JP5439344B2 - Membrane separation biological treatment equipment - Google Patents

Description

  Embodiments of the present invention relate to a membrane separation biological treatment apparatus for treating sewage containing anaerobic organic matter.

  The activated sludge treatment method used in sewage treatment and the anaerobic treatment method (or anaerobic digestion method) used in sludge treatment are methods that decompose and remove organic matter in wastewater and sewage using microorganisms. is there. In order to improve the efficiency of treatment using such microorganisms, it is necessary to increase the concentration of microorganisms in the biological reaction tank.

  As one method for increasing the concentration of microorganisms, a separation method using a membrane (membrane separation activated sludge method) has been put into practical use. The microorganism concentration in a general biological reaction tank applied to sewage treatment is about 3000 mg / L, whereas in the membrane separation activated sludge method, the microorganism concentration in the biological reaction tank is about 8000 to 10,000 mg / L. Since it can concentrate, there exists an advantage that a clear treated water can be obtained.

  However, since the treated water is separated from the wastewater by the membrane, the membrane is blocked by the organic matter and sludge in the wastewater. In order to prevent the membrane from being clogged with organic matter or sludge, generally, air is supplied for washing from the lower part of the membrane unit, and washing is performed by shearing force when coarse bubbles rise on the membrane surface. . On the other hand, when aeration is used in the membrane cleaning process, an air amount that is about five times the amount of air necessary for aeration in the biological treatment is required, so a great amount of power is required. Therefore, conventionally, in the membrane separation activated sludge method, various membrane cleaning methods have been proposed in order to reduce power in membrane cleaning (see, for example, Patent Document 1).

  As described above, in the membrane separation activated sludge method, since the movement of the concentrated sludge liquid obtained by filtration and the cleaning of the membrane surface are performed by aeration, a great amount of power is required. Further, in the cleaning by aeration, there is a problem that sludge accumulates on a part of the membrane surface when the aeration becomes non-uniform due to the accuracy and blockage of the diffusing tube, and the membrane area is reduced.

  Furthermore, when it comes to large equipment, it is necessary to increase the discharge pressure of the aeration blower for installation by increasing the membrane dimensions or by immersing the membrane in a deep water tank with multiple layers of membranes, Furthermore, the power consumption of the aeration blower increases.

Japanese Patent No. 3341427

  An object of this invention is to provide the membrane separation biological treatment apparatus which can perform the movement of sludge and washing | cleaning of the membrane surface with small power in view of the said subject.

  The membrane separation biological treatment apparatus according to the embodiment includes a storage tank, a pump, and an ejector. The storage tank contains a microorganism that biologically processes organic matter in the wastewater and a membrane that separates the wastewater into treated water and sludge. The pump generates a cross-flow water flow with respect to the membrane surface. The ejector is provided on the discharge side of the pump and sucks and mixes the gas into the water flow generated by the pump.

It is an example of sectional drawing explaining the membrane separation biological treatment apparatus concerning a 1st embodiment. It is an example of sectional drawing explaining the membrane separation biological treatment apparatus concerning a 2nd embodiment.

  Below, the membrane separation biological treatment apparatus concerning each embodiment of the present invention is explained using a drawing. The membrane separation biological treatment apparatus according to the present embodiment is an apparatus for biologically treating organic matter in wastewater using microorganisms and obtaining treated water by membrane separation of biologically treated wastewater.

<First Embodiment>
As shown in FIG. 1, in the membrane separation biological treatment apparatus 1 a according to the first embodiment, a membrane separation tank 10 and a sludge circulation tank 11 are connected by a circulation line 12. The membrane separation tank 10 and the sludge circulation tank 11 are formed in a sealed state. In the sludge circulation tank 11, microorganisms that biologically process organic matter in the wastewater exist, and the wastewater treated in the sludge circulation tank 11 is sent to the membrane separation tank 10. When the wastewater is separated into treated water and concentrated sludge by membrane separation in the membrane separation tank 10, the concentrated sludge is sent to the sludge circulation tank 11 through the circulation line 12.

  Wastewater flows into the sludge circulation tank 11 through the drainage supply pipe L1, and concentrated sludge obtained in the membrane separation tank 10 flows through the circulation line 12, and wastewater mixed with the concentrated sludge is stored. ing. In the sludge circulation tank 11, an inlet of a first water supply pipe L2 having a pump 15 and a valve 16 is arranged. When the valve 16 is open, the waste water in the sludge circulation tank 11 is sent to the membrane separation tank 10 by the pump 15 through the first water supply pipe L2.

  In the membrane separation tank 10, an ejector 18 connected to the first water supply pipe L2, a second water supply pipe L3 connected to the ejector 18, an air supply pipe 19 connected to the ejector 18, and a plurality of flat membranes A membrane unit 13 having 14 is built in.

  The wastewater sent from the sludge circulation tank 11 through the first water supply pipe L2 is introduced into the membrane unit 13 through the ejector 18 and the second water supply pipe L3 when the valve 16 is open. In addition, the ejector 18 sucks the gas generated in the membrane separation tank 10 when the valve 20 is open through the air supply pipe 19, mixes this gas into the waste water as air bubbles, and introduces it into the membrane unit 13. . For example, in the membrane separation tank 10 and the sludge circulation tank 11, gas such as methane gas generated by biological treatment exists, and excess gas is discharged from the membrane separation tank 10 and the sludge circulation tank 11 via the exhaust pipe L5. Discharge.

  In the membrane unit 13, the waste water flowing from the lower part through the second water pipe L <b> 3 rises and is filtered by the flat membrane 14 in a cross flow manner. Therefore, the pump 15 needs to supply water at such a pressure that a cross-flow water flow is formed with respect to the flat membrane 14 in the membrane unit 13 when the waste water is supplied. Further, the discharge port of the second water supply pipe L3 is also formed so that the water flow of the wastewater sent by the pump 15 becomes a cross flow with respect to the flat membrane 14.

  The treated water obtained in the flat membrane 14 flows out from the membrane separation tank 10 through the treated water discharge pipe L4 when the valve 22 is in the open state. In addition, when the concentrated sludge remaining after the treated water is separated from the wastewater by the flat membrane 14 flows out from the upper part of the membrane unit 13, it overflows from the inside of the membrane separation tank 10 to the sludge circulation tank 11 via the circulation line 12. be introduced.

  The sludge in the drainage is deposited as a cake on the surface of the flat membrane 14 of the membrane unit 13, but the laminar flow of the crossflow suppresses the accumulation of sludge on the flat membrane 14, and bubbles are generated in the water flow of the crossflow. The sludge can be peeled off from the flat membrane 14 by using the turbulent flow (jet flow) generated by mixing. Here, the size of the bubbles mixed by the ejector 18 is not limited, but it is preferable to make the size easy to generate turbulent flow.

  Here, the sludge is peeled off from the flat membrane 14 by opening and closing the valves 16, 20, and 22 with the corresponding motors 17, 21, and 23 according to the timing of the filtration treatment and the cleaning treatment of the flat membrane 14, respectively. The effect and the effect of suppressing the accumulation of sludge on the flat film 14 can be improved.

  For example, in the membrane separation biological treatment apparatus 1a, during the filtration process, the valve 16 on the first water supply pipe L2 is opened by the motor 17, the valve 20 on the air supply pipe 19 is closed by the motor 21, and no bubbles are contained. Waste water is introduced into the membrane unit 13 at a high speed. Further, the valve 22 on the treated water discharge pipe L4 is opened by the motor 23, and treated water obtained by filtration in the membrane unit 13 is sent out from the membrane separation tank 10. In this case, since the wastewater introduced into the membrane unit 13 becomes a laminar flow instead of a turbulent flow, as described in Patent Document 1, generation of a concentration polarization layer or a gel layer on the membrane surface, That is, accumulation of sludge on the flat membrane 14 surface can be suppressed.

  Further, for example, in the membrane separation biological treatment apparatus 1a, during the cleaning process of the flat membrane 14, the valve 16 on the first water supply pipe L2 is opened by the motor 17, and the valve 20 on the air supply pipe 19 is opened by the motor 21. Then, wastewater containing bubbles is introduced into the membrane unit 13. Further, the valve 22 on the treated water discharge pipe L4 is closed by the motor 23, and the discharge of treated water from the membrane unit 13 is stopped. In this case, turbulent flow is generated in the membrane unit 13 by mixing bubbles in the water flow of the cross flow, and the cake on the surface of the flat membrane 14 is effectively peeled by vibrating the flat membrane 14 with this turbulent flow. can do.

  In this membrane separation biological treatment apparatus 1a, the pressure loss seen from the pump 15 is only the pressure loss due to the restriction of the ejector 18 and the pressure loss of the cross flow water channel between the plurality of flat membranes 14, and from the membrane separation tank 10 to the sludge circulation tank 11. Since there is no pressure loss due to the head due to circulation between the same depths, the total pressure loss is negligible. Therefore, since the pressure loss is small, the power required for the pump 15 is reduced, and the power consumption can be reduced as compared with the case of cleaning with aeration.

For example, in the case of a membrane having a water depth of 5 m and a membrane area of 150 m ² , when cleaning using aeration as in the prior art, the amount of aeration air needs to be 1.5 to 2.0 m ³ / min. Required 2.7 kw. On the other hand, in the membrane separation biological treatment apparatus 1a, in order to obtain the same performance for a membrane having a water depth of 5 m and a membrane area, the circulating water volume is 1 lm ³ / min and the bubble flow rate is 0.7 m ³ / min, for a total of 1. A cross flow of 7 m ³ / min could be realized at about 2.2 kW.

  As described above, in the membrane separation biological treatment apparatus 1a, the laminar flow generated in the membrane unit 13 suppresses the accumulation of the sludge on the flat membrane 14, and the sludge accumulated on the flat membrane 14 is peeled off by the turbulent flow. be able to. Thereby, the movement of the sludge and the cleaning of the membrane surface can be performed with power smaller than aeration.

  In the example described with reference to FIG. 1, the ejector 18 has been described as sucking the gas generated in the membrane separation tank 10 through the air supply pipe 19 and mixing it with the wastewater. The gas to be used is not necessarily limited to the gas in the membrane separation tank 10.

Second Embodiment
2, the membrane separation biological treatment apparatus 1b according to the second embodiment performs biological treatment and membrane separation in the same tank as compared to the membrane separation biological treatment apparatus 1a described above with reference to FIG. Different in what to do. That is, the membrane separation biological treatment apparatus 1b does not include the sludge circulation tank 11, and the wastewater flows directly into the membrane separation tank 10 from the drainage supply pipe L1. Therefore, in the membrane separation biological treatment apparatus 1b, microorganisms that treat organic substances in the wastewater exist in the membrane separation tank 10. In the membrane separation biological treatment apparatus 1b, the pump 15 is disposed in the membrane separation tank 10 so as to be connected to the ejector 18, and the sewage inside the membrane separation tank 10 is transferred to the membrane unit 13 via the second water supply pipe L3. Introduce.

  In the membrane unit 13 of the membrane separation biological treatment apparatus 1b, the waste water flowing in from the lower part rises and the treated water filtered by the flat membrane 14 by the cross flow method flows out through the treated water discharge pipe L4. In addition, the concentrated sludge remaining after the treated water is separated from the wastewater by the flat membrane 14 flows out from the upper part of the membrane unit 13 into the membrane separation tank 10.

  In the membrane separation tank 10, wastewater mixed with wastewater flowing in via the drainage supply pipe L1 and concentrated sludge flowing out from the upper part of the membrane unit 13 is stored, and organic matter in the wastewater is biologically treated by microorganisms. . Wastewater stored in the membrane separation tank 10 is sent into the membrane unit 13 by the pump 15 via the ejector 18 and the second water supply pipe L3. Here, when the valve 20 is in the open state, the ejector 18 introduces the waste water mixed with the gas sucked through the air supply pipe 19 into the membrane unit 13.

  Even in the membrane separation biological treatment apparatus 1b according to the second embodiment, the valves 16, 20, and 22 are opened and closed according to the timing of the filtration treatment and the timing of the washing treatment of the flat membrane 14, and using the water flow of the cross flow, The formation of cake on the surface of the flat film 14 of the membrane unit 13 can be prevented, or the cake formed on the surface of the flat film 14 can be peeled off to improve the effect of suppressing the accumulation of sludge on the flat film 14.

  For example, in the membrane separation biological treatment apparatus 1a, during the filtration process, the valve 20 on the air supply pipe 19 is closed by the motor 21, and the waste water not containing bubbles is introduced into the membrane unit 13 by the pump 15 at a high speed. . Further, the valve 22 on the treated water discharge pipe L4 is opened by the motor 23, and treated water obtained by filtration in the membrane unit 13 is sent out from the membrane separation tank 10. In this case, since the wastewater introduced into the membrane unit 13 becomes a laminar flow instead of a turbulent flow, generation of a concentration polarization layer or gel layer on the membrane surface, that is, accumulation of sludge on the flat membrane 14 is suppressed. can do.

  Further, for example, in the membrane separation biological treatment apparatus 1a, during the cleaning process of the flat membrane 14, the valve 20 on the air supply pipe 19 is opened by the motor 21, and the waste water in the membrane separation tank 10 is sent out by the pump 15. Waste water containing bubbles is introduced into the membrane unit 13. Further, the valve 22 on the treated water discharge pipe L4 is closed by the motor 23, and the discharge of treated water from the membrane unit 13 is stopped. In this case, a turbulent flow is generated in the membrane unit 13 by the cross-flow water flow and the water flow including bubbles, and the flat membrane 14 is vibrated by the turbulent flow, thereby effectively peeling the cake on the surface of the flat membrane 14. be able to.

  In this membrane-separated biological treatment apparatus 1b, the pressure loss from the pump 15 is only the pressure loss due to the restriction of the ejector 18 and the pressure loss of the cross flow channel between the plurality of flat membranes 14. Therefore, since the pressure loss is small, the power required for the pump 15 is reduced, and the power consumption can be reduced as compared with the case of cleaning with aeration.

  As described above, in the membrane separation biological treatment apparatus 1b, the laminar flow generated in the membrane unit 13 suppresses the accumulation of sludge on the flat membrane 14, and the sludge accumulated on the flat membrane 14 by the turbulent flow is peeled off. Can do.

  In the example described above with reference to FIG. 2, the ejector 18 has been described as sucking the gas generated in the membrane separation tank 10 through the air supply pipe 19 and mixing it with the wastewater, but the ejector 18 sucks the gas. The gas to be used is not necessarily limited to the gas in the membrane separation tank 10.

  Although the embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, rewrites, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 1a, 1b ... Membrane separation biological treatment apparatus 10 ... Membrane separation tank (storage tank)
11 ... Sludge circulation tank (storage tank)
DESCRIPTION OF SYMBOLS 12 ... Circulation line 13 ... Membrane unit 14 ... Flat membrane 15 ... Pump 16 ... Valve 17 ... Motor 18 ... Ejector 19 ... Air supply pipe 20 ... Valve 21 ... Motor 22 ... Valve 23 ... Motor L1 ... Drain supply pipe L2 ... First Water pipe L3 ... Second water pipe L4 ... Treated water discharge pipe

Claims (1)

A micro-organism that biologically treats organic matter in the waste water, and a storage tank that includes a membrane unit having a membrane that separates the waste water into treated water and sludge;
A pump for generating a cross-flow water flow with respect to the membrane surface;
An ejector which is provided on the discharge side of the pump and sucks and mixes the gas generated in the storage tank with the water flow generated by the pump;
An air supply pipe connected to the ejector;
With
At the time of membrane filtration, the pump does not contain air bubbles into the membrane unit to generate laminar flow in the membrane unit,
The membrane-separated biological treatment apparatus, wherein at the time of membrane cleaning, the pump and the ejector introduce the waste water containing bubbles into the membrane unit through the air supply pipe to generate turbulent flow in the membrane unit.

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