KR20240037759A - Sewage treatment device with active sludge concentration control function and sewage treatment method using it - Google Patents

Abstract

The present invention provides a screen and silt basin for removing impurities, silt, or silt from sewage; a first sedimentation tank that freshens the sewage that has passed through the screen and the silt basin and allows it to remain for a certain period of time to precipitate sediment and separate it from supernatant water; an aeration tank that freshens the supernatant water discharged from the first sedimentation tank for a set period of time in a space where microorganisms live, supplies oxygen, exhausts carbon dioxide through a carbon reaction with the microorganisms, and consumes nitrogen and phosphorus; A sedimentation tank that freshens the treated water discharged from the aeration tank for a set time to separate the activated sludge from the supernatant; A filtration filter and total phosphorus treatment facility for removing nitrogen or phosphorus from the treated water discharged from the sedimentation tank; and a sterilization unit that removes microorganisms by providing disinfectants and ultraviolet rays to the treated water discharged from the filtration filter and the total phosphorus treatment facility, and in the aeration tank, activated sludge in which 70 to 80% of the biological reaction process has progressed is returned to the first sedimentation tank. It is characterized in that it is provided with a concentration control unit.

Description

Sewage treatment device with active sludge concentration control function and sewage treatment method using it {Sewage treatment device with active sludge concentration control function and sewage treatment method using it}

The present invention relates to a sewage treatment device having an activated sludge concentration control function and sewage treatment using the same. It relates to a method, and more specifically, to maintain the concentration of activated sludge within a set range by providing an equipment unit that controls the concentration of activated sludge in the bioreactor, and to lower the F/M ratio (Food to Microorganism ratio) to provide a sewage treatment device. A sewage treatment device equipped with an activated sludge concentration control function that can increase treatment efficiency, respond to inflow load, stabilize water quality at the interface of the final sedimentation tank, and reduce operating costs and chemical costs, and a sewage treatment device equipped with the same. It's about method.

In recent centuries, along with the rise in seawater temperature due to global warming, the emissions of nutrients such as nitrogen and phosphorus have rapidly increased due to industrialization and urbanization, causing eutrophication of coasts and lakes, causing red and green tides, severely deteriorating the water quality. It is polluting.

Therefore, we are continuously strengthening the quality standards for effluent water from sewage treatment plants, and taking regulatory measures such as the implementation of a total pollutant system that permits development on the premise of reducing pollutants, as well as encouraging recycling of effluent water from sewage treatment plants as gray water or river maintenance water. In accordance with the strengthening of the water quality standards for effluent from public sewage treatment plants to prevent eutrophication (effective January 1, 2008), newly installed public sewage treatment facilities will focus on nitrogen and phosphorus treatment, and existing facilities will also be subject to advanced treatment. Facilities are being installed.

However, despite the government's policy as above, most of the sewage treatment facilities currently in operation nationwide are operated by secondary treatment facilities based on the activated sludge method, and facilities that apply the existing activated sludge method use aeration tanks. It consists of a sedimentation tank, and organic matter in the sewage is removed through the metabolic process of microorganisms in an aeration tank supplied with oxygen, and in the subsequent sedimentation tank, the treated water from which microorganisms and organic matter have been removed is separated by gravity sedimentation. Some of the sludge is returned and circulated internally to maintain the microbial concentration in the aeration tank, and the remaining sludge is discharged to the outside. The existing activated sludge facility as described above is used to treat nutrients such as nitrogen and phosphorus contained in sewage. There was a problem that it was not suitable for advanced processing.

Meanwhile, in order to remove nutrients such as nitrogen and phosphorus contained in sewage, advanced treatment methods such as A2O, A/O, MLE, and VIP are used to For biological reactions such as intake and discharge, in addition to the aeration tank and sedimentation tank of the existing activated sludge process, several reaction tanks such as anoxic tank and anaerobic tank and facilities such as pumps for internal circulation are additionally provided.

Therefore, in the case of currently operating sewage treatment plants, only recently newly built treatment facilities are equipped with advanced treatment facilities capable of treating nitrogen and phosphorus, and existing sewage treatment facilities are unable to apply the advanced treatment process to the existing activated sludge method. To achieve this, an anoxic tank and an anaerobic tank must be additionally installed in the existing activated sludge facility, and additional facilities for internal circulation to the anoxic tank must be installed. However, in most sewage treatment facilities, additional land for the installation of these additional facilities is not secured. There are many difficulties in improving existing facilities.

Meanwhile, looking at patent applications for technologies developed to enable advanced treatment by improving conventional activated sludge facilities as a way to improve the above problems, as an example of prior art 1, domestic patent registration No. 0785044 A partition is installed inside the conventional aeration tank to separate it into an anoxic tank and an aerobic tank, the conventional sedimentation tank is improved into an equalization tank that equalizes the flow rate and water quality of the incoming sewage, and a submerged separation membrane is installed in the aerobic tank to suction filter the sewage and discharge the membrane permeate. An activated sludge method characterized in that a chemical storage tank for flocculant injection and a chemical injection device are installed just before the activated sludge mixture overflows from the anoxic tank to the aerobic tank to induce the installation and flocculation treatment of phosphorus to treat nutrients in sewage. There is a known method of remodeling existing sewage treatment facilities into advanced treatment facilities.

As an example of prior art 2, the reaction tank in Domestic Patent No. 0740580 uses an existing aeration tank, but installs three or more partitions inside it to form four or more compartments, and in the first compartment, at the end of the reaction tank It reduces the oxygen concentration of the returned water returned from the aerobic tank, induces anoxic conditions in the second compartment, induces anaerobic conditions in the third compartment, induces aerobic conditions in the fourth compartment at the end where the separation membrane is installed, and induces aerobic conditions in the diaphragm. A stirrer is installed in each area of the reactor divided by the reactor to ensure that the microorganisms and the influent or return water are well mixed. When the influent and return water flowing into the front end of the reactor progresses from the front end of the reactor, it moves in the form of a plug flow and transitions from anoxic conditions to anaerobic conditions. An advanced treatment device and method having a single reaction tank that is improved from the existing sewage treatment process using the activated sludge method is known.

However, in the case of patents such as the above prior art 1 and 2, it is an improved facility with a partition wall installed inside the activated sludge tank within the site area of the existing treatment facility, and although it is said to treat sewage at a high level, the nutritional value of the treated sewage flowing into the facility is not covered. If the type and concentration of salts changes significantly, there is a risk of problems not being able to properly treat the nutrients contained in the treated sewage. In particular, in the case of prior art 1, in order to promote the coagulation treatment of phosphorus to increase the efficiency of advanced sewage treatment, There was a problem in that a separate chemical storage tank and chemical injection device had to be provided.

In order to solve the above problems, an advanced treatment device for sewage was developed that improved the existing activated sludge treatment facility. The advanced treatment device according to the prior art is an existing activated sludge facility equipped with a plurality of reaction tanks and a plurality of sedimentation tanks. In the improved advanced treatment device for sewage, the reaction tank has a structure in which a plurality of stages are formed by a plurality of partition walls, and in each stage, the first stage is an anaerobic tank and an anoxic tank, and the remaining stages are an aerobic tank. , the reaction tank is operated with a variable arrangement of the anaerobic and anoxic tanks in the first stage, which consists of an anaerobic tank and an anoxic tank, depending on the type and concentration of nutrients contained in the influent sewage. In the reaction tank, the anaerobic tank receives influent sewage and external return water from the sedimentation tank. In the anoxic tank, external return water flows from the influent sewage and sedimentation tank, and internal return water flows in from the end of the oxic tank, and in the oxic tank, internal return water flows from the end of the oxic tank to the first stage of the oxic tank.

The background technology of the present invention is Republic of Korea Patent Publication No. 10-1019070 (announced on March 7, 2011, title of the invention: Advanced sewage treatment device that improved the existing activated sludge treatment facility and advanced treatment method using the device) It is disclosed in

Sewage treatment equipment according to the prior art is designed in a way to determine the appropriate activated sludge concentration based on low concentration, high concentration, and temperature according to the concentration of activated sludge inflow. Since it is a general concept customized sewage treatment method, existing activated sludge treatment Advanced treatment methods such as A2O and A/O were introduced by dividing the method into stages, but this method may result in a high F/M ratio in operation, and in the final sedimentation tank solid-liquid separation stage, pollutants due to increase or decrease in sludge volume were introduced. There is a problem that the quality of discharged water may deteriorate.

Therefore, there is a need to improve this.

The present invention is provided with an equipment unit that controls the concentration of activated sludge in a biological reactor, so that the concentration of activated sludge can be maintained within a set range and the treatment efficiency of the sewage treatment device can be increased by lowering the F/M ratio (Food to Microorganism ratio). The purpose is to respond to the inflow load, stabilize water quality at the interface of the final sedimentation tank, and provide a sewage treatment device equipped with an activated sludge concentration control function that can reduce operating costs and chemical costs, and a sewage treatment method equipped with the same. there is.

In addition, the present invention solves the problems of the advanced treatment method according to the prior art by using a sewage treatment device that includes a sensor unit that can measure the concentration and a pump that transports sludge to control the concentration of the biological reactor (aeration tank). The purpose is to provide a sewage treatment device equipped with an activated sludge concentration control function that can stabilize water quality and reduce operating costs, and a sewage treatment method equipped with the same.

The present invention provides a screen and silt basin for removing impurities, silt, or silt from sewage; a first sedimentation tank that freshens the sewage that has passed through the screen and the silt basin and allows it to remain for a certain period of time to precipitate sediment and separate it from supernatant water; an aeration tank that freshens the supernatant water discharged from the first sedimentation tank for a set period of time in a space where microorganisms live, supplies oxygen, exhausts carbon dioxide through a carbon reaction with the microorganisms, and consumes nitrogen and phosphorus; A sedimentation tank that freshens the treated water discharged from the aeration tank for a set time to separate the activated sludge from the supernatant; A filtration filter and total phosphorus treatment facility for removing nitrogen or phosphorus from the treated water discharged from the sedimentation tank; and a sterilization unit that removes microorganisms by providing disinfectants and ultraviolet rays to the treated water discharged from the filtration filter and the total phosphorus treatment facility, and in the aeration tank, activated sludge in which 70 to 80% of the biological reaction process has progressed is returned to the first sedimentation tank. It is characterized in that it is provided with a concentration control unit.

In addition, the concentration control unit of the present invention includes a main body portion connected to one side of an inlet through which activated sludge is supplied and providing a fresh water space into which activated sludge is freshened; A central pillar shaft rotatably installed on a walkway covering the upper surface of the main body and vertically installed in the center of the main body; a shaft blade that protrudes obliquely from the central pillar shaft and agitates the activated sludge freshened into the main body; A sludge pump extending from the bottom of the main body and installed in the discharge portion to discharge sludge; and a water level control unit installed on the upper part of the main body to control the internal water level of the main body.

In addition, the main body of the present invention has a fixed cone-shaped sliding plate installed on the inner wall, the sliding plate has a length of 1/3 of the diameter of the main body, and the height of the sliding plate is 1/5 from the lower end of the main body and It is characterized by being installed at a 45° downward slope at the 3/5 point.

In addition, the shaft wings protruding from the central drive shaft of the present invention are arranged at 2/5 points and 4/5 points from the lower part of the main body, 4 sets are installed at 2/5 and 4/5 heights, and each axis The wings are 20 cm wide and inclined downward at 45°, and the length of the axial wings is 1/3 of the diameter of the main body.

In addition, the water level control unit of the present invention is characterized in that a wire extending from the roller unit is connected to the top of the water level control unit to prevent the water level control unit from tilting or shaking due to the flow rate.

In addition, the end of the corrugated pipe is installed at the bottom of the water level control unit of the present invention, so that when the water level control unit rises or falls, the corrugated pipe expands or compresses and the height of the water level control unit is adjusted.

In addition, the present invention includes the steps of (a) passing sewage through a screen and a silt chamber to remove impurities, sediment, or sediment; (b) soaking the sewage supplied through the screen and the silt basin into a first settling tank and allowing it to settle for a residence time to separate the supernatant from the sediment; (c) putting the supernatant discharged from the first sedimentation tank into a biological reactor (aeration tank) where microorganisms live and supplying oxygen during the residence time to emit carbon dioxide and consume nitrogen and phosphorus through a carbon reaction with the microorganisms; (c) placing the water treated in the aeration tank into a sedimentation tank to separate activated sludge and supernatant during the residence time; (d) removing nitrogen or phosphorus from the treated water supplied from the sedimentation tank through the filter and total phosphorus treatment facility; and (e) removing microorganisms by supplying a disinfectant and ultraviolet rays to remove bacteria contained in the treated water discharged from the filter filtration and total phosphorus treatment facility, wherein step (c) is performed by placing activated sludge on one side. A main body part connected to the inlet supplied and providing a freshwater space in which activated sludge is freshened; A central pillar shaft rotatably installed on a walkway covering the upper surface of the main body and vertically installed in the center of the main body; a shaft blade that protrudes obliquely from the central pillar shaft and agitates the activated sludge freshened into the main body; A sludge pump extending from the bottom of the main body and installed in the discharge portion to discharge sludge; and a concentration control unit including a water level control unit installed at the top of the main body to control the internal water level of the main body.

The sewage treatment device having an activated sludge concentration control function and the sewage treatment method including the same according to the present invention have an inlet installed in a structure capable of supplying activated sludge at 70 to 80% of the bioreactor treatment process, and an inlet is installed to control the concentration. Activated sludge is returned and supplied by driving the device, so treatment efficiency can be increased by maintaining a low F/M ratio, and the trumpet-shaped funnel type is equipped with a V-ware type outlet to maintain sewage flow rate and constant concentration. Therefore, the final rear end of the bioreactor (aeration tank) can also have a low F/M ratio, increasing treatment efficiency, which has the advantage of reducing chemical and processing costs.

In addition, in the sewage treatment device having an activated sludge concentration control function and the sewage treatment method including the same according to the present invention, a transfer control unit is installed at the bottom of the equipment unit that controls the concentration of activated sludge, so activated sludge is discharged by driving the pump of the transfer control unit. There is an advantage that the activated sludge concentration can be easily controlled because it can be transported to the stage before the bioreactor.

In addition, the sewage treatment device and the sewage treatment method equipped with the activated sludge concentration control function according to the present invention are equipped with an equipment unit that controls the concentration of activated sludge, thereby controlling the inflow load, maintaining the final sedimentation tank interface, and stabilizing water quality. There are benefits to doing this.

Figure 1 is a flowchart showing a sewage treatment method using a sewage treatment device equipped with an activated sludge concentration control function according to an embodiment of the present invention.
Figure 2 is a configuration diagram showing a sewage treatment device equipped with an activated sludge concentration control function according to an embodiment of the present invention.
Figure 3 is a configuration diagram showing the inlet part, main body part, water level control part, and sludge part of a sewage treatment device equipped with an activated sludge concentration control function according to an embodiment of the present invention.
Figure 4 is a side view and a front view showing the main body of a sewage treatment device equipped with an activated sludge concentration control function according to an embodiment of the present invention.
Figure 5 is a configuration diagram showing the inlet and water level control unit of a sewage treatment device equipped with an activated sludge concentration control function according to an embodiment of the present invention.
Figure 6 is a configuration diagram showing the sludge portion of a sewage treatment device equipped with an activated sludge concentration control function according to an embodiment of the present invention.
Figure 7 is a configuration diagram showing the water level control unit of a sewage treatment device equipped with an activated sludge concentration control function according to another embodiment of the present invention.
Figure 8 is a diagram showing a foreign matter removal unit of a sewage treatment device equipped with an activated sludge concentration control function according to another embodiment of the present invention.

Hereinafter, an embodiment of a sewage treatment device having an activated sludge concentration control function and a sewage treatment method using the same according to the present invention will be described with reference to the attached drawings.

In this process, the thickness of lines or sizes of components shown in the drawings may be exaggerated for clarity and convenience of explanation.

In addition, the terms described below are terms defined in consideration of functions in the present invention, and may vary depending on the intention or custom of the user or operator.

Therefore, definitions of these terms should be made based on the content throughout this specification.

Figure 1 is a flow chart showing a sewage treatment method using a sewage treatment device equipped with an activated sludge concentration control function according to an embodiment of the present invention, and Figure 2 is a flow chart showing the activated sludge concentration control function according to an embodiment of the present invention. It is a configuration diagram showing a sewage treatment device equipped with a sewage treatment device, and Figure 3 is a configuration showing the inlet, main body, water level control section, and sludge section of a sewage treatment device equipped with an activated sludge concentration control function according to an embodiment of the present invention. It is also a degree.

In addition, Figure 4 is a side view and a front view showing the main body of a sewage treatment device equipped with an activated sludge concentration control function according to an embodiment of the present invention, and Figure 5 is an activated sludge concentration control function according to an embodiment of the present invention. It is a configuration diagram showing the inlet and water level control unit of a sewage treatment device equipped with a , and Figure 6 is a configuration diagram showing the sludge portion of a sewage treatment device equipped with an activated sludge concentration control function according to an embodiment of the present invention.

Referring to Figures 1 to 6, a sewage treatment device equipped with an activated sludge concentration control function according to an embodiment of the present invention includes a screen and a sedimentation basin for removing contaminants, sediment, or silt from sewage, and a screen and a sedimentation basin. A first sedimentation tank in which the passed sewage is freshened and allowed to remain for a certain period of time to precipitate the sediment and separate it from the supernatant water, and the supernatant water discharged from the first sedimentation tank is desalinated in a space where microorganisms inhabit for a set period of time, and oxygen is supplied to destroy the microorganisms and the supernatant water. An aeration tank that emits carbon dioxide and consumes nitrogen and phosphorus through a carbon reaction, a sedimentation tank that desalinates the treated water discharged from the aeration tank for a set period of time and separates the activated sludge from the upper part, and nitrogen or phosphorus is extracted from the treated water discharged from the sedimentation tank. It includes a filtration filter and total phosphorus treatment facility that removes phosphorus, and a sterilization unit that removes microorganisms by providing disinfectant and ultraviolet rays to the treated water discharged from the filtration filter and total phosphorus treatment facility.

The aeration tank of this embodiment is equipped with a concentration control unit that returns activated sludge, in which 70 to 80% of the biological reaction process has progressed, to each stage of the reaction tank and transfers excess sludge to the sludge storage tank, so that the concentration of activated sludge can be maintained within the set range. .

The concentration control unit as described above is connected to an inlet through which activated sludge is supplied on one side, and is rotatably installed on a main body part that provides a fresh water space where activated sludge is freshened, and a walkway covering the upper surface of the main body part, and is rotatably installed in the central part of the main body part. A central column shaft installed upright in the vertical direction, a shaft blade that protrudes obliquely from the central column shaft and agitates the activated sludge freshened into the main body, and a shaft extending from the bottom of the main body and installed in the discharge section to discharge the sludge. It includes a sludge pump and a water level control unit installed on the upper part of the main body to control the internal water level of the main body.

The inlet part of this embodiment is arranged so that the height of the water surface of the biological reactor (aeration tank) and the height of the top of the inlet part are the same or similar, the inlet part is a fallopian tube-type stainless steel fixed tube, and the inlet tube extending downward from the inlet part is, It is connected to the lower part of the main body of the concentration control unit at a height of about 30cm, and is connected to and fixed to a support that supports the main body.

In addition, the main body of this embodiment is arranged so that the upper part is 50 cm or more higher than the water depth of the biological reactor (aeration tank), prevents the inflow of other foreign substances that are not necessary for the treatment process, and has a central axis on the upper surface of the walkway to ensure smooth rotation of the central pillar axis. A reduction motor is installed, the lower part of the main body is fixed to the main body support to prevent it from being affected by vibration, the pipe extending from the main body is connected to the upper part of the sludge section, and a pump is installed in the pipe to remove the sludge provided from the main body. is soaked in the sludge part.

In addition, the main body of this embodiment has a fixed cone-shaped sliding plate installed on the inner wall, the sliding plate is made of a material of STS 5T or higher, and is integrally fixed to the inner wall of the main body to partition the inside of the main body in a sealed manner, and the sliding plate The length of the plate is 1/3 of the diameter of the main body, and the height of the sliding plate is installed at a 45° downward slope at 1/5 and 3/5 points from the bottom of the main body, so it plays a role in reducing the flotation flow rate of activated sludge. do.

In addition, the reduction motor of the embodiment is installed on the upper walkway, and a fixed rail to assist reduction rotation is installed at the lower part, so that the column axis is fixed so as not to move and connected to the reduction motor.

In this embodiment, the shaft wings protruding from the central drive shaft are arranged at 2/5 and 4/5 points from the lower part of the main body, and 4 sets are installed at 2/5 and 4/5 heights, and each shaft blade is 20 cm long. It is arranged slanted downward at 45° in width, and the length of the shaft blade is 1/3 of the diameter of the main body.

In addition, the shaft blade in this embodiment serves to induce sedimentation of the activated sludge, promotes cohesion of the activated sludge, and allows smooth solid-liquid separation of the activated sludge.

The water level control unit of this embodiment is installed to control the water depth and activated sludge concentration of the main body, the upper part of the water level control unit is made of a trumpet-shaped funnel V-WEIR type, and a circular floating body is fixedly installed at the lower part of the water level control unit to form the main body. It floats on the water surface and rises or falls depending on the height of the water surface, and rises or falls depending on the activated sludge concentration.

In addition, a wire extending from the roller unit is connected to the top of the water level control unit, so it is possible to prevent the water level control unit from tilting or shaking due to the flow rate. To prevent the water level control part from shaking due to the flow rate, a trumpet-shaped funnel is installed. The circular upper part is configured in a V-WEIR format to minimize movement due to the flow rate, and the fixture connecting shaft is fixed to the upper part of the trumpet-shaped funnel with three buckles and connected to the wire to more effectively prevent tilting of the water level control unit. There will be.

In addition, the end of the corrugated pipe is installed at the bottom of the trumpet-shaped funnel, so that when the water level control unit rises or falls, the corrugated pipe expands or compresses and the height of the water level control unit is adjusted, so that the activated sludge discharged from the main body can be smoothly discharged.

As described above, the floating body of this embodiment has a specific gravity smaller than that of the water surface, and is connected to the roller part by a wire, so the deceleration motor is driven to rise or fall in response to changes in the water level of the main body and the concentration of activated sludge. Sludge can be discharged.

In addition, the activated sludge is connected to the MLSS meter to automatically control the water level and is continuously supplied, passing through the inside of the corrugated pipe and being transferred to the next stage of the bioreactor (aeration tank).

The discharge portion that flows through the main body in this embodiment is connected to the biological reactor at the same height as the water surface of the biological reactor (aeration tank), and is formed in a T-shape to enable smooth discharge of activated sludge.

The sludge part of this embodiment is connected to the main body as an integrated structure, the lower part of the main body is connected to the sludge part, and a pump driven by a driving signal is installed in the lower part of the sludge part when the return rate is determined according to the concentration of activated sludge in the bioreactor. do.

In addition, the pipe connecting the main body and the sludge section of this embodiment is connected to each stage so that activated sludge can be supplied to each treatment stage of the biological reactor (aeration tank), and an electric valve is installed in each pipe to ensure activation. It is possible to control whether and how much sludge is supplied.

In this embodiment, a manhole and lifting equipment are installed on the upper part of the sludge part for operation and management of the pump to ensure the safety and convenience of the manager.

A sewage treatment method using a sewage treatment device equipped with an activated sludge concentration control function achieved by the technical components configured as described above will be described.

A sewage treatment method using a sewage treatment device having an activated sludge concentration control function according to an embodiment of the present invention includes the steps of passing sewage through a screen and a silt basin to remove contaminants, sediment, or soil, and passing the sewage through a screen and a silt basin. A step of desalching the supplied sewage into a first sedimentation tank and allowing it to settle for a residence time to separate supernatant water and sediments, and desalching the supernatant water discharged from the first sedimentation tank into a biological reactor (aeration tank) where microorganisms live and oxygenating during the residence time. A step of supplying carbon dioxide and consuming nitrogen and phosphorus through a carbon reaction with microorganisms; a step of immersing the treated water treated in the aeration tank into a sedimentation tank to separate activated sludge and supernatant water during the residence time; and processing the water supplied from the sedimentation tank. It includes a step of removing nitrogen or phosphorus by passing the water through filter filtration and a total phosphorus treatment facility, and a step of removing microorganisms by supplying disinfectants and ultraviolet rays to remove bacteria contained in the treated water.

Therefore, the sewage that flows into the sewage treatment plant passes through the screen and silt basin, goes through the first sedimentation tank, aeration tank, filtration and total phosphorus treatment facility, and disinfection process, and then the treated water is discharged into the river and sea, completing the sewage treatment process.

Here, in this embodiment, in the process of consuming nitrogen and phosphorus in a biological reactor (aeration tank), activated sludge whose retention time has progressed by 70 to 80% is continuously supplied to the concentration control unit through a collection passage. , the activated sludge recovered from the concentration control unit is returned and supplied to each step performed in the biological reactor (aeration tank), making it possible to control the concentration of activated sludge inside the biological reactor within a set range.

Figure 7 is a configuration diagram showing the water level control unit of a sewage treatment device equipped with an activated sludge concentration control function according to another embodiment of the present invention, and Figure 8 is a configuration diagram showing an activated sludge concentration control function according to another embodiment of the present invention. This is a diagram showing the foreign matter removal unit of a sewage treatment device.

Referring to Figures 7 and 8, the water level control unit 100 of this embodiment includes a corrugated pipe 102 that extends inside the main body 50 and whose length is adjusted, and is installed at the end of the corrugated pipe 102, A floating body 104 that floats on the water and rises or falls depending on the height of the water, and a roller member installed on a support extending from the floating body 104 and sliding along the guide rail 106 of the main body 50. Includes (107).

Therefore, when the water level rises or falls depending on the flow rate of the activated sludge supplied to the main body 50, the floating body 104 floating on the water surface rises or falls like the water surface, so the corrugated pipe connected to the floating body 104 ( As the end of 102) rises or falls, activated sludge can be collected from the water surface.

At this time, a roller member 107 is provided on the support extending from the floating body 104, and the roller member 107 rises or falls in the vertical direction along the guide rail 106 provided on the inner wall of the main body 50. Therefore, the ends of the floating body 104 and the corrugated pipe 102 of this embodiment are supported to be movable in the vertical direction without moving in the lateral direction inside the main body portion 50, so that the ends of the corrugated pipe 102 are supported in the main body portion 50. ) It is possible to prevent flow in the center direction.

As described above, the end of the corrugated pipe 102 rises or falls together with the floating body 104 to collect a sample from the surface of the activated sludge, making it possible to easily discharge the activated sludge, and the end of the corrugated pipe 102 Since it moves only in the vertical direction along the guide rail 106, the corrugated pipe 102 flows toward the center of the main body 50 according to the variable water surface position, thereby preventing malfunctions that interfere with other parts.

In addition, the guide rail 106 of this embodiment is used when foreign substances contained in the activated sludge flowing into the main body 50 accumulate on the guide rail 106 and the roller member 107 does not move. ) and a foreign matter removal unit 130 that sprays working fluid between the roller member 107 to remove foreign substances.

Therefore, if the activated sludge freshened into the main body 50 contains more sediment than the set value, foreign matter accumulates between the roller member 107 and the guide rail 106, so that the roller member 107 does not move and the corrugated pipe 102 ) is judged to have passed through the water surface of the supernatant and is inserted into the main body 50, and a drive signal is transmitted from the measurement control unit 36 to the foreign matter removal unit 130 to connect the guide rail 106 and the roller member 107. ) side to remove foreign substances interposed between the guide rail 106 and the roller member 107.

The foreign matter removal unit 130 of this embodiment includes a removal passage 132 that is inserted into the guide rail 106 from the top of the guide rail 106 and supplies working fluid, and a removal passage extending along the center of the guide rail 106. A plurality of branch passages 134 branching and extending from the passage 132 in one direction and the other, and a working fluid provided at the end of the branch passage 134 and supplied along the removal passage 132 and the branch passage 134. It includes a nozzle 135 that discharges toward the roller member 107.

Therefore, if the content of sediment contained in the sample supplied to the main body 50 is more than the set value, if the lower end of the corrugated pipe 102 is placed lower than the water surface, it is determined that sediment is flowing in, and through the removal passage 132 The working fluid is supplied to remove foreign substances interposed between the roller member 107 and the guide rail 106.

In addition, the foreign matter removal unit 130 of this embodiment includes a branch pipe 137 that branches off from the discharge passage 32a and extends toward the removal passage 132, and the branch pipe 137 and the removal passage 132 are detachable. It may further include a second detachable connection part 136 that connects the branch pipe 137 and a valve 138 that is installed in the branch pipe 137 to open or close the branch pipe 137.

Therefore, in the case where the branch pipe 137, the second attachment/detachment connection part 136, and the valve 138 are further provided, when the activated sludge in the main body 50 is returned, a part of the activated sludge is diverted to the branch pipe 137. It is possible to remove foreign matter by spraying it toward the guide rail 106 and the roller member 107 through the removal passage 132 and the nozzle 135.

In addition, in this embodiment, when the water level control unit 100 or the foreign matter removal unit 130 is damaged and repair or replacement work is performed, a portion of the inner wall of the main body 50 where the water level control unit 100 is provided A replacement part 110 is provided that can replace the auxiliary main body so that repair work or replacement work can be performed on the water level control part 100 while the sewage treatment process continues without interruption. After supplying the supplied activated sludge to the auxiliary main body to empty the inside of the main body 50, operate the replacement part 110 to separate a portion of the inner wall of the main body 50 to perform repair or replacement of the water level control part 100. The work can proceed, and at this time, the coupling state of the second removable connection part 136 can be released to separate the branch pipe 137 and the release passage.

The replacement part 110 of this embodiment includes a replacement block made of a separate block by cutting a portion of the outer wall of the main body 50, and a first connection part 112 that detachably connects the upper part of the replacement block and the main body 50. ) and a second connection part 122 that detachably connects the lower end of the replacement block and the main body 50.

Therefore, when the replacement block is pressed in the inner direction of the main body 50, the replacement block is combined to close the hole formed in the main body 50 by the operation of the first connection part 112 and the second connection part 122, When the first connection part 112 and the second connection part 122 are unlocked, the replacement block can be separated from the main body 50 to perform repair or replacement work on the water level control part 100, and the main body part ( 50) Cleaning work inside the main body 50 can also be performed through the hole formed in the outer wall.

The main body 50 of this embodiment may be made of a concrete structure, and if the main body 50 is made of a concrete structure and is a large structure, the replacement block can be moved using heavy equipment such as a crane, and the main body (50) may be made of a concrete structure. 50) The hole formed in the outer wall is provided with a step or stopper to prevent the replacement block from being lost into the main body 50.

The first connection portion 112 of this embodiment includes a first hook member 114 installed to protrude from the top of the replacement block, and a first coupling formed on the main body 50 to insert the first hook member 114. A groove portion 115, a first elastic member 116 interposed between the first hook member 114 and the replacement block to provide an elastic force for pressing the first hook member 114 toward the outside of the replacement block, and a first elastic member 116 It includes a first release portion 117 that releases the engaging combination of the first hook member 114 while retracting the hook member 114.

In addition, the first release portion 117 includes a first wire 118 extending from the back of the first hook member 114 to the outside of the replacement block, and a first lever 119 installed at the end of the first wire 118. ), so when the first lever 119 member is pulled by the operator's hand, using a tool, or by driving heavy equipment, the first elastic member 116 is compressed and the first hook member 114 is moved to the operating space inside the replacement block. As it is inserted, the engagement between the first hook member 114 and the first coupling groove 115 is released, allowing the replacement block to be separated from the main body 50.

In addition, the second connection portion 122 includes a second hook member 124 installed to protrude from the bottom of the replacement block, and a second coupling groove formed in the main body portion 50 into which the second hook member 124 is inserted. (126), a second elastic member 126 interposed between the second hook member 124 and the replacement block to provide an elastic force that presses the second hook member 124 toward the outside of the replacement block, and a second hook. It includes a second release portion 127 that releases the engaging coupling of the second hook member 124 while retracting the member 124.

In addition, the second release portion 127 includes a second wire 128 extending from the back of the second hook member 124 to the outside of the replacement block, and a second lever 129 installed at the end of the second wire 128. ), so when the second lever (129) member is pulled by the worker's hand, using a tool, or by driving heavy equipment, the second elastic member (126) is compressed and the second hook member (124) is moved to the operating space inside the replacement block. As it is inserted, the engagement between the second hook member 124 and the second coupling groove portion 126 is released, allowing the replacement block to be separated from the main body portion 50.

As a result, by providing an equipment unit that controls the concentration of activated sludge in the bioreactor, the concentration of activated sludge can be maintained within the set range and the treatment efficiency of the sewage treatment device can be increased by lowering the F/M ratio (Food to Microorganism ratio). , it is possible to provide a sewage treatment device and a sewage treatment method equipped with the activated sludge concentration control function that can respond to the inflow load and stabilize the water quality at the interface of the final sedimentation tank, and reduce operating costs and chemical costs.

The present invention has been described with reference to an embodiment shown in the drawings, but this is merely illustrative, and various modifications and other equivalent embodiments can be made by those skilled in the art. You will understand.

In addition, a sewage treatment device having an activated sludge concentration control function and a sewage treatment method using the same have been described as an example, but this is only an example, and the sewage treatment device having an activated sludge concentration control function and a sewage treatment method using the same The sewage treatment device of the present invention and the sewage treatment method using the same can be used for other products.

Therefore, the true technical protection scope of the present invention should be determined by the scope of the patent claims below.

1: Inlet 2: Central axis reduction motor
3: Central pillar axis 4: Inlet pipe discharge part
5: Fixed conical sliding plate 6: Floating body
7: Collection channel corrugated pipe 8: FLANGE joint
9: Roller unit 10: Automatic water level control reduction motor
11: MLSS METER 12: Sludge discharge pipe
13: return transfer pipe 14: discharge outlet T-shaped
15: Sludge pump 16: Body support
17: WALK WAY 18: SLUDGE TANK
19: shaft wing 20: electric valve

Claims (7)

Screens and silt basins for removing impurities, sediment or silt from sewage;
a first sedimentation tank that freshens the sewage that has passed through the screen and the silt basin and allows it to remain for a certain period of time to precipitate sediment and separate it from supernatant water;
an aeration tank that freshens the supernatant water discharged from the first sedimentation tank for a set period of time in a space where microorganisms live, supplies oxygen, exhausts carbon dioxide through a carbon reaction with the microorganisms, and consumes nitrogen and phosphorus;
A sedimentation tank that freshens the treated water discharged from the aeration tank for a set time to separate the activated sludge from the supernatant;
A filtration filter and total phosphorus treatment facility for removing nitrogen or phosphorus from the treated water discharged from the sedimentation tank; and
A sterilizing unit that removes microorganisms by providing disinfectant and ultraviolet rays to the treated water discharged from the filtration filter and the total phosphorus treatment facility,
A sewage treatment device having an activated sludge concentration control function, characterized in that the aeration tank is equipped with a concentration control unit that returns activated sludge, in which 70 to 80% of the biological reaction process has progressed, to the first sedimentation tank.
The method of claim 1, wherein the concentration control unit,
A main body portion connected to one side of an inlet through which activated sludge is supplied and providing a freshwater space where activated sludge is freshened;
A central pillar shaft rotatably installed on a walkway covering the upper surface of the main body and vertically installed in the center of the main body;
Shaft wings that protrude obliquely from the central column shaft and agitate the activated sludge freshened into the main body;
A sludge pump extending from the bottom of the main body and installed in the discharge portion to discharge sludge; and
A sewage treatment device having an activated sludge concentration control function, comprising a water level control unit installed at the top of the main body to control the internal water level of the main body.
According to paragraph 2,
The main body has a fixed cone-shaped sliding plate installed on the inner wall, the sliding plate has a length of 1/3 of the diameter of the main body, and the height of the sliding plate is at 1/5 and 3/5 points from the lower end of the main body. A sewage treatment device with an activated sludge concentration control function, which is installed at a 45° downward slope.
According to paragraph 3,
The axial wings protruding from the central drive shaft are arranged at 2/5 and 4/5 points from the bottom of the main body, and 4 sets are installed at 2/5 and 4/5 heights, and each axial wing is 20 cm wide. A sewage treatment device equipped with an activated sludge concentration control function, which is disposed inclined downward at 45°, and the length of the shaft blade is 1/3 of the diameter of the main body.
According to paragraph 4,
The water level control unit is a sewage treatment system having an activated sludge concentration control function, wherein a wire extending from the roller unit is connected to the top of the water level control unit to prevent the water level control unit from tilting or shaking due to the flow rate. Device.
According to clause 5,
A sewage treatment device with an activated sludge concentration control function, wherein an end of a corrugated pipe is installed at the bottom of the water level control unit, and when the water level control unit rises or falls, the corrugated pipe expands or compresses to adjust the height of the water level control unit. . (a) passing sewage through a screen and silt to remove contaminants, sediment, or silt;
(b) soaking the sewage supplied through the screen and the silt basin into a first settling tank and allowing it to settle for a residence time to separate the supernatant from the sediment;
(c) putting the supernatant discharged from the first sedimentation tank into a biological reactor (aeration tank) where microorganisms live and supplying oxygen during the residence time to emit carbon dioxide and consume nitrogen and phosphorus through a carbon reaction with the microorganisms;
(c) placing the water treated in the aeration tank into a sedimentation tank to separate activated sludge and supernatant during the residence time;
(d) removing nitrogen or phosphorus from the treated water supplied from the sedimentation tank through the filter and total phosphorus treatment facility; and
(e) comprising the step of removing microorganisms by supplying disinfectant and ultraviolet rays to remove bacteria contained in the treated water discharged from the filter filtration and total phosphorus treatment facility,
In step (c),
A main body portion connected to one side of an inlet through which activated sludge is supplied and providing a freshwater space where activated sludge is freshened;
A central pillar shaft rotatably installed on a walkway covering the upper surface of the main body and vertically installed in the center of the main body;
Shaft wings that protrude obliquely from the central column shaft and agitate the activated sludge freshened into the main body;
A sludge pump extending from the bottom of the main body and installed in the discharge portion to discharge sludge; and
A sewage treatment method using a sewage treatment device having an activated sludge concentration control function, characterized in that it is achieved by a concentration control unit including a water level control unit installed at the top of the main body to control the internal water level of the main body.