KR101185621B1 - Dredging device for sludge using ejector and air tank - Google Patents

Abstract

The present invention relates to a sludge dredging device using an ejector and an air tank, and more particularly, a sludge is dewatered in the sludge tank by having a screen membrane for filtering only the fluid to pass through the sludge tank during dredging such as sewerage. By loading the sludge tank, the sludge treatment capacity is increased, and by using an ejector equipped with a suction chamber as a driving force for providing the suction power of the sludge tank, it is possible to smoothly suck even if air or gas is mixed in the water separated from the sludge. At the same time, by supplying the water separated in the above process to the water tank, it is possible to reuse by the circulating power of the ejector circulation part, and the tank in the capacity detection sensor for detecting the capacity of the dewatered sludge accommodated in the sludge tank part If detected, the By injecting compressed air to the sludge tank portion relates to a sludge dredging apparatus using the ejector and an air tank to be rapidly and reliably discharge the dehydrated sludge, sludge contained within the tank portion to the outside, such as sludge carrier.
The sludge dredging device using the ejector and the air tank according to the present invention has a tank shape that can keep the airtight and airtight and accommodate the sludge, and has a sludge suction pipe and a dewatered sludge discharge pipe at one end, and a fluid discharge pipe and compressed air inlet at the other end. A pipe is provided, and a screen membrane for filtering only the fluid is provided therein, and the sludge introduced into the sludge suction tube by a predetermined suction force is filtered by the screen membrane, and the fluid is discharged to the fluid discharge tube and dewatered sludge The sludge tank portion accommodated therein; A water tank in which fluid is received to provide suction to the sludge tank, a pressurized pump for pumping fluid in the water tank, and an inlet end communicates with the pressurized pump and a suction chamber is a space between a nozzle and a diffuser. An ejector circulation portion communicating with the fluid discharge pipe of the tank portion, the outlet end having an ejector communicating with the water tank; An air compressor and an air tank for injecting compressed air into the sludge tank part in communication with an air compressor to discharge the dewatered sludge contained in the sludge tank part to the dewatered sludge discharge pipe and the compressed air inlet pipe of the sludge tank part. A supply unit; A capacity sensing sensor for sensing the capacity of the dewatered sludge accommodated in the sludge tank part and generating a full tank signal when the capacity of the dewatered sludge reaches a set amount; And operating the ejector circulation unit, and stopping the operation of the ejector circulation unit and operating the air supply unit when the capacity detecting sensor generates a full tank signal.

Description

Sludge dredging device using ejector and air tank {DREDGING DEVICE FOR SLUDGE USING EJECTOR AND AIR TANK}

The present invention relates to a sludge dredging device using an ejector and an air tank, and more particularly, a sludge is dewatered in the sludge tank by having a screen membrane for filtering only the fluid to pass through the sludge tank during dredging such as sewerage. By loading the sludge tank, the sludge treatment capacity is increased, and by using an ejector equipped with a suction chamber as a driving force for providing the suction power of the sludge tank, it is possible to smoothly suck even if air or gas is mixed in the water separated from the sludge. At the same time, by supplying the water separated in the above process to the water tank, it is possible to reuse by the circulating power of the ejector circulation part, and the tank in the capacity detection sensor for detecting the capacity of the dewatered sludge accommodated in the sludge tank part If detected, the By injecting compressed air to the sludge tank portion relates to a sludge dredging apparatus using the ejector and an air tank to be rapidly and reliably discharge the dehydrated sludge, sludge contained within the tank portion to the outside, such as sludge carrier.

Disposal of waste from industrial and living spaces is increasingly important in relation to environmental issues. In particular, water-containing wastes, that is, sludges, are industrial sludges generated at industrial sites, sewage sludges generated at sewage treatment plants, and purified sludges generated at water purification plants. However, since the mid-2000s, such treatment methods are completely banned in OECD countries, so sludge reduction and recycling technologies are required.

Sludge produced in Korea is treated at 290 water and sewage treatment plants and 100 industrial and agricultural industrial wastewater treatment plants. The amount of sludge generated is increasing more than 4 million tons every year.

Conventionally, in treating sludge such as sewage, the sludge is first sucked as it is by using a vacuum suction vehicle, and the sucked sludge is moved to a secondary treatment place and then treated, but the water content of the sludge, that is, the water content As the sludge is transported in a very laid state, it cannot transport a large amount of sludge compared to the volume of the sludge tank, resulting in a low transportation efficiency, and a secondary pollution such as leachate leaked during the sludge transportation process. .

A dredging car has been proposed in Korean Patent No. 075953 to solve the problem of leachate leakage during the transport of sludge as described above.

1 illustrates a dredging vehicle according to the prior art disclosed in the registered patent number 075953. Referring to the drawings, the dredging vehicle according to the prior art vacuums the sludge (S) and sewage (W) in the pipeline through the suction pipe 122 associated with the sludge tank 120 using the vacuum pump 130 into the sludge tank 120. In the dredging vehicle to be sucked and recovered, a conveying screw 200 is rotatably installed at the bottom of the sludge tank 120 by a driving motor M to force the sludge S to be discharged toward the sludge discharge port 220. Is configured, a portion of the sludge tank 120, the cylinder (C) is installed to lift the sludge tank 120 while the cylinder is extended, the sludge tank 120 is rotated at a predetermined angle around the hinge (H) at the front ( Or the rear part) is configured to be lifted and inclined so that the sludge tank 120 is lifted when the sludge S is discharged so that the feed screw 200 can be inclined, so that the sewage W is drain valve B1. Through nature Dropped and pure sludge (S) is characterized in that it is configured to be discharged to other transport means such as a dump truck along the transfer screw (200).

However, in the dredging vehicle according to the prior art as described above, sludge (S) and sewage (W) is accommodated in the sludge tank 120 at the same time can process the sludge (S) compared to the volume of the sludge tank 120. There was a limit to the capacity, and in order to separate the sludge (S) and sewage (W) in the sludge tank 120 had to wait for the sludge (S) to settle for a long time there was a problem that the working time is long, sludge tank ( In the discharge of sludge S deposited on the bottom of 120, the sludge tank 120 must be rotated at a predetermined angle using the cylinder C, and the discharge speed is adopted by adopting a feed screw 200 which is a mechanical transfer method. There was a limit to, there was a problem that the overall work efficiency, such as the sludge (S) is stuck to the transfer screw 200.

In addition, even in the suction of the sludge dredging car according to the prior art by using the vacuum pump 130 as the suction device when the air or gas is mixed in the vacuum pump 130 during the suction process, such as overload friction and clogging when the dredged material inflow The problems caused by the failure and breakdown of the device due to the problem, and the pollution caused by the extreme noise due to mechanical vacuum suction during work and the resulting complaints caused.

The present invention has been made to solve the problems of the prior art as described above, the object of the present invention is to include a screen membrane for filtering only the fluid to pass through the sludge tank portion by allowing the sludge dewatered and loaded in the sludge tank portion By increasing the sludge treatment capacity of the sludge tank portion and using an ejector as a driving force for providing the suction force of the sludge tank portion, even if air or gas is mixed in the water separated from the sludge, it is possible to smoothly suck and separate in the above process. By supplying water to the water tank, it is possible to reuse it by the circulating power of the ejector circulation part, and equipped with a capacity sensor and an air supply part to quickly and surely dehydrated sludge contained in the sludge tank part to the outside such as a sludge transport vehicle. Ejector and Air Allowed for Venting To provide a sludge dredging apparatus using a link.

In order to achieve the above object, the sludge dredging device using the ejector and the air tank according to the present invention has a tank shape capable of holding sludge with the outside and hermeticity, and one end is provided with a sludge suction pipe and a dewatered sludge discharge pipe, and the other end. It is provided with a fluid discharge pipe and compressed air inlet pipe, the inside is provided with a screen membrane for filtering only the fluid passing through, the sludge introduced into the sludge suction tube by a predetermined suction force is filtered by the screen membrane so that the fluid is the fluid A sludge tank part discharged into the discharge pipe and dewatered sludge is accommodated therein; A water tank in which fluid is received to provide suction to the sludge tank, a pressurized pump for pumping fluid in the water tank, and an inlet end communicates with the pressurized pump and a suction chamber is a space between a nozzle and a diffuser. An ejector circulation portion communicating with the fluid discharge pipe of the tank portion, the outlet end having an ejector communicating with the water tank; An air compressor and an air tank for injecting compressed air into the sludge tank part in communication with an air compressor to discharge the dewatered sludge contained in the sludge tank part to the dewatered sludge discharge pipe and the compressed air inlet pipe of the sludge tank part. A supply unit; A capacity sensing sensor for sensing the capacity of the dewatered sludge accommodated in the sludge tank part and generating a full tank signal when the capacity of the dewatered sludge reaches a set amount; And operating the ejector circulation unit and stopping the operation of the ejector circulation unit and operating the air supply unit when the capacity detecting sensor generates a full tank signal.

In addition, in the sludge dredging apparatus using the ejector and the air tank according to the present invention, the first check valve is installed in the sludge suction pipe so that sludge flowing into the sludge tank part through the sludge suction pipe is not flowed back, and the dewatering sludge A second check valve is installed on the dewatered sludge discharge pipe so that the dewatered sludge discharged to the outside through the discharge pipe is not flowed back, and a first control valve is installed on the fluid discharge pipe to open and close the fluid discharge pipe. A second control valve is installed in the compressed air inlet pipe to open and close the inlet pipe, and the control unit controls the opening and closing of the first control valve and the second control valve, when the ejector circulation unit is operated. The first control valve is opened and the second control valve is controlled to close, the air hole When the addition operation is characterized by controlling so that the first control valve is closed is opened and the second control valve.

In addition, the sludge dredging apparatus using the ejector and the air tank according to the present invention, the sludge tank is characterized in that the vibrator is further provided for transmitting vibration to the sludge accommodated therein.

The sludge dredging apparatus using the ejector and the air tank according to the present invention by the above configuration has the effect of increasing the sludge treatment capacity of the sludge tank part by receiving only the dehydrated sludge in the sludge tank part, and in the sludge by using the ejector Even if air or gas is mixed in the separated water, it can be sucked smoothly, and by supplying the separated water to the water tank in the above process, it can be reused by the circulating power of the ejector circulation part. Equipped with dewatered sludge can be quickly and surely discharged to the outside, such as sludge transport vehicle.

1 is a side view of a dredging vehicle according to the prior art
2 is a block diagram of a sludge dredging device using an ejector and an air tank according to an embodiment of the present invention
3 is a cross-sectional view of an ejector according to an embodiment of the present invention.

Hereinafter, a sludge dredging device using an ejector and an air tank according to an embodiment of the present invention will be described in detail with reference to the embodiment shown in the drawings.

2 is a configuration diagram of a sludge dredging apparatus using an ejector and an air tank according to an embodiment of the present invention, Figure 3 is a cross-sectional view of the ejector according to an embodiment of the present invention.

Referring to the drawings, the sludge dredging apparatus using the ejector and the air tank according to an embodiment of the present invention, the sludge tank unit 10, the ejector circulation unit 20, the air supply unit 30, the capacity detection sensor 40 And a control unit 50.

The sludge tank part 10 is configured to suck the sludge (S) such as sewerage by the suction force provided from the ejector circulation part 20 and to receive the inside of the sludge tank. The sludge suction pipe 11, the screen membrane 12, the fluid discharge pipe 13, the compressed air inlet pipe 14, the dewatered sludge discharge pipe 15, and the vibrator 16 are formed as possible as possible. It is provided.

The sludge suction pipe 11 is provided at one end of the sludge tank portion 10 is connected to the sewer for sludge dredging work, etc., the sludge suction pipe 11 through the sludge tank portion 10 through it. The first check valve 111 is installed so that the introduced sludge S does not flow backward.

That is, the first check valve 111 is opened when the ejector circulation part 20 is operated and negative pressure is formed in the sludge tank part 10, so that the sludge S is opened through the sludge suction pipe 11. The sludge tank part 10 is introduced into the sludge tank 10, and when the air supply unit 30 is operated to inject compressed air into the sludge tank part 10, the air is supplied to the sludge tank part 10 so as to be closed. Dehydrated sludge (S) is to be discharged through the sludge suction pipe (11).

The screen membrane 12 filters the fluid so that only the fluid passes therethrough and is provided in the sludge tank part 10.

That is, the screen membrane 12 divides the sludge tank part 10 into two parts connected to the sludge suction pipe 11 and two parts connected to the fluid discharge pipe 13 to connect the sludge tank 11 to the sludge suction pipe 11. The dewatered sludge S is loaded in a part of the part 10, and the water separated from the sludge S is connected to the fluid discharge pipe 13 at a part of the sludge tank part 10 connected to the fluid discharge pipe 13. It will be discharged through.

On the other hand, the screen film 12 is the sludge tank part in a position close to the fluid discharge pipe 13 as shown in Figure 2 to increase the loading capacity of the dewatered sludge (S) to the sludge tank part 10. (10) It will be preferable to be installed inside, the screen membrane 12, the sludge (S) is filtered, but the perforated plate is formed as a whole through-hole through which water is to be passed may be used.

In addition, in the portion of the sludge tank portion 10 connected to the sludge suction pipe 11 among the portions partitioned left and right by the screen membrane 12 inside the sludge tank portion 10 by the above configuration, dehydration is performed. The sludge S is loaded. In this case, the water remaining in the sludge S to be loaded is caused to fall downward by gravity, so that the sludge tank 10 can be dehydrated more completely. It is preferable to have a lower screen membrane 12 'connected to the screen membrane 12 at a lower portion of the dewatered sludge discharge pipe 15 so as not to cover the screen membrane.

Like the screen membrane 12, the lower screen membrane 12 ′ may also use a perforated plate in which sludge S is filtered but water is entirely formed therethrough, and falls to the lower screen membrane 12 ′. The fluid will be discharged to the fluid discharge pipe 13 through the screen film 12.

The fluid discharge pipe 13 is provided at the other end of the sludge tank part 10 to discharge water separated from the sludge S by the screen membrane 12, and a suction chamber of the ejector 23 to be described later. It is connected to the 232 is provided with a suction force so that the negative pressure is formed in the sludge tank 10, so that the sludge (S) is introduced into the sludge tank 10 through the sludge suction pipe (11).

On the other hand, the fluid discharge pipe 13 is provided with a first control valve 131 is controlled and controlled by the control unit 50, the first control valve 131 is the ejector circulation unit 20 is operated In case of opening, the air supply unit 30 is controlled by the controller 50 to be closed when the air supply unit 30 is operated. On the other hand, the first control valve 131 is preferably made of a solenoid valve capable of electronic control.

The compressed air inlet pipe 14 is provided at the other end of the sludge tank part 10 and is configured to inject compressed air from the air supply part 30, and is accommodated in the sludge tank part 10 by high pressure. Dehydrated sludge (S) is to be discharged to the outside through the dewatered sludge discharge pipe (15).

On the other hand, the compressed air inlet pipe 14 is provided with a second control valve 141, which is controlled by the control unit 50 and opened and closed, the second control valve 141 is the first control valve 131 On the contrary, when the ejector circulation unit 20 is operated, the ejector circulation unit 20 is closed, and when the air supply unit 30 is operated, the control unit 50 is controlled. On the other hand, the second control valve 141 is also preferably made of a solenoid valve capable of electronic control, like the first control valve 131.

Meanwhile, the first control valve 131 and the second control valve 141 are switched in one valve device, and the sludge tank part 10 is connected to the ejector circulation part 20 or the air supply part 30. It can also be configured as a two-way valve to allow communication.

The dewatered sludge discharge pipe 15 is provided at one end of the sludge tank part 10 and connected to a sludge transport vehicle T for transport of dewatered sludge S, and through the dewatered sludge discharge pipe 15 therethrough. The second check valve 151 is installed so that the dewatered sludge S discharged to the outside does not flow backward.

That is, the second check valve 151 is closed when the ejector circulation part 20 is operated to form a negative pressure in the sludge tank part 10 so that the air is discharged from the outside through the dewatered sludge discharge pipe 15. The dewatered sludge (S) is prevented from flowing into the sludge tank part 10, and when the air supply unit 30 is operated to inject compressed air into the sludge tank part 10, the sludge is opened. Dehydrated sludge (S) accommodated in the tank portion 10 is to be discharged to the outside through the dewatered sludge discharge pipe (15).

The vibrator 16 is configured to transmit vibration to the sludge S accommodated inside the sludge tank part 10. In one embodiment of the present invention, the inner center of the sludge tank part 10 is elongated in the longitudinal direction. Installed in a transverse form and configured as a vibrating rod form.

When the sludge S sucked into the sludge tank part 10 due to the vibration of the vibrator 16 is loaded into the sludge tank part 10, it may be prevented from being eccentrically loaded. The dehydration effect by the membrane 12 can also be increased.

Due to the configuration of the sludge tank unit 10 as described above, the sludge tank unit 10 is loaded with sludge (S) at the same time as the dehydration in parallel to increase the sludge (S) treatment capacity of the sludge tank unit 10. The dehydrated sludge S can be discharged quickly and reliably to the outside such as a sludge transport vehicle T.

The ejector circulation unit 20 is controlled by the control unit 50 and serves to provide a suction force to the sludge tank unit 10, the water tank 21, the pressure pump 22, and the ejector It is configured to include a (23) is composed of a system in which the fluid inside the water tank 21 is circulated to sequentially turn each of the components.

The water tank 21 serves to receive the fluid circulating in the ejector circulation portion 20 to communicate with the outlet end 233 of the pressure pump 22 and the ejector 23, and the upper end portion It communicates with sewer through valve (B).

That is, the fluid contained in the water tank 21 flows back into the water tank 21 through the ejector 23 through the pressure pump 22, and the sludge tank part in the ejector 23. The fluid separated from the sludge discharged from (10) flows into the water tank 21 together and is reused by the circulating power of the ejector circulation part 20, and the fluid exceeds the capacity of the water tank 21. In this case, by opening the valve (B), it is possible to flow to the sewer.

The pressurized pump 22 serves to provide circulating power of the fluid in the ejector circulation part 20, and transfers the fluid in the water tank 21 to the inlet end 231 of the ejector 23. To pump.

The ejector 23 is a device for generating a suction force in a vacuum state based on the Bernoulli principle generated from the fluid flowing through the nozzle (N) and the diffuser (D), the inlet end 231, the suction chamber 232, the outlet end 233.

That is, as shown in FIG. 3, the inlet end 231 communicates with the pressure pump 22. The fluid pumped by the pressure pump 22 and entering the inlet end 231 is connected to the nozzle N. The flow rate is rapidly increased and passes through the diffuser (D) and gradually decreases the flow rate to exit the outlet (233), where the suction chamber (232) is a space between the nozzle (N) and the diffuser (D). In Bern, the pressure decreases rapidly and becomes a vacuum by the Bernoulli principle.

The suction chamber 232 communicates with the fluid discharge pipe 13 of the sludge tank 10 so that the sludge tank 10 may receive sludge S by suction force by vacuum inside the suction chamber 232. The water separated from the sludge (S) sucked from the sludge tank part 10 through the suction chamber 232 is mixed with the water flowing out of the water tank 21 and the outlet end ( 233 is circulated back to the water tank 21.

The general centrifugal pump has a problem in that when the gas is mixed in the liquid, a cavity phenomenon (cavitaion) is generated and pumping, that is, the suction is impossible, but as the driving force for providing the suction power of the sludge tank unit 10 as described above. By using (23), even if gas is mixed in the water separated from the sludge (S), it is possible to smoothly suck in, and facilitates the suction transport of turbid material during rain and rain at the construction site and the water separated in the above process By supplying to the water tank 21 is to be reused by the circulating power of the ejector circulation unit 20.

The air supply unit 30 is controlled by the control unit 50 and the air is configured to discharge the dewatered sludge S contained in the sludge tank 10 to the dewatered sludge discharge pipe 15. A compressor (31) and an air tank (32) communicating with the compressed air inlet pipe (14) of the sludge tank portion (10) for injecting compressed air into the sludge tank portion (10) is provided. In an embodiment of the present invention, in adopting a method of discharging the dehydrated sludge S contained in the sludge tank part 10 to the outside, compressed air through the air supply unit 30 is not a mechanical operation method. By using it, it is configured to ensure the rapid certainty of the emission.

The capacity detecting sensor 40 detects the capacity of the dewatered sludge S accommodated in the sludge tank part 10, but only when the capacity of the dewatered sludge reaches the set amount. Generates a signal to allow the control unit 50 to control the operation of the ejector circulation unit 20 and the air supply unit 30, the control of the first control valve 131 and the second control valve 141 It is a configuration to control the opening and closing.

The capacity detecting sensor 40 may be used in various types, but a laser type, that is, provided in the upper end of the sludge tank part 10 to generate a laser signal and to receive a signal reflected by the sludge (S) to the sludge It may be configured to the type of sensing the capacity of the dewatered sludge (S) accommodated in the tank 10.

The control unit 50 controls the operation of the ejector circulation unit 20 and the air supply unit 30 and controls the opening and closing of the first control valve 131 and the second control valve 141. .

That is, the controller 50 operates the ejector circulation unit 20 when the sludge dredging device using the ejector and the air tank according to an embodiment of the present invention sucks the sludge S from the sewerage system. The first control valve 131 is to be opened and the second control valve 141 is controlled to be closed.

Sludge (S) is introduced into the sludge tank 10 by the operation of the ejector circulation part 20, the water separated from the sludge (S) by the screen film 12 is the fluid discharge pipe ( 12) and the dewatered sludge S is continuously stacked on the sludge tank part 10. The capacity detecting sensor 40 receives a full tank signal according to the volume of the sludge tank part 10. When it occurs, the control unit 50 stops the operation of the ejector circulation unit 20.

When the dewatered sludge S is fully accommodated in the sludge tank part 10, the operation is discharged to the outside such as a sludge transport vehicle T. For this purpose, the control unit 50 opens the air supply unit 30. In operation, the first control valve 131 is closed and the second control valve 141 is controlled to open.

The air supply unit 30 is activated and compressed air is injected into the sludge tank 10, and the dewatered sludge S accommodated in the sludge tank 10 is passed through the dewatered sludge discharge pipe 15. The sludge transport vehicle (T) is to be discharged to the outside.

The sludge dredging apparatus using the ejector and the air tank described above and shown in the drawings is only one embodiment for carrying out the present invention, and should not be construed as limiting the technical idea of the present invention. The scope of protection of the present invention is defined only by the matters set forth in the claims below, and the embodiments which have been improved and changed without departing from the gist of the present invention will be apparent to those skilled in the art. It will be said to belong to the protection scope of the present invention.

10 sludge tank
11 Sludge suction pipe 111 1st check valve
12 screen curtain 12 'bottom screen curtain
13 Fluid outlet line 121 1st control valve
14 Compressed air inlet pipe 141 Second control valve
15 Dewatering sludge discharge pipe 151 2nd check valve
16 vibrators
20 ejector circulation
21 Water Tank
22 Pressurized Pump
23 ejector
231 entrance
232 Suction Chamber
N nozzle
D diffuser
233 exit
30 Air Supply Unit
31 air compressor
32 air tank
40 capacity sensor
50 controls

Claims (3)

The tank shape is kept in the outside and airtight, and the sludge suction pipe and the dewatered sludge discharge pipe are provided at one end, the fluid discharge pipe and the compressed air inlet pipe are provided at the other end, and the screen for filtering only the fluid through the inside A sludge tank portion having a membrane, and the sludge introduced into the sludge suction tube by a predetermined suction force is filtered by the screen membrane so that the fluid is discharged to the fluid discharge tube and the dewatered sludge is accommodated therein;
A water tank in which fluid is received to provide suction to the sludge tank, a pressurized pump for pumping fluid in the water tank, and an inlet end communicates with the pressurized pump and a suction chamber is a space between a nozzle and a diffuser. An ejector circulation portion communicating with the fluid discharge pipe of the tank portion, the outlet end having an ejector communicating with the water tank;
An air compressor and an air tank for injecting compressed air into the sludge tank part in communication with an air compressor to discharge the dewatered sludge contained in the sludge tank part to the dewatered sludge discharge pipe and the compressed air inlet pipe of the sludge tank part. A supply unit;
A capacity sensing sensor for sensing the capacity of the dewatered sludge accommodated in the sludge tank part and generating a full tank signal when the capacity of the dewatered sludge reaches a set amount;
Sludge dredging device using the ejector and the air tank to operate the ejector circulation, the control unit for stopping the operation of the ejector circulation and operating the air supply when the capacity detection sensor generates a full tank signal . The method of claim 1,
The sludge suction pipe is provided with a first check valve to prevent the sludge flowing into the sludge tank part through the sludge suction pipe, and the dewatered sludge discharged to the outside through the dewatered sludge discharge pipe does not flow backward. A second check valve is installed in the discharge pipe, and a first control valve is installed in the fluid discharge pipe to open and close the fluid discharge pipe, and a second control valve is installed in the compressed air inlet pipe to open and close the compressed air inlet pipe. Is installed,
The control unit controls the opening and closing of the first control valve and the second control valve, and when the ejector circulation unit is operated, the first control valve is opened and the second control valve is controlled to close, and the air Sludge dredging device using an ejector and an air tank, characterized in that when the supply unit is operated to control the first control valve is closed and the second control valve is opened. The method according to claim 1 or 2,
The sludge tank unit, the sludge dredging device using an ejector and an air tank, characterized in that the vibrator is further provided for transmitting vibration to the sludge accommodated therein.

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