KR102545064B1 - Multi-stage sewage treatment system - Google Patents

Abstract

The present invention relates to a system for treating sewage through a multi-stage reaction tank using a decanter, and more particularly, a first reaction tank in which an anaerobic process is performed and a second reaction tank in which an aerobic process is performed are connected in series through a decanter, but a guide bar The present invention relates to a multi-stage sewage treatment system that is easy to maintain and can be miniaturized by minimizing the volume because the decanter that moves up and down transports supernatant water introduced into the inside while floating along the water level of the reaction tank.

Description

Multi-stage sewage treatment system {Multi-stage sewage treatment system}

The present invention relates to a system for treating sewage through a multi-stage reaction tank using a decanter, and more particularly, a first reaction tank in which an anaerobic process is performed and a second reaction tank in which an aerobic process is performed are connected in series through a decanter, but a guide bar The present invention relates to a multi-stage sewage treatment system that is easy to maintain and can be miniaturized by minimizing the volume because the decanter that moves up and down transports supernatant water introduced into the inside while floating along the water level of the reaction tank.

A batch treatment system for advanced treatment of sewage, sewage, livestock wastewater, manure, etc. containing organic matter, nitrogen (N) and phosphorus (P) using a single reactor {SBR; Sequencing Batch Reactor} has been proposed. Such a batch treatment system is applied to the wastewater treatment field in various forms for reasons such as a small installation area, a simple process, and low facility and operating costs compared to other biological wastewater treatment systems. For example, Registered Patent Publication No. 10-0378228 "Wastewater Treatment Apparatus" proposes a technique of treating wastewater by culturing bacteria of the genus Bacillus in a single reaction tank.

In addition, Laid-Open Patent Publication No. 10-2004-0006926 "Sewage treatment method using an internal circulation continuous batch reaction device" has a multi-purpose tank and a main reaction tank separately, and an automatic transfer device and internal liquid for material exchange in the tank In the sewage treatment method using a continuous batch reactor equipped with a circulation device and a sludge return line, the internal liquid circulation device is operated according to the operating conditions to transfer the reaction liquid in the multipurpose tank to the main reaction tank step by step to obtain necessary for denitrification and dephosphorization. The carbon source is provided, the main reactor is operated as a continuous batch reaction process, and the multipurpose tank is operated as an anaerobic tank or anoxic tank during the operation process of the main reactor, and operated as a flow control tank at other times. It is proposed.

Meanwhile, in such a batch treatment system, a decanter for discharging only supernatant water from treated water received in a reaction tank has been proposed and used. According to Registered Patent Publication No. 10-0535379, a position control unit is proposed in which a housing unit equipped with a submersible pump is placed in a reaction tank, installed on the ground and connected to the housing unit with a wire to move the housing unit up and down. However, there is a concern that the vertical movement of the housing unit through these wires may not be able to follow the change in water level in the reaction tank in real time, and also, installing a crane-shaped position control unit on the ground is a recent water treatment facility in which all structures are buried underground. There was a problem that did not fit the trend of .

KR 10-0378228 (B1) 2003.03.18. KR 10-2004-0006926 (A) 2004.01.24. KR 10-0535379 (B1) 2005.12.02.

In order to solve the above problems, an object of the present invention is to divide the reaction tank for treating the inflow sewage into a first reaction tank mainly performing an anaerobic process and a first reaction tank mainly performing an aerobic process to prevent sludge bulking It is to provide a multi-stage sewage treatment system capable of maximizing treatment efficiency by forming optimal conditions for sewage treatment because there is no re-elution of phosphorus and minimizes microbial stress.

Another object of the present invention is to form a first distribution hole through which raw water flows into the first reaction tank and a second distribution hole through which raw water flows into the flow control tank in the screen tank, the second distribution hole being formed higher than the first distribution hole, and the water level in the first reaction tank In accordance with the excess rise, a ball-top gate is provided to seal the first distribution port, which blocks the inflow flow that exceeds the processing capacity of the first reaction tank and sends it to the flow control tank, maximizing the use of the flow control tank to cope with high flow loads and emergencies. It is possible to provide a multi-stage sewage treatment system capable of reducing power consumption by significantly reducing the operation time of a flow control pump.

Another object of the present invention is to provide a buoyant body at the top of the decanter that is provided in the reaction tank and transfers the supernatant, so that the height is changed in real time according to the water level in the reaction tank, so that scum can be prevented from entering the decanter regardless of the amount of scum generated It is to provide a multi-stage sewage treatment system.

Another object of the present invention is that the decanter is raised and lowered in real time according to the change in water level in the reaction tank, and the upper and lower lifting holes are inserted into the guide bar, and the balance hole formed between the upper and lower lifting holes is supported by the guide bar, so that water is introduced. It is to provide a multi-stage sewage treatment system in which the decanter can be stably moved up and down by maintaining balance without being shaken even during the aeration process.

Another object of the present invention is to block the inflow of contaminants such as sludge by filling air into the decanter through an air hose when the aeration and precipitation processes are performed in the reaction tank, so that supernatant water can flow into the decanter after the precipitation process. It is to provide a multi-stage sewage treatment system capable of cleanly treating the supernatant transported through the decanter without contaminating the supernatant when contaminants and the supernatant are not mixed.

A screen tank (10) for filtering impurities from incoming raw water through a screen (11) provided therein; a first reaction tank (30) for purifying the water flowing in from the screen tank (10); a second reaction tank 40 which purifies the water introduced from the first reaction tank 30; and a buoyancy body 110 that moves up and down along the vertical guide bar 180 installed in the first reaction tank 30 and the second reaction tank 40 and floats along the water level of the reaction tank, and the buoyancy and a decanter 100 for transporting the supernatant at a lower position than the sieve 110 into the inside and outwardly. The decanter 100 is provided at the lower part of the buoyancy body 110, and the lower surface is open. an upper housing 120; It is inserted into the upper housing 120, is formed in a smaller size than the upper housing 120, has an upper end disposed higher than the lower end of the upper housing 120, and has a side wall at the lower end of the upper housing 120. a lower housing 130 protruding downward and having an open upper surface; a coupling bracket 140 connecting the upper housing 120 and the lower housing 130; And it is formed as a spaced gap between the side surface of the upper housing 120 and the side surface of the lower housing 130, and the reaction tank water at a position lower than the lower end of the upper housing 120 overflows the upper end of the lower housing 130 It further includes an inlet 150 that flows into the inside, and the upper surface of the housing 130 always maintains an open state; The lower housing 130 is a plate disposed in the horizontal direction, protrudes outward from the upper housing 120, and is disposed below the inlet 150 and expands the contact area with water (160). );

In addition, the screen tank 10 of the present invention supplies water filtered through the screen 11 to the first reaction tank 30, and a ball top gate 34 that moves up and down according to the water level of the first reaction tank 30 A first distribution port 12 opened and closed by; and a second distribution port 13 formed higher than the first distribution port 12 and supplying the water filtered through the screen 11 to the flow control tank 20 for temporarily storing it.

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In addition, the decanter 100 of the present invention further includes an air hose 121 supplied with air from a compressor; During the aeration process or sedimentation process of the reaction tank, air is supplied into the decanter 100 through the air hose 121 to form an air layer inside the decanter 100 and the water in the reaction tank does not flow into the decanter 100. do not; After the precipitation process is finished, the air inside the decanter 100 is discharged to the outside through the air hose 121 so that the supernatant water is introduced into the reaction tank.

In addition, the decanter 100 of the present invention is disposed on the buoyancy body 110, and is installed vertically in the reaction tank to guide the lifting movement of the decanter 100. An upper lifting hole 112 inserted into a guide bar 180 ; a lower elevation hole 136 disposed in the lower housing 130 and inserted into the guide bar 180; and a balance hole 161 formed in the balance plate 160 between the upper elevation hole 112 and the lower elevation hole 136 and supported by the guide bar 180.

In addition, the coupling bracket 140 of the present invention is inclined inward toward the lower housing 130 .

In the multi-stage sewage treatment system according to the present invention, the reaction tank for treating sewage is divided into a first reaction tank mainly performing an anaerobic process and a first reaction tank mainly performing an aerobic process, suppressing sludge bulking and reducing microbial stress Since it is minimized and there is no re-elution of phosphorus, it has the effect of maximizing the treatment efficiency by forming the optimal conditions for sewage treatment.

In addition, in the present invention, a first distribution hole through which raw water flows into the first reaction tank and a second distribution hole through which raw water flows into the flow control tank are formed in the screen tank, and the second distribution hole is formed higher than the first distribution hole, and the water level in the first reaction tank is exceeded. According to this, a ball top gate is provided to seal the first distribution port, so that the inflow volume exceeding the processing capacity of the first reaction tank is blocked and sent to the flow control tank, so it is possible to cope with high flow loads and emergencies by maximizing the utilization of the flow control tank. It has the effect of significantly reducing the operation time of the flow control pump and reducing power consumption.

In addition, the present invention is equipped with a buoyant body at the top of the decanter that is provided in the reaction tank to transfer the supernatant water, and the height is changed in real time according to the water level in the reaction tank, so it is effective in blocking scum from entering the decanter regardless of the amount of scum generated. .

In addition, in the present invention, the decanter moves up and down in real time according to the change in water level in the reaction tank, but the upper and lower lift holes are inserted into the guide bar, and the balance hole formed between the upper and lower lift holes is supported by the guide bar, so that water inflow or aeration During the process, the decanter does not shake and maintains balance, so it has the effect of stably going up and down.

In addition, in the present invention, when the aeration process and the precipitation process are performed in the reaction tank, air is filled into the decanter through an air hose (air layer formation) to block water so that contaminants such as sludge do not flow in, and after the precipitation process, the supernatant is When flowing into the decanter, contaminants and supernatant are not mixed, so the supernatant transferred through the decanter is not polluted and treated cleanly.

1 is a flow chart of a multi-stage sewage treatment system of the present invention.
Figure 2 is a simplified representation of the flow in the screen tank in the multi-stage sewage treatment system of the present invention, (a) is a state in which water flows into the first reaction tank through the first distribution port, (b) is the first distribution port A state in which water flows into the flow control tank as it is closed by the ball top gate.
Figure 3 is a view briefly showing a state in which the decanter introduces supernatant water after the reaction tank completes the precipitation process in the multi-stage sewage treatment system of the present invention.
Figure 4 is a top perspective view showing a decanter in the multi-stage sewage treatment system of the present invention.
Figure 5 is a bottom perspective view showing a decanter in the multi-stage sewage treatment system of the present invention.
Figure 6 is an exploded perspective view of Figure 4;
Figure 7 is a cross-sectional view showing a decanter in the multi-stage sewage treatment system of the present invention.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the present invention will be described so that those skilled in the art can easily implement it.

As shown in FIGS. 1 to 7, the multi-stage sewage treatment system according to the present invention relates to a system for treating sewage, sewage, livestock wastewater, manure, etc. containing organic matter, nitrogen (N), and phosphorus (P). with that,

A screen tank (10) for filtering impurities from incoming raw water through a screen (11) provided therein;

A first reaction tank (30) for purifying raw water introduced from the screen tank (10) through an anaerobic process;

a second reaction tank (40) for purifying the raw water introduced from the first reaction tank (30) through an aerobic process; and

It moves up and down along the vertical guide bar 180 installed in the first reaction tank 30 and the second reaction tank 40, and a buoyancy body 110 floating along the water level of the reaction tank is provided at the top, and the supernatant water of the reaction tank is provided. It includes; a decanter 100 that flows into the inside and transfers it to the outside.

The batch-type reactor used to treat sewage is a method in which raw water is not continuously inflowed, but is treated by receiving an amount of raw water as much as one treatment amount, mooring it without discharge for a certain period of time, and then discharging it. The reaction tank is a facility that treats water using microorganisms in a stationary state without inflow and outflow of raw water. After putting raw water in the amount of treatment in the reaction tank and treating it, it is discharged to the next process. After one process is finished, the next process proceeds sequentially.

The conventional batch treatment method using a reactor used an aerobic process of treating sewage in an oxygen-rich environment and an anaerobic process of decomposing organic matter in an oxygen-free environment. However, whenever the environment is changed from a single reactor to an aerobic environment and an anaerobic environment, microorganisms are under extreme stress and the efficiency of treating sewage is reduced.

Therefore, the present invention is provided by separating the first reaction tank 30, which mainly performs an anaerobic process, and the second reaction tank 40, which mainly performs an aerobic process, thereby minimizing the stress of microorganisms due to environmental changes and creating optimal conditions. Maximize the treatment efficiency of sewage.

In addition, the decanter 100 is placed in the first reaction tank 30 and the second reaction tank 40 to transfer water to the next process. It follows the water level of each reaction tank in real time, and the inlet 150 through which water flows into the decanter 100 is formed at the bottom of the buoyancy body 110, so that the scum is formed layer by layer as shown in FIG. 3 inside the reaction tank, Among supernatant water, treated water, and sludge, the inlet 150 is located on the supernatant layer, so that only supernatant water can be transported to the outside.

In particular, scum is located above the supernatant and may rise high depending on the type of raw water flowing in, but in the present invention, the influence of scum is very small due to the buoyancy of the buoyancy body 110 located at the top, so the inside of the decanter 100 It can prevent scum from entering. In addition, the present invention makes the outer shape of the buoyancy body 110 larger than the upper housing 120 or the lower housing 130 to push the scum out of the decanter 100 and pass through the lower end of the upper housing 120 to the lower housing 130. ) It is possible to increase the efficiency of sewage treatment by microorganisms by overflowing the upper end of the decanter 100 so that only supernatant water is moved to the next reaction tank or treatment tank.

In the present invention, the sewage flowing into the screen tank 10 is referred to as 'raw water', but the sewage in the step after the screen tank 10 may be close to raw water or effluent depending on the degree of treatment, so it is not differentiated in detail. The sewage in the step after the screen tank 10 is referred to as 'water'.

In addition, the present invention is provided with a first reaction tank 30 and a second reaction tank 40 to perform anaerobic treatment and aerobic treatment, respectively. .

In the present invention, a sludge storage tank, an effluent tank, a filtration tank, etc. are further provided after the second reaction tank 40 to treat incoming sewage, but the steps after the second reaction tank 40 are well known, so descriptions are omitted.

Referring to FIG. 1, the multi-stage sewage treatment system according to the present invention is a system for treating sewage, including a screen tank 10 into which raw water to be treated flows, and a flow control tank for receiving water from the screen tank 10 ( 20) and the first reaction tank 30, the second reaction tank 40 receiving water from the first reaction tank 30, and the inside of the reaction tank disposed inside the first reaction tank 30 and the second reaction tank 40 Includes a decanter 100 for transferring the water of the outside.

When sewage flows into the system of the present invention, it first flows into the screen tank 10, and the screen tank 10 is equipped with a screen 11 for filtering impurities and vomit. Impurities and vomit contained in the raw water (sewage) are caught on the screen 11 to prevent deterioration in processing function due to wear and closing of machinery provided in the subsequent process.

The raw water filtered through the screen 11 is supplied to the flow control tank 20 or the first reaction tank 30. In the screen tank 10, a first distribution port 12 through which raw water is supplied to the first reaction tank 30 and a second distribution port 13 through which raw water is supplied to the flow control tank 20 are formed at the rear end of the screen 11. do. Here, the downstream means the direction that follows in the sewage treatment flow.

Referring to FIG. 2 , the second distribution hole 13 is formed to protrude higher than the height of the first distribution hole 12 . Therefore, the raw water flowing into the screen tank 10 passes through the first distribution port 12 before the second distribution port 13 and is supplied to the first reaction tank 30, and the raw water flows through the first distribution port 12. When the flow rate exceeds the discharge capacity of the screen tank 10, the water level of the screen tank 10 gradually increases. When the water level of the screen tank 10 is higher than the set height, the water in the screen tank 10 is supplied to the flow control tank 20 through the second distribution port 13 as shown in FIG. 2(b). That is, the second distribution port 13 functions as an overflow.

When more water than the treatment capacity of the first reaction tank 30 is supplied through the first distribution port 12, the water level of the first reaction tank 30 gradually rises. The first reaction tank 30 is provided with a ball top gate 34 that moves up and down according to the water level, and when the water level in the first reaction tank 30 reaches a set threshold, the ball top gate 34 operates, as shown in FIG. 2(a). Likewise, the lower end of the first distribution port 12 is closed.

In summary, when raw water flows into the screen tank 10, impurities and vomit are filtered by the screen 11 as shown in FIG. When the first distribution port 12 is closed by the ball top gate 34 due to an increase in the water level in the first reaction tank 30 or when an amount greater than the processing capacity of the first distribution port 12 is supplied. As shown in FIG. 2(b), the water level in the screen tank 10 rises, overflows into the second distribution port 13, and is supplied to the flow control tank 20. The water supplied to the flow control tank 20 is supplied to the first reaction tank 30 again through the flow control pump 21 installed in the flow control tank 20 . At this time, the operation of the flow control pump 21 should consider the water level of the first reaction tank 30, and when there is room for the operation and water level of the first reaction tank 30, the water in the flow control tank 20 is transferred to the first reaction tank ( 30) is supplied. When the raw water stably flows into the first reaction tank 30, the flow control pump 21 does not need to be operated all the time, so power consumption can be reduced, and when the flow rate of the incoming raw water changes rapidly, the screen tank 10 ) Since the raw water flows into the flow control tank 20, the operation of the flow control pump 21 can be minimized.

Therefore, the ball top gate 34 closes the first distribution port 12 corresponding to the water level of the first reaction tank 30, and the second distribution port 13 is formed higher than the first distribution port 12, thereby overflowing the first distribution port 12. function, and the water exceeding the treatment capacity of the first distribution port 12 and the first reaction tank 30 is supplied to the flow control tank 20 through the second distribution port 13, to the screen tank 10 By absorbing and equalizing the temporal fluctuations in the inflow of raw water flow, it can be applied to sewage treatment facilities in small towns with large fluctuations in inflow flow rate, so that sewage can be treated stably and the performance of subsequent processes can be improved.

Referring to FIG. 1 , water introduced into the first reaction tank 30 through the first distribution port 12 is purified through an anaerobic process. The first reactor 30 removes organic matter and nitrogen from water in an anaerobic environment. The first stirrer 32 installed in the first reaction tank 30 is operated so that the inside of the first reaction tank 30 is stirred without supplying oxygen during the anaerobic process, and nitrate nitrogen is finally released as nitrogen gas by denitrifying bacteria. Removed.

In addition, the first reaction tank 30 aerates the first reaction tank 30 through the first blower 33 as well as the anaerobic process, and at this time, some oxygen is supplied, but the anaerobic process is mainly performed in the first reaction tank 30, and aerobic The process is carried out at a lower rate compared to the anaerobic process.

First, when water is supplied from the screen tank 10 to the first reaction tank 30, the first stirrer 32 operates in the first reaction tank 30 to perform an anaerobic process, and then the first blower 33 operates By doing so, the inside of the first reaction tank 30 is aerated to increase the mixing effect of microorganisms and organic substances. The microorganisms in the first reaction tank 30 oxidize and decompose organic matter, and nitrogen and phosphorus (P) are removed.

When the aeration process is completed in the first reaction tank 30, the operations of the first agitator 32 and the first blower 33 are stopped, and a precipitation process is performed. The sedimentation process is a process of gravity settling sludge in water.

When the precipitation process is completed, the water in the first reaction tank 30 is layered into scum, supernatant water, treated water, and sludge from the top layer to the bottom layer as shown in FIG. , Supernatant means water with a high level of purification treatment, treated water means water with incomplete purification treatment compared to supernatant water, and sludge means gravity settled foreign matter.

Here, the decanter 100 is provided in the first reaction tank 30 as shown in FIG. 3 to extract only the supernatant water and transfer it to the next storage tank (here, the second reaction tank 40), and the first reaction tank 30 through the decanter 100 The supernatant of ) is transferred to the second reaction tank 40.

Referring to FIG. 1 , the second reaction tank 40 is a tank for purifying water by mainly creating an aerobic environment, and is provided with a second stirrer 42 and a second blower 43 . The water flowing into the second reaction tank 40 has a small pollution load because organic substances and nitrogen are largely removed from the first reaction tank 30 .

Although the anaerobic process is performed by operating the second agitator 42 without supplying oxygen in the second reaction tank 40, the time of the anaerobic process in the second reaction tank 40 is less than the time of the aerobic process. Contrary to the first reaction tank 30, in the second reaction tank 40, an aerobic state is maintained for a long time, and organic matter and phosphorus are removed in the aerobic process. During the aeration process, the second blower 43 operates to supply oxygen into the second reaction tank 40 .

Thereafter, a precipitation process is performed in the second reaction tank 40, and the second reaction tank 40 is also divided into scum, supernatant water, treated water, and sludge, and only the supernatant water is decanter provided in the second reaction tank 40 ( 100), it is transported to the outside, such as a filtration tank.

The sludge settled by the precipitation process in the first reaction tank 30 and the second reaction tank 40 is the first sludge pump 31 installed in the first reaction tank 30 and the second sludge installed in the second reaction tank 40 It flows into the sludge storage tank by the pump 41.

Also, when the supernatant water in the first reaction tank 30 is transferred to the second reaction tank 40 through the decanter 100, the transfer time is increased. Since the first reaction tank 30 is in a stable state in which the precipitation process is performed and the water quality is divided into layers, this is to prevent the precipitated solids from floating and contaminating the supernatant water.

The decanter 100 shown in FIGS. 4 and 7 is provided in the first reaction tank 30 and the second reaction tank 40. The decanter 100 of the first reaction tank 30 transfers water to the second reaction tank 40, and the decanter 100 of the second reaction tank 40 transfers water to the outside of the filtered water tank. At this time, the decanter 100 transfers only the supernatant of each reaction tank.

The decanter 100 is formed to move up and down along the water level of the reaction tank, and introduces the supernatant formed on the lower layer of the scum into the inside.

The decanter 100 is provided with a buoyancy body 110 at the top to float along the water level of the reaction tank. The buoyancy body 110 may be formed of or embedded in a material having a specific gravity lower than that of water, such as air, gas, or suspended matter. The volume of the buoyancy body 110 may be formed in various ways according to conditions such as density and salinity of water in the reaction tank. All surfaces of the buoyancy body 110 are sealed, and water does not flow into the inside.

Since the buoyancy body 110 floats on the water surface of the reaction tank, the scum does not flow into the decanter 100 through the inlet 150 formed at the bottom of the buoyancy body 110, and the supernatant water located on the lower layer of the scum decanter 100 ) enters the interior. That is, the upper part of the buoyancy body 110 corresponds to the position of the scum, the lower part is located below the scum, and the inlet 150 is located in the supernatant formed in the lower layer of the scum. The buoyancy body 110 is larger than the upper housing 120 and the lower housing 130 on the side and allows the scum to move away from the inlet 150.

An upper housing 120 and a lower housing 130 are provided below the buoyancy body 110 . The upper housing 120 has a hollow interior and an open lower surface, and the lower housing 130 has an open upper surface.

The lower housing 130 has a hollow interior and is smaller in size than the upper housing 120, so that the lower housing 130 is inserted into the open lower surface of the upper housing 120. The upper end of the lower housing 130 is disposed higher than the lower end of the upper housing 120 .

A part or all of the lower housing 130 is accommodated inside the upper housing 120, and a gap is formed between the side surface of the lower housing 130 and the side surface of the upper housing 120. The upper housing 120 side surface and the lower housing 130 side surface are spaced apart from each other through a gap in which the supernatant water of the reaction tank flows into the interior. This gap is referred to as an inlet port 150 .

The upper housing 120 and the lower housing 130 are coupled to each other through a coupling bracket 140. The coupling bracket 140 connects the lower end of the upper housing 120 and the side surface of the lower housing 130, but does not completely seal the inlet 150. The coupling bracket 140 according to an embodiment of the present invention is located at the four corners of the upper housing 120 and the lower housing 130, but does not completely block the inlet 150 and adjusts the opening rate of the inlet 150 appropriately. If you can secure it, it can be located in various places.

Since the upper housing 120 is formed to have a larger size than the lower housing 130 , the coupling bracket 140 is inclined toward the lower housing 130 . That is, the coupling bracket 140 is inclined inward as it goes downward in the upper housing 120 .

When the supernatant water in the reaction tank flows into the decanter 100 through the inlet 150 at a position equal to or lower than the lower end of the upper housing 120, the inner surface of the upper housing 120 and the outer surface of the lower housing 130 It rises along, flows over the upper end of the lower housing 130 (bending wall 137), and flows into the lower housing 130. At this time, the upper end of the side of the lower housing 130 is formed as a bending wall 137 bent toward the inside. Water flowing into the decanter 100 through the inlet 150 can easily flow into the lower housing 130 along the curve of the bent wall 137 .

A transfer pump 170 for sucking in water and discharging it to the outside is provided inside the lower housing 130, and a pump pipe 131 is provided at the discharge port side of the transfer pump 170. The pump pipe 131 may be formed in a bellows shape with a length that is flexible, and the length of the pump pipe 131 may be flexibly adjusted in response to the decanter 100 moving up and down according to the water level of the reaction tank. A pump valve 132 is provided in the pump pipe 131 to open and close the pump pipe 131 . The pump pipe 131 is opened when the transfer pump 170 operates.

The pump pipe 131 extends to the outside of the lower housing 130 to transfer water to the outside. Water enters the inlet 150 and crosses the bending wall 137 and flows into the lower housing 130. The water is transferred to the outside through the transfer pump 170 and the discharge pipe 133 for the next process. It will be. At this time, the transfer pump 170 provided in the first reaction tank 30 transfers water to the second reaction tank 40, and the transfer pump 170 provided in the second reaction tank 40 transfers water to the filter water tank, etc. Water is transported to the process.

It is preferable that the suction power of the transfer pump 170 is formed so as not to disturb the stable sedimentation state inside the reaction tank.

A power cable 134 for supplying power to operate the transfer pump 170 is extended from the outside and connected to the transfer pump 170 . Considering the range in which the decanter 100 moves up and down, the length of the power cable 134 is preferably not tight and has a margin.

The decanter 100 moves up and down in real time according to the water level of the reaction tank, the buoyancy body 110 floats on the surface of the water, and the inlet 150 sinks below the surface of the water. More strictly, the inlet 150 is settled in the supernatant layer formed on the lower layer of the scum.

A guide bar 180 guiding the ascending and descending movement of the decanter 100 is installed in the reaction tank, and an ascending hole inserted into the guide bar 180 is provided in the decanter 100 . The lifting hole is divided into an upper lifting hole 112 and a lower lifting hole 136 according to its location.

The upper lift hole 112 is formed in the upper coupling table 111, and the upper coupling table 111 is coupled to the outer surface of the buoyancy body 110. A lifting hole 113 is formed at the upper end of the upper coupling table 111 and an upper lifting hole 112 is formed at the lower part. A crane is fastened to the lifting hole 113 so that the decanter 100 can be lifted, and the upper lifting hole 112 is inserted into the guide bar 180 to prevent the decanter 100 from swinging left and right and stably so that the lifting operation is performed.

In addition, a lower coupling table 135 is coupled to the lower end of the lower housing 130 in a horizontal direction, and a lower lifting hole 136 is formed in the lower coupling table 135. While the lower coupling table 135 is disposed horizontally on the lower surface of the lower housing 130, the upper coupling table 111 is disposed vertically on the side surface of the buoyancy body 110.

Since the upper and lower elevation holes 112 and the lower elevation holes 136 respectively formed on the upper and lower portions of the decanter 100 are inserted into the guide bar 180, the upper and lower portions of the decanter 100 are supported by the guide bar 180. When the decanter 100 moves up and down along the water level of the reaction tank, its posture can be stably maintained.

In addition, the lower housing 130 is provided with a balance plate 160 arranged in a horizontal direction. The balance plate 160 protrudes outward more than the upper housing 120, and is more stable in leveling by expanding an area in contact with water.

A balance hole 161 is formed in the balance plate 160 to be supported with the guide bar 180 . The upper lift hole 112 and the lower lift hole 136 firmly surround the guide bar 180 through the inner hole, and the balance hole 161 disposed between the upper lift hole 112 and the lower lift hole 136. ) is supported by the guide bar 180 so that the decanter 100 is stably maintained horizontally without overturning while moving up and down along the water level of the reaction tank.

The decanter 100 sucks in the supernatant and discharges it to the outside while sludge such as foreign substances is accumulated on the inner lower part of the lower housing 130, and a discharge pipe 133 is provided to discharge the sludge. The discharge pipe 133 is closed when the transfer pump 170 operates, so that water does not flow into the decanter 100 through the discharge pipe 133, and when the sludge is accumulated inside the decanter 100 above a certain level Open the discharge pipe 133 to discharge. When discharging the sludge inside the decanter 100, it can be done after taking it out of the reaction tank by connecting a crane to the lifting hole 113.

Since the inlet 150 of the decanter 100 is submerged below the water surface, water in the reaction tank flows in through the inlet 150. When the anaerobic process and the aerobic process are performed in the reaction tank, the blower and the agitator are operated to float sludge such as foreign substances in the water. This sludge sinks to the bottom during the settling process, and the inflow of the floating sludge into the decanter 100 must be blocked before the settling process.

Therefore, the decanter 100 of the present invention blocks water in the reaction tank from entering the decanter 100 by filling the inner space with air until the precipitation process is completed. An air hose 121 for supplying external air to the inside of the decanter 100 through a compressor (not shown) is provided to fill the air into the decanter 100 . The air hose 121 is connected to the inside of the decanter 100 and is provided in a bellows shape whose length can be varied along the ascending decanter 100.

The air hose 121 is provided with a supply valve 122 for supplying air into the decanter 100 and a discharge valve 123 for discharging air inside the decanter 100 to the outside. The supply valve 122 and the discharge valve 123 are controlled to open and close.

In order to prevent the water in the reaction tank from flowing into the decanter 100 before the anaerobic process and the aerobic process are performed and the precipitation process is completed, the supply valve 122 is opened to fill the decanter 100 with air, but the inlet Fill until air is discharged through (150). When the operator opens the supply valve 122 and confirms that air bubbles rise to the inlet 150 while filling the inside of the decanter 100 with air, it can be seen that the inside of the decanter 100 is completely filled with air. Thereafter, the supply valve 122 is closed to stop filling of air.

In a state in which the inside of the decanter 100 is filled with air and an air layer is formed, the anaerobic process and the aerobic process proceed in the reaction tank, and water in the reaction tank does not flow into the decanter 100 until the subsequent precipitation process is completed.

And after the precipitation process is completed, the water in the reaction tank is divided layer by layer, and in order to introduce the supernatant water into the decanter 100, the closed discharge valve 123 is opened to release the air filled in the decanter 100 to the outside. discharge

As the air inside the decanter 100 is discharged to the outside through the discharge valve 123 provided in the air hose 121, the supernatant water in the reaction tank flows into the decanter 100 and the transfer pump 170 operates to transport it to the outside do.

Looking at the sewage treatment procedure using the multi-stage sewage treatment system of the present invention with reference to Figs. .

The water filtered through the screen 11 flows into the first reaction tank 30 through the first distribution port 12 and the water level in the first reaction tank 30 rises. At this time, when the flow rate flowing into the screen group 10 increases rapidly and becomes greater than the discharge capacity of the first distribution port 12, the water level of the screen group 10 rises, and the water level of the screen group 10 rises to the second When it rises to the height of the distribution port 13, some of the water flows into the flow control tank 20. Alternatively, when the water level in the first reaction tank 30 rises above a certain level, the ball top gate 34 closes the first distribution port 12 and the water level in the screen tank 10 rises, and the water level rises for the second minute. When it rises to the volleyball 13, it flows into the flow control tank 20 through the second distribution port 13. The water flowing into the flow control tank 20 is supplied to the first reaction tank 30 through the flow control pump 21 when there is a surplus in the treatment capacity of the first reaction tank 30 .

When the water level in the first reaction tank 30 rises, the decanter 100 provided in the first reaction tank 30 rises along with the water level. Since the balance hole 161 is supported by the guide bar 180 and the area in which the balance plate 160 contacts water is expanded, the lifting operation of the decanter 100 is stable and balanced.

An anaerobic process and an aerobic process are performed in the first reaction tank 30, but the anaerobic process is mainly performed, and the first blower 33 and the first stirrer 32 operate. Thereafter, the precipitation process is performed. Before the precipitation process is completed, the supply valve 122 is opened to prevent the water in the first reaction tank 30 from entering the decanter 100, and the decanter through the air hose 121 ( 100) Fill the inside with air. At this time, the discharge valve 123 and the pump valve 132 are closed. The operator can confirm that the inside of the decanter 100 is completely filled by confirming that air bubbles rise through the inlet 150 while filling the inside of the decanter 100 . Then, the supply valve 122 is closed to stop filling the air.

When the precipitation process is completed, the air inside the decanter 100 is discharged to the outside by opening the discharge valve 123 to allow the supernatant to flow into the decanter 100. After sufficiently discharging air, the discharge valve 123 is closed, and supernatant water flows into the decanter 100 through the inlet 150. Then, the pump valve 132 is opened and the transfer pump 170 is operated to supply supernatant water in the first reaction tank 30 to the second reaction tank 40 .

As the water level in the first reaction tank 30 decreases, the decanter 100 also descends along the guidance of the guide bar 180. When the decanter 100 moves up and down, the air hose 121 and the pump pipe 131 may be expanded and contracted according to their height.

In the second reaction tank 40, the anaerobic process and the aerobic process are performed, but the aerobic process is mainly performed, and the second stirrer 42 and the second blower 43 operate. When the precipitation process is completed, the decanter 100 provided in the second reaction tank 40 also performs the same operation as the decanter of the first reaction tank 30, and the supernatant water of the second reaction tank 40 is transferred to a filtered water tank, etc. discharge to the outside

And the sludge precipitated in the first reaction tank 30 and the second reaction tank 40 is discharged to the sludge storage tank through the first sludge pump 31 and the second sludge pump 41, respectively.

In the multi-stage sewage treatment system according to the present invention, a reaction tank for treating sewage in a batch manner is divided into a first reaction tank 30 and a second reaction tank 40, and in the first reaction tank 30, the anaerobic process is mainly performed, and the second reaction tank 40 ), the aerobic process is mainly performed, which can minimize the stress of microorganisms due to rapid environmental changes.

In addition, since the decanter 100 tracks the water level in the reaction tank in real time, there is no need to provide a separate lifting device, and a stable lifting operation is possible according to the guidance of the guide bar 180.

In addition, by filling the inside of the decanter 100 (the inside of the lower housing 130) with air through the air hose 121, sludge such as foreign substances is prevented from entering the decanter 100 before the settling process is completed, When the precipitation process is completed, only the supernatant water can be introduced by discharging the air filled therein.

10: screen group 11: screen 12: first distribution port 13: second distribution port
20: flow adjustment tank 21: flow adjustment pump
30: first reaction tank 31: first sludge pump 32: first agitator 33: first blower 34: ball top gate
40: second reaction tank 41: second sludge pump 42: second agitator 43: second blower
100: decanter
110: buoyancy body 111: upper coupling table 112: upper lifting hole 113: lifting hole
120: upper housing 121: air hose 122: supply valve 123: discharge valve
130: lower housing 131: pump pipe 132: pump valve 133: discharge pipe
135: lower coupling table 136: lower lifting hall 137: bending wall
140: coupling bracket 150: inlet 160: balance plate 161: balance hole
170: transfer pump 180: guide bar

Claims (7)

A screen tank (10) for filtering impurities from incoming raw water through a screen (11) provided therein;
a first reaction tank (30) for purifying the water flowing in from the screen tank (10);
a second reaction tank 40 which purifies the water introduced from the first reaction tank 30; and
It ascends and descends along the vertical guide bar 180 installed in the first reaction tank 30 and the second reaction tank 40, and is provided with a buoyancy body 110 floating along the water level of the reaction tank at the top. Including; decanter 100 for transporting the supernatant at a position lower than (110) to the inside and to the outside,

The decanter 100 is
an upper housing 120 provided under the buoyancy body 110 and having an open lower surface;
It is inserted into the upper housing 120, is formed in a smaller size than the upper housing 120, has an upper end disposed higher than the lower end of the upper housing 120, and has a side wall at the lower end of the upper housing 120. a lower housing 130 protruding downward and having an open upper surface;
a coupling bracket 140 connecting the upper housing 120 and the lower housing 130; and
It is formed as a spaced gap between the side surface of the upper housing 120 and the side surface of the lower housing 130, and the reaction tank water at a position lower than the lower end of the upper housing 120 overflows the upper end of the lower housing 130 to enter the interior It further includes; an inlet 150 flowing into the

The upper surface of the housing 130 always remains open;
The lower housing 130 is a plate disposed in the horizontal direction, protrudes outward from the upper housing 120, and is disposed below the inlet 150 and expands the contact area with water (160). );
Multi-stage sewage treatment system.
According to claim 1,
In the screen group 10
A first distribution port 12 that supplies water filtered through the screen 11 to the first reaction tank 30 and is opened and closed by a ball top gate 34 that moves up and down according to the water level of the first reaction tank 30 ; and
A second distribution port 13 formed higher than the first distribution port 12 and supplying the water filtered through the screen 11 to the flow control tank 20 for temporarily storing it
Multi-stage sewage treatment system.
delete delete According to claim 1,
The decanter 100 further includes an air hose 121 receiving air from the compressor;
During the aeration process or sedimentation process of the reaction tank, air is supplied into the decanter 100 through the air hose 121 to form an air layer inside the decanter 100 and the water in the reaction tank does not flow into the decanter 100. do not;
After the precipitation process is finished, the air inside the decanter 100 is discharged to the outside through the air hose 121 so that the supernatant is introduced into the reaction tank;
Multi-stage sewage treatment system.
According to claim 1,
The decanter 100 is
an upper lifting hole 112 disposed on the buoyancy body 110 and inserted into a guide bar 180 installed vertically in the reaction tank to guide the lifting movement of the decanter 100;
a lower elevation hole 136 disposed in the lower housing 130 and inserted into the guide bar 180; and
A balance hole 161 formed in the balance plate 160 between the upper elevation hole 112 and the lower elevation hole 136 and supported by the guide bar 180; further comprising
Multi-stage sewage treatment system.
According to claim 1,
The coupling bracket 140 is formed inclined inward toward the lower housing 130
Multi-stage sewage treatment system.

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