JP5474482B2 - Membrane immersion tank and membrane treatment apparatus - Google Patents

Description

  The present invention relates to a membrane immersion tank and a membrane treatment apparatus that contain one or a plurality of immersion type membrane units for membrane filtration of raw water.

  Advanced water treatment equipment such as river water, lake water, groundwater, water storage, secondary sewage treatment water, factory effluent, sewage, high turbidity sewage membrane filtration equipment, and reverse osmosis membrane (RO) equipment used for seawater desalination In pre-treatment membrane filtration processing equipment and membrane separation activated sludge treatment (MBR) equipment, raw water that is subject to solid-liquid separation is stored in a tank, and the membrane unit is immersed in the stored raw water for solid-liquid separation. A film processing apparatus for achieving this is used. The membrane treatment apparatus includes, for example, an immersion type membrane unit (membrane separation apparatus) installed in a membrane immersion tank such as an aeration tank (see Patent Document 1). This type of membrane unit has a leg portion standing in the membrane immersion tank, and the leg portion is fixed to a bottom portion made of concrete with an anchor fitting or the like.

JP-A-8-257581

  However, the bottom of conventional membrane immersion baths is often flat in consideration of the stability when the membrane unit is installed, and there is no clear distinction between the location where the membrane unit is installed and the location where deposits are deposited. Therefore, the installation of the membrane unit is often left to the operator's intuition, installation at an appropriate place is not easy, and the burden associated with the installation work is not small.

  The present invention has been made in view of such a problem, and provides a film immersion tank and a film processing apparatus that facilitate the installation of an immersion type membrane unit at an appropriate position and improve workability. With the goal.

The present invention relates to a membrane soaking tank that houses one or a plurality of submerged membrane units for membrane filtration of raw water, and has a lower tank part that stores raw water and contains a plurality of membrane elements of the submerged membrane unit. And a unit support portion that is provided at the bottom of the lower tank portion and supports the immersion type membrane unit by contacting the immersion type membrane unit, and an opening provided below the unit support portion and avoiding the unit support portion A deposit discharging part communicating with the upper part of the lower tank part through the region , and the unit support part is a pedestal part that abuts the lower end of the immersion type membrane unit and supports the immersion type membrane unit And

In the present invention, the unit support part that supports the submerged membrane unit is clearly distinguished from the sediment discharge part, and when newly installed, it is appropriate to install the submerged membrane unit on the unit support part. It can be easily installed in various places. In addition, even when the immersion type membrane unit is pulled up from the membrane immersion tank for maintenance, etc., it is difficult to collect deposits on the unit support part. Inconveniences such as tilting are unlikely to occur, which is advantageous in improving workability.
Furthermore, since it installs so that the lower end of an immersion type membrane unit may be mounted on a base part, an immersion type membrane unit can be easily installed in a predetermined position.

Furthermore, the immersion type membrane unit includes an immersion part having a plurality of membrane elements, and a pipe part that is provided on the upper side of the immersion part, provided with a pipeline through which treated water that has passed through the membrane element passes. , the tank body has a lower tank portion to submerge the submerged portion to accommodate a submerged portion, and the upper tank part piping unit is disposed, and a raw water reservoir portion disposed adjacent to the upper tank portion, upper tank And a weir part that the raw water supplied to the raw water storage part passes over and flows into the upper tank part, and the volume of the raw water storage part is at least that of the lower tank part The volume is preferably smaller than the volume. The raw water is once stored in the raw water storage part, and when it reaches a predetermined water level, it passes over the weir part and flows into the upper tank part. By configuring the raw water so that it cannot flow into the upper tank unless it gets over the weir, the turbidity in the raw water is equalized at least within a certain range where the weir is provided. This makes it easier to improve the processing efficiency.

  Furthermore, it is preferable to provide a positioning member that holds the interval between the plurality of submerged membrane units installed side by side. The positioning member can securely hold the submerged membrane unit at a predetermined position.

  Further, the positioning member is a spacer extending in the vertical direction from the bottom of the tank body, and the upper end of the spacer is preferably disposed in the upper tank. Even in a state where the raw water is stored in the lower tank part, the spacer can be visually confirmed because the spacer protrudes into the upper tank part. Therefore, even if the submerged membrane unit is pulled up by maintenance or the like and then installed again, the submerged membrane unit can be easily installed at a predetermined position.

The present invention also provides:
In a membrane treatment apparatus comprising a membrane immersion tank and one or more immersion type membrane units installed in the membrane immersion tank and membrane-filtering raw water, the immersion type membrane unit includes a plurality of membrane elements and a plurality of membrane elements. A frame that supports the membrane element, an air diffuser provided below the membrane element, and a conduit that is provided above the plurality of membrane elements and through which treated water that has passed through the membrane element passes. And the membrane immersion tank is provided at the bottom of the lower tank section and the tank main body having a lower tank section for storing raw water and accommodating a plurality of membrane elements, and in contact with the immersion type membrane unit. a unit support portion for supporting a submerged membrane unit provided below the unit supporting portion, and the discharge portion of the sediment through the top and communicating in the lower tank portion through the opening region formed to avoid the unit supporting portion The provided, unit support unit is characterized in that a pedestal for supporting the contact with submerged membrane unit to the lower end of the immersion type membrane unit. According to the present invention, the unit support portion and the deposit discharge portion are clearly distinguished from each other, which is advantageous in improving workability when the immersion type membrane unit is installed on the unit support portion. In particular, since the submerged membrane unit is installed so that the lower end of the submerged membrane unit is placed on the pedestal, the submerged membrane unit can be easily installed at a predetermined position.

Furthermore, the ratio of the installation area of the membrane area and the frame in the immersion type membrane unit is suitable that is 400~2000m ² / ^{m 2.} According to this configuration, air diffusion can be efficiently performed by densely mounting the membrane module.

  According to the present invention, it is easy to install the immersion type membrane unit at an appropriate position, and it is easy to improve workability.

1 is a cross-sectional view of a film processing apparatus according to a first embodiment of the present invention. It is sectional drawing along the II-II line of FIG. It is sectional drawing along the III-III line of FIG. The 1st example of an immersion type membrane unit is shown, (a) is a side view, (b) is a top view. It is a perspective view which shows typically the state which installed the immersion membrane unit in the membrane immersion tank. It is sectional drawing of the film | membrane immersion tank which concerns on 2nd Embodiment of this invention. It is sectional drawing along the VI-VI line of FIG. It is a perspective view of the receiving part of the tank main body of a film | membrane immersion tank. It is sectional drawing of the film processing apparatus which concerns on 3rd Embodiment of this invention. The 2nd example of an immersion type membrane unit is shown, (a) is a side view, (b) is a top view.

  Hereinafter, preferred embodiments of a film processing apparatus according to the present invention will be described with reference to the drawings. In the present embodiment, a membrane treatment apparatus 1A used for membrane separation activated sludge treatment (MBR) will be described as an example.

  As shown in FIGS. 1 to 3, the membrane treatment apparatus 1 </ b> A includes a membrane immersion tank 3 </ b> A for storing raw water containing activated sludge, and an immersion type membrane unit 5 installed in the membrane immersion tank 3 </ b> A. Yes. The membrane immersing tank 3A is designed so that a single membrane unit 5 or a plurality of membrane units 5 can be accommodated in an arbitrary number of pitches (according to the amount of treated water) in a cassette shape, but in this embodiment, The case where five membrane units 5 are installed is illustrated.

  As shown in FIG. 4, the membrane unit 5 includes a water collection header (pipe) 7 and a plurality of membrane modules 9 connected to the water collection header 7. The water collection header 7 includes a pair of main header pipes 7a arranged in two rows, and a merge pipe 7b that communicates with the pair of main header pipes 7a and merges treated water in the main header pipe 7a. I have. The pair of main header pipes 7a are integrally fixed by a reinforcing member 7c such as a rib. The junction pipe 7b is provided at a position near the end of the main header pipe 7a, and is flange-connected to the treated water discharge pipe 11. A suction pump (not shown) is connected to the treated water discharge pipe 11, and treated water that has passed through the membrane module 9 by driving the suction pump is collected in the water collection header 7 and discharged through the treated water discharge pipe 11. The

  A plurality of branch pipes 13 are arranged in a line along the longitudinal direction of the main header pipe 7a, and a vertically long membrane module 9 is connected to each branch pipe 13. The connecting portion between the branch pipe 13 and the membrane module 9 is allowed to move the membrane module 9 along the axial direction of the branch pipe 13 during assembly work, and to allow a slight inclination of the membrane module 9 relative to the axis. An adjustment joint 15 that can be adjusted is arranged.

  The membrane module 9 includes a plurality of hollow fiber membranes 9a, a lower binding portion (not shown) for binding the plurality of hollow fiber membranes 9a on one end (lower end) side, and a skirt portion attached to the lower binding portion (Cylindrical member) 9b, an upper binding portion (not shown) that binds the plurality of hollow fiber membranes 9a on the other end (upper end) side, and a cap portion 9c that is attached to the upper binding portion. It is equipped with. The cap portion 9 c is connected to the water collection header 7 via the adjustment joint 15 and the branch pipe 13.

  The hollow fiber membrane 9a is, for example, a tube-shaped microfiltration membrane obtained by hydrophilizing a filtration membrane made of a hydrophobic material, and a flow path through which treated water that permeates the peripheral wall is formed. The lower end of the hollow fiber membrane 9a is closed and the upper end is opened. The treated water that has permeated through the peripheral wall of the hollow fiber membrane 9a and flowed into the interior is collected in the water collection header 7 from the opening at the upper end through the inside of the cap portion 9c and the branch pipe 13. Hereinafter, a bundle of a plurality of hollow fiber membranes 9 a gathered together by the upper binding portion and the lower binding portion is referred to as a membrane element 17.

The ratio of the installation area of the membrane area and membrane unit 5 membrane unit 5 in this embodiment is preferably from 400~2000m ² / ^{m 2,} more preferably 500~1500m ² / ^{m 2.}
Here, “the membrane area of the membrane unit” means a plurality of membrane modules 9 housed in the membrane unit 5 disposed in the membrane immersion tank 3A, and a plurality of membrane modules 9 combined by the upper and lower binding portions of the membrane module 9. The total outer surface area of the peripheral wall of the membrane element 17 of the bundle of hollow fiber membranes 9a.

  In addition, “the installation area of the membrane unit” means that the membrane module 9 is perpendicular to the ground surface in a rectangular (rectangular) frame 21 constituting the membrane unit 5 in which a plurality of membrane modules 9 are accommodated. The product of the width and depth of the frame 21 when the membrane unit 5 is turned upside down.

The raw water supplied to the membrane immersion tank 3A is stirred or flowed into the raw water in the tank 3A by giving aeration air periodically or continuously from the lower part of the membrane unit 5 installed in the membrane immersion tank 3A. Flow) and the density distribution of the turbid components of the raw water in the membrane immersion tank 3A can be homogenized.
This stirring flow can improve the strength of the stirring flow by the diffused air by densely mounting the membrane module 9 in the membrane unit 5.

One or more membrane units 5 can be installed in the membrane immersion tank 3A.
By providing a wall at a position separated by 50 mm or more from the outer surface of the last membrane unit 5 in which the membrane units 5 are sequentially arranged, the upward flow generated by the diffused air from the lower part of the membrane unit 5 is swirled so as to face downward A flow (swirl downflow) can be obtained.
In addition, the above-mentioned wall for rectifying downward flow (swirling downward flow) has no opening to control the flow velocity, and punching plate (perforated plate) as a baffle plate of various shapes with different opening areas Etc. may be installed.

  The baffle plate may be a flat plate, a lattice assembly plate, or the like, and can be arranged in the vertical (vertical) direction of the film immersion tank.

  The skirt portion 9 b of the membrane module 9 is held by the under support 19. The under support 19 is a rectangular box-shaped resin member, and an insertion hole for receiving the skirt portion 9b and supporting the membrane module 9 is formed on the upper surface side. In the under support 19, a plurality of insertion holes are formed to support the plurality of membrane modules 9. In this embodiment, four holes are provided to support the four membrane modules 9 arranged adjacent to each other. The insertion hole is formed.

  The water collection header 7 and the plurality of membrane modules 9 are supported by a rectangular (rectangular) frame 21. The frame 21 includes a rectangular lower support 21a, four column members 21b erected at each corner of the lower support 21a, and a rectangular upper support 21c supported by the four column members 21b. I have.

  The lower support 21a is a rectangular structure and is held so as to surround a plurality of under supports 19 arranged in a horizontal row. The plurality of under supports 19 in a state of being held by the lower support 21a are formed with a main air flow path communicating with each other inside and a plurality of air diffusion flow paths branched from the main air flow path. The main air channel is a channel through which air for air cleaning (air scrubbing) and supply to activated sludge passes. Further, the air diffusion channel communicates with each of the skirt portions 9b of the plurality of membrane modules 9, and the air that has passed through the main air channel is diffused from a predetermined air diffusion port through the air diffusion channel, The inside of the skirt part 9b rises. The under support 19 corresponds to an air diffuser.

  The column member 21b erected on the lower support 21a is tubular, and the internal cavity communicates with the main air flow path of the under support 19. The inside of the column member 21b is an air flow path, and the air that has passed through the column member 21b is supplied to the main air flow path.

  The upper support 21c supported by the four column members 21b forms a rectangular annular body, supports both ends of the water collection header 7 and supports the water collection header 7 from the side. A cavity that communicates with the interior of the column member 21b is formed inside the upper support 21c, and an air introduction pipe 21d that communicates with the interior cavity is provided in the upper support 21c. The air introduction pipe 21d is flange-connected to the pneumatic feed pipe 23.

  When the membrane element 17 is subjected to air cleaning (air scrubbing), the air passing through the pneumatic feeding pipe 23 is supplied to the main air flow path of the under support 19 through the upper support 21c and the column member 21b. Air is diffused into the raw water through the aeration channel. Bubbles generated by the air diffusion pass through the skirt portion 9b, ascend in the raw water, vibrate the membrane element 17, and remove the sludge adhered to the surface of the membrane element 17 by the scrubbing action. In addition, oxygen is supplied to the activated sludge by aeration into the raw water.

  In addition, when the membrane element 17 is cleaned with a chemical solution, the chemical solution is supplied to the water collection header 7 through the treated water discharge pipe 11 from a chemical solution tank (not shown) installed outside the membrane immersion tank 3A. Further, the chemical solution is supplied to the membrane module 9 through each branch pipe 13 to wash the membrane element 17. The chemical solution is, for example, a hypochlorous acid aqueous solution, an oxalic acid aqueous solution, a citric acid aqueous solution, or a caustic soda aqueous solution.

  As shown in FIGS. 1 to 3 and 5, the membrane unit 5 is installed in the membrane immersion tank 3 </ b> A. In the state of being installed in the membrane immersion tank 3A, the portion below the water collection header 7, specifically, the portion to which the plurality of membrane modules 9 are attached constitutes the immersion portion 25, and the immersion portion 25 The portion disposed on the upper side, specifically, the portion provided with the water collection header (pipe) 7 where the treated water that has passed through the membrane element 17 is collected constitutes a piping portion 27. A plurality of the membrane units 5 are arranged in the membrane immersion tank 3A at equal intervals, and the number of the membrane units 5 is appropriately determined according to the amount of treated water.

  3 A of film | membrane immersion tanks are equipped with the tank main body 31 and the leg part 33 which makes the tank main body 31 stand upright. The tank body 31 is divided into a lower tank part 35 that houses and immerses the immersion part 25 of the membrane unit 5, and an upper tank part 37 in which the piping part 27 of the membrane unit 5 is arranged. This is wider than the lower tank part 35. Specifically, the area of the cross section of the upper tank part 37 is about 1.5 times as large as the area of the cross section of the lower tank part 35.

  The lower tank portion 35 includes an outer wall 35 a that surrounds the plurality of membrane units 5 in a rectangular shape from four sides in a state of being close to the plurality of membrane units 5. A pedestal 35b that supports the membrane unit 5 by being in contact with the lower support 21a of the membrane unit 5 is provided at the bottom of the lower tank portion 35 that is a lower portion of the outer wall 35a. The lower support 21 a corresponds to the lower end of the membrane unit 5.

  The pedestal portion 35b is a rectangular annular plate along the outer wall 35a, and a plurality of spacers 35c extending in the vertical direction are provided on the pedestal portion 35b. The spacer 35 c is a vertically long plate disposed between adjacent membrane units 5, and the upper end 35 k is disposed in the upper tank portion 37. The pedestal portion 35b corresponds to a unit support portion.

  The spacer 35c plays a role of holding the membrane unit 5 at a predetermined position so that adjacent membrane units 5 do not interfere with each other. As a result, each membrane unit 5 has a predetermined position where the merging pipe 7b of the water collecting header 5 can be connected to the treated water discharge pipe 11, that is, the center lines of the merging pipe 7b and the treated water discharge pipe 11 coincide. Positioned securely in position.

  Furthermore, the spacer 35c also serves as a guide rail (guide portion) for guiding the membrane unit 5 to a predetermined position when the membrane unit 5 is installed in the membrane immersion tank 3A. In particular, since the upper end 35k of the spacer 35c is arranged in the upper tank part 37, even if the lower tank part 35 is filled with turbid raw water, the upper end 35k of the spacer 35c will protrude from the raw water, In this case, it is easily visible and it is easy to aim at a predetermined position.

  At the bottom of the lower tank portion 35, a discharge portion 35d for collecting and discharging the deposit F such as sludge is provided so as to avoid the pedestal portion 35b. The discharge part 35d is provided so as to avoid the pedestal part 35b. Specifically, since the pedestal portion 35b has a rectangular annular shape (ring shape), a region closer to the center surrounded by the pedestal portion 35b becomes a rectangular opening region A formed so as to avoid the pedestal portion 35b. The discharge part 35d is provided below the pedestal part 35b so as to communicate with the upper part of the lower tank part 35 via the opening region A.

  The discharge unit 35d includes an accumulation chamber (accumulation unit) 35e that collects sediment F such as sludge that settles in the lower part, and a drain pipe 35f that communicates with the lower part (near the lowermost end) of the accumulation chamber 35e. The accumulation chamber 35e has four side walls forming a quadrangular pyramid whose lower end is the apex. Of the four side walls, one is a vertical wall 35g perpendicular to the horizontal plane, and the remaining three are inclined walls 35h having a predetermined gradient with respect to the horizontal plane. An opening communicating with the drain pipe 35f is formed at the lower end of the vertical wall 35g. A straight valley portion 35j is formed at a connection point (intersection line) between the vertical wall 35g and the inclined wall 35h and a connection part (intersection line) between the inclined walls 35h. The inclined wall 35h is inclined so as to be lower on the side closer to the drain pipe 35f and higher on the far side, and the lowermost part of the inclined wall 35h communicates with the drain pipe 35f. As a result, the inclined wall 35h guides the deposit F to the drain pipe 35f side, facilitates smooth discharge from the drain pipe 35f, and facilitates complete discharge of the deposit F.

  The drain pipe 35f is fixed to the vertical wall 35g, and the pipe axis L1 of the drain pipe 35f extends in a direction (lateral direction) intersecting the vertical direction (vertical direction), for example, an orthogonal direction (horizontal direction). To do. The drain pipe 35f is connected to a sludge discharge pipe 36, and the sludge discharge pipe 36 is connected to a sludge pump (not shown). Deposits F such as concentrated sludge accumulated in the accumulation chamber 35e are periodically drawn out by the sludge pump. Moreover, water level control can also be performed by extracting the deposit F and raw | natural water with a sludge pump.

  Further, since the drain pipe 35f is disposed laterally from the accumulation chamber 35e, the drain pipe 35f is disposed below the accumulation chamber 35e as compared with the case where the drain pipe 35f is disposed downward from the lower end of the accumulation chamber 35e. The space for arrangement | positioning becomes unnecessary, As a result, it becomes possible to hold down the volume of 3 A of film | membrane immersion tanks low. Moreover, it becomes easy to enlarge a pipe diameter by arrange | positioning the drain pipe 35f sideways, and it is effective in discharge | emission promotion of the deposit F.

  As shown in FIGS. 1 and 2, the upper tank portion 37 provided on the upper side of the film immersion tank 3 </ b> A is wider than the lower tank portion 35 over the entire circumference of the lower tank portion 35. The upper surface of the upper tank part 37 is covered with a detachable lid part (cover part) 37a, and the treated water discharge pipe 11 and the pneumatic feed pipe 23 penetrate the lid part 37a. By providing the lid part 37a in the upper tank part 37, it is possible to prevent leakage of the chemical solution during chemical washing of the membrane element 17 and to prevent corrosion of external equipment. The lid 37a is made of a material that is resistant to chemicals. For example, a Teflon (registered trademark) resin or chloroprene rubber that is resistant to chemicals is applied to the wetted part of the nylon-based fabric. The coated one is processed into a lid shape, or the inner surface obtained by processing a metal plate on the lid is coated with Teflon (registered trademark) resin or chloroprene rubber. It is preferable to apply a Teflon (registered trademark) resin or the like to the wetted part of the stainless steel plate because of its high mechanical strength. Note that when the membrane element 17 is cleaned by introducing a chemical solution, the lower tank portion 35 becomes a cleaning tank.

  An overflow pipe 37 b is provided on the side wall of the upper tank portion 37. Since filtration stops during backwashing, backwashing water discharged from the membrane element 17 is stored in the upper tank portion 37. That is, at the time of backwashing, the upper tank part 37 becomes a reservoir part of backwashing water, and backwashing water is discharged from the overflow pipe 37b when the water level exceeds a certain level. It should be noted that water is not passed through the overflow pipe 37b except when the membrane treatment apparatus 1A is malfunctioning.

  In the film immersion tank 3A and the film processing apparatus 1A according to the present embodiment, the pedestal part 35b where the film unit 5 is installed and the discharge part 35d of the deposit F are clearly distinguished. By installing the unit 5 aiming at the pedestal portion 35b, it is possible to easily perform installation at an appropriate place.

  In particular, the membrane element 17 according to the present embodiment is a filtration membrane obtained by hydrophilizing a filtration membrane made of a hydrophobic material. When this type of membrane element 17 is used, it is necessary not to dry the membrane element 17. Yes, it is necessary to install the membrane unit 5 in the membrane immersion tank 3A as quickly as possible, and to inject raw water into the membrane immersion tank 3A in as short a time as possible. Here, in the membrane immersion tank 3A and the membrane treatment apparatus 1A, the membrane unit 5 can be easily installed, which is advantageous for speeding up the operation.

  In addition, for example, when the membrane unit is anchored to the bottom made of concrete, sufficient time for water-resistant curing of the concrete is required, and it is difficult to speed up the enforcement work. However, in the present embodiment, the installation of the membrane unit 5 is completed by placing the membrane unit 5 on the pedestal portion 35b, and the membrane unit 5 is held at a predetermined position by the spacer 35c. It is also advantageous for speeding up.

  In general, the membrane unit is generally provided with a leg portion, and the membrane module is arranged to avoid the entrainment of concentrated sludge accumulated at the bottom of the tank. In the case of this type of membrane unit, the height of the membrane unit is increased by the length of the leg portion. Therefore, in the conventional membrane immersion tank (see Patent Document 1), the depth is increased by the length of the leg portion. There is a need. Then, the height of the head for installing the membrane unit also increases, and as a result, workability for attaching and detaching the membrane unit is impaired.

  On the other hand, in the film immersion tank 3A according to the present embodiment, the discharge portion 35d for the deposit F is provided below the pedestal portion 35b, avoiding the pedestal portion 35b that supports the film unit 5, and the inside of the discharge portion 35d. As a result, the sediment F is concentrated. Therefore, even if the membrane unit 5 has no leg portion, it is possible to avoid the deposit F from being caught in the membrane element 17. Therefore, the depth of the membrane immersion tank 3A can be a depth corresponding to the membrane unit 5 having no leg portions and can be relatively shallow, and the height of the head for installing the membrane unit 5 is high. This is also effective for improving workability for attaching and detaching the membrane unit 5.

  Further, for example, in a configuration in which a recess (opening) is provided at the bottom of the membrane immersion tank and a beam for fixing and supporting the membrane unit is installed in the recess, a space for installing the beam in the membrane immersion tank Is required, and the film immersion tank itself tends to be large. Furthermore, if there are projections such as beams, the filtration membrane may be caught and damaged when the membrane unit is installed. On the other hand, according to the present embodiment, no beam or the like is provided, which is effective for downsizing and can be installed while guiding the membrane unit 5 to an appropriate position by the spacer 35c, thereby reducing damage to the membrane unit 5. it can.

  Further, when the membrane unit 5 according to this embodiment is pulled up from the membrane immersion tank 3A for maintenance or the like, it is necessary to replace it after the membrane module 9 is replaced. Here, in the conventional film immersion tank (see Patent Document 1), the part where the film unit is installed and the part where the deposit is deposited are not necessarily clearly distinguished, and therefore the deposit accumulates at the bottom. Therefore, when the membrane unit is re-installed, the deposit may be stepped on and tilted obliquely, which may reduce workability. However, in the film immersion tank 3A according to the present embodiment, since the pedestal portion 35b and the discharge portion 35d are clearly distinguished from each other, the deposit F hardly accumulates in the pedestal portion 35b. In this case, problems such as tilting of the membrane unit 5 are unlikely to occur, which is advantageous in improving workability.

  Moreover, in the conventional film | membrane immersion tank, generally an internal diameter is constant ranging from the bottom to the upper part. Here, since filtration stops when the membrane element is backwashed, it is necessary to secure a capacity for holding the amount of backwash water discharged from the membrane element, and the membrane immersion tank tends to become deep. On the other hand, in the film immersion tank 3A according to this embodiment, the tank body 31 is divided into a lower tank part 35 and an upper tank part 37, and the width of the upper tank part 37 is wider than the lower tank part 35. At the time of backwashing, the upper tank part 37 becomes a reservoir part of backwashing water, and the backwashing water does not easily overflow. Therefore, when determining the volume of the lower tank part 35, it is less necessary to consider the overflow of backwash water, and as a result, the lower tank part 35 can be actively downsized until it approaches the immersion part 35. . If the lower tank part 35 is reduced in size, the amount of chemical solution required for chemical cleaning of the membrane element 17 is reduced, and as a result, chemical cleaning efficiency can be improved.

  Furthermore, by expanding the upper tank part 37 beyond the width of the lower tank part 35, it is possible to suppress the foaming of the liquid surface as a result of air cleaning (air scrubbing) during backwashing, and as a result, the raw water overflows outside the tank. It becomes easy to connect to.

  Moreover, since the film | membrane immersion tank 3A which concerns on this embodiment is equipped with the spacer 35c (positioning member) which hold | maintains the space | interval of the several film units 5 installed side by side, the several film | membrane unit 5 is made into a predetermined position. Positioning and holding can be performed reliably.

  Further, the spacer 35 c extends beyond the lower tank part 35 to the upper tank part 37, and the upper end 35 k of the spacer 35 c is disposed in the upper tank part 37. Therefore, even when the raw water is filled in the lower tank portion 35, the upper end 35k of the spacer 35c can be visually confirmed. As a result, even when the membrane unit 5 is pulled up and reinstalled due to maintenance or the like, the membrane unit 5 can be easily installed at a predetermined position while viewing the upper end 35k of the spacer 35c.

Furthermore, the discharge part 35d of the deposit F includes a drain pipe 35f and an accumulation chamber 35e that guides the deposit F toward the drain pipe 35f, and the accumulation chamber 35e is inclined with a gradient with respect to the horizontal plane. A wall 35h is provided, and a lower portion of the inclined wall 35h communicates with a drain pipe 35f. Accordingly, the deposit F is guided toward the drain pipe 35f along the inclined wall 35h of the accumulation chamber 35e, and is smoothly discharged from the drain pipe 35f.
(Second Embodiment)

  Next, a film immersion tank and a film processing apparatus according to the second embodiment will be described with reference to FIGS. The film immersion tank 3B and the film processing apparatus 1B according to the second embodiment include elements, members, and the like equivalent to the film immersion tank 3A and the film processing apparatus 1A according to the first embodiment. Elements, members, and the like that are equivalent to those in FIG.

  6 is a cross-sectional view of the film immersion tank 3B according to the present embodiment, and FIG. 7 is a cross-sectional view taken along the line VII-VII in FIG. FIG. 8 is an enlarged perspective view showing the receiving part of the tank body.

  The membrane immersion tank 3 </ b> B includes a vertically long tank body 41 that stores raw water containing activated sludge, and four leg portions 43 that erect the tank body 41. Two (plural) membrane units 5 are accommodated in the tank body 41 side by side. The membrane unit 5 has the same configuration as that of the membrane unit 5 according to the first embodiment, and includes a rectangular (rectangular) frame 21, a water collection header 7 supported by the frame 21, a membrane module 9, and Under support 19 is provided.

  The tank body 41 is divided into three parts, that is, a receiving part 45, a body part 47, and a bottom part 49 in order from the upper side, and a leg part 43 is fixed to the bottom part 49 arranged on the lowermost side. The body portion 47 disposed in the center has a cylindrical shape with a rectangular cross section, and has a volume corresponding to the number of membrane units 5 to be accommodated. The body portion 47 is flange-bonded to the receiving portion 45 and the bottom portion 49 in a liquid-tight manner.

  The bottom 49 includes a rectangular cylindrical peripheral wall 49a whose inner surface is connected flush with the body 47, a pedestal 49b formed at a lower portion of the peripheral wall 49a, and a peripheral wall 49a avoiding the pedestal 49b. And a discharge portion 49c for the deposit F provided below.

  The pedestal portion 49b is a rectangular annular plate fixed to the inner surface of the peripheral wall portion 49a, and two membrane units 5 are installed side by side on the pedestal portion 49b. In addition, a plurality of spacers 49j are provided on the pedestal portion 49b so as to hold the adjacent membrane units 5 at predetermined positions. The spacer 49j is a vertically long plate extending in the vertical direction between the membrane units 5 and plays a role of holding the adjacent membrane units 5 so as not to interfere with each other. Also plays a role as a guide rail (guide part). The upper end 49k of the spacer 49j is disposed in a header accommodating portion 53 described later.

  Since the pedestal portion 49b has a rectangular ring shape (ring shape), a region closer to the center surrounded by the pedestal portion 49b becomes a rectangular opening region A formed so as to avoid the pedestal portion 49b. The discharge part 49 c communicates with the inside of the peripheral wall part 49 a through the opening region A.

  The discharge part 49c includes an accumulation chamber (accumulation part) 49d that collects sediment F such as sludge that settles in the lower part, and a drain pipe 49e that communicates with the lower part of the accumulation room 49d. The accumulation chamber 49d has four side walls that form a quadrangular pyramid whose lower end is the apex. Of the four side walls, one is a vertical wall 49f and the remaining three are inclined walls 49g. An opening communicating with the drain pipe 49e is formed in the vicinity of the lower end of the middle inclined wall 49g sandwiched between the left and right inclined walls 49g. A straight valley portion 49h is formed at a connection point (intersection line) between the vertical wall 49f and the inclined wall 49g and a connection part (intersection line) between the inclined walls 49g. The inclined wall 49g is inclined so as to be lower on the side closer to the drain pipe 49e and higher on the far side, and the lowermost part of the inclined wall 49g communicates with the drain pipe 49e to guide the deposit F to the drain pipe 49e side. Then, smooth discharge of the deposit F from the drain pipe 49e is promoted. The tube axis L2 of the drain tube 49e according to the present embodiment extends along the vertical direction.

  As shown in FIG. 8, the receiving part 45 of the tank body 41 includes a communication part 51 communicating with the body part 47, a header accommodation part 53 provided above the communication part 51, and a header accommodation part 53. A provided raw water introduction section 55 is provided. The connecting part 51 is a rectangular cylindrical body whose inner surface is flush with the rectangular body part 47. The lower part of the communication part 51 is flange-bonded to the body part 47 in a liquid-tight manner.

  The header accommodating portion 53 is provided above the connecting portion 51, and is wider than the connecting portion 51 over the entire circumference of the connecting portion 51. The header accommodating portion 53 has four wall portions 53a and 53b that surround the four sides in a rectangular shape, and an overhang portion 53c that is connected to the connecting portion 51 to form a step. A pair of partition walls 53 d erected along the peripheral wall of the connecting portion 51 are provided inside the header accommodating portion 53.

  The raw water introducing portion 55 is provided above the header accommodating portion 53, and has four wall portions 55a and 55b disposed so as to surround the four sides in a rectangular shape, and an overhang portion 55c that is connected to the header accommodating portion 53 to form a step. And having. The short side wall 55a of the raw water introduction part 55 and the short side wall 53a of the header accommodating part 53 are flush with each other to form a T-shaped flat wall. The T-shaped flat wall is provided with an overflow pipe 54 that overflows when the backwash water accumulated in the header accommodating portion 53 reaches a predetermined water level.

  The width D1 along the long side of the raw water introduction portion 55 and the width D1 along the long side of the header accommodating portion 53 are the same. On the other hand, the width D3 along the short side of the raw water introduction part 55 is wider than the width D2 along the short side of the header accommodation part 53, and the raw water introduction part 55 has a header accommodation part on the long side. A raw water reservoir 57 is formed so as to project outward from 53. A pair of dam portions 59 erected along the long side wall portion 53 b of the header accommodating portion 53 are provided inside the raw water introduction portion 55.

  In the raw water introduction portion 55, a pair of dam portions 59 partitions a raw water fall space S 1 communicating with the header accommodating portion 53 and a raw water storage space S 2 in the raw water storage portion 57. A supply port 57 a through which raw water is supplied is formed in the wall portion forming the raw water storage portion 57. The raw water is supplied into the raw water storage part 57 via the supply port 57a, and the raw water is temporarily stored in the raw water storage space S2, and when it reaches a predetermined water level, it passes over the weir part 59 (overflow), and the raw water fall space S1. Flows into and falls.

  As described above, the tank body 41 includes the receiving portion 45, the body portion 47, and the bottom portion 49, and the receiving portion 45 further includes the raw water introduction portion 55, the header accommodating portion 53, and the communication portion 51. The connecting portion 51, the body portion 47, and the bottom portion 49 form a rectangular tubular body having the same cross-sectional area (cross-sectional outer shape) to form the lower tank portion 56. Moreover, the header accommodating part 53 of the receiving part 45 is wider than the lower tank part 56, and the piping part 27 is arrange | positioned and it is equivalent to an upper tank part. Furthermore, in this embodiment, the raw water storage part 57 is configured by a part of the raw water introduction part 55, and as a result, the raw water storage part 57 is embodied adjacent to the header housing part (upper tank part) 53. Furthermore, a dam portion 59 is provided between the raw water storage portion 57 and the header accommodating portion (upper tank portion) 53.

  As described above, the film immersion tank 3B and the film processing apparatus 1B according to the present embodiment can enjoy the same benefits as those of the first embodiment, and are advantageous in improving workability when the film unit 5 is installed or reinstalled. It is.

Furthermore, the tank body 41 according to the present embodiment is disposed between the raw water storage part 57 provided adjacent to the header storage part (upper tank part) 53, and between the header storage part 53 and the raw water storage part 57. In addition, a weir 59 in which the raw water supplied to the raw water storage part 57 gets over and flows into the header accommodating part 53 is provided. The raw water is once stored in the raw water storage part 57, and when it reaches a predetermined water level, it passes over the weir part 59 and flows into the header accommodating part 53. Since the raw water cannot flow into the header accommodating portion 53 unless it passes over the dam portion 59, the turbidity in the raw water is equalized at least within a certain range where the dam portion 59 is provided, and the raw water in the tank body 41 Turbidity is equalized and it becomes easy to improve the processing efficiency.
(Third embodiment)

  Next, a film immersion tank and a film processing apparatus according to the third embodiment will be described with reference to FIGS. 9 and 10. The film immersion tank 3C and the film processing apparatus 1C according to the third embodiment include elements, members, and the like equivalent to the film immersion tank 3A and the film processing apparatus 1A according to the first embodiment. Elements, members, and the like that are equivalent to those in FIG.

  FIG. 9 is a cross-sectional view of a film processing apparatus 1C according to the present embodiment, FIG. 10 shows a second example of the immersion type membrane unit, (a) is a side view, and (b) is a plan view.

  As shown in FIG. 10, the membrane unit 60 includes a water collection header (pipe) 7 and a plurality of membrane modules 9 connected to the water collection header 7. The water collection header 7 and the plurality of membrane modules 9 are supported by a rectangular (rectangular) frame 21. The frame 21 includes a rectangular lower support 21a, four column members 21b erected at each corner of the lower support 21a, and a rectangular upper support 21c supported by the four column members 21b. I have.

  On the upper part of the membrane unit 60, a pair of left and right hanging parts 21f are provided. The hanging part 21f is a stainless steel plate provided so as to protrude from the upper end of the column member 21b to the outside in the longitudinal direction of the upper support 21c. A stepped portion 21g that engages with is formed. The membrane unit 60 has substantially the same configuration as the membrane unit 5 described above except for the hanging portion 21f.

  As shown in FIG. 9, the membrane unit 60 is installed in the membrane immersion tank 3C. In the state of being installed in the membrane immersion tank 3C, the portion below the water collection header 7, specifically, the portion to which the plurality of membrane modules 9 are attached constitutes the immersion portion 25, and the immersion portion 25 The portion disposed on the upper side, specifically, the portion provided with the water collection header (pipe) 7 where the treated water that has passed through the membrane element 17 is collected constitutes a piping portion 27.

  3 C of film | membrane immersion tanks are provided with the tank main body 61 and the leg part 63 which makes the tank main body 31 stand upright. The tank body 61 is divided into a lower tank part 35 that houses and immerses the immersion part 25 of the membrane unit 60, and an upper tank part 37 in which the piping part 27 of the membrane unit 5 is disposed.

  The upper tank part 37 is wider than the lower tank part 35, and a step is formed between the peripheral wall of the lower tank part 35 and the peripheral wall of the upper tank part 37. The upper tank portion 37 is provided with an annular floor portion 37c along a step, and a support receiving portion 65 is fixed on the floor portion 37c. The support receiving portion 65 is a plate body, contacts the lower surface of the hanging portion 21f provided so as to protrude from the upper portion of the membrane unit 60, and supports the membrane unit 60 so as to engage with the step portion 21g. In the present embodiment, the support receiving portion 65 corresponds to a unit support portion, and no pedestal portion that abuts and supports the lower end of the membrane unit 60 is provided.

  As described above, the film immersion tank 3C and the film processing apparatus 1C according to the present embodiment can enjoy the same benefits as those of the first embodiment, and are advantageous in improving workability when the film unit 5 is installed or reinstalled. It is.

  In particular, the membrane unit 60 can be easily installed at a predetermined position by installing the suspending portion 21f provided on the upper portion of the membrane unit 60 so as to be locked to the support receiving portion 65.

  As mentioned above, although this invention was demonstrated based on each embodiment, this invention is not limited only to said embodiment. For example, the above-described membrane treatment apparatus and membrane immersion tank have been described by way of example for membrane filtration using high turbidity sewage as raw water. However, solid-liquid separation of raw water is performed using an immersion type membrane unit. In this case, the deposit is not limited to sludge, but widely includes other solids that settle and deposit in the film immersion tank. Further, the membrane element is not limited to a filtration membrane obtained by hydrophilizing a filtration membrane made of a hydrophobic material, and may be an immersion type filtration membrane made of another material or another form. The number of membrane units installed in the membrane immersion tank is not limited to a plurality of cases, and a mode in which a single membrane unit is installed may be used.

  DESCRIPTION OF SYMBOLS 1A, 1B, 1C ... Membrane processing apparatus, 3A, 3B, 3C ... Membrane immersion tank, 5, 60 ... Membrane unit, 7 ... Water collection header (pipe), 17 ... Membrane element, 19 ... Under support (aeration part) ), 21 ... Frame, 21 f ... Suspension part, 25 ... Immersion part, 27 ... Piping part, 31, 41 ... Tank body, 35, 56 ... Lower tank part, 35b, 49b ... Pedestal part (unit support part), 35c , 49j ... spacer (positioning member), 35k, 49k ... upper end of spacer, 35d, 49c ... discharge part, 35e, 49d ... collection chamber (stacking part), 35f, 49e ... drain pipe, 35h, 49g ... inclined wall, 37 ... upper tank part, 49a ... bottom part of tank main body according to the second embodiment, 53 ... header accommodating part (upper tank part), 57 ... raw water storage part, 59 ... weir part, 65 ... support receiving part, F ... deposit .

Claims (7)

In a membrane immersion tank containing one or more immersion membrane units for membrane filtration of raw water,
A tank body having a lower tank part for storing the raw water and containing a plurality of membrane elements of the submerged membrane unit ;
A unit support that is provided at the bottom of the lower tank and supports the submerged membrane unit in contact with the submerged membrane unit;
A deposit discharge unit that is provided below the unit support part and communicates with an upper part of the lower tank part through an opening region formed so as to avoid the unit support part ;
The membrane dipping tank , wherein the unit support portion is a pedestal portion that abuts a lower end of the submerged membrane unit and supports the submerged membrane unit. The discharge part has a drain pipe and an accumulation part that guides the deposit toward the drain pipe,
The accumulation portion has an inclined wall having a gradient with respect to a horizontal plane, and a lower portion of the inclined wall communicates with the drain pipe,
The membrane immersion tank according to claim 1, wherein the drain pipe extends in a lateral direction intersecting with the vertical direction. The submerged membrane unit includes a submerged portion having a plurality of membrane elements, and a pipe portion treated water having passed through the membrane element with the conduit passing through is provided, which is arranged above the said immersion portion, With
The tank body includes a lower tank part that houses the immersion part and submerges the immersion part, an upper tank part in which the piping part is disposed, and a raw water storage part that is provided adjacent to the upper tank part. And a weir part that is disposed between the upper tank part and the raw water storage part, and the raw water supplied to the raw water storage part flows over into the upper tank part,
The volume of the said raw | natural water storage part is at least smaller than the volume of the said lower tank part, The film | membrane immersion tank of Claim 1 or 2 characterized by the above-mentioned.   The membrane immersion tank according to any one of claims 1 to 3, further comprising a positioning member that holds a distance between the plurality of immersion type membrane units installed side by side. The submerged membrane unit includes a submerged portion having a plurality of membrane elements, and a pipe portion treated water having passed through the membrane element with the conduit passing through is provided, which is arranged above the said immersion portion, With
The tank body includes a lower tank part that houses the immersion part and submerges the immersion part, and an upper tank part in which the piping part is disposed,
5. The film immersion according to claim 4, wherein the positioning member is a spacer extending in a vertical direction from a bottom portion of the tank body, and an upper end of the spacer is disposed in the upper tank portion. Tank. In a membrane treatment apparatus comprising a membrane immersion tank, and one or a plurality of immersion type membrane units installed in the membrane immersion tank and membrane-filtering raw water,
The submerged membrane unit includes a plurality of membrane elements, a frame that supports the plurality of membrane elements, an air diffuser provided on the frame and disposed below the membrane elements, and the plurality of membrane elements And a pipeline through which treated water that has passed through the membrane element passes,
The membrane immersion tank is provided at a tank body having a lower tank portion for storing raw water and containing the plurality of membrane elements, and a bottom portion of the lower tank portion, and is in contact with the immersion membrane unit. A unit support for supporting the submerged membrane unit;
A deposit discharge unit that is provided below the unit support part and communicates with an upper part of the lower tank part through an opening region formed so as to avoid the unit support part ;
It said unit support portion, before Symbol submerged membrane unit membrane treatment apparatus, characterized in that the base portion lower end abutting supporting the submerged membrane unit. Wherein the ratio of the installation area of the membrane area and the frame in the immersion type membrane unit, membrane treatment apparatus according to claim 6, characterized in that the 400~2000m ^{2 /} m 2.

Images