KR100945081B1 - Dredging and dehydration device for sludge using ejector - Google Patents

Abstract

PURPOSE: A vacuum suction dredging and dehydration device of the sludge using an ejector is provided to reduce the cost for transferring the sludge by dehydrating the sludge in a sludge tank part. CONSTITUTION: A vacuum suction dredging and dehydration device of the sludge using an ejector comprises a sludge tank part(10) and an ejector circulation part(20). The sludge tank part maintains air-tightness and contains the sludge. An inlet tube(11) is located on one end of the sludge tank part. An outlet tube(12) is located on the other end of the sludge tank part. A screen-film(13) is located inside the sludge tank part and filters the sludge to pass fluid. The ejector circulation part comprises a water tank(21), a booster pump(22) and the ejector. The fluid is accepted in the water tank to give the suction force to the sludge tank part.

Description

Vacuum suction dredging and dewatering device of sludge using ejector {DREDGING AND DEHYDRATION DEVICE FOR SLUDGE USING EJECTOR}

The present invention relates to a vacuum suction dredging and dewatering device of sludge using an ejector, and more particularly, the sludge tank unit is provided with a screen membrane for filtering only the fluid to pass the sludge tank unit during dredging operations such as sewerage. Dehydration and loading can accommodate a large amount of sludge, reducing the cost of transporting sludge and preventing secondary contamination such as leachate that may occur during the transportation of sludge, and the sludge tank By using an ejector equipped with a suction chamber as a driving force to provide negative suction power, even if air or gas is mixed in the water separated from the sludge, it can be sucked smoothly and the ejector circulation by supplying the water separated in the above process to the water tank. Vacuum suction of sludge using ejector which can be reused by negative circulation power It relates to the installation and dewatering equipment.

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. .

In addition, since the sludge tank and the vacuum suction device are mounted on the vacuum suction vehicle at the same time, dredging is effective for a small amount of dredging, but it takes a lot of time for setting the equipment during dredging of large capacity, fresh water lake, reservoir, etc. As the volume is reduced, there is a problem that a large capacity vacuum dewatering dump vehicle and a separate vacuum suction dredge fixing device are required due to problems such as efficient operation of the vacuum suction device.

In addition, when inhaling sludge, the suction device of a conventional suction dredging vehicle may cause trouble or damage to the device due to problems such as overload friction and blockage when dredged material is introduced if air or gas is mixed into the suction device during the dredging suction process. There was a 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 provided with a screen membrane for filtering only the fluid to pass through the sludge tank during dredging operations such as sewage sludge in the sludge tank portion By dehydration and loading, it can accommodate a large amount of sludge, reducing the cost of transporting sludge, and preventing secondary pollution such as leachate that may occur during the transportation of sludge. By using the ejector equipped with suction chamber as the driving force to provide the suction force of the tank part, even if air or gas is mixed in the water separated from the sludge, it can be sucked smoothly and supply the water separated in the above process to the water tank. Vacuum suction of sludge using ejector that can be reused by the circulation power of the circulation part To provide a stand and dewatering equipment.

Another object of the present invention comprises a gas discharge pipe communicating with the upper end portion and a liquid discharge pipe communicating with the lower end portion of the discharge pipe of the sludge tank unit to suck in the substances such as air or gas that cannot be mixed with the ejector circulation water by using the gas discharge pipe. It is to provide a vacuum suction dredging and dewatering device of sludge using an ejector that can be stored, discharged and discharged.

Vacuum suction dredging and dewatering device of the sludge using the ejector according to the present invention in order to achieve the above object is a tank shape that can maintain the outside and airtight and accommodate the sludge, one end is provided with a suction pipe, the other end is a discharge pipe And a screen membrane for filtering only the fluid to pass therethrough, and the sludge introduced into the suction pipe by a predetermined suction force is filtered by the screen membrane so that the fluid is discharged to the discharge pipe and the dewatered sludge is accommodated therein. Sludge tank portion that is; 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. The outlet portion is in communication with the discharge pipe of the tank portion is characterized in that it comprises an ejector circulation portion having an ejector communicated to the water tank.

In addition, the vacuum suction dredging and dewatering device of the sludge using the ejector according to the present invention, the discharge pipe is composed of a gas discharge pipe communicated with the other end upper end of the sludge tank portion, and a liquid discharge pipe communicated with the lower end of the other end of the sludge tank portion. The valve may be provided at each of the gas discharge pipe and the liquid valve pipe.

In addition, the vacuum suction dredging and dewatering device of the sludge using the ejector according to the present invention, the sludge tank is mounted on the vehicle, the hatch is hinged to the other end is rotated and open and close the inside, the hatch And the hatch cylinder for rotating the end, in the state that the hatch is open, the end cylinder is lifted and connected to the vehicle so that the sludge accommodated therein can be unloaded in the other end direction.

Vacuum suction dredging and dewatering device of the sludge using the ejector according to the present invention by the configuration as described above to increase the sludge transport efficiency by loading the sludge in the sludge tank at the same time and dehydration, turbidity even during rain and rain on the construction site It is easy to transport the material, and it is effective to prevent the secondary pollution during the transportation of the sludge, and even if air or gas is mixed in the water separated from the sludge by using an ejector as a driving force that provides the suction power of the sludge tank part. It is possible to smoothly inhale and at the same time by supplying the water separated in the above process to the water tank can be reused by the circulating power of the ejector circulation.

Hereinafter, with reference to the embodiment shown in the drawings will be described in more detail the vacuum suction dredging and dewatering device of the sludge using the ejector according to the present invention.

1 is a block diagram of a vacuum suction dredging and dewatering device of the sludge using an ejector according to an embodiment of the present invention, Figure 2 is a cross-sectional view of the ejector according to an embodiment of the present invention, Figure 3 is one of the present invention 4 is a view illustrating a state of use of the vacuum suction dredging and dewatering apparatus of the sludge using the ejector, and FIG. 4 is a state diagram of the use of the hatch, the hatch cylinder, and the dump cylinder according to the embodiment of the present invention.

Referring to the drawings, the vacuum suction dredging and dewatering device of the sludge using the ejector according to an embodiment of the present invention is configured to include a sludge tank 10 and the ejector circulation 20.

The sludge tank 10 is maintained in the outside and airtight so that the sludge (S), such as sewage (D) can be sucked by the suction force provided from the ejector circulation unit 20, the reception of the sludge (S) The tank C is configured to be mounted on the vehicle C, and the suction pipe 11, the discharge pipe 12, the screen membrane 13, the hatch 14, the hatch cylinder 15, and the dump cylinder 16 are mounted on the vehicle C. ) Is provided.

The suction pipe 11 is provided at one end of the sludge tank part 10 and is connected to the sewer (D) for dredging operation of the sludge (S).

The discharge pipe 12 is provided at the other end of the sludge tank part 10, the sludge tank part 10 is connected to the suction chamber 232 of the ejector 23 to be described later to receive the suction force is the suction pipe (10) 11) is configured to suck the sludge (S) through.

On the other hand, the discharge pipe 12 is composed of a gas discharge pipe 121 communicated with the upper end of the other end of the sludge tank 10, and the liquid discharge pipe 122 communicated with the lower end of the other end of the sludge tank 10, The gas discharge pipe 121 and the liquid discharge pipe 122 are provided with valves B1 and B2, respectively.

That is, when the sludge S is introduced into the sludge tank 10, the sludge tank 10 has a sludge deposited in the lower end of the sludge tank 10, the sludge is present in the turbidity, the sludge is present in the upper end of the sludge Substances that cannot be mixed with the gas or ejector circulating water generated in (S) are present in a gaseous state, and when the valve B1 of the gas discharge pipe 121 is opened, the substances that cannot be mixed with the ejector circulating water are formed. Existing inhalation device may cause a disaster due to frictional shock, but may be solved in the physical ejector inhalation method such as the present invention. When the valve B2 of the liquid discharge pipe 122 is opened, the dredging and dewatering operation of the conventional sludge S is performed.

The screen membrane 13 is provided to filter the fluid so as to pass through the sludge tank 10.

That is, the screen membrane 13 divides the sludge tank part 10 into a part connected to the suction pipe 11 and two parts connected to the discharge pipe 12 to connect the sludge tank part 10 connected to the suction pipe 11. Dewatered sludge (S) is loaded in the portion of the sludge tank 10 connected to the discharge pipe 12, the water separated from the sludge (S) is to be discharged through the discharge pipe 12. .

On the other hand, the screen film 13 is the sludge tank portion (in the position close to the discharge pipe 12, as shown in Figure 1 to increase the loading capacity of the dewatered sludge (S) to the sludge tank portion 10) 10) It is preferable to be installed inside, and the screen membrane 13 may be a perforated plate in which the sludge S is filtered but the through hole through which water passes is formed as a whole.

Due to the configuration of the sludge tank unit 10 as described above, the sludge tank 10 is loaded with the sludge S at the same time as the dehydration at the same time to increase the sludge (S) transport efficiency, secondary pollution in the transport process It is possible to prevent, dehydration of the sludge (S) through the above process is of course easier to handle than the liquid or concentrated sludge even after being transported.

As shown in FIG. 4, the hatch 14 is rotated while the upper end of the other end of the sludge tank 10 is connected to the hinge 14a and is provided to open and close the inside thereof.

That is, the hatch 14 which is opened and closed in the sludge tank part 10 for unloading the dewatered sludge S and washing or replacing the screen membrane 13 is provided.

The hatch cylinder 15 serves to rotate the hatch 14, the body portion and the rod to be advanced to the sludge tank 10 and the hatch 14 are hingedly connected to the hatch 14 By rotating around the hinge 14a, the inside of the sludge tank 10 is opened and closed.

The dump cylinder 16 serves to lift one end of the sludge tank 10 from the vehicle C so that the sludge S accommodated therein slides in the other end and is unloaded. 10) is provided at the lower end of the connection to the vehicle.

Due to the configuration of the sludge tank 10 mounted on the vehicle C as described above, dredging and dredging of the sludge immediately after moving to the workplace for dredging the sludge S such as the sewerage D using the vehicle C and Dewatering operation is possible, and after the operation, the dewatered sludge S as it is can be transported to the sludge S treatment place using the vehicle C in a state in which the sludge tank part 10 is accommodated. And the sludge (S) accommodated in the sludge tank part 10 at the treatment place due to the configuration of the hatch 14, the hatch cylinder 15, and the dump cylinder 16 provided in the sludge tank part 10. As soon as it can be unloaded, the dredging, transport and unloading operations of the sludge (S) is connected to a series of processes, thereby maximizing the work efficiency.

The ejector circulation part 20 serves to provide suction power to the sludge tank part 10 and includes a water tank 21, a pressure pump 22, and an ejector 23. (21) The internal fluid is constituted by a system in which each of the above components is circulated sequentially.

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 the sewer D through the valve B3.

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, the valve B3 is opened to allow flow to the sewer D.

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. 2, 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 discharge pipe 12 of the sludge tank part 10, so that the sludge tank part 10 sucks the sludge S by the suction force by the vacuum inside the suction chamber 232. The fluid separated from the sludge sucked from the sludge tank part 10 through the suction chamber 232 is mixed with the fluid flowing out of the water tank 21 and through the outlet end 233. The water tank 21 is then circulated again.

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 vacuum suction dredging and dewatering apparatus of the sludge using the ejector 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.

1 is a block diagram of a vacuum suction dredging and dewatering device of the sludge using an ejector according to an embodiment of the present invention

2 is a cross-sectional view of an ejector according to an embodiment of the present invention.

Figure 3 is a state diagram using the vacuum suction dredging and dewatering device of the sludge using an ejector according to an embodiment of the present invention

4 is a state diagram used in the hatch, the hatch cylinder and the dump cylinder according to an embodiment of the present invention

<Short description of the major reference symbols>

D sewer

     S sludge

10 sludge tank

     11 suction line

     12 exhaust pipe

           121 gas exhaust pipe

           122 Liquid Discharge Tube

     13 screen curtain

     14 hatch

     15 Hatch Cylinder

     16 Dump Cylinder

20 ejector circulation

     21 Water Tank

     22 Pressurized Pump

     23 ejector

           231 entrance

           232 Suction Chamber

                 N nozzle

                 D diffuser

           233 exit

Claims (3)

The tank shape is kept in the outside and airtight and the sludge can be accommodated, one end is provided with a suction pipe, the other end is provided with a discharge pipe, the inside is provided with a screen membrane for filtering only the fluid passing through, the suction pipe by a predetermined suction force A sludge tank portion in which sludge introduced into the filter is filtered by the screen film and the fluid is discharged to the discharge pipe 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. A suction device and a vacuum suction dredging and dewatering device of the sludge using the ejector, characterized in that it comprises an ejector circulation portion which is in communication with the discharge pipe of the tank portion is provided with an ejector in communication with the water tank. The method of claim 1, The discharge pipe is composed of a gas discharge pipe communicating with the other end upper end of the sludge tank portion, and a liquid discharge pipe communicating with the other end of the lower end of the sludge tank, characterized in that the gas discharge pipe and the liquid valve pipe is provided with a valve, respectively. Vacuum suction dredging and dewatering device of sludge using ejector. The method according to claim 1 or 2, The sludge tank part is mounted on the vehicle, the hinge is connected to the upper end of the other end is rotated, the hatch capable of opening and closing the inside, the hatch cylinder for rotating the hatch, and one end is lifted in the open state Vacuum suction dredging and dewatering device of the sludge using an ejector, characterized in that the dump cylinder connected to the vehicle is further provided so that the sludge accommodated therein can be unloaded in the other end direction.

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