JP6308062B2 - Air diffuser and water treatment device - Google Patents

Description

  The present invention relates to an air diffuser and a water treatment apparatus including the air diffuser.

  In recent years, various methods for solid-liquid separation of activated sludge using a membrane module unit provided with a separation membrane such as a microfiltration membrane or an ultrafiltration membrane have been studied. For example, when an activated sludge treatment device is formed as a water treatment device equipped with a membrane module unit, and the treated water containing activated sludge is filtered by the separation membrane using the activated sludge treatment device, a treatment with high water quality is performed. You can get water.

However, when solid-liquid separation of water to be treated is performed using the separation membrane, the clogging of the separation membrane surface due to suspended solids (solid content) proceeds as the filtration treatment continues, resulting in a decrease in filtration flow rate, Increase in differential pressure occurs.
Therefore, conventionally, in order to prevent clogging of the separation membrane surface, for example, as shown in Patent Documents 1 to 7, a diffusion tube (aeration device) is disposed below the membrane module unit, and air is supplied from the diffusion holes of the diffusion tube. Air bubbles are generated by aeration, and the membrane module unit is washed by applying a gas-liquid mixed flow of the bubbles and the liquid to be processed formed by the rising of the bubbles to the membrane module unit. That is, suspended substances such as sludge adhering to the surface of the membrane module are peeled off by the gas-liquid mixed flow and removed from the membrane module.

JP-A-11-244673 JP 2010-111976 A JP 2001-276875 A Japanese Patent Laid-Open No. 2003-144876 Japanese Patent Laid-Open No. 2002-186991 US Patent Application Publication No. 2011/0133348 US Pat. No. 7,850,151

  However, in the submerged membrane separation apparatus of Patent Document 1, if the operation is continued for a long period of time, contaminants such as sludge accumulate in the diffuser pipe and in the air header (main pipe) communicating with the diffuser pipe, thereby clogging the diffuser holes. This makes it difficult to uniformly apply bubbles (gas-liquid mixed flow) to the membrane module. As a result, an insufficiently cleaned portion remains on the surface of the membrane module, and it becomes difficult to stably perform the solid-liquid separation process (filtration process).

  Further, in the devices of Patent Documents 2 to 7, the branch pipe is indirectly connected to the main pipe through the connecting member without being directly connected, so that the number of parts is increased and the cost is increased accordingly. It is easy.

  The present invention has been made in view of the above circumstances, and prevents the accumulation of contaminants such as sludge in the main pipe and the like, and further suppresses an increase in cost due to an increase in the number of parts, and an air diffuser and water An object is to provide a processing apparatus.

The present invention has the following aspects.
[1] An air diffuser comprising: a main pipe extending in the horizontal direction to which gas is supplied from the gas supply apparatus; and a plurality of branch pipes each having an air diffusion hole and extending in the horizontal direction directly connected to the main pipe. The main pipe has an open port on one end side thereof.
[2] The air diffuser according to [1], wherein an opening of the branch pipe is formed at an end portion on a side opposite to a side connected to the main pipe.
[3] The air diffuser according to [2], wherein the opening of the main pipe is disposed below the opening of the branch pipe.
[4] In any one of [1] to [3], the bottom of the branch pipe is located on the same horizontal plane as the bottom of the main pipe, or is located below the bottom of the main pipe. Aeration device as described.
[5] The air diffuser according to any one of [1] to [4], wherein a cross-sectional shape of the main pipe is a curved surface shape protruding upward.
[6] The air diffuser according to any one of [1] to [5], wherein the opening of the main pipe is disposed below the air diffuser of the branch pipe.
[7] The cross-sectional shape of the main pipe is a curved shape that is convex upward, and a pair of vertical straight portions that are respectively connected to both ends of the upper portion and whose lower portions are vertically downward, and the pair of vertical straight portions. Any one of the above [1] to [6], wherein the branch pipe is connected to a vertical straight section at a lower portion of the main pipe. The air diffuser described in 1.
[8] A water tank, a membrane module unit disposed in the water tank, and the air diffuser according to any one of [1] to [7] disposed below the membrane module unit. Equipped with a water treatment device.

According to the air diffuser of the present invention, since the open end is provided on one end side of the main pipe, the sludge accumulated in the main pipe or the like by flowing the water to be treated from the open port when the air diffuser operation is stopped. Such impurities can be easily moistened. Further, during the cleaning operation of the diffuser by resuming the diffuser operation, sludge and the like in the main pipe can be easily discharged (outflowed) from the open port by air from a blower or the like. Therefore, it is possible to prevent accumulation of contaminants such as sludge at the bottom of the main pipe, thereby preventing clogging of the air diffusion holes.
Further, since the branch pipe is directly connected to the main pipe, the number of parts can be reduced, thereby suppressing an increase in cost.
According to the water treatment device of the present invention, the membrane module unit is satisfactorily washed by the aeration device in which clogging of the aeration holes is prevented, so that the operation can be performed stably.

It is a perspective view which shows one Embodiment of the diffuser which concerns on this invention. It is a side view of the air diffusing device shown in FIG. FIG. 3 is a cross-sectional view taken along line AA in FIG. 2. FIG. 4 is a cross-sectional view taken along line B-B in FIG. 3. It is a side view of a membrane module unit. It is a front view of a membrane module unit. It is a figure which shows typically the schematic structure of one Embodiment of the water treatment apparatus which concerns on this invention. (A), (b) is a figure which shows the modification of this invention. (A), (b) is principal part side sectional drawing for demonstrating the form of a comparative example.

In the present invention, the horizontal direction means a substantially horizontal direction, and the vertical direction means a substantially vertical direction.
Moreover, the cross-sectional shape of the main pipe means a cross-sectional shape inside the main pipe.

Hereinafter, the present invention will be described in detail with reference to the drawings. In the following drawings, the scale of each member is appropriately changed to make each member a recognizable size.
FIG. 1 is a perspective view showing an embodiment of an air diffuser according to the present invention, and FIG. 2 is a side view of the air diffuser shown in FIG.

  In these drawings, reference numeral 1 denotes an air diffuser. The air diffuser 1 is connected to a main pipe 2 that receives supply of air (gas) from an air supply apparatus (gas supply apparatus) (not shown), and is connected to the main pipe 2. A plurality of branch pipes 3 are provided.

  As shown in FIG. 2, the main pipe 2 is disposed so as to extend in the horizontal direction so that the central axis thereof is along the horizontal direction. A flange pipe 5 is connected to the base end side of the main pipe 2 via an elbow pipe 4, By connecting another flange pipe (not shown) to the pipe 5, it is connected to an air supply device as will be described later. Note that one side of the elbow pipe 4 (the side opposite to the side connected to the main pipe 2) faces upward in the vertical direction, and therefore the flange pipe 5 connected to the elbow pipe 4 is also arranged so as to face upward in the vertical direction.

  On the distal end side (one end side) of the main pipe 2, that is, on the side opposite to the side connected to the elbow pipe 4, a down pipe 20 is integrally provided. The descending pipe 20 is formed by bending the distal end side of the main pipe 2 downward in the vertical direction, and the lower end thereof is a main pipe opening 20a that is opened without being closed. The descending pipe 20 may be bent by bending the distal end side of the main pipe 2, or may be formed by assembling parts such as an elbow. Further, the vicinity of the main pipe opening 20 a is a diameter-expanded portion 20 b formed with a larger diameter than the upper side of the downcomer 20.

  In the present embodiment, the cross-sectional shape of the main pipe 2 is a curved shape, preferably a semicircular shape, with the upper portion 21 protruding upward, as shown in FIG. 3 which is a cross-sectional view taken along line AA in FIG. A pair of vertical straight portions 23, 23 whose lower portions 22 are respectively connected to both ends of the upper portion 21 and directed downward in the vertical direction, and a horizontal straight portion connecting the lower ends of the pair of vertical straight portions 23, 23 24. That is, as shown in FIG. 1, the main pipe 2 is formed in a curved surface shape with the upper side 2a protruding upward, and the bottom portion 2b is formed in a horizontal flat surface shape. Further, the side surface 2c between the upper side of the curved surface shape and the bottom portion of the flat surface shape is a flat surface along the vertical direction.

  A cylindrical branch pipe 3 is directly connected to and connected to the main pipe 2 on its side peripheral surface. Specifically, as shown in FIG. 4 which is a cross-sectional view taken along line B-B in FIG. 3, the branch pipe 3 is connected to the side surface 2 c (vertical straight portion 23). That is, a circular opening (not shown) is formed on the side surface 2c of the main pipe 2, and the branch pipe 3 is connected to the side surface 2c in a state of communicating with the opening.

Here, the branch pipe 3 and the main pipe 2 are made of a synthetic resin such as polycarbonate, polysulfone, polyethylene, polypropylene, acrylic resin, ABS resin, or vinyl chloride resin, or a metal such as stainless steel.
Therefore, the branch pipes 3 are connected (connected) to the main pipe 2 by bonding or welding when each is a synthetic resin, and by welding when each is a metal. At this time, since the side surface 2c of the main pipe 2 is a flat surface, the end face of the cylindrical branch pipe 3 can be abutted and adhesion and welding can be easily performed in this state.

In the present embodiment, the branch pipe 3 is connected to the side surface 2c of the main pipe 2 such that the bottom 3a thereof is located on the same horizontal plane as the bottom 2b of the main pipe 2.
Here, the branch pipe 3 is formed in a cylindrical shape having the same inner diameter as the circular opening of the side surface 2c of the main pipe 2 described above, and therefore the bottom 3a is the lowest point, that is, the lowest point on the inner peripheral surface. . On the other hand, the bottom portion 2 b of the main pipe 2 is a horizontal flat surface as described above, that is, the inner surface at the lower end portion of the main pipe 2.

In the present embodiment, as shown in FIG. 4, the thickness of the main pipe 2 and the thickness of the branch pipe 3 are formed to be substantially the same, so that the lowest point on each outer surface is combined (connected). As a result, the bottom 3 a of the branch pipe 3 is positioned on the same horizontal plane as the bottom 2 b of the main pipe 2.
The opening area of the main pipe 2 is about 5 to 10 times the opening area of the branch pipe 3.

  As shown in FIGS. 1 and 2, the branch pipe 3 is connected to the side surface 2c of the main pipe 2 and extends in the horizontal direction as described above. A circular air diffusion hole 6 is formed on the side surface so as to function as an air diffusion pipe. One or more are formed. The number of air diffusion holes 6 is appropriately set based on the length of the branch pipe 3 and the like, but from the viewpoint of uniform air diffusion, it is preferably 2 to 6, and 3 to 5 Is more preferable. In this embodiment, as shown in FIG. 1, three are formed at intervals (equal intervals) of about 80 mm to 100 mm.

  Further, in the present embodiment, these air diffusion holes 6 are all formed so as to face upward in the vertical direction in a state where the main pipe 2 is horizontally disposed. That is, the branch pipe 3 is formed so that the portion where the side air diffusion holes 6 are formed is horizontal and is located at the upper end of the branch pipe 3 in a state where the main pipe 2 is horizontally arranged. Thereby, all the air diffusion holes 6 of the branch pipe 3 are positioned above the bottom portion 2b of the main pipe 2, and therefore air supplied into the branch pipe 3 via the main pipe 2 is smoothly and uniformly ejected. Can do.

Further, the branch pipe 3 is integrally provided with a bent pipe 7 on the side opposite to the side connected to the main pipe 2. The bent pipe 7 is formed by bending the distal end side of the branch pipe 3 downward in the vertical direction, and its lower end is a branch pipe opening 7a that is opened without being closed.
The bent pipe 7 may be bent by bending the distal end side of the branch pipe 3, or may be formed by assembling parts such as elbows.
Further, the vicinity of the branch pipe opening 7 a is an enlarged diameter part 7 b formed with a larger diameter than the upper side of the bent pipe 7.

Further, the branch pipe opening 7 a of the bent pipe 7 is positioned above the main pipe opening 20 a of the descending pipe 20 in the main pipe 2. That is, the main pipe opening 20a is disposed below the branch pipe opening 7a. In addition, the main pipe opening 20 a is disposed below the air diffuser 6 of the branch pipe 3.
In addition, although it does not specifically limit about the pipe part which faces the perpendicular direction downward in the bending pipe 7, For example, when the flow volume of the air supplied to the branch pipe 3 is large, the length is comparatively long, for example, 50 mm-300 mm It is preferable to form to the extent.
This is because, when the air flow rate is increased, a relatively large amount of air is ejected from the branch pipe opening 7a, which may affect the uniformity of the ejection of air from the air diffuser holes 6. .
Therefore, as described above, the length of the pipe portion of the bent tube 7 that is directed downward in the vertical direction can be prevented from affecting the uniformity of air ejection from the air diffuser holes 6.

As shown in FIG. 1, all of the branch pipes 3 are arranged in parallel with the other branch pipes 3 under such a configuration. Further, the branch pipes 3 are respectively connected to the side surfaces 2 c on both sides of the main pipe 2 at the same location in the length direction of the main pipe 2. As a result, the branch pipes 3 are arranged symmetrically about the main pipe 2.
In FIG. 1 and FIG. 2, six branch pipes 3 are connected to the main pipe 2 on the left and right, a total of six, but the number of branch pipes 3 connected to the main pipe 2 is arbitrary. 2 is appropriately determined based on the length of 2.

  The length of the branch pipe 3 in plan view, that is, the length in plan view from the base end to the distal end connected to the main pipe 2 is 500 mm or less, preferably 400 mm or less. If the length of the branch pipe 3 is short, it is suitable for uniform air diffusion, but it is preferable to select 50 mm or more, more preferably 100 mm or more according to the size of the water treatment apparatus.

The inner diameter of the branch pipe 3 is preferably 10 mm or more and 20 mm or less, although it varies depending on the size (size) of the air diffuser 1. Similarly, the diameter (inner diameter) of the air diffusion holes 6 is preferably 4.5 mm or more and 7.0 mm or less.
The reason why the diameter of the air diffuser 6 is preferably 4.5 mm or greater and 7.0 mm or less is that if the air diffuser 6 is less than 4.5 mm, the air diffuser 6 is likely to be blocked. This is because the flow rate of the air is low, and there is a possibility that a sufficient aeration effect cannot be obtained.

  In addition, you may connect the pressure reduction means which consists of a suction pump etc. to the air diffuser 1 of such a structure separately from the said air supply apparatus (gas supply apparatus) to the flange piping 5, for example. If it does in this way, when the aeration operation which supplies air with an air supply device will be stopped as will be described later, the inside of the main pipe 2 and the branch pipe 3 can be decompressed by the decompression means.

  The air diffuser 1 having such a configuration is used by being disposed below the membrane module unit 10 as shown in FIGS. 5 and 6. The membrane module unit 10 includes a plurality of membrane modules 11, and the membrane module 11 includes a membrane element (not shown) such as a hollow fiber membrane.

  In the example shown in FIG. 5 and FIG. 6, two air diffusion devices 1 shown in FIG. 1 and FIG. 2 are arranged adjacent to each other as shown in FIG. An air supply pipe 13 is connected via a connecting pipe (flange pipe) 12. An air supply device (not shown) such as a blower is connected to the air supply pipe 13 as will be described later.

  Such a membrane module unit 10 and the diffuser 1 are arranged and used in a water treatment device 30 as shown in FIG. The water treatment device 30 is an embodiment of the water treatment device according to the present invention, and includes a water tank (treatment tank) 32 into which treated water 31 such as activated sludge is charged, and the water tank 32 disposed in the water tank 32. It is a submerged membrane separation device including the membrane module unit 10, the air diffuser 1 disposed below the membrane module unit 10, and the air supply device 40. In addition, in the water treatment apparatus 30 of this embodiment, it has three membrane module units 10, Therefore, the diffuser 1 is also arrange | positioned under each corresponding to each membrane module unit 10. FIG. However, the numbers of the membrane module units 10 and the air diffuser 1 are not particularly limited and can be arbitrarily set.

Although the water tank 32 has a rectangular parallelepiped shape and the size is not particularly limited, it is preferable that the depth sufficiently exceeds 1 m so that the depth of the water to be treated 31 is 1 m or more.
The air supply device 40 includes a blower 41 and a connection pipe 42 that connects the blower 41 and the air supply pipe 13.

Further, a suction pump (not shown) is connected to the membrane module unit 10 (membrane module 11) via a suction pipe 33 so that suction filtration by the membrane module unit 10 is possible.
In FIG. 7, for convenience, the main pipe 2 and the branch pipe 3 of the air diffuser 1 are omitted. Of course, the air diffuser denoted by reference numeral 1 in FIG. 7 is shown in FIGS. In this way, it is assumed that the two air diffusing devices 1, that is, the two air diffusing devices 1 shown in FIGS. 1 and 2 are provided.

Next, the processing operation method of such a water treatment apparatus 30 is demonstrated.
First, as shown in FIG. 7, the membrane module unit 10, the diffuser 1, and the like are disposed in the water tank 32, and the water to be treated 31 is stored so as to have a predetermined water level (water depth). In this state, suction filtration by the membrane module unit 10 is performed by operating the suction pump on the membrane module unit 10 side.

  In parallel with such suction filtration, air is continuously (continuously) supplied from the air supply device 40 (blower 41) toward the diffuser device 1 for a predetermined time. The supply amount of air is appropriately determined according to the size of the air diffuser 1 and the like. By supplying air in this way, most of the air supplied to the air diffuser 1 through the air supply pipe 13 is ejected from the air diffuser 6 of the branch pipe 3 through the main pipe 2. That is, the water pressure in the air diffuser 6 is lower than that of the branch pipe opening 7a of the branch pipe 3, and the water pressure is lower than that of the main pipe opening 20a of the main pipe 2. Therefore, air must be supplied particularly at a high air volume. For example, most of the air supplied to the air diffuser 1 is ejected from the air diffuser 6.

  When air is ejected from the air diffusion holes 6 in this manner, the ejected air becomes bubbles and rises in the water tank 32, that is, in the liquid to be treated 31. The rising bubbles form a gas-liquid mixed flow with the liquid 31 to be processed. This gas-liquid mixed flow hits the membrane module unit 10 (membrane module 11) to wash each membrane element (not shown). That is, the gas-liquid mixed flow peels off suspended substances such as sludge adhering to the surface of the membrane element (membrane module unit 10) and removes them from the membrane module unit 10.

  When such an aeration operation is performed for a predetermined time (for example, several hours), sludge or the like in the water to be treated 31 slightly flows into the branch pipe 3 or the main pipe 2 and accumulates and accumulates. Contaminants such as sludge accumulated in this manner are gradually dried by blowing air during the aeration operation. Therefore, as this drying progresses, the sludge adheres, and the inside of the main pipe 2 and the branch pipe 3 is blocked, or the air diffuser 6 is clogged.

  Therefore, in order to prevent such inconvenience due to accumulation of contaminants such as sludge, if the aeration operation is performed for a predetermined time, the blower 41 is stopped for a certain time (for example, several tens of seconds to several minutes), and the aeration apparatus 1 is reached. Stop supplying air. Then, the air remaining in the main pipe 2 and the branch pipe 3 passes through the air diffusion holes 6 and is discharged into the water to be treated 31 to clean the membrane module unit 10. In addition, the water to be treated 31 flows in from the branch pipe opening 7a and the main pipe opening 20a in place of the air.

The treated water 31 thus flowing wets, for example, dry deposits (sludge) clogging the air diffusion holes 6 and contaminants such as sludge accumulated in the main pipe 2 and the branch pipe 3.
Therefore, after the elapse of a certain time, the blower 41 is operated to restart the aeration, whereby the aeration holes 6, the branch pipe opening 7a, and the main pipe opening 20a together with the water to be treated 31 into which these dry deposits and sludge have flowed. Can be easily discharged (flowed out). That is, the inside of the main pipe 2, the branch pipe 3, and the air diffusion holes 6 can be cleaned.

  At this time, in the present embodiment, the bottom 3a of the branch pipe 3 is located on the same horizontal plane as the bottom 2b of the main pipe 2, and therefore the bottom 2b of the main pipe 2 is particularly lower than the bottom 3a of the branch pipe 3. Thus, accumulation of contaminants such as sludge on the bottom 2b of the main pipe 2 is prevented. That is, it is prevented that contaminants such as sludge accumulate in the stepped portion and accumulate without being discharged as it is, so that the sludge and the like on the bottom portion 2b of the main pipe 2 are treated together with the water to be treated 31 by resuming aeration. Easily discharged.

  Therefore, in the air diffuser 1 of this embodiment, since sludge etc. on the bottom 2b of the main pipe 2 can be easily discharged, the air flow in the main pipe 2 is made smooth, and thereby air flows into the branch pipe 3. Can be supplied evenly. Further, since sludge and the like on the bottom 2b of the main pipe 2 can be easily discharged, clogging of the air diffuser holes 6 can be prevented, and air can be uniformly ejected from all the air diffuser holes 6. Therefore, according to this air diffusing device 1, it is possible to uniformly apply bubbles (gas-liquid mixed flow) to the membrane module unit 10 and perform the cleaning well.

  In particular, since the upper side 2a of the main pipe 2 is formed in a curved surface shape that is convex upward (transverse cross section is semicircular), sludge and the like hardly adhere to the upper side 2a. However, it can be easily discharged without accumulating by the above washing. Note that the curved surface shape that protrudes upward is not limited to a semicircular shape in cross section, and may be a substantially circular arc shape in which the cross section is convex upward, such as a semi-elliptical shape in cross section. Various forms can be adopted. Even when such a configuration is adopted, the above-described effects such as sludge and the like hardly adhere to the upper side 2a can be obtained.

Further, since the side surface 2c of the main pipe 2 is a flat surface along the vertical direction, the end surface of the cylindrical branch pipe 3 can be abutted against the side surface 2c, and bonding and welding can be easily performed in this state.
In addition, since the bottom 2b of the main pipe 2 is formed in a horizontal flat surface shape, for example, compared to a case where a corner is formed at the bottom, the sludge is locally accumulated and prevented from being deposited as it is. can do.

  Moreover, since the main pipe 2 has the main pipe opening 20a on the tip side (one end side) opposite to the side connected to the air supply device 40, when the aeration operation is stopped, from the main pipe opening 20a. To-be-treated water is allowed to flow, and contaminants such as sludge accumulated in the main pipe 2 can be easily moistened. Further, during the cleaning operation of the air diffuser 1 by resuming the air diffuser operation, sludge and the like in the main pipe 2 can be easily discharged (outflowed) from the main pipe opening 20a by the air from the blower 41. Therefore, it is possible to prevent accumulation of contaminants such as sludge at the bottom of the main pipe, thereby preventing clogging of the air diffusion holes.

  Further, since the main pipe opening 20a is disposed below the air diffuser hole 6 and further below the branch pipe open hole 7a, the air diffuser 6 is connected to the branch pipe open port of the branch pipe 3 during the air diffuser operation. Since the water pressure is lower than 7a and further lower than the main pipe opening 20a of the main pipe 2, most of the air supplied to the air diffuser 1 can be ejected from the air holes 6.

Further, since the branch pipe 3 is directly connected to the main pipe 2, the number of parts can be reduced, thereby suppressing an increase in cost.
According to the water treatment device 30 of the present invention, the membrane module unit 10 is satisfactorily washed by the air diffuser 1 in which the clogging of the air diffuser 6 is prevented, so that the operation can be performed stably.

  As mentioned above, although preferred embodiment of this invention was described referring drawings, this invention is not limited to the said embodiment. Various shapes, combinations, and the like of the constituent members shown in the above-described embodiments are merely examples, and various modifications can be made based on design requirements and the like without departing from the gist of the present invention.

  For example, in the above embodiment, the bottom 3a of the branch pipe 3 is positioned on the same horizontal plane as the bottom 2b of the main pipe 2 as shown in FIG. 4, but for example, as shown in FIG. 3 may be positioned below the bottom 2 b of the main pipe 2. In that case, with respect to the end opening of the branch pipe 3 on the side connected to the main pipe 2, the portion that does not contact the main pipe 2 is closed by the lid 15, thereby airtight between the main pipe 2 and the branch pipe 3. Keep connected. If comprised in this way, since the bottom part 3a of the branch pipe 3 can be made lower than the bottom part 2b of the main pipe 2, the sludge etc. which accumulate | stored in the main pipe 2 can be sent in the branch pipe 3 more easily, Therefore, a branch pipe open | release port It can be easily discharged from 7a.

  In the above embodiment, a cylindrical pipe is used as the branch pipe 3. However, as shown in FIG. 8B, for example, the branch pipe 3 is formed in a shape substantially similar to the cross-sectional shape of the main pipe 2 shown in FIG. May be. In this way, since the bottom 3a of the branch pipe 3 is also a flat surface, it can be formed and arranged flush with the bottom 2b of the main pipe 2 that is also formed on the flat surface. The accumulated sludge and the like can be easily discharged to the branch pipe 3 side.

In the above embodiment, the down pipe 20 is provided on the front end side (one end side) of the main pipe 2 and the lower end of the down pipe 20 is the main pipe opening 20a facing downward. May be opened in the horizontal direction, for example, on one end side of the main pipe extending in the horizontal direction without being directed downward. Further, the lower end of the downcomer 20 may be further bent in the horizontal direction so that the main pipe opening is opened in the horizontal direction.
Moreover, in the said embodiment, although air was supplied from the air supply apparatus 40 with respect to the diffuser 1 and air was ejected from the diffuser hole 6, gas other than air, such as nitrogen, as needed, for example May be supplied from the gas supply device to the diffuser.

Hereinafter, the present invention will be described more specifically with reference to examples.
[Example 1]
1 to 3, the branch pipe 3 and the main pipe 2 on the down pipe 20 side are disposed from the vicinity of the down pipe 20 of the main pipe 2 of the air diffuser 1 (before the main pipe bends). The main pipe 2 up to the connected part was intentionally clogged with contaminants such as sludge. And this aeration apparatus 1 was immersed in the activated sludge mixed liquid. Next, air was supplied from the base end side (side to which the elbow pipe 4 was connected) of the main pipe 2 by an air supply device at a flow rate of 75 L / min for about 5 minutes, and then the air diffusion was stopped for 1 minute.

And after supplying air for 5 minutes on the said conditions, aeration was stopped.
After the aeration is stopped, the aeration apparatus 1 is pulled up from the activated sludge mixed liquid, and whether or not contaminants such as sludge are accumulated in the main pipe 2 and the main pipe opening 20a and the branch pipe 3 and the branch pipe opening 7a, respectively. This was confirmed by visual inspection.
As a result of visual confirmation, contaminants such as sludge were not accumulated in the main pipe 2 and the main pipe opening 20a, and the branch pipe 3 and the branch pipe opening 7a.

[Example 2]
The diffuser 1 shown in FIGS. 1 to 3 was used and immersed in the activated sludge mixed solution. Then, air was supplied at 75 L / min, 125 L / min, 150 L / min, and 250 L / min from the proximal end side (side to which the elbow pipe 4 was connected) of the main pipe 2 by an air supply device.

Thus, when air was supplied with each air volume, it was confirmed that air was almost uniformly ejected from each air diffuser 6 of the branch pipe 3 in all air volumes.
In addition, after the aeration operation is performed for 24 hours with each air volume in this way, the aeration is stopped and the aeration apparatus 1 is lifted from the activated sludge mixed liquid, and dirt such as sludge is placed on the top and bottom of the main pipe 2 It was visually confirmed whether or not an object was accumulated.
As a result of visual confirmation, no contaminants such as sludge accumulated at both the top and bottom of the main pipe 2 at all flow rates. Therefore, the evaluations of the criteria shown below were all “◯”.

The results confirmed by visual observation were evaluated according to the following criteria.
・ There is no accumulation of contaminants such as sludge ： Evaluation “○”
・ Slightly accumulated contaminants such as sludge: Evaluation “△”
・ A little (more than a little) of dirt such as sludge is accumulated: Evaluation “× ˜ △”
・ Many contaminants such as sludge are accumulated: Evaluation “×”

[Comparative Example 1]
For comparison, an air diffuser having the same configuration as the air diffuser 1 shown in FIGS. 1 to 3 was prepared except that one end of the main pipe 2 had no opening and was closed.
Also in this air diffuser, sludge is present in the main pipe 2 from the same place as in the first embodiment, that is, the place where the main pipe is closed to the place where the branch pipe 3 and the main pipe 2 on one end side are connected. Etc. were intentionally blocked. And this aeration apparatus was immersed in the activated sludge liquid mixture like the said Example 1. FIG. Next, air was supplied from the base end side (side to which the elbow pipe 4 was connected) of the main pipe 2 by an air supply device at a flow rate of 75 L / min for about 5 minutes, and then the air diffusion was stopped for 1 minute.

And after supplying air for 5 minutes on the said conditions, aeration was stopped.
After the aeration was stopped, the aeration apparatus 1 was lifted from the activated sludge mixed liquid, and it was visually confirmed whether or not contaminants such as sludge accumulated in the main pipe 2, the branch pipe 3, and the branch pipe opening 7a. .
As a result of visual confirmation, a large amount of contaminants such as sludge accumulated in the main pipe 2, and the evaluation was “x” based on the criteria shown in Example 2.
In Comparative Example 1, since the main pipe 2 does not have the main pipe opening 20a, it has been clarified that when foreign matters such as sludge are accumulated in the main pipe 2, the foreign matters cannot be discharged.

[Example 3]
Using the two types of air diffusers shown in FIGS. 9A and 9B in which the cross-sectional shape of the main pipe 2 and the connection position of the branch pipe 3 with respect to the main pipe 2 are different, the same air volume and the same as in the second embodiment. Operation was carried out, and after 24 hours of operation, whether or not contaminants such as sludge accumulated on the top and bottom of the main pipe 2 was confirmed by visual observation, and the above evaluation was performed.

9A, the main pipe 2 has a cylindrical shape, and the branch pipe 3 is connected to an intermediate portion between the upper end portion and the lower end portion of the side peripheral surface of the main pipe 2. Yes. Accordingly, the bottom 3 a of the branch pipe 3 is located above the bottom 2 b of the main pipe 2.
In the air diffuser of the example shown in FIG. 9B, the main pipe 2 has a rectangular tube shape, and the branch pipe 3 is connected to an intermediate portion between the upper end portion and the lower end portion on the side surface of the main pipe 2. . Accordingly, the bottom 3 a of the branch pipe 3 is located above the bottom 2 b of the main pipe 2.

  As described above, when air is supplied at 75 L / min, 125 L / min, 150 L / min, and 250 L / min with the air supply device as described above, the air diffuser of these two examples is used for all the air volumes. It was confirmed that air was ejected from the branch pipe 3 almost uniformly.

Further, after 24 hours of operation, it was visually confirmed whether or not contaminants such as sludge accumulated on the top and bottom of the main pipe 2, and in the example shown in FIG. No contaminants such as sludge accumulated in the upper portion of the main pipe 2, and therefore the evaluations based on the criteria shown in Example 2 were all “◯”. However, at the bottom of the main pipe 2, the evaluation was “x” at each flow rate of 75 L / min, 125 L / min, and 150 L / min, and the evaluation was “× ˜Δ” at a flow rate of 250 L / min.
This is because, in the example shown in FIG. 9A, the upper part has a semicircular shape (curved surface shape that protrudes upward), so that contaminants such as sludge are present on the upper part of the main pipe 2 as in the second embodiment. It is thought that did not accumulate. On the other hand, since the bottom part 3a of the branch pipe 3 is located above the bottom part 2b of the main pipe 2, it is considered that contaminants such as sludge accumulated on the bottom part of the main pipe 2 due to a step between them. .

Further, in the example shown in FIG. 9B, contaminants such as sludge accumulated at the upper part of the main pipe 2 at respective flow rates of 75 L / min and 125 L / min, and the evaluation was “x”. The evaluation was “× ˜Δ” at a flow rate of 150 L / min, and the evaluation was “Δ” at a flow rate of 250 L / min. Furthermore, in the bottom part of the main pipe 2, contaminants such as sludge accumulated at all flow rates, and the evaluation was “x”.
It is considered that the contaminants such as sludge accumulated on the bottom of the main pipe 2 for the same reason as in the example shown in FIG. In addition, in the example shown in FIG. 9B, since a corner portion is formed at the upper portion, contaminants such as sludge are likely to adhere to the corner portion, and as a result, contaminants such as sludge are accumulated at the upper portion. Conceivable.

  From the above results, it was confirmed that the examples of the present invention were less likely to collect contaminants such as sludge in the main pipe 2 than the comparative example.

DESCRIPTION OF SYMBOLS 1 ... Air diffuser, 2 ... Main pipe, 2a ... Upper side, 2b ... Bottom part, 2c ... Side surface, 3 ... Branch pipe, 3a ... Bottom part, 6 ... Air diffuser hole, 7a ... Branch pipe open port, 10 ... Membrane module unit, DESCRIPTION OF SYMBOLS 11 ... Membrane module, 20a ... Main pipe opening, 21 ... Upper part, 22 ... Lower part, 23 ... Vertical linear part, 24 ... Horizontal linear part, 30 ... Water treatment apparatus, 31 ... Water to be treated, 32 ... Water tank, 40 ... Air Feeder, 41 ... Blower

Claims (6)

An air diffuser comprising: a main pipe extending in a horizontal direction to which gas is supplied from a gas supply apparatus; and a plurality of branch pipes having air diffuser holes and extending in the horizontal direction directly connected to the main pipe,
The main pipe has an opening at one end thereof ,
The cross-sectional shape of the main pipe is a curved shape in which the upper part is convex upward, the lower part is connected to both ends of the upper part, and a pair of vertical straight parts extending downward in the vertical direction, and the pair of vertical straight parts It is a shape consisting of a horizontal straight line connecting the lower ends,
The said branch pipe is a diffuser connected with the vertical straight part of the lower part of the said main pipe .   The air diffuser according to claim 1, wherein the opening of the branch pipe is formed at an end portion on a side opposite to a side connected to the main pipe.   The diffuser according to claim 2, wherein the opening of the main pipe is disposed below the opening of the branch pipe.   The aeration apparatus according to any one of claims 1 to 3, wherein a bottom portion of the branch pipe is located on the same horizontal plane as the bottom portion of the main pipe, or is located below the bottom part of the main pipe. The diffuser according to any one of claims 1 to 4 , wherein the opening of the main pipe is disposed below the diffuser hole of the branch pipe. A tank,
A membrane module unit disposed in the water tank;
A water treatment device comprising: the air diffusion device according to any one of claims 1 to 5 disposed below the membrane module unit.

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