liquid separator 30, wherein the circulating gas is included in the circulating gas. Moisture condenses on the low temperature baffle 33 surface.

Since the condensation pin 34 increases the surface area of the baffle 33, a larger amount of moisture may condense by increasing the contact amount of the circulating gas.

Therefore, the circulating gas from which the water is removed as described above is discharged to the outside of the gas-liquid separator 30 and resupplied to the microbial reaction tank 10.

Meanwhile, a gas circulation pump 40 is installed in the gas supply pipe 21 serving as a path for supplying gas to the microbial reaction tank 10 of the gas circulation pipe 20.

However, moisture contained in the gas flowing into the gas circulation pump 40 is condensed inside the gas circulation pump 40, thereby lowering the performance of the pump and lowering durability.

However, since the present invention removes the water contained in the circulating gas in advance in the gas-liquid separator 30, the performance and durability of the gas circulation pump 40 due to moisture can be prevented.

In addition, in the gas-liquid separator 30, condensation of the gas circulation pump 40 may be prevented by removing water and decreasing the temperature of the circulating gas. In particular, in the summer as well as in the winter when the temperature of the gas circulation pump 40 drops significantly, the water does not condense on the gas circulation pump 40, thereby preventing the performance and durability of the gas circulation pump 40 due to moisture. .

Meanwhile, a dehumidifier 50 filled with a dehumidifying agent may be installed between the gas-liquid separator 30 and the gas circulation pump 40.

Therefore, by removing the water contained in the circulating gas more reliably, it is possible to more reliably prevent the problem of deterioration in stability of the gas circulation pump 40 due to water.

On the other hand, since the circulating gas in which moisture is first removed by the gas-liquid separator 30 flows into the dehumidifier 50, the dehumidifier 50 can be used for a relatively long period of time compared to the case where only the dehumidifier is installed alone. .

Therefore, the frequent replacement of the dehumidifier 50 is not necessary.

On the other hand, the water condensed on the surface of the baffle 33 and the condensation pin 34 in the gas-liquid separator 30 drops into the lower portion of the gas-liquid separator 30.

Since the droplets are collected in the cone-shaped portion 35 below the gas-liquid separator 30, the operator directly opens or closes the open / close valve 36 or the open / close valve 36 is opened at a predetermined time by the control unit. From 30).

On the other hand, as shown in Figure 2, the baffle 33 may be installed to be inclined in a state where the portion connected to the water jacket 32 is high and the end protruding therefrom is low.

Even in this case, the condensation pins 34 protrude in the direction of gravity, that is, vertically downward, rather than maintaining a right angle with respect to the baffle 33.

The structure as described above allows the water droplets condensed on the surfaces of the baffle 33 and the condensation pins 34 to move downward and fall more easily.

Accordingly, the water removal performance is further increased by preventing contact between the surfaces of the baffles 33 and the condensation pins 34 and the water in the circulating gas by the water film formed on the baffles 33 and the condensation pins 34.

In addition, the inside of the baffle 33, as shown in Figure 3, the guide plate 33a is provided.

The guide plate 33 is installed along the longitudinal direction of the internal space of the baffle 33, and divides the internal space of the baffle into two, and the two divided spaces are connected at the end side of the baffle 33.

Therefore, the cooling water passage is formed to circulate the inside of the baffle 33, the inlet and discharge of the coolant to the inside of the baffle 33 can be made more smoothly to keep the surface temperature of the baffle 33 lower moisture removal performance This is improved.

In addition, the present invention can be used by connecting a plurality of the gas-liquid separator 30 in series, as shown in FIG.

In this case, as the number of gas-liquid separators 30 repeatedly removes water from the circulating gas, most of the water in the circulating gas may be removed, thereby causing a problem of deterioration of the efficiency of the gas circulation pump 40 due to moisture. You will not.

10: microbial reaction tank 11: wastewater inlet pipe
12: wastewater discharge pipe 20: gas circulation pipe
21: gas supply pipe 30: gas-liquid separator
32: water jacket 33: baffle
34: condensation pin 35: cone shape
35a: condensate discharge pipe 36: on-off valve
37: water cooler 37a: water inlet pipe
37b: water discharge pipe 38: cooling water pump
40 gas circulation pump 50 dehumidifier

Claims (8)

delete Microbial reaction tank;
A gas circulation pipe passing through the microbial reaction tank;
A gas-liquid separator installed in the gas circulation pipe;
Including;
Water jacket is installed in the gas-liquid separator,
The baffle connected to the water jacket is formed to protrude into the gas-liquid separator,
Wastewater treatment apparatus using a gas lift anaerobic microbial reactor, characterized in that the guide plate for forming a cooling water circulation path is installed inside the baffle. The method according to claim 2,
A condensation pin is formed on the baffle. The method according to claim 2,
The baffle wastewater treatment apparatus using a gas lift anaerobic microbial reactor, characterized in that the end is installed inclined in a low state. The method according to claim 2,
Wastewater treatment apparatus using a gas lift anaerobic microbial reactor, characterized in that the water jacket is connected to the water jacket. The method according to claim 2,
Cone-shaped portion is formed in the lower portion of the gas-liquid separator,
Condensate discharge pipe is formed at the end of the cone-shaped portion,
Waste water treatment apparatus using a gas lift anaerobic microbial reactor, characterized in that the opening and closing valve is installed in the condensate discharge pipe. delete The method according to claim 2,
And another gas-liquid separator identical to the gas-liquid separator connected to the gas circulation pipe in series.

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