KR101126619B1 - Membrane bio reactor having aeration-mixing-liquid transfer device and wastewater treatment method using the same - Google Patents

Abstract

The present invention is divided into two biological reactors to facilitate smooth material movement between the brewing to remove contaminants such as nitrogen and phosphorus in the incoming raw water, and a membrane separation tank is provided at the rear of the biological reactor to separate the solid-liquid separation for the treated water It is a water treatment device that can improve water quality, and especially, by configuring a device capable of selectively aeration, agitation, and liquid transfer as needed, it does not need a separate pump or aeration device, and thus improves operation efficiency by simplifying the equipment configuration. The present invention relates to an MBR reactor equipped with an aeration, agitation, and liquid transfer device, and a sewage and wastewater treatment method using the same.

Description

Membrane bio reactor having aeration-mixing-liquid transfer device and wastewater treatment method using the same

The present invention is divided into two biological reactors to facilitate smooth material movement between the brewing to remove contaminants such as nitrogen and phosphorus in the incoming raw water, and a membrane separation tank is provided at the rear of the biological reactor to separate the solid-liquid separation for the treated water It is a water treatment device that can improve water quality, and especially, by configuring a device capable of selectively aeration, agitation, and liquid transfer as needed, it does not need a separate pump or aeration device, and thus improves operation efficiency by simplifying the equipment configuration. The present invention relates to an MBR reactor equipped with an aeration, agitation, and liquid transfer device, and a sewage and wastewater treatment method using the same.

Recently, due to the increase of population, the concentration of cities, and the rapid development of industry, environmental pollution is rapidly progressing, and the damage of water quality environment has emerged as a serious problem. In addition, nutrients such as nitrogen and phosphorus are introduced into rivers and lakes to cause eutrophication, causing problems such as destruction of aquatic ecosystems due to the death of fish and fish, a decrease in the value of water resources, and an increase in water treatment costs. . In addition, nitrogen in the nutrients exists mainly in the form of organic nitrogen and ammonia nitrogen in sewage and wastewater, and this type of nitrogen is released into water and then passed through the form of nitrite nitrogen (NO 2- -N). It is converted into acidic nitrogen (NO 3 -N), which causes dissolved oxygen to be consumed, which degrades the water quality. Therefore, in order to solve this problem, apparatuses for simultaneously treating nitrogen and phosphorus by physical, chemical or biological unit processes have been developed, but there is an inadequate problem in the Korean situation where the content of organic matter in the wastewater is low.

Therefore, the problem to be solved by the present invention is to improve the efficiency of nitrogen and phosphorus removal efficiency of nitrogen and phosphorus even in the change of contaminant concentration and flow rate of the influent raw water by the efficient movement of organic matter contained in the influent raw water and the removal of organic matter and nitrogen and phosphorus It is an object of the present invention to provide an MBR reactor equipped with an aeration, agitation, and liquid transfer device, and a sewage and wastewater treatment method using the same, by performing a solid-liquid separation process using a separator to the treated water.

In addition, by separately configuring the devices that aeration, agitation, and liquid transfer can be performed in one step, it is possible to reduce the power cost required for internal circulation, which is advantageous in terms of facility economy and excellent in energy economy. Another purpose is to provide an MBR reactor and a sewage and wastewater treatment method using the same.

The aeration, stirring, and liquid transfer device according to the problem to be solved by the present invention of the MBR reactor is a multi-purpose tank for receiving the influent and operating in an anaerobic tank or anaerobic tank; A main reaction tank communicating with the multi-purpose tank and circulating with the multi-purpose tank and accommodating the reaction solution introduced therethrough to repeatedly perform anaerobic and aerobic reactions; A membrane separation tank (MBR; Membrane Bio Reactor) which communicates with the main reaction tank and receives a treated water of the main reaction tank to discharge solid matter in the treated water and discharges the filtrate therethrough; And aeration provided in the main reaction tank and the membrane separation tank for transferring the reaction liquid of the multi-purpose tank to the main reaction tank or transferring the treated water of the main reaction tank to the membrane separation tank, and optionally performing aeration or agitation. Liquid transfer device; And a conveying machine for conveying the reaction liquid of the main reaction tank to the multipurpose tank.

In this case, the aeration, stirring, liquid transfer device according to a preferred embodiment of the present invention, the motor, a rotating shaft that rotates in conjunction with the motor, an air fan mounted to the end of the rotating shaft, and the air fan and the play gap A water fan mounted on the rotating shaft and having a diameter larger than that of the air fan, a casing in which a motor is accommodated in an inner accommodating space and the water fan and the air fan are exposed, and a plurality of connecting portions at an outer circumference of the casing. Is connected to the tubular water guide tube and the inside of the water guide tube is configured to include a guide portion configured to receive the air fan therein and an air guide tube fixed by the inner circumference of the water guide tube and a plurality of supports Can be.

Accordingly, the present invention is a liquid transfer between the multi-purpose tank and the main reaction tank, if necessary by a single device and at the same time or separately to give the main reaction tank an anaerobic condition by simple stirring or aerobic condition by air suction Bar, it is possible to increase the treatment efficiency of the water treatment device, and to simplify the treatment process to increase the operating efficiency and energy efficiency by selectively performing the liquid transfer, aeration, and stirring without a separate pump, diffuser device. .

Meanwhile, the present invention proposes a wastewater treatment method using an MBR reactor equipped with an aeration, agitation, and liquid transfer device. In this treatment method, a) raw water is introduced into a multipurpose tank and operated in an anaerobic state to release phosphorus. Inducing and simultaneously removing organic matter; b) stirring the main reaction tank using the aeration, stirring and liquid transfer device during the step a) and transferring the reaction liquid of the multipurpose tank to the main reaction tank; c) inducing denitrification and dephosphorization by repeatedly operating the main reaction tank into which the reaction solution of the multi-purpose tank is introduced in an aerobic state and anaerobic state and returning the reaction solution of the main reaction tank to the multi-purpose tank using a conveying machine; And d) after completion of the denitrification and dephosphorization reaction, the treatment liquid of the main reaction tank is transferred to the membrane separation tank using the aeration, stirring, and liquid transfer device, and the solid-liquid separation of the treated water is carried out using the separation membrane in the membrane separation tank. Discharging the filtered filtrate; is characterized in that the simultaneous or sequential.

As described in detail above, the aeration / stirring / liquid transfer apparatus according to the present invention is equipped with an MBR reactor and a sewage / wastewater treatment method using the same, unlike a conventional continuous batch reactor (SBR; Sequencing Bach Reactor), a flow control tank, an anaerobic tank, or It is divided into multi-purpose tank functioning as an oxygen-free tank and main reaction tank which performs general continuous batch reaction, and separates biological reaction tank into two, and performs elasticity according to the change of organic matter concentration and flow rate of inflowing raw water by performing stage and inflow / transfer operation between brewing. Operation is possible to obtain a stable treatment efficiency and by the action of the microorganism in the multi-purpose tank has the effect of shortening the processing time required for the reaction in the main reaction tank and improve the treatment efficiency of contaminants.

In addition, the treated water discharged through the treatment process between the multi-purpose tank and the main reaction tank is transferred to the membrane separation tank and discharged to the outside through a solid-liquid separation process using the separation membrane, thereby achieving an excellent water quality improvement than the conventional.

In particular, the reaction liquid is circulated between the main reaction tank and the multipurpose tank by using an aeration, agitation, liquid transfer device, and a conveyer, and a proper amount of carbon source necessary for denitrification and dephosphorization reaction is mixed in a timely manner. It solves the problem of easy carbon source shortage and improves the treatment efficiency of nitrogen and phosphorus. The aeration, stirring, and liquid transfer can be selectively performed in each tank by one device, so the facility (process) can be simplified as well as the equipment configuration. It is simple and can increase the operating efficiency and save energy.

1 is a view showing an MBR reactor equipped with aeration, stirring, liquid transfer device of the present invention.
Figure 2a is a view for explaining the liquid transport and stirring action according to the aeration, stirring, liquid transfer device of the present invention MBR reactor.
Figure 2b is a view for explaining the aeration action according to the MBR reactor equipped with aeration, stirring, liquid transfer device of the present invention.
Figure 3 is a cutaway perspective view showing a basic example of an aeration, stirring, liquid transfer device of one configuration of the present invention.
Figure 4 is a side cross-sectional view of an aeration, stirring, liquid transfer device of one configuration of the present invention.
Fig. 5 is a cutaway perspective view showing an embodiment of an aeration, agitation, and liquid transfer device of one configuration of the present invention.
Figure 6 is a view showing an embodiment of an aeration, stirring, liquid transfer device of one configuration of the present invention.

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

1 is a view showing an MBR reactor equipped with aeration, stirring and liquid transfer device of the present invention, Figure 2a is a liquid transfer and stirring action according to the MBR reactor equipped with aeration, stirring, liquid transfer device of the present invention 2B is a view for explaining the aeration action according to the MBR reactor equipped with aeration, stirring and liquid transfer device of the present invention.

3 is a cutaway perspective view showing a basic example of an aeration / stirring / liquid transfer device of one configuration of the present invention, and FIG. 4 is a side cross-sectional view of the aeration / stirring / liquid transfer device of one configuration of the present invention. FIG. 6 is a cutaway perspective view showing an embodiment of an aeration / stirring / liquid transfer device of one embodiment of the present invention, and FIG. 6 is a view showing an embodiment of an aeration / stirring / liquid transfer device of one embodiment of the present invention.

The MBR reactor equipped with an aeration, stirring and liquid transfer device according to the present invention relates to a wastewater treatment apparatus for efficiently removing organic matter, nitrogen, phosphorus and suspended solids, etc., present in influent raw water. A bioreactor for treating phosphorus and the like and a membrane separation tank 30 for treating suspended solids are combined. Bioreactor of the present invention is defined as a reaction tank for treating nitrogen, phosphorus and the like except for the suspended solids to be treated in the membrane separation tank (30). As an example of the bioreactor, a bioreactor including a multi-purpose tank 10 and a main reactor 20 is shown in FIG. 1, but is not limited thereto. However, hereinafter, the present invention will be described by an example in which the bioreactor is composed of the multipurpose tank 10 and the main reactor 20.

As shown in FIG. 1, the MBR reactor equipped with an aeration, agitation, and liquid transfer device according to the present invention includes a multipurpose tank 10 and a main reactor 20 for performing a series of treatment processes for influent raw water. The circulation of the material between the brews 10, 20 is configured through the conveyer 50 and the aeration, agitation, liquid transfer device 40. In addition, the treated water finally treated in the main reaction tank 20 is finally discharged to the outside after the solid material is removed through the membrane separation tank (30).

The aeration, stirring, and liquid transfer device 40 are provided in the main reaction tank 20 and the membrane separation tank 30, respectively, and transfer the reaction liquid of the multi-purpose tank 10 to the main reaction tank 20. Allows the circulation of the liquid between the brews 10, 20. In addition, the aeration, stirring, liquid transfer device 40 to transfer the treated water of the main reaction tank 20 to the membrane separation tank 30 to selectively perform aeration or agitation as necessary. will be.

According to the present invention, the multi-purpose tank 10 spatially divides and shares the reaction to be made in the main reaction tank 20 in which the continuous batch reaction process takes place, depending on the organic matter concentration and the flow rate of the influent raw water between the brewing (10, 20) It is configured to maximize the treatment efficiency of nitrogen and phosphorus by controlling the amount and frequency of material circulation.

First, looking specifically at the multi-purpose tank 10 and the main reaction tank 20 in which the reaction to the incoming raw water is made, the multi-purpose tank 10 is provided with a predetermined space to receive the raw water from the sewage pipe (not shown) Although, the inflow point of the raw water from the sewage conduit may be the upper portion of the multi-purpose tank 10, the height of the raw water inflow point may be different depending on the depth of the sewage conduit laid.

The multi-purpose tank 10 is preferably composed of about 30% of the total volume, the main reaction tank 20 of about 70% of the total volume, the reaction in the multi-purpose tank 10 undergoing anaerobic reaction with the raw water introduced The liquid is transferred to the main reaction tank 20 by the aeration, stirring, and liquid transfer device 40, and the reaction in the main reaction tank 20 containing the nitrate nitrogen generated through the aerobic reaction in the main reaction tank 20. The liquid is conveyed back to the multi-purpose tank 10 through the conveyer 50 to circulate the reaction liquid.

At this time, the inlet raw water in the present invention is introduced into the multi-purpose tank 10 along the inlet pipe 11 from the sewage conduit, from the multi-purpose tank 10 to the main reaction tank 20 intermittent or depending on the concentration of organic matter of the incoming raw water Continuous injection is done. The treated water finally treated in the main reaction tank 20 is filtered through the separation membrane 31 of the membrane separation tank 30 and then intermittently discharged through the filtrate pump 32 and the discharge pipe 33.

The main reaction tank 20 is provided with an aeration, stirring, liquid transfer device 40 at the bottom thereof to generate aeration to perform the aerobic reaction in the main reaction tank 20.

That is, as illustrated in FIG. 2B, the aeration, agitation, and liquid transfer device 40 selectively performs aeration, agitation, and liquid transfer by controlling the opening and closing of the on / off valve v1 or v2 shown in the drawing. , During the aerobic reaction, opening and closing valves (v1 and v2) of the aeration, stirring, liquid transfer device 40 is to provide aeration action with the liquid transfer. The operation state of this aeration, stirring, liquid transfer device 40 will be described in detail below.

In addition, the excess sludge produced in the microbial reaction process is drawn to the sludge discharge means 60 installed in the main reaction tank 20 to be discharged to the outside to brew without increasing the concentration of microorganisms in the multi-purpose tank 10 and the main reaction tank 20 The level of microorganisms required by (10, 20) is maintained.

Here, the sludge discharge means 60 is to discharge the excess sludge including the microorganisms generated in the circulation process between the main reaction tank 20 and the multi-purpose tank 10 as described above, in the preferred embodiment of the present invention According to the sludge discharge means 60, as shown in Figure 1, when the load of microorganisms in the raw water flowing into the multi-purpose tank 10 is low, a portion of the excess sludge including the microorganism to the multi-purpose tank 10 It is configured to be introduced.

Specifically, the sludge discharge means 60 is connected to the lower portion of the main reaction tank 20, the sludge discharge pipe 61 is installed to open and close, the sludge discharge pipe 61 and the excess sludge of the main reaction tank 20 It is composed of a sludge discharge pump 62 for suction and discharge through the sludge discharge pipe (61).

On the other hand, the reaction liquid in the multi-purpose tank 10 is introduced into the main reaction tank 20 at the anaerobic reaction time of the main reaction tank 20 by the aeration, stirring, and liquid transfer device 40, of the main reaction tank 20 The reaction liquid is conveyed to the multipurpose tank 10 through the conveyer 50 and the conveying pipe 51. Injecting and conveying between the brewing 10, 20 is not made before and after at intervals of time, but mutual circulation is simultaneously performed for a predetermined time in consideration of the amount of injection and conveying.

Here, in the anaerobic reaction of the main reaction tank 20, in order to agitate the internal liquid (reaction liquid in the main reaction tank), a stirring device should be provided and the reaction liquid in the multi-purpose tank 10 to be transferred to the main reaction tank 20 In order to be provided with a separate pump, but aeration, stirring, liquid transfer device 40 according to the present invention as shown in Figure 2a and at the same time the reaction liquid of the multi-purpose tank 10 is transferred to the main reaction tank 20 As a result, it is not necessary to install a separate pump, thereby reducing the operating cost of the pump.

On the other hand, when the configuration of the aeration, stirring, liquid transfer device 40 described above with reference to Figures 3 to 6, in the present invention, the aeration, stirring, and aeration to perform the aeration, stirring, and aeration in the present invention. The liquid transfer device 40, as shown in Figure 3, the motor 100, the rotary shaft 200 to rotate in conjunction with the motor 100, and the air fan mounted to the end of the rotary shaft 200 ( 300 and a water fan 400 having a gap with the air fan 300 and mounted to the rotary shaft 200 and having a diameter larger than that of the air fan 300, and a motor is accommodated in an inner receiving space. Casing 500 is formed so that the fan 400 and the air fan 300 is exposed, the water guide pipe 620 of the tubular shape is connected by a plurality of connecting portion 610 in the outer periphery of the casing 500 The air fan 300 and the water fan 400 together with the guide unit 600 is configured by the motor 100 together The air vortex is formed inside the air fan 300 and the air guide tube 640 to be described below, and the water vortex is formed from the outside based on the water fan 400 and the water guide tube 620. In order to expand the aeration area by allowing air to be dissolved in the water while mixing each vortex after a separate flow, it is configured to selectively perform a stirring or liquid transfer function.

The motor 100 is a well-known technique, the description thereof is omitted, and although not shown in the drawings, the operation of the motor 100 may be controlled by an external controller. The motor 100 is configured in the casing 500, the end of the casing 500 is configured with a tubular air collector 510, the air collector 510 is an air suction pipe 520 As shown in FIG. 1, the air suction pipe 520 has a straight pipe 520-1 and an air collecting portion 510 whose ends are exposed to the upper surface of the water collection portion 510 from the outside. ) Is composed of a curved pipe 520-2 formed in the direction of the water fan 400 from the outside. The end of the curved pipe 520-2 is preferably not exposed to the outside of the air collecting portion 510, which means that the air discharged from the curved pipe 520-2 is inside the air collecting portion 510. This is to prevent it from being collected and mixed with water. The operation of the air suction pipe 520 is a negative pressure is formed inside the air collecting unit 510 based on the rotation of the water fan 400 and the air fan 300, this negative pressure is the air suction pipe 520 is the surface of the water The air is sucked in communication with the outside.

This air is collected in the air collecting unit 510, so that the vortex is formed to the outside through the air guide pipe 640 by the rotation of the air fan 300. To this end, the air collecting unit 510 is preferably configured to have a diameter that increases in the end direction thereof, that is, in the direction in which the water fan 400 is configured, which is the air sucked by the air suction pipe 520. Based on the shape of the collection unit 510 is to be diffused in the direction of the water fan 400 and the air fan 300, this diffusion is eventually based on the interaction of the air fan 300 and the air guide pipe 640 It is to make the vortex formation easier.

A water fan 400 interlocked with the rotary shaft 200 is formed outside the air collector 510, and the water fan 400 has the air collector 510 based on the rotation as mentioned above. The negative pressure is formed therein, and the water vortex (W) is formed through the water guide pipe 620 by sucking water from the outside of the apparatus from the induction hole 650 to be described below.

The air fan 300 is formed to form a predetermined gap with the water fan 400 and is configured to interlock with the rotating shaft 200, the air collected in the air collecting unit 510 the air guide pipe 640 It is to form an air vortex through. It is reasonable that the air fan 300 has a diameter smaller than that of the water fan 400.

Referring to the interaction between the water fan 400 and the air fan 300, the water fan 400 having a large diameter sucks water from the induction hole 650 to the outside and the air collecting unit 510 to the inside. The air is sucked from the air, and the air guided to the inside of the water fan 400 is such that air vortices are formed inside the air guide pipe 640 based on the rotation of the small diameter air fan 300. Water guided to the outside to form a water vortex between the water guide pipe 620 and the air guide pipe 640, for this purpose, as shown in Figure 4, the air guide pipe 640 is the water fan 400 It is reasonable to configure a narrow separation distance so that the air guided inwardly by the water fan 400 can be guided to the vortex based on the operation of the air fan 300 directly from the air guide pipe 640.

The guide unit 600 serves as a guide to suck water from the outside of the device and to secure a certain flow distance without mixing the air vortex with the water vortex. The guide part 600 having such a function includes a connection part 610 connected to the casing 500, a water guide pipe 620, a support 630, an air guide pipe 640, and an induction hole 650. do.

The connection part 610 is connected to the end of the water guide pipe 620 while forming an upward slope at the outer periphery of the casing 500 in the shape of a bar, based on the shape of the connection part 610. In the liver is formed an induction hole 650, the upward inclination gradient is formed in the water guide tube 620 direction.

Based on the shape of the induction hole 650 and the operation of the water fan 400, the external water of the device is easily introduced from the induction hole 650.

Also, in the present invention, as shown in FIG. 5, the liquid transfer part 530 communicating with the induction hole 650 may be configured, and the liquid transfer part 530 communicates with the induction hole 650. While the induction hole 650 is formed adjacent to the connecting portion 610, the outer periphery of the casing 500 is connected to one end of each connecting portion 610, and the water guide pipe 620 connected to each connecting portion 610 In communication with the suction chamber 530-1 and the suction chamber 530-1, each surface is formed at the end of the multi-purpose tank 10, the main reaction tank 20 and the main reaction tank 20 as shown in FIG. ) And a suction pipe 530-2 communicating with the membrane separation tank 30.

In this manner, a negative pressure is formed in the suction chamber 530-1 based on the rotation of the water fan 400 and the air fan 300, and the multipurpose tank 10 is formed through the suction pipe 530-2 by the negative pressure. And water (reaction liquid) is introduced from the main reaction tank 20 is to be aerated or stirred by the water fan 400 and the air fan 300.

In addition, based on such a configuration, the water (reaction liquid) from the multipurpose tank 10 and the main reaction tank 20 is caused by the action of the liquid transfer part 530 and the main reaction tank 20 and the membrane separation tank 30. It will flow into. The liquid flows in between the adjacent tanks in this way, and the liquid thus flowed is conveyed by the conveyer 50 or the circulation pipe 34 to be described below to circulate each of the tanks. Injecting and conveying between brewing is not done before and after the time interval, but mutual circulation is simultaneously performed for the time set for the filling / conveying amount.

The water guide tube 620 is a tubular shape is the end of the diameter is increased in shape is connected to the connecting portion 610 at its end. This diameter is configured to increase the shape to guide the water from the outside of the device in a large area. The water guide pipe 620 guides the water vortex in a state in which the water vortex guided to the outside from the water fan 400 is not mixed with the air vortex between the air guide pipe 640 and the water vortex It is to keep the straightness to expand the aeration area.

The air guide tube 640 is fixed by an inner circumference of the water guide tube 620 and a plurality of supports 630 such that the air fan 300 is positioned inside the water guide tube 620. .

In addition, the air guide pipe 640 is not accommodated by mixing the water vortex and air vortex by receiving the air vortex guided from the inside by the water fan 400 by the rotation of the air fan 300 therein To keep it straight. The air guide pipe 640 separates the water vortex from the air vortex so that the dissolved water vortex due to premature mixing of the water vortex and the air vortex deteriorates linearity, thereby preventing the aeration area from decreasing.

Meanwhile, in the present invention, as shown in FIG. 4, spiral guide grooves 660 and 670 are formed at inner circumferences of the water guide pipe 620 and the air guide pipe 640, respectively. It is reasonable to improve the formation and straightness.

And, although not shown in the drawings, a configuration of the aeration, stirring, liquid transfer device 40 of the present invention is a manual operation method in which the user operates the aeration device by selecting the agitation or aeration action according to the sewage and wastewater conditions It is configured to form a well-known measuring sensor and automatic driving circuit for measuring the BOD (Biochemical Oxygen Demand) value of the sewage and stored sewage and mixed liquor suspended solids (MLSS) value and the like. Alternatively, a control unit may be configured to perform an aeration operation. Thus, in the present invention, it is possible to selectively aeration or stirring using the aeration, stirring, liquid transfer device 40, as shown in Figures 2a and 2b is an on-off valve interlocking with the control unit in the air suction pipe 520 By constructing (V1) to open the on-off valve (V1) during the aeration to suck the air through the air suction pipe 520 to form a dissolved water vortex, when stirring, close the on-off valve (V1) to only the water vortex To form.

In addition, the aeration, stirring and liquid transfer device 40 according to the present invention presents a water pan 400a as another embodiment as shown in FIG. The water fan 400a is formed on the outer periphery of the partition pipe 430a and the partition pipe 430a which are integrally formed with the inner fan 420a fixed to the rotation shaft 200 and the end of the inner fan 420a. The outer fan 410a is formed to protrude.

The inner fan 420a, the partition pipe 430a and the outer fan 410a are configured to connect the partition pipe 430a with the air guide pipe 640 as much as possible by the inner fan 420a. Induced by the air vortex guided to the air guide pipe 640 by the compartment pipe 430a, the air vortex induced in this way to the rotation of the air fan 300 inside the air guide pipe 640 By accommodating therein, the straightness is more reliably maintained in the state where the water vortex and the air vortex are not mixed.

To this end, preferably, the diameter of the compartment pipe 430a should be the same as the diameter of the air guide tube 640, and the length of the compartment pipe 430a is configured inside the water guide pipe 620. According to the formation length of the air guide pipe 640 is to be adjusted, as mentioned above, the air vortex formed by configuring the compartment pipe 430a and the air guide pipe 640 as close as possible to the straightness It is desirable to maintain it.

On the other hand, when the aeration / stirring / liquid transfer device 40 described above with reference to FIG. 2B performs aeration, the aerobic reaction in the main reaction tank 20 will be described. The aeration / stirring liquid transfer device 40 is not shown in the drawing, but when the power switch is turned on, the motor 100 of the aeration / stirring liquid transfer device 40 rotates to rotate the water fan 400 and The air fan 300 is rotated.

When the rotation is performed, water outside the device is introduced through the induction hole 650, and at the same time, a negative pressure is formed in the air collecting unit 510. Such negative pressure is an air suction pipe 520 (opening and closing valve V2) Is introduced into the air from the outside of the water through the open state to be collected in the air collector 510. Water introduced outside the apparatus and air inside the air collecting unit 510 are formed with air vortices on the inside by rotation of the water fan 400, and water vortices are formed on the outside. The air vortex formed in the inside flows through the air guide tube 640 without being mixed with the water vortex due to the operation of the air guide tube 640 and the air fan 300 installed therein. Done.

At the same time, the water vortex formed on the outside is to flow between the water guide pipe 620 and the air guide pipe 640 in a state that is not mixed with the air vortex. The unmixed air vortex and the water vortex are mixed with each other on the outside of the air guide tube 640 to form a dissolved water vortex. The dissolved water vortex continues to flow through the water guide tube 620. These dissolved vortices continue to go to a certain degree to be scattered, and the dissolved water vortices are scattered upwards by the rising force of dissolved oxygen, and the separation membrane of the entire main reaction tank 20 or the membrane separation tank 30. It is to make aeration uniformly by (31).

That is, the dissolved water vortex must flow while maintaining the straightness for a long time, so that the aeration area is widened. The aeration / stirring / liquid transfer device 40 dissolves by allowing the water vortex and the air vortex to flow without being mixed. The straightness of the water vortex can be taken long so that the aeration can be carried out over the separation membrane 31 of the entire main reaction tank 20 or the membrane separation tank 30.

On the other hand, when looking at the conveyer 50, the conveying chamber 51 is disposed in the main reaction tank 20 to accommodate the reaction liquid of the main reaction tank 20, a part is configured to open the reaction liquid flows in do. In addition, one side of the conveying pipe 52 connected to the conveying chamber 51 may penetrate the bottom surface of the conveying chamber 51 so that the reaction liquid contained in the conveying chamber 51 may be conveyed with natural force. And the other side is configured to communicate with the multi-purpose tank 10 from the inside of the main reaction tank (20).

And, the conveying machine lifting device 53 is installed on the upper side of the side close to the multi-purpose tank 10 in the main reaction tank 20 to move the conveying chamber 51 to which the conveying pipe 52 is connected vertically. According to the water level change of the reaction tank 20, it is comprised so that a reaction liquid can be conveyed by the force of natural flow.

Accordingly, the conveyer 50 is configured such that the conveying chamber 51 can be vertically moved by the conveyer lifting device 53 installed at the upper end of the main reactor 20, and does not use a separate pump. It is possible to mutually move the reaction solution in the brewing (10, 20) with only the force of the natural flow, it is possible to minimize the power consumption for the circulation of the reaction solution and to facilitate maintenance and repair.

Hereinafter, the water treatment method by the function and interaction of the multipurpose tank 10 and the main reactor 20 of the reaction apparatus according to the present invention will be described in detail.

First, the main reaction tank 20 is converted into the form of transport of treated water to anaerobic (inflow), exhalation, anaerobic (inflow), aerobic ... anaerobic, aerobic and membrane separation tank 30 over time It consists of two operating cycles. Nitrogen is denitrified in the anaerobic state and finally removed by nitrogen gas (N ₂ ).

However, organic matter in the reaction solution is not only removed in anaerobic state but also in aerobic state irrelevant to the final removal of nitrogen. Therefore, in order to increase the nitrogen removal efficiency, almost no organic matter is removed when the main reactor 20 is in aerobic state, and almost all amounts of organic matter are used and removed in the anaerobic state where denitrification occurs.

In order to achieve this purpose, by supplying the appropriate carbon source (organic matter) in the main reaction tank 20 to solve the problem of carbon source shortage, which is a problem of the general continuous batch reaction process, it was possible to obtain a stable treatment efficiency.

On the other hand, when the concentration of influent organic matter is high, such as the area where the sewage sewer pipe is installed, the reaction liquid is introduced into the main reactor not only in the anaerobic time but also in the aerobic time so that the organic matter is removed in the aerobic time. At this time, it is natural that the amount of water introduced into the aerobic time period should be adjusted according to the size of the inflow organic matter concentration.

The reason why the multi-purpose tank 10 is placed in front of the main reactor 20 is to promote the hydrolysis of organic matter in the initial influent by anaerobic reaction in the multi-purpose tank 10 to improve the effect of phosphorus release and at the same time the main reactor ( This is to remove nitrogen by denitrifying (N ₂ ) NO ₃ -N (nitric acid nitrogen) of the return water returned from the 20 to the multi-purpose tank 10. Since the removal of NO ₃ -N in the multi-purpose tank 10 lowers the concentration of NO ₃ -N in the main reaction tank 20, the removal rate of phosphorus from the main reaction tank 20 by the effect of NO ₃ -N is prevented that much. can do.

Again, phosphorus release should occur in anaerobic conditions, but when NO ₃ -N is present, the microorganism uses NO ₃ -N as the final electron acceptor, causing phosphorus intake rather than phosphorus release. In addition, the growth of denitrifying microorganisms (Pseudomonas) and phosphorus removal micro-organisms is high (Acinetobacter) has between the anaerobic zone of the primary reactor 20. Since the competition in the substrate intake side NO ₃ -N this increases as Pseudomonas (Pseudomonas) Is promoted, and the growth of Acinetobacter is reduced. At this time, in order to maximize the removal rate of phosphorus Acinetobacter rather than Pseudomonas (Acinetobacter) should be the dominant species in the main reaction tank (20).

Therefore, the main reactor 20 located at the rear end of the multi-purpose tank 10 removes organic matter and nitrogen and releases phosphorus by a denitrification reaction using organic matter in the influent water as a carbon source in the anaerobic state. In addition, since there is no inflow of influent water in the aerobic state of the main reaction tank 20, the removal and residual nitrification of the organic matter in the tank is made and the absorption of phosphorus occurs. The lower the concentration of organic matter in the aerobic state of the main reactor 20, the dominant rate of nitrifying microorganism increases.

In addition, since the anaerobic and aerobic conditions of the main reactor 20 are repeatedly changed over time, Pseudomonas, which is relatively more proliferative than other microorganisms, becomes a dominant species, thereby increasing phosphorus removal rate. . Phosphorus is finally removed by removing the microorganisms having a high phosphorus removal rate with sludge immediately after the aerobic reaction or treated water discharge time, which is the final stage of the main reaction tank 20 in which phosphorus absorption occurs.

On the other hand, during the aerobic reaction or the treatment water discharge time, which is the last step performed in one cycle of the main reaction tank 20 operation, the reaction solution from the multi-purpose tank 10 to the main reaction tank 20 to increase the efficiency of removing contaminants. Inflow or conveyance is prevented from occurring, and during this period, raw water continuously introduced into the multipurpose tank 10 is temporarily stored in the multipurpose tank 10. Therefore, some space of the multi-purpose tank 10 located in front of the main reaction tank 20 also serves as a flow control tank.

On the other hand, the above-mentioned conveyer 50, aeration, stirring, liquid transfer device 40 is a device for smooth material exchange between the brewing (10, 20), in order to increase the anaerobic reaction in the anaerobic time, a stirring device is necessarily required And the liquid transfer device (pump) is required for the material exchange between the main reaction tank 20 and the multi-purpose tank 10. The aeration, stirring, liquid transfer device 40 according to the present invention is the main reaction tank (10) as described above In addition to the agitation function for), the multi-purpose tank 10 has a feature that can perform the liquid transfer to the main reaction tank 20 at the same time or alone. Accordingly, the liquid transfer can be performed simultaneously with only the power required for stirring without a separate pump power.

The conveyer 50 can be moved vertically by the conveyer lifting device 53, and can arbitrarily adjust the operation level of the multi-purpose tank 10 and the main reaction tank 20, without using a separate pump. It is possible to move the reaction solution in the brewing with only the force of.

Looking at the operation method of the conveyer 50 with reference to Table 1, when the multi-purpose tank liquid flows into the main reaction tank 10, when the position of the conveyer 50 is high, the operation level of the main reaction tank 20 is Increases. When the water level of the main reaction tank 20 is operated to be relatively high, the water level of the multipurpose tank 10 is relatively low. This reduces the residence time of the multipurpose tank 10 and thus reduces the ratio of anaerobic and anaerobic times in the entire process.

On the contrary, when the multipurpose tank 10 is operated at a high water level, anaerobic and anaerobic times are increased, so the ratio of anaerobic reaction and aerobic reaction can be controlled by the anaerobic and aerobic operation time of the main reaction tank 20 in the entire process. And by the level control of the main reaction tank (20). Therefore, more aggressive countermeasures can be made according to the change in inflow quantity and appearance.

In addition, when the carrier 50 is lowered than the level of the main reaction tank 10 in the state where the water level of the main reaction tank 20 is higher than the multipurpose tank 10, the main reaction tank liquid is returned to the multipurpose tank 10. Therefore, there is no need to provide a separate pump for conveyance to minimize the power consumption and easy maintenance and repair occurs.

Thus, the above-mentioned conveyer 50 and the aeration, stirring, and liquid transfer device 40 are driven properly according to the odor, the characteristics of the wastewater and the operating conditions of the main reactor 20, and the nitrogen and phosphorus in the wastewater. It is possible to increase the removal efficiency.

In addition, according to a preferred embodiment of the present invention, although not shown in the drawings, the water level meter, dissolved oxygen system, oxidation / reduction potentiometer, microbial concentration meter, pH meter, etc. By installing an oxygen meter, oxidation / reduction potentiometer, etc., it is configured to promptly detect and control the change in the operating state and cope with it to improve the processing efficiency.

On the other hand, in the membrane separation tank 30 communicated through the aeration, stirring, liquid transfer device 40 described above to the rear end of the main reaction tank 20 to accommodate the treated water treated from the main reaction tank 20 Perform solid-liquid separation for.

To this end, the separator 31 is provided in the membrane separator 30. In addition, the membrane separation tank 30 is connected to the filtrate pump 32 for sucking the filtrate from the separation membrane 31 and the separation membrane 31 and the filtrate sucked through the filtrate pump 32 It is configured to include a discharge pipe 33 for discharging to the outside.

Accordingly, the membrane separation tank 30 filters the treated water using the separation membrane 31 and discharges the filtered filtrate to the outside, thereby stably obtaining the highest quality treated water.

Here, the membrane separation tank 30 according to the present invention uses excessive aeration in order to prevent clogging of the separation membrane 31.

The excessive aeration of the supply is provided from the aeration, stirring and liquid transfer device 40, with the liquid transfer to the treated water of the main reaction tank 20 by the aeration, stirring, liquid transfer device (40). The aeration action is to be made, the configuration for the liquid transfer and aeration action by the aeration, stirring, liquid transfer device 40 as described above will be omitted a detailed description.

As such, the aeration, stirring, and liquid transfer device 40 is provided, so that the treated water of the main reaction tank 10 is introduced and the aeration for the separation membrane 31 is supplied, thereby requiring air from a separate diffuser or air pump. By assisting it will be possible to reduce the energy consumed.

On the other hand, the membrane separation tank 30 according to a preferred embodiment of the present invention may be configured to further include a circulation pipe 34 in communication with the main reaction tank 20 on one surface.

The circulation pipe 34 is equipped with a separate pump serves to return the treated water contained in the membrane separation tank 30 back to the main reaction tank (20).

This causes the membrane separation tank 30 to generate excessive aeration using the aeration, stirring, and liquid transfer device 40 described above to prevent clogging of the separation membrane 31, thereby causing a membrane separation tank ( DO (Dissolved Oxygen) concentration of 30) is close to the saturation state to solve this, the membrane separation tank (30) containing MLSS that the DO concentration is saturated when the main reaction tank 20 is an aerobic environment (30) Inflow of the return water) has the effect of supplying DO to the main reaction tank 20, thereby reducing the amount of air required for the aeration of the main reaction tank 20, thereby reducing energy consumption and cost for the water treatment process. It will be possible to save.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

10: multi-purpose tank 20: main reactor
30 membrane separation tank 31 membrane
40: aeration, stirring, liquid transfer device 50: conveying machine
60: sludge discharge means

Claims (8)

It is connected with the main reaction tank and the main reaction tank for accommodating the incoming water and operating with an anaerobic tank or an anaerobic tank, communicating with the multi-purpose tank, circulating with the multi-purpose tank, and accommodating the reaction liquid introduced therethrough to repeatedly perform anaerobic and aerobic reactions. In the MBR reactor comprising a membrane separation tank for receiving the treated water of the main reaction tank to remove the solid matter in the treated water to discharge the filtrate through
And aeration provided in the main reaction tank and the membrane separation tank for transferring the reaction liquid of the multi-purpose tank to the main reaction tank or transferring the treated water of the main reaction tank to the membrane separation tank, and optionally performing aeration or agitation. Liquid transfer device; And a conveyer for conveying the reaction liquid of the main reaction tank to the multipurpose tank.
The aeration, stirring, liquid transfer device,
A motor; A rotating shaft rotating in association with the motor; An air fan mounted to an end of the rotary shaft; It forms a gap with the air fan and is mounted to the rotary shaft, and formed in the inner end of the inner fan and the end of the inner fan fixed to the rotating shaft and protruded to the outer periphery of the partition tube and has a diameter than the air fan A water fan composed of a large external fan; A casing in which a motor is accommodated in an inner receiving space and the water fan and the air fan are exposed; The outer periphery of the casing is connected by a plurality of connecting portions and configured in a tubular shape, the diameter of the end portion in the water pan direction is configured in a shape that is larger, the plurality of connecting portions connecting the casing slope in the downward direction respectively It is formed to have a water guide pipe between the connection portion and each of the connecting portion and the inside of the water guide tube to accommodate the air fan therein is arranged to be connected to the outer fan with the same diameter as the outer fan of the water fan and the A guide part including an air guide pipe fixed by an inner circumference of the water guide pipe and a plurality of supports; And a liquid transfer part communicating with the induction hole and the suction chamber and forming a suction tube communicating with the multipurpose tank, the main reaction tank, the main reaction tank, and the membrane separation tank, respectively. The water guide pipe and the air guide include: Spiral guide grooves are respectively formed at the inner circumference of the tube, and the casing is formed at the end of the tubular air collecting portion, and the air collecting portion communicates with the outside and forms a curved pipe from the inside of the air collecting portion to the outside. MBR reactor with aeration, stirring, liquid transfer device, characterized in that the suction pipe is configured.
delete delete delete delete delete a) introducing raw water into the multipurpose tank to drive the anaerobic state to induce phosphorus release and at the same time to remove organic matter;
b) a motor in progress of step a); A rotating shaft rotating in association with the motor; An air fan mounted to an end of the rotary shaft; It forms a gap with the air fan and is mounted to the rotary shaft, and formed in the inner end of the inner fan and the end of the inner fan fixed to the rotating shaft and protruded to the outer periphery of the partition tube and has a diameter than the air fan A water fan composed of a large external fan; A casing in which a motor is accommodated in an inner receiving space and the water fan and the air fan are exposed; The outer periphery of the casing is connected by a plurality of connecting portions and configured in a tubular shape, the diameter of the end portion in the water pan direction is configured in a shape that is larger, the plurality of connecting portions connecting the casing slope in the downward direction respectively It is formed to have a water guide pipe between the connection portion and each of the connecting portion and the inside of the water guide tube to accommodate the air fan therein is arranged to be connected to the outer fan with the same diameter as the outer fan of the water fan and the A guide part including an air guide pipe fixed by an inner circumference of the water guide pipe and a plurality of supports; And a liquid transfer part communicating with the induction hole and the suction chamber and forming a suction tube communicating with the multipurpose tank, the main reaction tank, the main reaction tank, and the membrane separation tank, respectively. The water guide pipe and the air guide include: Spiral guide grooves are respectively formed at the inner circumference of the tube, and the casing is formed at the end of the tubular air collecting portion, and the air collecting portion communicates with the outside and forms a curved pipe from the inside of the air collecting portion to the outside. Agitating the main reaction tank by using an aeration, agitating, and liquid transfer device including a suction pipe, and transferring the reaction liquid of the multipurpose tank to the main reaction tank;
c) inducing denitrification and dephosphorization by repeatedly operating the main reaction tank into which the reaction solution of the multi-purpose tank is introduced in an aerobic state and anaerobic state and returning the reaction solution of the main reaction tank to the multi-purpose tank using a conveying machine; And
d) After completion of the denitrification and dephosphorization reactions, the treatment solution of the main reaction tank is transferred to the membrane separation tank using the aeration, stirring and liquid transfer device, and the solid-liquid separation of the treated water is carried out using the separation membrane in the membrane separation tank and filtered. Aeration, agitation, sewage and wastewater treatment method using the MBR reactor equipped with a liquid transfer device characterized in that it comprises a step of discharging the filtrate. delete

Images