KR102141378B1 - Decanter apparatus to discharge supernatant - Google Patents

Abstract

The present invention relates to a treated water discharge apparatus which enables continuous discharge of supernatant water along with sludge precipitation from the time when a supernatant layer of a certain level is secured while sludge precipitation occurs in a precipitation process for solid-liquid separation of the supernatant water and active microorganisms after an aerobic process in a batch-type reactor for treating sewage or wastewater, specifically, in an SBR reactor. The present invention has the advantage of shortening two processes consisting of precipitation and discharge of the conventional SBR method into one process.

Description

DECANTER APPARATUS TO DISCHARGE SUPERNATANT

The present invention is a batch reactor for treating sewage or wastewater, specifically, a supernatant layer of a certain water level is secured during the process of sludge precipitation in the sedimentation process in which the active microorganisms and supernatant are separated by solid-liquid separation after the aerobic process in the SBR (Sequencing batch reactor) It relates to a treatment water discharging device that continuously discharges the supernatant with sludge sedimentation.

In general, sewage and wastewater including municipal sewage, livestock wastewater, agricultural wastewater, and industrial wastewater contain nutrients including organic matter and nitrogen and phosphorus. This increase in nutrients destroys the balance of the ecosystem, and causes eutrophication, causing water pollution problems.

In general, sewage and wastewater are mostly treated by activated sludge. Among the activated sludge process, SBR (Sequencing batch reactor) is a method of sequentially performing anoxic, anaerobic and aerobic processes in a single reactor to remove nutrients such as nitrogen or phosphorus. have.

In the SBR method, nitrogen is processed through denitrification and nitrification through bioreaction under anaerobic or anaerobic conditions and aerobic conditions depending on whether oxygen is supplied in a single reactor, and phosphorus release and phosphorus over-absorption are induced. And nutrients. In this process, some of them are converted into surplus microorganisms by microbial growth and accumulated in the bottom of the reaction tank in the form of sludge during the precipitation process to be drawn and treated. At this time, supernatant is present at the top of the reaction tank.

As the supernatant water is discharged as treated water, a decanter, which is a discharge device, is used so that the sediment and the floating material, Scum, are not discharged together. The decanter discharges supernatant water without disturbing the sludge layer to prevent deterioration of the water quality of the treated water.

In the conventional case, the sewage introduced from the bioreactor was usually allowed to discharge the supernatant only after waiting for the separation of the supernatant by sludge precipitation by setting the precipitation time for solid-liquid separation for at least 2 hours after the biological reaction for at least 3 hours.

In addition, a prior art document (Korean Patent Registration No. 0535379) discloses a decanter applicable to a batch-type water treatment system. However, the decanter disclosed in the above-mentioned prior art can be driven in a state of being completely submerged in supernatant water. Therefore, it is applicable only when the supernatant is formed above a certain level. In particular, the decanter disclosed in the above prior art does not disclose a configuration for preventing the inflow of scum formed on the water surface. Accordingly, scum is forced into the decanter in an initial state in which wastewater to be treated is introduced into the reactor, and there is a limit to retain supernatant water above a certain level in the reactor even in the final state.

Korean Patent Registration Publication No. 0535379

The present invention was devised to solve the above problems, and a decanter device capable of simultaneously performing sludge precipitation and discharge of supernatant water after formation of a supernatant layer of a certain water level by monitoring the sludge interface of the reactor in the precipitation process of the SBR method. By providing, it is an object of the present invention to shorten the process time by simultaneously performing precipitation and discharge processes in the SBR method of sequentially performing supernatant discharge after precipitation.

The present invention provides a decanter device for discharging supernatant formed during the sludge precipitation process of the SBR (Sequencing batch reactor) method for treating sewage or wastewater. In one example, the decanter device, one surface is coupled to the decanter support member, the opposite surface of the surface coupled to the decanter support member is a structure in which supernatant is introduced, and a decanter body moving along the decanter support member; A scum wall that covers the open surface of the decanter body and is connected to the decanter body by a connect arm, opening or closing the open surface of the decanter body by the movement of the connect arm; A connect arm structurally connecting the decanter body and the scum wall, but opening or closing the scum wall; And a decanter support member that controls the level of the decanter body to correspond to the sleep level by a moving shaft or wire.

In one example, the decanter support member, the level of the decanter body is controlled by the moving shaft to correspond to the water level, the shaft is a rotating shaft formed with a thread on the outer circumferential surface, the decanter body is a through-hole through the moving shaft It includes, and the inner circumferential surface of the through hole is a structure in which a screw line corresponding to the screw line formed on the outer circumferential surface of the moving shaft is formed.

In a specific example, the decanter body is raised or lowered along the movement axis by rotation in one direction or in the opposite direction of the movement axis.

In one example, the connect arm is a structure that swings a fixed pin formed on the side surface of the decanter body as an axis, and when the scum wall descends due to the swing of the connect arm, the lower joining line between the scum wall and the decanter body is opened. As it is, the supernatant is introduced.

In a specific example, the decanter device includes: an upper stopper formed on the decanter support member; And a lower stopper formed on the side of the decanter body, wherein the swing motion of the connect arm is a structure limited by the upper and lower stoppers.

In another specific example, the decanter body moves along the decanter support member,

When the decanter body is at the maximum level, the connect arm is fixed by the upper stopper to keep the scum wall closed, and when the decanter body is below the maximum level, the connect arm is restricted by the lower stopper to limit the scum wall. It is a structure to control the open range of.

For example, in the decanter device, when the connect arm is restricted by the lower stopper and the scum wall is opened, the opened inlet height ranges from 20 cm to 40 cm.

In one example, the connect arm includes a connecting bar for structurally connecting a fixing pin formed on a side of the decanter body and a scum wall; And an extension bar extending from one end of the connecting bar toward the decanter support member.

In a specific example, the extension bar is a structure bent at an angle in the range of 10° to 60° from the longitudinal extension line of the connection bar.

In another example, the decanter device according to the present invention further includes a pipe that is fluidly connected to the decanter body and discharges the supernatant flowing into the decanter body into the treatment tank.

In another example, the lower end of the open side of the decanter body is a structure in which a V-notch weir is formed.

In another example, it further includes at least one of a sludge interface sensor and an underwater particulate matter measurement sensor.

In a specific example, the decanter support member further includes a wire member that controls the height of the decanter body, and the level of the decanter body is controlled by the wire member to correspond to the sleep level.

In another specific example, the lower portion of the decanter body is a structure in which the cross-sectional area is sequentially narrowed, and the scum wall includes a structure bent at an angle to correspond to the lower portion of the decanter body in which the cross-sectional area is narrowed.

The decanter device according to the present invention further improves the biological water treatment process time by shortening the sedimentation and discharge processes of the conventional SBR process to one process by simultaneously performing sludge sedimentation and supernatant discharge through sludge interface monitoring during the sedimentation process of the SBR process. can do. In addition, the decanter device according to the present invention has an advantage in that it is possible to reduce the hydraulic residence time compared to the existing SBR method, thereby increasing the treatment capacity of sewage wastewater in the same area.

1 shows a sewage treatment process in a batch reactor (SBR; Sequencing Batch Reactor) to which a decanter device according to an embodiment of the present invention is applied.
2 is a perspective view showing a decanter device according to an embodiment of the present invention.
Figure 3 shows a decanter device according to an embodiment of the present invention, a side view showing a state in which the connect arm is fixed by the upper stopper and the scum wall is closed.
4 illustrates a decanter device according to an embodiment of the present invention, and is a side view showing a state in which the scum wall is opened because the connect arm is restricted by the lower stopper.
Figure 5 shows the opening surface of the decanter body according to an embodiment of the present invention.
6 shows a driving process of a decanter device according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail. Prior to this, the terms or words used in the present specification and claims should not be interpreted as being limited to ordinary or lexical meanings, and the inventor appropriately explains the concept of terms to explain his or her invention in the best way. It should be interpreted as a meaning and a concept consistent with the technical idea of the present invention based on the principle that it can be defined as such.

The present invention relates to a decanter device for discharging supernatant formed during the sludge precipitation process of the SBR (Sequencing batch reactor) method for treating sewage or wastewater.

In one embodiment, the decanter device according to the invention,

One surface is coupled to the decanter support member, the opposite surface of the surface coupled to the decanter support member is a structure in which supernatant is introduced, and a decanter body moving along the decanter support member;

A scum wall that covers the open surface of the decanter body and is connected to the decanter body by a connect arm, opening or closing the open surface of the decanter body by the movement of the connect arm;

A connect arm structurally connecting the decanter body and the scum wall, but opening or closing the scum wall; And

It includes a decanter support member for controlling the level of the decanter body to correspond to the sleep level by a moving shaft or wire.

The decanter device of the present invention can block the inflow of the scum existing on the surface of the water through the scum wall, and it is possible to discharge the supernatant located at the bottom of the scum into the decanter body and then discharge it to the next stage treatment tank. In addition, the decanter device can discharge the supernatant separated from the precipitated sludge in real time by adjusting the height of the decanter device to correspond to the water level.

In one embodiment, the decanter support member, the level of the decanter body is controlled by the moving shaft to correspond to the sleep level, the moving shaft is a rotating shaft formed with a screw thread on the outer circumferential surface, the decanter body passes through the moving shaft The structure includes a through hole, and a screw line corresponding to a screw line formed on the outer circumferential surface of the moving shaft is formed on the inner circumferential surface of the through hole. Specifically, the decanter body is raised or lowered along the moving axis by rotation in one direction or the opposite direction of the moving axis. In the present invention, the position of the decanter device is controlled by rotating the moving shaft on which the thread is formed on the outer circumferential surface. The decanter device according to the present invention rises or falls corresponding to the sleep level, and at the same time, it is possible to continuously treat the supernatant water while blocking the inflow of the skim. In addition, the present invention moves the decanter device using a moving shaft, thereby enabling more stable and sophisticated control.

In another embodiment, the decanter device is structured to be raised or lowered by a wire formed on the decanter support member. In this case, the decanter body fastened to the wire is structured to rise or fall as the wire moves.

In another embodiment, the connect arm is a structure in which the connect arm swings a fixed pin formed on the side of the decanter body in an axis, and when the scum wall descends due to the swing of the connect arm, the scum wall and decanter The lower junction line of the body is opened, and supernatant is introduced. In addition, by forming a sealing member at a portion where the scum wall and the decanter body contact each other, the sealing property between the scum wall and the decanter body can be enhanced. The sealing member is not particularly limited, and may be formed of, for example, a member having elasticity such as rubber or resin, and its shape includes a pad, a structure having an uneven pattern formed on the pad, or the like.

In a specific embodiment, the decanter device includes: an upper stopper formed on the decanter support member; And a lower stopper formed on the side of the decanter body, wherein the swing motion of the connect arm is a structure limited by the upper and lower stoppers. For example, the upper stopper is formed on the decanter support member, and is fixed to a specific height. When the sedimentation tank is at full water level, the connect arm is fixed and fixed to the upper stopper, and at this time, the scum wall is in a state of closing the open surface of the decanter body. Then, when the decanter body descends vertically along the decanter support member, the fixation to the connect arm, which is limited to the upper stopper, is released. When the connection arm is disengaged, the scum wall moves to the bottom of the decanted body. At this time, when the scum wall descends, the lower joining line between the scum wall and the decanter body is opened.

In summary, in the present invention, the decanter body moves up and down along the decanter support member, but when the decanter body is at the maximum level, the connect arm is fixed by the upper stopper to keep the scum wall closed, and the decanter When the body is below the maximum level, the connect arm is restricted by the lower stopper to control the opening range of the scum wall. Therefore, the present invention does not require a separate power source for opening and closing the scum wall. The present invention provides an energy-saving water treatment device in which the opening and closing of the scum wall is interlocked with the non-power according to the vertical movement of the decanter.

For example, in the decanter device, when the connect arm is restricted by the lower stopper and the scum wall is opened, the opened inlet height ranges from 20 cm to 40 cm. The height of the inlet part is based on the case where the scum wall is fully opened. By controlling the inlet height to the above range, it is possible to prevent the sediment from entering the sludge interface without reducing the water treatment capacity.

In one embodiment, the connect arm includes a connecting bar for structurally connecting a fixing pin formed on a side surface of the decanter body and a scum wall; And an extension bar extending from one end of the connecting bar toward the decanter support member. The connecting bar and the extension bar divide the connect arm into regions or parts. The connecting bar and the extension bar may be in the form of a single connected bar or may be separated and connected.

For example, the extension bar may be a structure bent at an angle in the range of 10° to 60° from the longitudinal extension line of the connection bar. The bending angle of the extension bar can be variously modified, for example, 10° to 45°, 20° to 60°, or 25° to 45°.

In one embodiment, the decanter device according to the present invention further comprises a pipe which is fluidly connected to the decanter body and discharges the supernatant flowing into the decanter body into the treatment water tank. Through the piping, the decanter device according to the present invention can continuously process the supernatant formed in the reaction tank.

In another embodiment, the lower end of the open surface of the decanter body is a structure in which a V-notch weir is formed. Since the decanter body has a water collecting structure to which V-notch weir is applied, it is possible to effectively control the overflow load flowing into the decanter body.

In another embodiment, the decanter device according to the present invention further includes at least one of a sludge interface sensor and an underwater particulate matter measurement sensor. It is possible to monitor the interface of the sludge and/or the concentration of particulate matter in water by using the sludge interface sensor or the underwater particulate matter measurement sensor, thereby minimizing the introduction of sludge into the decanter body. For example, the sludge interface sensor or underwater particulate matter measurement sensor may be formed at the bottom of the decanter device, specifically, below the decanter body or below the scum wall. In the present invention, it is possible to apply sensors for measuring the level of the sludge interface to the concentration of particulate matter in water, etc., and various types of sensors performing these functions should be interpreted as the scope of the present invention.

In one embodiment, in the decanter device according to the present invention, the lower portion of the decanter body is a structure in which the cross-sectional area is sequentially narrowed, and the scum wall includes a structure bent at an angle to correspond to the lower portion of the decanter body where the cross-sectional area is narrowed. do. In the present invention, the lower portion of the decanter body is a structure in which the cross-sectional area is sequentially narrowed. Through this, even if the decanter device descends below a certain height, it is possible to minimize the area in contact with the precipitated sludge under the sedimentation tank. When the sludge precipitated during the descending process of the decanter device is brought into contact with a large area, a phenomenon in which a part of the precipitated sludge in the contacted range flows back into the supernatant may be caused. The decanter device according to the present invention, by forming the lower portion of the decanter body relatively narrow, it is possible to minimize or prevent the phenomenon that a part of the precipitated sludge flows back into the supernatant water even if it contacts the sludge precipitated by the descending of the decanter device. In addition, the scum wall is a structure that is bent at a certain angle to correspond to a lower portion of the decanter body having a narrow cross-sectional area, thereby closing the open surface of the decanter body by the scum wall.

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

1 shows a sewage treatment process in a batch reactor (SBR; Sequencing Batch Reactor) to which a decanter device according to an embodiment of the present invention is applied. Referring to FIG. 1, the batch reactor (SBR) 1 is divided into a bioreactor 10 and a treatment tank 20 in which bioreaction and sludge precipitation are performed.

Sewage treatment using a batch reactor (SBR) is a process in which all processes, from the inflow of sewage to the outflow of treated water, are continuously performed according to the arrangement of time set in a single reactor. In the batch reactor, the inflow of sewage, bioreaction, sedimentation, and discharge proceed in order, and the sewage is continuously or intermittently introduced. In the SBR method, since all reactions are performed in a single reactor, there is an advantage that there is no sludge return, no sedimentation basin is required, and the facility is simple, thereby ensuring flexibility in operation. When using the continuous batch single reactor method as described above, a decanter must be installed to discharge the treated water.

The sewage introduced into the bioreactor 10 undergoes a process of being purified by aerobic microorganisms while staying for about 4 to 8 hours. At this time, in order to vigorously decompose the organic matter, the bioreactor 10 supplies sufficient oxygen to cause microorganisms to proliferate using the organic matter in the sewage, and precipitates sludge for solid-liquid separation. Sludge is deposited in the lower part of the bioreactor 10, and the precipitated sludge is returned or discharged to the outside to undergo a separate surplus sludge treatment process for concentration, dehydration and disposal. On the other hand, the supernatant water is discharged to the treatment water tank 20 using the decanter 100. In addition, the treated water tank 20, the supernatant water is introduced through the decanter device 100 of the bioreactor 10, and collects it for discharge.

2 is a perspective view showing a decanter device according to an embodiment of the present invention. Referring to FIG. 2, the present invention relates to a decanter device 100 for discharging supernatant formed during a sludge precipitation process for treating sewage or wastewater. The decanter device 100 includes a container-shaped decanter body 110 having an open surface; A scum wall 120 that opens and closes the open surface of the decanter body 100; And a connect arm 130 structurally connecting the decanter body 100 and the scum wall 120.

Specifically, the decanter body 110 is in the shape of a hollow prismatic container, one surface is coupled to the decanter support member 140, the opposite surface of the surface coupled with the decanter support member 140 is opened, and the supernatant is introduced. It is structured and moves up and down along the decanter support member 140. The scum wall 120 is a form that covers the open surface of the decanter body 110, and is connected to the decanter body 110 by the connect arm 130, but is connected to the movement of the connect arm 130. By this, the open surface of the decanter body 110 is opened or closed by a non-power. The connect arm (130) structurally connects the decanter body (110) and the scum wall (120), but swings based on the fixing pin (133) formed on the side of the decanter body (110), and the scum Control the opening or closing of the wall 120.

In addition to this, the decanter device 100 according to the present invention is fixed to the decanter body 110, a decanter support member 140 with a rail formed to allow vertical movement; And a pipe (not shown) that is fluidly connected to the decanter body 110 and discharges the supernatant flowing into the decanter body 110 into the treatment water tank when the scum wall 120 is opened.

The decanter body 110 is fixed to the decanter support member 140 on which the rail 142 allowing vertical movement is formed to move. Specifically, the decanter support member 140 further includes a moving shaft 141 that controls the height of the decanter body 110, and sleeps the level (height) of the decanter body 110 by the moving shaft 141. It is possible to control to correspond to the level. The moving shaft 141 is a rotating shaft with a screw thread formed on the outer circumferential surface, the decanter body 110 includes a through hole through the moving shaft 141, and an inner circumferential surface of the through hole is formed on the outer circumferential surface of the moving shaft 141. It is a structure in which a screw line corresponding to the screw line is formed. Specifically, the decanter body 110 is raised or lowered along the movement shaft 141 by rotation in one direction or the opposite direction of the movement shaft 141.

Meanwhile, the decanter body 110 is a space into which supernatant water flows, and the inside is a hollow container shape. The lower portion of the decanter body 110 is a structure in which the cross-sectional area is sequentially narrowed, and the upper one side is partially open. The decanter body 110 has a structure in which one surface is in contact with the decanter support member 140 and the other surface is in contact with the scum wall 120. The open surface of the decanter body 110 is a structure that can be opened and closed by the scum wall 120. When the scum wall 120 moves downward, the open surface of the decanter body 110 is opened and the supernatant is introduced downward.

The scum wall 120 is a structure that covers the open surface of the decanter body 110, and the lower part of the scum wall 120 is bent at a constant angle so as to correspond to the lower portion of the decanter body 110 having a narrow cross-sectional area. to be.

The scum wall 120 includes a scum wall front cover 121 and a scum wall side cover 122. The scum wall front cover 121 is a form that covers the open surface of the decanter body 110. The scum wall side cover 122 is extended and vertically bent at both sides of the scum wall front cover 121. The scum wall side cover 122 blocks the inflow of scum or supernatant water from the side when the scum wall 120 is opened. In addition, the scum wall 120 has a structure in which a hole is formed and a pipe 123 is inserted therein. The pipe 123 is fastened to one end of the connect arm 130.

Figure 3 shows a decanter device according to an embodiment of the present invention, a side view showing a state in which the connect arm is fixed by the upper stopper and the scum wall is closed. Referring to FIG. 3, a step portion (dashed line portion) may be formed inside the scum wall 120, thereby increasing adhesion between the scum wall 120 and the decanter body 110.

The connect arm 130 is a structure in which the fixing pin 133 formed on the side surface of the decanter body 110 is swinged to the central axis, and serves to structurally connect the decanter body 110 and the scum wall 120. Specifically, the connecting arm 130 includes a connecting bar 131 connecting between the fixing pin 133 formed on the side of the decanter body 110 and the pipe 123 of the scum wall 120; And an extension bar 132 extending in the direction of the decanter support member 140 at one end of the connection bar. In some cases, a separate fixing pin (not shown) is formed on the side surface of the scum wall 120, and a structure for fastening the connection bar 131 is also possible.

The extension bar 132 is bent at an angle of about 20° from the longitudinal extension line of the connection bar 131. In the present invention, the maximum level (highest rising point) and minimum level (lowest falling point) of the decanter device 100 according to the angle of inclination formed between the connecting bar 131 and the extension bar 132 constituting the connect arm 130 Can be adjusted.

The connect arm 130 as described above connects between the decanter body 110 and the scum wall 120. In addition, the scum wall 120 is moved in the vertical direction by the movement of the connecting arm 130 about the fixing pin 133 as an axis. Specifically, when the connect arm 130 swings counterclockwise, the scum wall 120 descends relative to the decanter body 110, at this time, the lower junction of the scum wall 120 and the decanter body 110 The line opens. In addition, when the connect arm 130 swings clockwise, the scum wall 120 rises by the height of the decanter body 110, and at this time, the lower joining line between the scum wall 120 and the decanter body 110 is Is closed. Through the movement of the scum wall 120, the opening and closing between the scum wall 120 and the decanter body 110 are controlled, and supernatant water flows into the decanter device 110 along the opened gap.

Meanwhile, the decanter device according to the present invention includes an upper stopper 143 and a lower stopper 111 that control the swing range of the connect arm 130. Specifically, the upper stopper 143 is a projection formed on the decanter support member 140, and the lower stopper 111 is a projection formed on the side of the decanter body 110. The movements of the connecting bar 131 and the extension bar 132 of the connect arm 130 are restricted through the upper and lower stoppers of the projection type, and accordingly, the movement of the scum wall 120 is controlled.

Specifically, when the decanter body 110 is at the maximum level (highest height), the connect arm 130 is fixed by the upper stopper 143. Referring to FIG. 3, the extension bar 132 of the connect arm 130 is prevented from swinging counterclockwise by the upper stopper 143 to limit the connect arm 130. At the same time, the scum wall 120 is in close contact with the open surface of the decanter body 110 to maintain a closed state.

4 illustrates a decanter device according to an embodiment of the present invention, and is a side view showing a state in which the scum wall is opened because the connect arm is restricted by the lower stopper. Referring to FIG. 4, when the decanter body 110 is at a minimum level (lowest height), the connection bar 131 of the connect arm 130 is restricted in swing in the counterclockwise direction by the lower stopper 111 to connect Limit the arm 130. At the same time, an open gap is formed between the scum wall 120 and the decanter body 110, through which supernatant water flows into the decanter device 100. In some cases, the decanter device 100 according to the present invention further includes at least one of a sludge interface sensor and an underwater particulate matter measurement sensor.

Specifically, when the interface height measured by the sludge interface sensor is equal to or less than a predetermined height, the decanter body 110 descends to open the scum wall 120, and supernatant water flows through the opened gap. On the other hand, when the sludge interface height measured by the sludge interface sensor is higher than a predetermined height, the decanter body is stopped to reduce the inflow of supernatant water, and finally the decanter device is moved to the maximum level to block the inflow of supernatant water. For the sludge interface sensor, for example, an optical sensor or an ultrasonic sensor can be applied. It is possible to check the level of the sludge interface by irradiating light to ultrasonic waves of a specific wavelength and receiving light or ultrasonic waves reflected therefrom.

In addition, when the concentration of the particulate matter in water measured by the underwater particulate matter measurement sensor is equal to or less than the predetermined concentration, the decanter body 110 descends, the scum wall 120 is opened, and supernatant water is introduced through the opened gap. On the other hand, when the concentration of the particulate matter in water measured by the underwater particulate matter measurement sensor is greater than or equal to a predetermined concentration, the decanter body is stopped to reduce the inflow of supernatant water, and finally the decanter device is moved to the maximum level to induce the inflow of supernatant water. Cut off. The underwater particulate matter measurement sensor may be, for example, a turbidimeter or the like.

In the decanter device 100, when the connect arm 130 is restricted by the lower stopper 111 and the scum wall 120 is opened, the opened inlet height H ranges from about 25 cm to 35 cm. The height of the inlet is based on the case where the scum wall 120 is fully opened.

Figure 5 shows the opening surface of the decanter body according to an embodiment of the present invention. 5, the lower end of the open surface of the decanter body 110 is a structure in which a V-notch weir 160 is formed. Since the decanter body 110 has a water collecting structure to which the V notch wear 160 is applied, it is possible to effectively control the overflow load flowing into the decanter body 160. The V-notch wear 160 is also called a triangular notch wear, and the V-notch wear 160 has a structure in which a partition wall such as a beam is installed in a direction perpendicular to a fluid flow of supernatant water.

Hereinafter, a driving method of the decanter device of the present invention will be described. 6 shows a driving process of a decanter device according to an embodiment of the present invention.

Referring to FIG. 6, the decanter device is driven at a maximum level and lowered to a maximum level or lower to reach a minimum level. In FIG. 6, the level of sleep is indicated by a dotted line. Specifically, in the decanter device, the connect arm tries to swing counterclockwise due to the weight of the scum wall. However, referring to FIG. 6A, the movement of the extension bar of the connect arm is restricted by the upper stopper so that the scum wall does not descend. At the same time, in this case, the decanter body has reached the maximum level.

Thereafter, when the sludge interface sensor is measured, when the sludge interface is lowered below a certain height, or when the concentration of the particulate matter in water by the underwater particulate matter measurement sensor falls below the minimum concentration, the decanter body is lowered. Referring to Figures 6b and 6c, the decanter body is lowered by the wire member. In this case, as the separation distance is secured between the upper stopper and the extension bar, the connect arm swings clockwise. At the same time, the lower wall of the scum wall and the decanter body opens as the scum wall descends. The supernatant water flows into the scum wall through the open line, and the scum wall continuously blocks the inflow of scum formed on the water surface. The introduced supernatant is discharged to the treatment tank through piping.

The discharge of the supernatant using a decanter device and the sludge precipitation proceed simultaneously at the bottom of the bioreactor. That is, in the prior art, the process efficiency was lowered by discharging the supernatant water after the sludge precipitation was completed, but the discharge of the supernatant water and the sludge precipitation can be performed simultaneously even before the precipitation is completed by using the decanter device of the present invention.

On the other hand, after the gap between the scum wall and the decanter body gradually increases due to the descending of the decanter body, the descent of the scum wall is stopped as shown in FIG. 6D. This is because the connect arm is stopped by contacting the lower stopper formed on the side of the decanter body.

The decanter device 100 of the present invention as described above can effectively discharge the supernatant water while blocking the inflow of the scum existing on the water surface through the scum wall. In addition, the level of the decanter device can be controlled to correspond to the level of the water surface, through which the sludge precipitation and supernatant discharge can be simultaneously performed. In addition, the sludge interface height is monitored by the sludge interface sensor, and at the same time, the inflow of the sludge can be minimized by monitoring the concentration of the particulate matter in water by the underwater particle measurement sensor. In addition, as the decanter device 100 moves, opening and closing of the scum wall 120 is interlocked with a non-power, thereby saving energy.

The above description is merely illustrative of the technical spirit of the present invention, and those of ordinary skill in the art to which the present invention pertains will be capable of various modifications and variations without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical spirits within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

1: batch reactor (SBR) 10: bioreactor
20: treatment tank 100: decanter device
110: decanter body 111: lower stopper
120: scum wall 121: scum wall front cover
122: scum wall side cover 123: pipe
130: connect arm 131: connection bar
132: extension bar 133: fixing pin
140: decanter support member 141: moving shaft
142: rail 143: upper stopper
150: piping 160: V notch wear
H: Inlet height

Claims (13)

In the decanter device for discharging the supernatant formed during the sludge sedimentation process of the SBR (Sequencing batch reactor) method for treating sewage or wastewater,
One surface is coupled to the decanter support member, the opposite surface of the surface coupled to the decanter support member is a structure in which supernatant is introduced, and a decanter body moving along the decanter support member;
A scum wall that covers the open surface of the decanter body and is connected to the decanter body by a connect arm, opening or closing the open surface of the decanter body by the movement of the connect arm;
A connect arm structurally connecting the decanter body and the scum wall, but opening or closing the scum wall; And
It includes a decanter support member for controlling the level of the decanter body to correspond to the sleep level by a moving shaft or wire,
The connect arm is a structure that swings a fixed pin formed on the side of the decanter body on an axis,
When the scum wall is lowered by the swing of the connect arm, the lower joining line of the scum wall and the decanter body is opened, and supernatant water is introduced,
The decanter device,
An upper stopper formed on the decanter support member; And
Further comprising a lower stopper formed on the side of the decanter body,
The swing motion of the connect arm is a structure limited by the upper and lower stoppers,
The decanter body moves up and down along the decanter support member,
When the decanter body is at the maximum level, the connect arm is fixed by the upper stopper to keep the scum wall closed,
When the decanter body is below the maximum level, the decanter device has a structure in which the connect arm is restricted by the lower stopper to control the opening range of the scum wall.
According to claim 1,
The decanter support member, the level of the decanter body is controlled to correspond to the sleep level by the moving shaft, the moving shaft is a rotating shaft with a screw thread formed on the outer peripheral surface,
The decanter body includes a through hole through which the movement shaft passes, and a decanter device having a structure in which a screw thread corresponding to a thread formed on an outer circumferential surface of the movement shaft is formed on an inner circumferential surface of the through hole.
According to claim 2,
The decanter device has a structure in which the decanter body is raised or lowered along the movement axis by rotation in one direction or in the opposite direction of the movement axis.
According to claim 1,
The decanter device,
When the scum wall is opened because the connect arm is restricted by the lower stopper,
Decanter device with an open inlet height ranging from 20 cm to 40 cm.
According to claim 1,
The connect arm,
A connecting bar structurally connecting between the pin and the scum wall formed on the side of the decanter body; And
A decanter device comprising an extension bar extending in the direction of the decanter support member from one end of the connecting bar.
The method of claim 5,
The extension bar is a decanter device having a structure bent at an angle in the range of 10° to 60° from the longitudinal extension line of the connecting bar.
According to claim 1,
A decanter device further comprising a pipe which is fluidly connected to the decanter body and discharges supernatant water flowing into the decanter body into the treatment tank.
According to claim 1,
The decanter device is a structure in which the V-notch weir is formed at the bottom of the open face of the decanter body.
According to claim 1,
A decanter device further comprising at least one of a sludge interface sensor and an underwater particulate matter measurement sensor.
According to claim 1,
The lower part of the decanter body is a structure in which the cross-sectional area is sequentially narrowed,
The scum wall is a decanter device including a structure bent at a certain angle to correspond to a lower portion of the decanter body having a narrow cross-sectional area. delete delete delete

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