KR20080087899A - Membrane filtration apparatus and its operating method - Google Patents

Abstract

This invention provides a membrane filtration apparatus that can realize stable membrane filtration operation at a high percentage operation recovery even for raw water having a relatively high level of turbidity. The membrane filtration apparatus comprises a dipping tank (1) having a raw water supply port in its upper part and a water discharge port in its lower part. A dipping-type hollow fiber membrane module (2) comprising a large number of hollow fiber membranes which have been bundled, is disposed within the dipping tank (1) so that the longitudinal direction of the hollow fiber membrane is a vertical direction. A diffuser tube (3) is disposed below the hollow fiber membrane module. The position of the raw water supply port is located above the hollow fiber membrane module. In a horizontal section of the dipping tank in which the hollow fiber membrane module has been disposed, the proportion of the sectional area of the hollow fiber membrane module to the sectional area within the dipping tank is 60% to 90%, the distance between the diffuser tube and the bottom face of the dipping tank is not less than 200 mm, and the position of the water discharge port is not less than 200 mm below the diffuser tube.

Description

Membrane filtration device and its operation method {MEMBRANE FILTRATION APPARATUS AND ITS OPERATING METHOD}

The present invention provides a structure of a device for separating and filtering water by a hollow fiber membrane, and more specifically, membrane filtration can be stably performed at a high recovery rate even when raw water has a high turbidity. Membrane filtration apparatus.

Since the membrane filtration method of filtering water by the separation membrane has characteristics such as energy saving, space saving, power saving, and water quality improvement, the method has been widely used in various fields. For example, membrane filtration using microfiltration membranes or ultrafiltration membranes has been applied to water-tablet manufacturing processes for producing industrial water or tap water from river water, ground water, and sewage treated water.

Hollow fiber membrane modules have been applied in a variety of fluid processing applications, such as chemical purification, sterile filtration, and clarification, with the aim of ensuring a large membrane area per unit volume.

Hollow fiber membrane modules include pressurized hollow fiber membrane modules and submerged hollow fiber membrane modules. In the pressurized hollow fiber membrane, a plurality of hollow fiber membranes are loaded into a pressure-resistant cylindrical case without an opening, wherein both ends of the membrane bundle and the inner wall of the cylindrical case are bonded and fixed, and one end or both ends are cut to cut the hollow fiber membrane. Is opened, the open end is provided with a filtered water collector for collecting the filtered water, a stock solution supply for supplying the stock solution to the cylindrical case, and pressurized raw water introduced into the module is applied to the surface of the hollow fiber membrane. Filtered by. On the other hand, in the immersed hollow fiber membrane, both ends of the hollow fiber membrane bundle are adhesively fixed by an adhesive, and one or both ends are cut to open the inside of the hollow fiber membrane, and the open portion is filtered to collect the filtered water. A water collector is provided, and the membrane module is submerged in raw water in an air immersion tank. The permeated water side provided with the filtered water collector is absorbed and filtered.

Pressurized hollow fiber membrane modules can increase throughput per membrane area in that they set a filtration pressure greater than the immersion type. As a result, the number of membranes for the filtration process can be reduced, thereby reducing the installation space. On the other hand, the immersed hollow fiber membrane module is used by submerging the hollow fiber membrane bundle in the penetration raw water without the pressure-resistant cylindrical case around the hollow fiber membrane. Thus, there is an advantage in that it is easy to discharge suspended substances stuck between the hollow fiber membranes, that is, the discharge performance of the suspended substance is good and thus membrane filtration can be performed even in high-turbidity water. In addition, since the filtration system is simple and the number of auxiliary pipes is small, there is an advantage of reducing the equipment cost.

As described above, the immersed membrane module has the advantage of having a good performance in discharging suspended matter stuck between the membranes because no pressure-resistant cylindrical casing is provided, and even membrane filtration can be performed in high-turbidity raw water. Has the advantage of Thus, various studies have been made with raw water-filled immersion tanks in which immersed membrane modules are arranged such that membrane filtration can be performed even in high-turbidity water.

For example, in Patent Document 1, a plurality of membrane modules comprising a plurality of tube-shaped ceramic separation membranes arranged in parallel are stacked up, an air diffusion pipe is placed underneath, and a sedimentation zone is formed in the ground below. An apparatus is disclosed. In this arrangement, the membrane module is arranged horizontally so that the longitudinal direction of the pipe-shaped separation membrane coincides with the horizontal direction. The apparatus is provided with a settling zone to reduce turbidity of the raw water around the membrane module, so that the suspended components are easily settled in the settling zone as they are peeled off from the surface of the separation membrane by air scrubbing through the tank.

Patent document 2 describes the placement of a barrier plate between the air diffusion device and the bottom of the immersion tank to prevent suspended components deposited in the settling area from resuspending by air scrubbing.

Patent Document 3 discloses a device in which a flat membrane module is placed in an aeration tank (treatment tank) for active sludge treatment and an air diffusion device is disposed below, wherein the area of the treatment tank occupied on the same horizontal plane is It is set at least three times larger than the area of the membrane module. The inner surface of the treatment tank is extended to facilitate the in-tank circulation flow caused by the air supplied from the air diffusion device as described above to improve the discharge performance of suspended substances stuck between the membranes.

However, specifically, the immersed hollow fiber membrane module among the immersed membrane modules has a large membrane area per unit volume because a plurality of hollow fiber membranes are bundled and placed in the module. Thus, there is a disadvantage that suspended components are easily filled between the membranes. Thus, it is difficult to treat high-turbidity raw water only with the conventional techniques disclosed above. For this reason, a constant air scrubbing method of performing air scrubbing in the filtration process and the physical cleaning process, a method of regularly draining most of the concentrated raw water from the immersion tank to flow relatively transparent raw water prior to concentration (drainage method), Or a combination of both methods has been generally applied.

Although certain air scrubbing methods are widely used mainly for sewage wastewater treatment, there are practical problems of enormous running costs and lack of reliability as a stable operation method for high-turbidity raw water.

In the gentle drainage method, on the other hand, the whole amount of water is drained when the concentration of concentrated water in the tank rises to reach a predetermined concentration, and then the tank is filled with raw water before it is concentrated again. Thus, the method is reliable as a stable operating method for high-turbidity raw water. However, the immersed membrane module is placed in a wide immersion tank. Thus, when the slow drainage method is applied in a conventional apparatus that has a good performance in discharging suspended matter, most of the concentrated water in the immersion tank is discharged, and thus, its operation recovery rate is greatly reduced.

Here, the inner surface of the immersion tank can be set to a shape similar to the membrane module and substantially the same size as the membrane module. In this case, even when the slow drainage method is used, the problem that the operation recovery rate is greatly reduced can be solved. However, if the inner surface of the immersion tank has a shape similar to the membrane module and substantially the same size as the membrane module, there is little functional difference from the pressurized module formed by inserting the hollow fiber membrane bundle into the pressure-resistant cylindrical case, so that The ability to discharge stuck suspended substances will be greatly reduced.

With regard to the membrane filtration device comprising the hollow fiber membrane module immersed as described above, the improvement of the performance of discharging suspended matter and the improvement of operation recovery rate are balanced, and both are considered difficult to satisfy.

Patent Document 1: JP-A-2002-191946

Patent Document 2: JP-A-9-220441

Patent Document 3: JP-A-8-267083

Problems to be Solved by the Invention

The present invention provides a membrane filtration apparatus in which an immersed hollow fiber membrane module for separating solids and liquids by absorption and filtration is disposed in an immersion tank, an air diffusion pipe is disposed below the hollow fiber membrane module, and a raw water supply is disposed on the hollow fiber membrane module. To provide. According to the filtration membrane device, the performance of discharging suspended matter stuck between the membranes is high, the operation recovery rate is kept high even when applying the wastewater method, and the high recovery rate even with respect to high-turbidity raw water. Stable membrane filtration.

Means to solve the problem

In order to solve the above-mentioned problem, a membrane filtration apparatus is provided, in which an immersed hollow fiber membrane module formed by bundle of a plurality of hollow fiber membranes has a raw water supply port at the top thereof so that the longitudinal direction of the hollow fiber membranes coincides with the vertical direction. And an air diffusion pipe under the hollow fiber membrane module, wherein the raw water supply port is disposed above the hollow fiber membrane module, and the hollow fiber membrane for the cross-sectional area of the tank of the immersion tank. The ratio of the cross-sectional area of is 60% to 90% in the horizontal plane where the hollow fiber membrane module is arranged, the distance between the bottom of the air diffusion pipe and the immersion tank is 200 mm or more, and the drain port is 200 mm below the air diffusion pipe. Or further below 200 mm.

In this case, the ratio of the cross-sectional area of the hollow fiber membrane to the cross-sectional area of the tank of the immersion tank is 70% to 80% in the horizontal plane where the hollow fiber membrane module is disposed, and the distance between the bottom of the air diffusion pipe and the immersion tank is 200 mm to 700 mm. Is preferably.

In addition, the hollow fiber membrane module, the plurality of hollow fiber membranes are tied at least at the top and bottom thereof, the top side of the hollow fiber membrane bundle is tied and fixed in the state that the cross section of the hollow fiber membrane is open, the water collector is an open cross section of the hollow fiber membrane It is preferable to have a structure in which the bottom side of the hollow fiber membrane bundle is bundled by a plurality of cattle bundles in a state where the cross section of the hollow fiber membrane is closed.

In addition, the drain port is preferably arranged at the bottom of the immersion tank.

In an operation method of filtering raw water using a membrane filtration device, it is effective to regularly lower the water level in the immersion tank to a lower position by 200 mm or more than 200 mm above the air diffusion pipe. Moreover, in the operation method of filtering raw water using a membrane filtration apparatus, it is preferable that a part of the water in the immersion tank is regularly discharged from the drain port.

Advantage of the present invention

According to the present invention, it is possible to maintain a good performance of draining heavily suspended particles between the membranes, which is an advantage of the immersed hollow fiber membrane module, and the operation recovery rate even if all or most of the water in the immersion tank is regularly discharged. Can be kept high. In addition, a significant amount of suspended material contained in the raw water is not filtered by the membrane and settles near the bottom of the immersion tank, so that it is accumulated or concentrated. Thus, a stable membrane filtration operation can be performed with high recovery in relation to relatively high-turbidity raw water.

1 is a schematic cross-sectional view showing an embodiment of the membrane filtration device according to the present invention.

FIG. 2 is a schematic cross-sectional view showing a horizontal cross section taken along the horizontal line Z-Z of FIG. 1, viewed from above.

3 is a schematic cross-sectional view showing a specific example of the hollow fiber membrane module used in the present invention.

4 is a schematic cross-sectional view showing yet another embodiment of the membrane filtration apparatus according to the present invention.

FIG. 5 is a schematic cross sectional view showing a horizontal cross section taken along the horizontal line Z-Z of FIG. 4, seen from above. FIG.

FIG. 6 is a schematic cross-sectional view showing the flow of water in the immersion tank during air scrubbing in the membrane filtration apparatus shown in FIG. 1.

Explanation of Reference Numbers and Symbols

1: immersion tank, 1A: inner surface of immersion tank, 2: hollow fiber membrane module, 2B: outer surface of hollow fiber membrane module, 3: air diffusion pipe, 4: air diffusion hole, 5: permeated water pipe, 6: raw water supply port , 7: drain line, 8: hollow fiber membrane, 9a, 9b: adhesive fixing, 10: water collection cap, 11: air inlet cylinder, 12: penetration hole, 13: drain port.

Best Practices for Carrying Out the Invention

In the membrane filtration apparatus according to the present invention, the immersed hollow fiber membrane module formed by bundling a plurality of hollow fiber membranes is arranged in an immersion tank having a raw water supply port at the top and a drainage port at the bottom to vertical direction of the hollow fiber membrane Match the air diffusion pipe and place it under the hollow fiber membrane module. The raw water supply port is placed above the hollow fiber membrane module, and the ratio of the cross-sectional area of the hollow fiber membrane to the cross-sectional area of the tank of the immersion tank is 60% to 90% in the horizontal plane where the hollow fiber membrane module is disposed, and the bottom of the air diffusion pipe and the immersion tank. The distance between them is 200 mm or more, with the drain port being arranged 200 mm below or more than 200 mm below the air diffusion pipe.

The invention will now be described with reference to the drawings, which schematically illustrate a membrane filtration device according to the best embodiment of the invention. The scope of the invention is not limited to the embodiments.

1 is a schematic view showing an embodiment of the membrane filtration apparatus according to the present invention, and FIG. 2 is a schematic cross-sectional view showing the immersion tank and hollow fiber membrane module shown in FIG. 1 obtained along horizontal line Z-Z, viewed from above. 3 is an enlarged schematic cross-sectional view showing an embodiment of the hollow fiber membrane module shown in FIG. 4 is a schematic cross-sectional view showing yet another embodiment of the membrane filtration apparatus according to the present invention. FIG. 5 is a schematic cross-sectional view showing the immersion tank and hollow fiber membrane module shown in FIG. 4 obtained along the horizontal line Z-Z, viewed from above. FIG.

In the present invention, the immersed hollow fiber membrane module 2 has a structure formed by collecting a plurality of (eg, hundreds to tens of thousands) of hollow fiber membranes 8 and bonding and fixing both ends of the hollow fiber membrane bundles formed by bundles. . Preferably, the hollow fiber membrane module is disposed on one end side 9a of the adhesive fixing part with the filtered water collecting section open at the end face of the hollow fiber membrane, and the other end side 9b is closed at the end surface of the hollow fiber membrane. Adhesively fixed type (illustrated in FIGS. 1 and 3, etc.). However, the hollow fiber membrane module may be of a type in which both ends of the adhesion fixing part are adhesively fixed with both cross-sections of the hollow fiber membrane open, and the filtered water collector is provided thereon.

The hollow fiber membranes 8 are not particularly limited if they are porous hollow fiber membranes having desired filtration performance, but are preferably polyacrylonitrile, polyphenylene sulfone, polyphenylene sulfide sulfone, polyvinylidene fluoride , Polypropylene, polyethylene, polysulfone, polyvinyl alcohol, and a polymer material such as cellulose acetate, or an inorganic material such as ceramic, and the like. It is made of lidene fluoride. The pore diameter formed on the surface of the hollow fiber membrane is not particularly limited but may be selected to have a desired filtration performance in the range of 0.001 μm to 1 μm. Although the outer diameter of the hollow fiber membrane 8 is not specifically limited, either, Preferably it is the range of 250 micrometers-2000 micrometers, because a hollow fiber membrane has a big fluctuation | variation and a washability is favorable.

The adhesive used for adhesively fixing both ends of the hollow fiber membrane bundle is not particularly limited, but it is preferable to use a thermosetting resin such as an epoxy resin and a urethane resin.

Adhesion fixing portions 9a and 9b formed at both ends of the hollow fiber membrane bundles are connected to each other through a plurality of hollow fiber membrane portions disposed therebetween. In many hollow fiber membrane portions, the hollow fiber membranes are spun in parallel and exhibit a membrane filtration function. The outer periphery of the bundles spun in parallel among the plurality of hollow fiber membrane portions may have a structure without interposing the reinforcing member as specifically illustrated in FIG. 3, and may have a structure in which the reinforcing member is opened (not shown). A structure having a reinforcing member interposed therebetween, for example, a structure in which 1 to 30 reinforcing stays (for example, metal rods) are disposed on an outer circumference or inside of parallel spinning, whereby the fixing fixing parts are connected to each other by the stay, or between the fixing fixing parts. There is a structure in which a porous plate-like material, such as a net, is disposed to cover the outer circumference of the hollow fiber membrane spun bundle. The stay includes, for example, a cylindrical rod-shaped body having a cross-sectional area of 3 mm ² to 700 mm ² .

In the hollow fiber module according to the present invention, the adhesion fixing part 9a integrally adhered in the state where the end surface of the hollow fiber membrane is opened is formed on the upper side where the plurality of hollow fiber membranes are bundled, and the water collection cap 10 The water collection unit formed by) is disposed in the open cross section of the hollow fiber membrane.

The adhesion fixing portion 9b provided on the lower side of the hollow fiber membrane bundle may have a structure that forms an adhesion fixing portion, in which a plurality of units of the small bundle are adhesively fixed while the cross section of the membrane is closed. By having the unit of soda bundles it is possible to further improve the performance of discharging suspended matter from the interior of the module. In the adhesion fixing part formed on the bottom side of the hollow fiber membrane bundle by the cow bundles, the adhesive fixed cow bundles are independent of each other in a non-adhesive manner, and there is a gap between the cow bundles. The number of small bundles formed on the bottom side of the hollow fiber membrane bundle is preferably 3 to 50 per one membrane module, and the number of hollow fiber membranes forming the small bundle is preferably 50 to 2000.

In the membrane filtration apparatus according to the present invention, the ratio of the cross-sectional area of the membrane module to the in-tank cross-sectional area of the immersion tank is from the upper end to the lower end of the membrane module 2 disposed in the immersion tank 1 as shown in FIG. 2. In the horizontal plane at the height, it is the ratio (percentage) of the cross-sectional area of the membrane module outer surface 2B to the cross-sectional area of the immersion tank inner surface 1A. The membrane occupied by the horizontal cross-sectional area of the immersion tank at a height from the upper end to the lower end of the membrane module 2 disposed in the immersion tank 1 is not constant and the cross-sectional area of the immersion tank 1 is not constant. If the proportion of the module cross-sectional area is varied, its maximum value may be a predetermined value in the range of 60% to 90%.

When defining the ratio of the cross-sectional area of the membrane module to the cross-sectional area of the tank in the immersion tank, the membrane module represents the portion from the adhesion fixing at one end to the adhesion fixing at the other end, and the air belonging to the water collection cap or its vicinity. It does not include an introduction cylinder. The cross-sectional area of the outer surface 2B of the membrane module from the upper end to the lower end of the membrane module 2 represents the area surrounded by the outer peripheral part in the case of the bonding fixing parts 9a and 9b, and the hollow fiber membrane between the fixing fixing parts is opened. In the case of a broken part, the circumscribed area including the entire hollow fiber membrane is shown. When the outer circumferential portion of the hollow fiber membrane bundle between the adhesion fixing portions is covered with a porous plate-like member such as a net, the cross-sectional area represents an area surrounded by the outer circumferential portion such as the net.

When a plurality of hollow fiber membrane modules are arranged in the immersion tank as shown in FIG. 4, the cross-sectional area is the sectional area of the inner surface 1A of the immersion tank as the denominator, and the cross-sectional area of the outer surface 2B of the membrane module as shown in FIG. 5. The ratio computed by making sum of as a molecule is shown.

In the present invention, an air diffusion pipe 3 for air scrubbing is disposed under the membrane module 2 to discharge suspended substances accumulated in the hollow fiber membrane module out of the membrane module system, but the structure or material is not limited. In the air diffusion pipe 3, an air diffusion hole 4 is formed to diffuse the pressurized air supplied from the blower (not shown) or to diffuse it into the raw water in the immersion tank 1, The diameter or number is not limiting.

In the present invention, the distance between the air diffusion pipe and the bottom of the immersion tank is the distance when the position of the air diffusion hole 4 formed in the air diffusion pipe 3 is expressed by the height from the bottom of the immersion tank. In the position of the bottom of the immersion tank, the actual lowest position of the bottom is the relative position when the bottom has the conical shape shown in the figure. When the height of the air diffusion holes 4 is changed according to each of the air diffusion holes, the distance represents the distance from the bottom of the immersion tank to the air diffusion hole at the lowest position.

Next, the membrane filtration operation using the membrane filtration apparatus including the immersed hollow fiber membrane module having the above-described configuration will be described, and the advantages of the present invention will also be described.

One or several hundred hollow fiber membrane modules 2 are arranged in the immersion tank 1 according to conditions such as water throughput or the area of the immersion tank. In this case, the raw water containing the suspended material is previously placed in the immersion tank 1. When the upper adhesion fixing part which is adhesively fixed while the cross section of the hollow fiber membrane is opened is pumped by the pump, the raw water containing the suspended substance is separated into the solid and liquid by the hollow fiber membrane 8 (filtered), The filtered water is sent to the water collection pipe through the water pipe 5 transmitted from the water collection cap 10. When raw water is absorbed and the filtered water is taken out of the immersion tank, the level of the immersion tank is lowered. Thus, raw water is supplied to the immersion tank intermittently or periodically as necessary.

In this case, in the present invention, the raw water supply port 6 is disposed in the membrane module, and the ratio of the cross-sectional area of the membrane module occupied in the tank cross-sectional area of the immersion tank is 60% to 90%. For this reason, a significant amount of suspended material in the raw water rides on the downward flow caused by the inflow of raw water, so that the gap between the membrane module 2 and the immersion tank 1 with some space or between the multiple membrane modules. Settles at the bottom of the immersion tank and passes through the gap. In the present invention, the distance from the air diffusion pipe 3 disposed under the membrane module 2 to the bottom of the immersion tank is 200 mm or more than 200 mm. Thus, suspended matter deposited below the air diffusion pipe accumulates at a position below the air diffusion pipe without rotating the membrane filtration surface, so that the concentration of suspended material around the hollow fiber membrane 8 can be lowered. Thus, clogging caused by suspended material can be prevented.

Some of the suspended material that has not precipitated reaches around the membrane surface of the hollow fiber membrane 8 and adheres to the surface of the membrane and inside the membrane pore. For this reason, when the filtration process is completed at a predetermined time, a cleaning operation (backwash cleaning) is performed to flow filtered water or pressurized air from the water collection cap 10 in the raw water direction to suspend the inside of the membrane pore. The air inlet cylinders 11 and the lower adhesive strips disposed below the membrane modules are removed from the air diffusion holes 4 of the air diffusion pipes 3 disposed under the hollow fiber membrane modules 2, and the material is peeled off and / or pressurized air. A washing operation (air scrubbing) supplied to the hollow fiber membrane 8 through the infiltration hole 12 of the government is performed to shake the hollow fiber membrane, peel off the suspended matter attached to the surface of the hollow fiber membrane, and suspend from the hollow fiber membrane. Drain the material.

6 shows the flow of water in the immersion tank when performing air scrubbing in the membrane filtration apparatus shown in FIG. 1. In the present invention, the space in the tank where the membrane module is not installed is secured in a predetermined range such that the ratio of the cross-sectional area of the membrane module 2 occupied by the tank cross-sectional area of the immersion tank 1 is 60% to 90%. . Thus, the membrane module can provide an important property of releasing suspended material stuck between the hollow fiber membranes, which is an advantage of the immersed membrane module, and immediately removes the suspended material peeled from the hollow fiber membrane by countercurrent cleaning and air scrubbing. Drain it out. The stripped suspended material floats in the immersion tank and passes through the gap between the membrane module 2 and the inner wall of the immersion tank 1 or between the plurality of membrane modules and settles at the bottom of the immersion tank. At this point, some of the suspended material is precipitated in the suspended material accumulation space below the air diffusion pipe, but other portions of the suspended material move back near the surface of the hollow fiber membrane along the flow of air.

In the present invention, the distance from the air diffusion pipe 3 disposed under the membrane module 2 to the bottom of the immersion tank is 200 mm or more than 200 mm. Thus, water in the area below the air diffusion pipe and in which suspended material accumulates and concentrates is not mixed even when air scrubbing. Thus, suspended material that has moved below the air diffusion pipe and is moved to an area which is hardly affected by air scrubbing does not float again and does not move near the hollow fiber membrane 8.

As described above, in the membrane filtration apparatus, suspended matter stuck between the hollow fiber membranes can be easily discharged out during air scrubbing and can precipitate at least a portion of the suspended matter below the air diffusion pipe. In addition, accumulated and concentrated suspended matter once settled near the bottom of the immersion tank 1 does not float again.

The membrane filtration process, countercurrent cleaning and air scrubbing are carried out repeatedly, and suspended matter accumulated and concentrated at the bottom of the immersion tank 1 is regularly discharged from the drain line 7. Thus, stable membrane filtration operations can be continued even with high-turbidity raw water.

However, in the immersed hollow fiber membrane module, a plurality of bundled hollow fiber membranes are arranged in the module, and the area of the membrane per unit volume is large. Thus, there is a problem that suspended components are easily filled between the membranes. Thus, even in the case of the membrane filtration apparatus, suspended suspended substances which do not settle at the bottom of the immersion tank remain near the membrane surface of the hollow fiber membrane 8, so that the concentration of the suspended substance in the vicinity of the hollow fiber membrane is increased for a long time of operation. Will be higher. As a result, it is difficult to perform stable work.

In order to solve this problem, it is necessary to carry out an operation that can reduce the concentration of suspended material in the vicinity of the hollow fiber membrane (8). For example, a slow drainage method in which most or all of the water in an immersion tank 1 having a high concentration of suspended matter is regularly discharged, and instead a relatively transparent raw water (raw water with a relatively small amount of suspended matter) is flown. Is performed. In the case of a conventional immersed hollow fiber membrane module, since the volume of the membrane module occupied by the volume of the immersion tank is small, the water recovery rate (operation recovery rate) of the filtration operation is greatly lowered when performing the slow drainage method. However, in the present invention, since the cross-sectional area of the membrane module 2 occupied by the horizontal cross-sectional area of the immersion tank 1 is from 60% to 90%, it is possible to maintain a high recovery rate even when performing the drainage method.

When performing the slow drainage method in the membrane filtration apparatus according to the present invention, the operation may be performed so that the water level of the immersion tank 1 is lowered to a position 200 mm or more lower than the air diffusion pipe 3. In the membrane filtration apparatus according to the present invention, suspended substances held at a position as low as 200 mm and lower than that of the air diffusion pipe are not suspended by performing air scrubbing. Thus, when performing drainage, it is not necessary to replace the water staying 200 mm lower than the air diffusion pipe. For this reason, the water in the immersion tank is discharged when performing regular drainage to lower the level of the immersion tank by 200 mm or more than the air diffusion pipe, thereby sufficiently increasing the concentration of the substance suspended in the vicinity of the hollow fiber membrane 8. Reducing, which fulfills the purpose of complete multiples.

In particular, in the case of an immersion tank having a large space in the vertical direction under the hollow fiber membrane, it is preferable to improve the operation recovery rate by not discharging most or all of the water in the immersion tank to reduce excessively discharged water, Lower to a position 200 mm to 400 mm lower than the air diffusion pipe. When the complete drainage is carried out by the above-described operating method, it is possible to maintain a high recovery rate even in a membrane filtration apparatus using an immersion tank having a large space in the vertical direction under the hollow fiber membrane module 2.

Immediately before carrying out the complete drainage, the water level in the immersion tank is adjusted to reduce the amount of water in the tank above the hollow fiber membrane module 2 as much as possible. The operation recovery rate can be kept higher. The air diffusion pipe 3 is disposed as close as possible to the lower end of the hollow fiber membrane module 2, and the operation recovery rate can be increased because the amount of drainage can be further reduced when performing the complete drainage.

As described above, according to the membrane filtration apparatus according to the present invention, it is possible to maintain the property of discharging the suspended material stuck between the membranes, which is an advantage of the immersed hollow fiber membrane module, and the whole or most of the water in the immersion tank Even when discharged regularly, a high recovery rate can be maintained. In addition, since a significant amount of suspended material contained in the raw water is precipitated at the bottom of the immersion tank without being filtered by the membrane, it is possible to perform a stable membrane filtration operation with a high recovery rate in relation to the relatively high-turbidity raw water.

In order to greatly improve the operation recovery rate and to maintain good characteristics of discharging suspended matter, it is preferable that the ratio of the cross-sectional area of the membrane module 2 occupied to the horizontal cross-sectional area of the immersion tank 1 is set to 70% to 80%. More preferably, in view of the installation space and manufacturing cost, it is more preferable that the distance between the bottoms of the air diffusion pipe 3 and the immersion tank is set to 200 mm to 700 mm.

In the case of increasing the sedimentation of suspended matter in raw water, such as when adding a flocculant to raw water, the amount of suspended matter suspended in the vicinity of the hollow fiber membrane is reduced. Therefore, stable operation can be performed at a high recovery rate by applying an operation method of regularly draining a part of the water in the immersion tank without performing the regular drainage. However, in this operation method, since the ratio of the cross-sectional area of the membrane module 2 occupied to the horizontal cross-sectional area of the immersion tank 1 is high, the property of discharging suspended matter is lowered. As the ratio is lowered, the installation area for the device is wider and the cost is increased. Therefore, even when the above operation method is performed, it is effective that the ratio of the cross-sectional area of the membrane module 2 occupied to the horizontal cross-sectional area of the immersion tank 1 is 60% to 90%, and the ratio is 70% to 80%. Is preferably set to. In addition, it is effective that the distance between the air diffusion pipe 3 and the bottom of the immersion tank is 200 mm or more, and considering the installation space and manufacturing cost, the distance is preferably set to 200 mm to 700 mm.

<Example 1>

The hollow fiber membrane bundle formed of 3500 hollow fiber membranes made of polyvinylidene fluoride having an outer diameter of 1.5 mm, an inner diameter of 0.9 mm and a length of about 1000 mm is bundled, and the cross section at the top of the hollow fiber membrane is open and the cross section at the bottom of the hollow fiber membrane is closed. In this state, the hollow fiber membrane module having a membrane area of 15 m ² is prepared by fixing with a urethane-based adhesive. As shown in FIG. 3, the membrane module has a penetration hole 12 in the lower adhesion fixing portion, an air inlet cylinder 11 is provided in the lower adhesion fixing portion, and a water collection cap 10 is provided in the upper adhesion fixing portion. Has the structure provided. A mesh-shaped porous plate made of polyethylene is attached between the top and bottom adhesive fasteners to surround the outer circumference of the hollow fiber membrane bundle (not shown).

One hollow fiber membrane module is disposed in the vertical direction in the immersion tank shown in FIG. At this time, the ratio of the cross-sectional area of the membrane module occupied to the horizontal cross-sectional area of the immersion tank was 75%, the distance between the air diffusion pipe and the bottom of the immersion tank was 300 mm, and the membrane filtration test was performed under the following conditions.

The filtration process was carried out for 30 minutes at a membrane filtration flow rate of 0.5 m / day using lake water having a turbidity of 2 to 50 as raw water, followed by 1.0 by membrane filtered water to which 10 mg / L of sodium hypochlorite was added. The countercurrent scrubbing process was performed for 30 seconds at a flow rate of m / day, and the air scrubbing process was performed for 60 seconds at an air flow rate of 100 L / min. At the time of filtration, the entire amount of water in the immersion tank was discharged once, the countercurrent washing and the air scrubbing were repeated 12 times, and the operation recovery rate was set to 98%.

The above operations were performed continuously for about 1 week, but no differential pressure was observed between the membranes during the test period, and stable membrane filtration operations could be continued.

Comparative Example

By using the hollow fiber membrane module used in Example 1, the hollow fiber membrane module and the like were installed in different sized immersion tanks so that the ratio of the cross sectional area occupied by the horizontal cross sectional area of the immersion tank was 95% and between the air diffusion pipe and the bottom of the immersion tank. The distance was 100 mm. In the working conditions, only the number of times the total amount of water in the immersion tank was discharged was changed, and the membrane filtration flow rate, the operating recovery rate, and the like were set under the same conditions. Under these conditions, the same membrane filtration test as in Example 1 was performed.

As a result, differential pressure between the membranes occurred at a rate of 1.0 kPa / day.

Comparative Example 2

By using the hollow fiber membrane module used in Example 1, the hollow fiber membrane module or the like was installed in an immersion tank having a different size, so that the ratio of the cross sectional area occupied by the horizontal cross sectional area of the immersion tank was 30%, and the bottom of the air diffusion pipe and the immersion tank. The distance between the livers was 500 mm. In the working conditions, only the number of times the total amount of water in the immersion tank was discharged was changed, and the membrane filtration flow rate, the operating recovery rate, and the like were set under the same conditions. Under these conditions, the same membrane filtration test as in Example 1 was performed.

As a result, differential pressure between the membranes occurred at a rate of 1.0 kPa / day.

The membrane filtration apparatus using the immersed hollow fiber membrane module can be applied to sewage treatment and industrial wastewater treatment as well as water treatment.

Claims (6)

The immersed hollow fiber membrane module formed by tying a plurality of hollow fiber membranes is in an immersion tank having a raw water supply port at the top and a drain port at the bottom, and the longitudinal direction of the hollow fiber membrane is in the vertical direction. A membrane filtration device arranged to coincide with an air diffusion pipe disposed below a hollow fiber membrane module, The raw water supply port is disposed above the hollow fiber membrane module, and the ratio of the cross-sectional area of the hollow fiber membrane to the in-tank cross-sectional area of the immersion tank is 60% to 90% in the horizontal plane where the hollow fiber membrane module is disposed, and the air diffusion pipe And a membrane filtration device in which the distance between the bottoms of the immersion tanks is 200 mm or more than 200 mm, and the drain port is located 200 mm below or more than 200 mm below the air diffusion pipe. The ratio of the cross-sectional area of the hollow fiber membrane to the cross-sectional area of the tank of the immersion tank is 70% to 80% in the horizontal plane on which the hollow fiber membrane module is disposed, and the distance between the bottom of the air diffusion pipe and the immersion tank is 200 mm to Membrane filtration device of 700 mm. The hollow fiber membrane module of claim 1, wherein the hollow fiber membrane module has a structure in which a plurality of hollow fiber membranes are bundled at least at the top and the bottom thereof, and the top side of the hollow fiber membrane bundle is bundled and fixed with the cross section of the hollow fiber membrane open. A collecting unit is disposed in the open end surface of the hollow fiber membrane, the lower end side of the hollow fiber membrane bundle is bundled by a plurality of small bundles in a state that the cross section of the hollow fiber membrane is closed. The membrane filtration apparatus of claim 1, wherein the drain port is disposed at the bottom of the immersion tank. Using the membrane filtration device according to any one of claims 1 to 4, which regularly lowers the water level in the immersion tank to a position 200 mm below the air diffusion pipe or to a position further above 200 mm. Operation method to filter raw water. A method of operating raw water by using a membrane filtration device according to any one of claims 1 to 4, wherein a part of water in an immersion tank is regularly discharged from a drain port.

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