JP2008114154A - Method of cleaning separation membrane - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method of cleaning a separation membrane which is convenient and has a high cleaning effect. <P>SOLUTION: The cleaning method is a method for cleaning a separation membrane 102 to be used in membrane filtration and comprises blocking a lower opening of a separation membrane unit 10 in which the separation membrane 102 is incorporated and pouring a liquid into the separation membrane unit 10 to immerse the separation membrane 102 in the liquid. The method allows a convenient cleaning of the separation membrane unit 10, requires less working labor and achieves a high cleaning effect. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a separation membrane cleaning method. More specifically, the present invention relates to a separation membrane cleaning method used for membrane filtration treatment.

  Regardless of living system or industrial system, waste water containing organic matter is generated, and the activated sludge method is used as waste water treatment. The activated sludge method is a biological treatment method that utilizes the action of decomposing organic matter into carbon dioxide and water by aerobic microorganisms, and is a wastewater treatment method that uses a mass of aerobic microorganisms with excellent sedimentation properties as activated sludge.

  The activated sludge method requires separation of sludge and treated water, but membrane separation activated sludge that separates treated water from sludge etc. by directly immersing a separation membrane such as a microfiltration (MF) membrane in an aeration tank. The law has recently attracted attention and is becoming popular. The membrane-separated activated sludge method is a method that can obtain highly treated water relatively easily, but because the dirt component adheres to the membrane surface of the separation membrane, the membrane permeation performance is reduced, and the usage time is reduced. There is a problem that the membrane separation ability decreases with progress. Therefore, it is necessary to restore the membrane permeability by periodically cleaning the membrane module in which the separation membrane is stored, etc.

  As a cleaning method, for example, there is a method of performing chemical cleaning by installing a cleaning tank and immersing the membrane module pulled up from the membrane tank in the cleaning tank containing fresh water (hereinafter referred to as “immersion cleaning method”). is there. For example, Patent Document 1 discloses a technique related to a method for cleaning an immersion membrane in which a separation membrane unit is installed separately from an aerobic wastewater treatment tank, and the water to be treated is discharged and washed. In addition, a method (hereinafter referred to as an “in-line cleaning method”) in which the cleaning liquid is reversely passed through the permeate drawing pipe while the membrane module is immersed in the aeration tank is performed. Hereinafter, a typical prior art of the immersion cleaning method will be described with reference to the accompanying drawings.

  FIG. 7 is a conceptual diagram for explaining a general immersion cleaning method. Reference numeral 2 in FIG. 7 denotes a membrane separation device, which shows a state in which the separation membrane is washed. The membrane separation device 2 includes a separation membrane unit 20, a membrane immersion aeration tank 21, and a cleaning tank 22.

  The separation membrane unit 20 collects and stores separation membrane elements 201. The separation membrane unit 20 includes air pipes 202 and 203 for diffusing the separation membrane element 201, connection parts 202 a and 203 b, a suction pipe 204 for membrane filtration with the separation membrane element 201 and connection parts thereof. 204c. In the immersion cleaning method, dirt components such as sludge adhering to the separation membrane unit are immersed and cleaned.

  The membrane immersion aeration tank 21 is a tank for treating activated sludge by immersing the separation membrane unit 20 in the tank. The membrane immersion aeration tank 21 includes an air pipe 211 for aeration and a suction pipe 214 for performing membrane filtration with the separation membrane element 201 of the separation membrane unit 20.

  When the activated sludge is separated from the treated water, the aeration blower 212 aerates the connection portions 211a and 212b of the air pipe 211 connected to the connection portions 202a and 203b of the separation membrane unit 20, respectively. Similarly, suction is performed by the suction pump 215 in a state where the connection portion 214 c of the suction pipe 214 and the connection portion 204 c of the separation membrane unit 20 are connected.

  When cleaning the separation membrane unit 20, the separation membrane unit 20 is separated by the connecting portions 202 a (211 a), 203 b (211 b), and 204 c (214 c) as shown in FIG. Then, the cleaning chemical solution is introduced into the entire cleaning tank 22 and the chemical cleaning is performed in the cleaning tank 22. After completion of the cleaning, the separation membrane unit 20 is transferred again to the membrane immersion aeration tank 21, and the connecting portions 202a and 211a, 203b and 211b, 204c and 214c are connected and returned.

JP 2000-167555 A.

  However, the above immersion cleaning method exhibits a high cleaning effect, but it is necessary to newly install a cleaning tank, to move the separation membrane unit to the cleaning tank, or to administer the chemical solution to the entire volume of the cleaning tank. Therefore, it is not excellent in economic efficiency and workability because it requires a large amount of chemical solution. The in-line cleaning method can be said to be a simple cleaning method because it is cleaned in-line. However, when the separation membrane is heavily soiled or clogged, a sufficient cleaning effect cannot be obtained. That's not true.

  Accordingly, the main object of the present invention is to provide a separation membrane cleaning method that is simple but has a high cleaning effect.

  First, in the present invention, for the separation membrane cleaning method used for membrane filtration, the lower opening of the separation membrane unit in which the separation membrane is incorporated is closed, and a liquid is poured into the separation membrane unit to perform the separation. Provided is a separation membrane cleaning method in which a membrane is immersed in the liquid for cleaning. Accordingly, the lower opening of the separation membrane unit is closed and immersed in a liquid for cleaning, so that the cleaning can be performed efficiently and easily while using a small amount of liquid.

  Next, in the present invention, there is provided a separation membrane cleaning method for cleaning while introducing gas into the separation membrane immersed in the liquid. Thereby, the separation membrane immersed in the liquid can be more effectively cleaned. Then, in this invention, the said separation membrane provides the washing | cleaning method which is an immersion type microfiltration membrane.

  According to the separation membrane cleaning method of the present invention, a high cleaning effect can be exhibited while being a simple cleaning method.

  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments for carrying out the invention will be described with reference to the accompanying drawings. The embodiment shown in the drawings is an example of a preferred embodiment of the present invention, and the present invention is not construed narrowly.

  FIG. 1 is a conceptual diagram for explaining a cleaning method according to the present invention. Reference numeral 1 in FIG. 1 denotes a membrane separation device, which shows a state in which the separation membrane is being washed. The membrane separation apparatus 1 is in a state where a separation membrane unit 10 is submerged in a membrane immersion aeration tank 11 and a cleaning tool 12 is mounted.

  The separation membrane unit 10 collects and stores separation membrane elements 101. The separation membrane unit 10 is connected to an air pipe 111 and the cocks 112 and 113 are open so that the aeration blower 116 can aerate. In addition, the lower part of the separation membrane unit 10 has a lower opening for discharging the liquid processed by the separation membrane element 101 and the like.

  The membrane-immersed aeration tank 11 is in a state where activated sludge is stored. A cleaning tool 12 is attached to the bottom of the separation membrane unit 10 immersed in the membrane immersion aeration tank 11, and the bottom of the separation membrane unit 10 is closed by the cleaning tool 12, and the separation membrane The liquid is not drained from inside the unit. In the separation membrane unit 10 in this state, clean water (cleaning water for cleaning) is poured up to the liquid level W. That is, only the separation membrane unit 10 is filled with the cleaning solution, and the cleaning solution does not leak into the membrane immersion aeration tank 11.

  In the present invention, the lower opening of the separation membrane unit 10 only needs to be closed, and the method and means thereof are not limited. However, preferably, the lower opening is closed by a plate or sheet that can cover the lower opening. This method is desirable, and is preferable in that the lower opening can be closed by a simpler method.

  In the present invention, the method and means for fixing the lower opening of the separation membrane unit 10 and the cleaning tool 12 are not particularly limited. For example, the separation membrane unit 10 and the cleaning tool 12 are fixed by a belt. Alternatively, the cleaning tool 12 having a size and shape that conforms to the standard and shape of the separation membrane unit 10 may be fixed with a connecting tool such as a buckle that can be easily attached and detached.

  In the present invention, since the lower opening of the separation membrane unit 10 only needs to be closed, a large washing tank is unnecessary, and it is not necessary to connect the entire separation membrane unit 10 to a large apparatus, so that the washing operation is simple. And less labor. In particular, when the scale of the membrane immersion aeration tank 11 to be used is large, or when the installation location and the working environment are narrow, the work of moving the separation membrane unit 10 in the left-right direction requires particularly labor and a moving space. However, since the cleaning method according to the present invention only needs to be moved up and down within the range of the membrane immersion aeration tank 11, work efficiency and the like are excellent.

  In this state, a cleaning chemical can be introduced into the separation membrane unit 10 filled with fresh water, and air can be washed from the air pipe 111 to the bottom of the separation membrane unit by the aeration blower 116 to wash the membrane while stirring. .

  FIG. 2 is a conceptual diagram for explaining the cleaning method according to the present invention in the order of steps. Hereinafter, it will be described in conjunction with FIG.

  The state A in FIG. 2 is a state in which the operation of the apparatus is stopped and the cleaning of the separation membrane element 101 stored in the separation membrane unit 10 is started. First, the cocks 112 and 113 of the air pipe 111 are closed to shut off the separation membrane unit 10 and the aeration blower 116 (see FIG. 1). Similarly, although not shown, the separation membrane unit 10 and the suction pump 115 (see FIG. 1) are also blocked so that the inside of the separation membrane element 101 is not sucked and depressurized. Then, the separation membrane unit 10 is pulled upward (see FIG. 2; arrow S), and the cleaning tool 12 is attached to the bottom of the separation membrane unit 10.

  The state B is a state in which the cleaning tool 12 is completely attached to the separation membrane unit 10 pulled upward. By attaching the cleaning tool 12 to the bottom of the separation membrane unit 10, the lower opening of the separation membrane unit 10 can be sufficiently closed. In this way, while injecting fresh water into the separation membrane unit 10 to which the cleaning tool 12 is attached, it is immersed in the membrane immersion aeration tank 11 by being lowered downward (FIG. 2; T direction).

  The state C is a state in which the separation membrane unit 10 to which the cleaning tool 12 is attached is immersed in the membrane immersion aeration tank 11 for cleaning. That is, clean water for cleaning is poured into the separation membrane unit 10 up to the liquid level W. Then, a cleaning chemical is introduced into the separation membrane unit 10 filled with fresh water, and air is introduced by opening the cocks 112 and 113, and the membrane element 101 is cleaned while stirring. If the separation membrane unit 10 is washed with a high concentration of chemical solution, the tube of the separation membrane is damaged, so it is desirable to stir with aeration.

  After the cleaning is completed, the cleaning tool 12 is removed from the membrane unit 10 as it is, the state is returned to the normal operation state, and the operation of the apparatus is started. That is, according to the cleaning method of the present invention, the amount of clean water or cleaning chemical used for the cleaning only needs to be the volume of the separation membrane unit 10, so that it is economical only in that these usages are small. It is also simple in that it can be sufficiently neutralized by discharging it into the membrane-immersed aeration tank 11 as it is.

  Therefore, according to the cleaning method of the present invention, since the entire separation membrane element 101 is first immersed in the cleaning liquid, a high cleaning effect can be obtained. Next, since it is not necessary to transfer the separation membrane unit to another washing tank, there is no need to move the separation membrane unit 10 in the horizontal direction (left and right direction), and the vertical direction (see arrows S, T, etc. in FIG. 2). Therefore, the operation at the time of cleaning is simple and labor-saving. Further, since the cleaning liquid used for cleaning only needs to be dispensed only into the internal volume in the separation membrane unit 10, the amount of cleaning liquid used can be reduced. Therefore, it is economical and environmentally friendly. Furthermore, since the used cleaning liquid can be neutralized in the aeration tank, the operation is simple in that no special post-treatment or waste water treatment is required.

  FIG. 3 is a perspective view when the cleaning tool is mounted on the separation membrane unit, FIG. 4 is a side view when the cleaning tool is mounted on the separation membrane unit, and FIG. 5 is a mounting view of the cleaning tool on the separation membrane unit. FIG. 6 is a top view when the cleaning tool is mounted on the separation membrane unit.

  First, FIG. 3 shows a state in which the cleaning tool 12 is positioned in the bottom direction of the membrane separation unit 10. The membrane separation unit 10 stores a membrane separation element 101, and stores a diffuser tube 102 below the membrane separation element 101. The diffuser tube 102 is provided with a coupler 1021, so that an external device is provided. It can be attached to and detached from the air pipe (for example, reference numeral 111 in FIG. 1). The membrane separation unit 10 is provided with a suspension string 103, which can be lifted up and down. Further, guides 104 a, 104 b, 104 c for moving the separation membrane unit 10 up and down are provided on the outer edge of the membrane separation unit 10. It can be stabilized by passing a belt through this guide.

  The cleaning tool 12 has a sheet shape, and closes the lower opening of the separation membrane unit 10 by bringing the surface 121 into close contact with the bottom of the separation membrane unit 10 in the direction of arrow U (see FIG. 3). And it is a tool which can block | close the lower opening part of the separation membrane unit 10 more effectively by bend | folding the edge part 121a of the surface 121 to the arrow V direction (refer FIG. 3). A belt 123 is provided at an end 121 a of the surface 121, and this belt 123 is for fixing the membrane separation unit 10 and the cleaning tool 12. The belt 123 is provided with a fastener (buckle) 124, and the separation membrane unit 10 and the cleaning tool 12 can be fixed by fastening the fastener 124 on the separation membrane unit 10.

  4 and 5 show a state in which the cleaning tool 12 attached to the separation membrane unit 10 of FIG. That is, the lower opening portion of the separation membrane unit 10 is further closed by pulling the bent end portion 121 a of the cleaning tool upward with the belt 123.

  FIG. 6 shows the state in which the belts 123 pulled upward are tied together on the upper surface, whereby the lower opening of the separation membrane unit is covered with the cleaning tool 12 and can be closed. The method for tying the belt 123 is not particularly limited, and for example, it can be tied using a connecting tool such as a buckle.

  The shape, type, material, and the like of the cleaning tool 12 used in the present invention are not particularly limited as long as the lower opening of the separation membrane unit 10 can be closed. Preferably, a waterproof synthetic resin is used. A sheet made of metal or a plate made of metal or plastic is desirable, and more desirably, a material that can be watertightly closed with the separation membrane unit and has a flexibility, such as tarpaulin (soft vinyl chloride laminate). A sheet made of plastic such as cloth) is desirable. Thereby, the leakage of the cleaning liquid to be injected for cleaning can be prevented more effectively.

  In addition, the cleaning method according to the present invention is not particularly limited as to which stage is used for the processing stage in the activated sludge method. For example, a separation membrane unit (element) used for pretreatment may be used. Well, it can be used in a wide range of biological treatment processes by the activated sludge method. Further, the washing conditions and the like are not particularly limited, and the washing conditions, the number of washings, and the like can be appropriately determined according to the quality of raw water and the performance and type of the separation membrane.

  And in this invention, it does not specifically limit about the property, kind, etc. of the membrane itself used, For example, a microfiltration membrane (MF; Microfiltration), an ultrafiltration membrane (UF; Urtrafiltration) etc. may be sufficient, Preferably, it is preferably an immersion type microfiltration membrane having high separation ability and easily clogging, and is desirable in that a higher cleaning effect can be obtained. The submerged microfiltration membrane may be a microfiltration membrane that is immersed in some form during use. For example, it may be a microfiltration membrane that is temporarily immersed and used. It is not limited to a microfiltration membrane in which the entire membrane is immersed.

  In the present invention, the type and shape of the membrane module to be cleaned are not particularly limited, but a tank immersion type is preferable, and a hollow fiber type module is more preferable. The hollow fiber type module is easily clogged with activated sludge because of its thin tube diameter, but according to the cleaning method of the present invention, the clogging of the tube diameter can be effectively eliminated.

  In the present invention, the liquid used for washing is not particularly limited. For example, the liquid may be alkaline or acidic, but preferably sodium hypochlorite for organic soils. It is desirable to use hydrochloric acid, and it is desirable to use hydrochloric acid for inorganic soils.

  Hereinafter, comparative experiments were performed for the purpose of verifying the effects of the present invention. It is a comparison of the cleaning effect etc. of the cleaning method according to the present invention and the conventional cleaning method (immersion cleaning method, in-line cleaning method).

The experimental procedure was as follows.
As cleaning methods, the following three cleaning methods were verified. First, cleaning was performed by the cleaning method according to the present invention and, as a comparative example, an immersion cleaning method (Comparative Example 2) and an in-line cleaning method (Comparative Example 2). The separation membrane used in the membrane separation activated sludge method was washed by each washing method, and the washing effect was verified. The wastewater treatment conditions were as shown in Table 1.

  The separation membrane used in the membrane separation activated sludge method was washed by each washing method, and the washing effect was evaluated. The results are shown in Table 2.

<Discussion>
In the example (cleaning method according to the present invention), as a result of using 0.2% sodium hypochlorite as the cleaning liquid, the suction pressure recovered 20.6 kPa while the amount used was 1.0 m ³ / unit. . On the other hand, in Comparative Example 1, the suction pressure recovered 20.5 kPa, but the amount of sodium hypochlorite used was 2.0 m ³ / unit. In Comparative Example 2, the amount of sodium hypochlorite used was 0.5 m ³ / unit, but the suction pressure recovered only 8.5 kPa.

  From the above, as a result of carrying out the comparison and verification of the three types of cleaning methods at the same time, the effect of the cleaning method according to the present invention is that it is a simple cleaning method, but has a small amount of chemical solution to be used and has a high cleaning effect Indicated.

  The membrane module cleaning method according to the present invention can be used for cleaning a wide range of separation membranes used for biological treatment wastewater for treating domestic wastewater, industrial wastewater, and the like, and can therefore be used in many fields for wastewater treatment. I can do it.

Conceptual diagram for explaining a cleaning method according to the present invention. Conceptual diagram for explaining the cleaning method according to the present invention over time A perspective view when attaching a cleaning tool to the separation membrane unit Side view when attaching cleaning tools to the separation membrane unit Front view when attaching cleaning tools to the separation membrane unit Top view when a cleaning tool is attached to the separation membrane unit Conceptual diagram for explaining a conventional typical immersion cleaning method

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Membrane separation apparatus 10 Separation membrane unit 11 Membrane immersion aeration tank 12 Cleaning tool 101 Separation membrane element 111 Air piping 112 Aeration blower 114 Suction piping 115 Suction pump

Claims (3)

A method for cleaning a separation membrane used for membrane filtration treatment,
Blocking the lower opening of the separation membrane unit in which the separation membrane is incorporated,
Putting liquid into the separation membrane unit,
A method for cleaning a separation membrane, wherein the separation membrane is immersed in the liquid for cleaning.   2. The separation membrane cleaning method according to claim 1, wherein the cleaning is performed while introducing a gas into the separation membrane immersed in the liquid.   2. The separation membrane cleaning method according to claim 1, wherein the separation membrane is an immersion type microfiltration membrane.

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