KR200295350Y1 - Sludge discharger using lumped air - Google Patents

Abstract

The present invention relates to an apparatus for discharging sludge using a bubble mass, and more particularly, it is installed at a lower part of a sludge stack such as a sedimentation tank of a biological wastewater treatment device or a lower part of a reactor or a reservoir, and is generated when the air is collected and discharged at once. It relates to a device for discharging the sludge deposited by using a bubble mass.

To this end, in the present invention, a tubular discharge pipe having a sludge inlet at the bottom, an outlet at the top, and an air inlet formed through the side wall of the lower region, and coupled to the discharge pipe at the upper portion of the air inlet, have a lower downward opening than the inlet. A guide member forming a space and an air guide coupled to the discharge pipe in the guide space and extending radially outwardly and upwardly from a lower portion of the air inlet, a compressor for generating discharge air, and the guide space of the guide member. And an air supply pipe for delivering the discharged air from the compressor. As a result, a sludge discharge device that can easily discharge sludge deposited on a sedimentation tank or a reactor bottom and a reservoir by using bubble masses is provided.

Description

Sludge discharger using lumped air

The present invention relates to an apparatus for discharging sludge, and more particularly, a device for pulling up and discharging sludge deposited on the bottom of water and sludge deposited on the bottom of a reactor or settling tank out of the water surface by using a bubble mass.

Since the 1970's, when industrial development began to develop rapidly, many factories have entered the country and the population has been concentrated into cities, and huge amounts of factory sewage and domestic sewage have been discharged. As a result, these sewage flows into rivers and reservoirs, causing serious pollution, and the bottom of the river is also contaminated with sludge in which wastewater floats are deposited. In the case of water reservoirs and reservoirs storing constant water, contamination by the main metal components contained in the flocculant is also serious because the flocculant is deposited when the algae is generated or turbidity is high. Therefore, to maintain clean, uncontaminated water quality, it is necessary to periodically remove deposits at the bottom of the bed.

The mechanical sludge discharge device installs a dredger on the surface of the water, and a mechanical sludge discharge device is installed on the dredger. Mechanical sludge discharge device has a central axis formed in the center, the central axis has a tubular long sludge discharge pipe is installed so that the screw can be rotated, the power unit for rotating the screw is installed. After the sludge intake was submerged to the sludge deposit in the bed, the sludge was discharged through the sludge discharge pipe by rotating the screw in the power unit.

On the other hand, in order to discharge the sludge, in addition to the above discharge device, a vacuum pump is installed in the discharge pipe, or an air lift pump (Air-lift pump) is used to install.

The prior art as described above has the following disadvantages in each case.

Mechanical discharge device, the configuration of the equipment is complicated and costly, and there is a disadvantage that can not work in deep water. In addition, since the mechanical discharge device works while the screw is continuously excavating the bottom surface to discharge the sludge, the surrounding sludge is suspended to increase turbidity.

When the vacuum pump is used as the discharge power, the sedimentation tank where the sludge is located, the lower part of the reactor, and the bottom of the reservoir are under high water pressure, so a lot of power is required when the sludge is taken out. .

On the other hand, an air-lift pump discharges water and sludge by the buoyancy movement of small air bubbles generated by injecting compressed air from the intake port of water toward the discharge pipe. Therefore, it is not possible to generate a high discharge force has a disadvantage that the sludge with a large specific gravity is not discharged, the discharged concentration is low and the discharged area is narrow.

As such, the conventional sludge discharging technique is complicated in configuration and has various problems in terms of cost and function and efficiency of the equipment.

Accordingly, an object of the present invention is to provide a sludge discharge device that effectively discharges sludge and prevents the sludge from floating while using a device of a simple structure to solve the above problems.

To this end, by collecting air without using small air bubbles such as air lift to form a bubble lump to generate a high discharge force to discharge the sludge with a high specific gravity and to provide a large discharge area sludge discharge device.

1 is a cross-sectional view of the sludge discharge apparatus

Figure 2 is a schematic view of the sludge discharge apparatus installed in the sludge deposited sludge, such as sedimentation tank or reactor lower portion deposited

Figure 3 (A) (B) is an exemplary view showing the sludge discharge of the embodiment

<Description of the code | symbol about the principal part of drawing>

1: discharge pipe 3: sludge intake port

5: guide member 7: sludge discharge port

9: compressor 11: supply pipe

13: Information space 15: Air inlet

17: suction baffle 19: air guide

21: sludge deposited layer 23: bubble mass

25: discharge sludge

According to the present invention, in the sludge discharge device, a tubular discharge pipe having a sludge inlet at the bottom, an outlet at the top and an air inlet formed through the side wall of the lower region, and coupled to the discharge pipe at the upper portion of the air inlet, A guide member having a wide downward opening to form a guide space, an air guide coupled to the discharge pipe in the guide space and extending radially outwardly and upwardly from a lower portion of the air inlet, and a compressor for generating outgoing air; It is achieved by an air supply pipe for delivering the discharged air from the compressor in the guide space of the guide member.

Here, it is preferable to further include a suction baffle extending downward from the bottom of the discharge pipe and gradually expands downward.

Hereinafter, described with reference to the accompanying drawings, preferred embodiments of the present invention is as follows.

1 is a cross-sectional view of the sludge discharge device, Figure 2 is a schematic view of the sludge discharge device installed in the sludge deposited sludge, such as the sedimentation tank or the reactor bottom, Figure 3 (A) (B) is the process of the sludge discharged It is an exemplary view showing the.

As shown in Figs. 1 and 2, the tubular elongated discharge pipe 1 extends from the water surface to the bottom of the lower bed and collects air in the sludge inlet port 3 formed at the lower end of the discharge pipe 1. (5) and a compressor 9 for injecting air into the guide member 5 from the outside.

The discharge pipe 1 extends a predetermined length toward the sludge sludge inlet 3 from the portion connected with the guide member 5 into the guide member 5. A suction baffle 17 is formed which extends downwardly from an end of the discharge pipe 1 and is widened. The suction baffle 17 of the discharge pipe 1 is located in the guide member 5 of the discharge pipe 1. An air guide 19 is provided upwardly along the longitudinal direction to accommodate the air inlet 15. In the lower region of the discharge pipe (1) where the air guide (19) is formed, an air inlet (15) penetrates through at least one side wall for discharging the volume of air to the guide member (5) through the air supply pipe (11). It is. At this time, the air guide 19 is a cylindrical shape of the upward opening or funnel and conical shape.

The guide member 5 is formed downward in the lower end of the discharge pipe 1, and is formed wider than the diameter of the discharge pipe (1). On one side of the outer wall of the guide member 5, an air supply pipe 11 is formed which communicates with the air by inducing air supplied from the compressor 9. The air supply pipe 11 may be bent through the open lower end of the guide member 5 so that the air supply port is upward.

The compressor 9 which injects air into the guide member 5 supplies air into the guide member 5 through the air supply pipe 11 as a kind of air injection pump. At this time, the pressing force of the pump is selected by using a pump having a sufficiently strong supply capacity in consideration of the water pressure.

(A) and (B) of FIG. 3 illustrate sludge discharge by injecting air, and as shown in FIG. (A), the sludge discharge device is installed by submerging the guide member 5 to the sludge deposition layer 21. After that, when the compressor 9 is operated, pressurized air is introduced into the guide member 5 along the air supply pipe 11.

And (B) illustrates that the bubble mass and the sludge is deposited through the sludge discharge device, the air introduced into the guide member 5 through the air supply pipe 11 by the compressor 9 is a guide member In the guide space (13) existing in the (5) is changed to a bubble form to rise upward by buoyancy. Then, these air bubbles are accumulated along the upper wall of the upper portion of the guide member 5 to form a bubble space, and the bubble space continues to expand while lowering the water at the upper end of the guide member 5 by buoyancy of air. Push it out. When the bubble space formed in this way continues downward in the guide member 5 to the air inlet 15 at the lower end of the discharge pipe 1 accommodated in the air guide 21, the air in the bubble space without additional power is generated. Is a large bubble lump 23 (air slugging phenomenon) is discharged to the discharge pipe (1) through the air inlet (15). At this time, the force discharged is proportional to the size of the bubble lump, and the air of the huge bubble is discharged by the buoyancy of the volume as much as the space of the air guide 19 discharged through the air inlet 15 and the water pressure around it do. At the same time, the sludge 21 at the bottom of the suction baffle 17 is sucked into the sludge intake port 3 while the cavity phenomenon is generated at the place where the bubbles are discharged, and together with the bubble mass 23 to the outside through the discharge pipe 1. Discharged rapidly.

As described above, the air supplied via the air supply pipe 11 fills the guide space 13 and the air guide 19 of the guide member 5, and the air flows into the discharge pipe 1 through the air inlet 15. The sludge is discharged periodically while the discharge process is repeated at regular intervals.

On the other hand, the air is injected from the outside through the air supply pipe 11, the volume of air in the guide member 5, the air from the top of the guide member 5 to the air inlet 15 formed in the lower end of the discharge pipe 15 To be filled, a certain amount of time is required depending on the air injection speed. In other words, if the speed of air injection is fast, it takes a short time, and if it is slow, it takes a long time. This is closely related to the time interval for discharging the sludge, there is an advantage that the sludge discharge interval can be arbitrarily adjusted by adjusting the air injection speed of the compressor (9). In addition, since the pressure discharged through the discharge pipe 1 increases in the depth of water, the sludge can be easily discharged even in a reservoir or a deep water bed.

In addition, when the sludge is discharged together with the water from the lower end of the suction baffle 17, the surrounding water flows, causing turbulence, which may cause the sludge to float, so that the trumpet-shaped suction baffle 17 blocks the floating sludge. As a result, the sludge is spread to the periphery to prevent it from floating and increasing turbidity.

Due to the installation of the suction baffle 17 and the guide member 5 compared to the air lift area is limited to the sludge suction port 3 can be discharged a large area of sludge.

As such, the sludge discharge device according to the present invention, when the guide member 5 having the sludge suction port 3 is installed on the bottom of the lower bed or the reservoir, the sedimentation tank and the bottom of the reactor, where the sludge is deposited, and the air is injected from the outside. The sludge in the lower bed is discharged at regular intervals together with the bubble-type air, so that the sludge can be easily discharged even with a small amount of power. When the suction baffle 17 is provided in the sludge intake port 3, sludge floating phenomenon generated during sludge discharge is provided. Can also be prevented.

On the other hand, in the configuration of the present invention described above, the structure including both the discharge pipe 1, the suction baffle 17 and the air guide 19 including the guide member (5). However, in the above configuration, even if the suction baffle 17 is excluded from the configuration of the present invention, only the guide member 5, the air guide 19, the air supply pipe 11, and the discharge pipe 1 are necessary for the basic sludge discharge function. There is no obstacle.

As described above, according to the present invention, by providing a guide member for collecting air, a compressor for injecting air, and a discharge pipe having a suction baffle and an air guide for inducing air flow at the sludge inlet, the bubble mass is discharged at one time. By using it can provide a sludge discharge device that can easily remove the sludge deposited on the bed or reservoir, sedimentation tank and the bottom of the reactor.

Claims (2)

In the sludge discharge device, A tubular discharge pipe having a sludge inlet at the bottom, an outlet at the top, and an air inlet formed at a side wall of the bottom region; A guide member coupled to the discharge pipe at an upper portion of the air inlet to form a guide space having a downward opening wider than that of the sludge inlet; An air guide coupled to the discharge pipe in the guide space and extending radially outward and upward from a lower portion of the air inlet; A compressor for generating discharge air; And a supply pipe for delivering the discharged air from the compressor to the guide space of the guide member. The method of claim 1, And a suction baffle extending downward from the lower end of the discharge pipe and gradually expanding downwardly.