KR101305426B1 - Low power diffuser - Google Patents

Abstract

PURPOSE: A low-energy fine air bubble generator, in which stenosed materials, etc. are automatically flushed due to the pulsating operation of an air diffusion part by air bubbles, reduces power consumption and prevents blockage caused by the stenosed materials and the decline of efficiency. CONSTITUTION: A low-energy fine air bubble generator has a feed part (100) and an air diffusion part (200). The feed part includes a cylindrical body (110) covering the body of the low-energy fine air bubble generator and an air pipe (150) supplying air bubbles to the inside of the body. The air diffusion part contains a ring type frame (210), a shaft inside of a frame, a shaft bearing (221) and blades (230). The frame ushered in the body moves up and down by air bubbles supplied inside of the body. The blades are bond to the shaft to slice rising air bubble supplied from the feed part.

Description

Low energy micro bubble generator {Low power diffuser}

The present invention relates to a low-energy microbubble generating device, and more particularly, to reduce power consumption due to less air resistance during microbubble generation, and to prevent clogging due to the attachment of constriction and reduction of efficiency. The present invention relates to a low-energy microbubble generating device capable of automatic washing such as a constriction by pulsating motion and capable of performing agitation in an aerobic tank by pulsating motion and rotational motion.

As a conventional sewage treatment method, one of the most widely used methods is a biological treatment method. In the biological treatment method, the inflow water is introduced into the aerobic tank after the first settling basin, and oxygen dissolved in the aerobic tank is removed by using microorganisms to remove organic matter and ammonia nitrogen. Therefore, the aerobic tank requires a sufficient amount of dissolved oxygen for the activity of microorganisms, but since the excessive increase in the amount of air flow increases the power ratio, it has conventionally improved the oxygen transfer efficiency by increasing the residence time of the bubble in the aeration tank. .

Among these conventional microbubble generators, a membrane-type diffuser device having a membrane having a fine hole at the end of the diffuser, through which the bubbles pass through the fine hole and splits finely, has been mainly used. However, these membrane type diffusers have a lot of resistance due to the minute holes through which air passes, and there is a problem in that the power consumption increases, and the inconvenience of having to constantly change the diffusers due to the blockage of the fine holes in the membrane. There was this.

Therefore, it is necessary to develop a microbubble generating device that can finely split bubbles without air resistance when the microbubbles are generated, and that efficiency is not lowered by various suspended matters.

Korea Patent Publication KR 10-2004-0072775 (2004.08.19)

Accordingly, an object of the present invention is to provide a low-energy microbubble generating device capable of reducing power consumption due to low resistance of air, and preventing clogging due to adhesion of constriction and a decrease in efficiency.

In addition, an object of the present invention is to provide a low-energy micro-bubble generating device capable of automatic washing, such as a constriction by the up and down pulsating movement, capable of performing agitation in the aerobic tank by pulsating and rotating movement.

The present invention, the supply portion is configured to include a cylindrical body, and an air pipe provided in the lower end of the body to supply bubbles into the body; And a ring-shaped frame which is guided by the body to be moved up and down by bubbles supplied into the body, and is provided to surround the body, an axis provided inside the frame, and an axis to fix the axis to the frame. It is characterized in that it comprises a; and the air dispersing portion is coupled to the support and the shaft is configured to include a blade for splitting the air bubbles supplied from the supply.

In addition, the present invention, the blade is radially or symmetrically coupled to the shaft, and further comprises a removable joint for coupling the blade to the shaft, is provided with a plurality of joints, the blade is a plurality of To form a layer.

According to the present invention, since the air bubbles are diffused using the blade-shaped blades 230, the air resistance is low, thereby reducing power consumption, and there is an effect of preventing clogging due to the attachment of the constriction and a decrease in efficiency.

In addition, the present invention, since the diffuser 200 with the blade 230 is pulsating movement up and down by the bubble, it is possible to automatically wash, such as a constriction, and to rotate in addition to the pulsating movement, stirring in the aerobic tank There is an effect that can be easily performed.

1 is a cross-sectional view of a low-energy microbubble generating device according to an embodiment of the present invention.
Figure 2 is an exploded view of the blade of the low-energy microbubble generating device according to an embodiment of the present invention.
3 is a plan view of a low-energy microbubble generating device according to an embodiment of the present invention.
Figure 4 is a cut perspective view of the lower body of the low-energy microbubble generating device according to an embodiment of the present invention.
5 is an exploded perspective view of main parts of a low-energy microbubble generating device according to an embodiment of the present invention.
6 is an exemplary view showing a lifting process of the low-energy microbubble generating device according to an embodiment of the present invention.

Hereinafter, a low energy microbubble generating device according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view of a low-energy microbubble generating device according to an embodiment of the present invention, Figure 2 is an exploded view of a blade of a low-energy microbubble generating device according to an embodiment of the present invention, Figure 3 is according to an embodiment of the present invention 4 is a plan view of the lower body of the low energy microbubble generating device according to an embodiment of the present invention, Figure 5 is a main portion of the low energy microbubble generating device according to an embodiment of the present invention separated 6 is a perspective view illustrating a lifting process of a low energy microbubble generating device according to an embodiment of the present invention.

1 to 6, the low-energy microbubble generating device according to an embodiment of the present invention, the upper and lower cylindrical supply unit 100, and pulsating up and down around the supply unit 100 to diffuse bubbles It is configured to include a diffuser (200).

The supply unit 100 is installed inside the aerobic tank and serves to circulate raw water and supply oxygen, and for this purpose, a cylindrical body 110 and a lower end of the body 110 are provided to bubble air into the body 110. It is comprised including the air pipe 150 which supplies.

The body 110 is formed in a cylindrical shape through which the top and bottom are penetrated, and an air pipe 150 is installed at the lower end, and the inner circumferential edge of the diffuser 200 is guided to the upper outer circumference to move up and down.

The upper outer periphery of the body 110 is formed with a stepped body 111 stepped inward, the body side upward rotation block 112 and the triangular block-shaped body of the sawtooth shape on the outer periphery of the body step 111 The side downward rotation block 113 is provided.

To explain this in more detail, the body side upward rotation block 112 is formed to have a sawtooth shape continuous to the outer periphery upper end of the body stepped portion 111, and the frame side upward rotation block of the frame 210 to be described below ( 212) to slide and to rotate as it rises. To this end, the body side upward rotation block 112 is formed to protrude in a sawtooth shape on the outer periphery of the body step portion 111, the vertical surface formed vertically from the top of the body step portion 111, and upward from the lower end of the vertical surface It is configured to include an inclined surface formed to be inclined. This vertical plane determines the angle at which the frame 210 to be described below rotates once when pulsating up and down, and the inclined plane determines the rotational direction so that the frame 210 can continue to rotate in the same direction during rotation. do.

The body-side upward rotation block 112 described above is caused by buoyancy in a state where the inclined surface of the frame-side upward rotation block 212 and the inclined surface of the body-side upward rotation block 112 are shifted from each other when the frame 210 is raised. As a result, the frame 210 rotates about the body 110 by sliding and rising, and when the frame 210 descends and descends from the same position when descending, the frame-side upward rotation block again rises ( Since the inclined surface of the 212 and the inclined surface of the body-side upward rotation block 112 are meshed again without being misaligned with each other, the frame 210 cannot be rotated.

Therefore, when the frame 210 repeatedly performs the pulsating motion of rising and falling, the frame 210 can be continuously rotated, so that the frame 210 can be rotated in the rotational direction even when the frame 210 is lowered. More rotational configuration is needed.

In order to achieve the above object, the present invention further includes a body side downward rotation block 113 and a frame side downward rotation block 213 in the body 110.

The body side downward rotation block 113 is provided to correspond to each other in the same number as the teeth of the body side upward rotation block 112 on the inner circumference of the body side upward rotation block 112, the frame side of the frame 210 to be described later When the downward rotation block 213 descends serves to slide and rotate. To this end, the body side downward rotation block 113 is formed to protrude in a triangle on the inner circumference of the body side upward rotation block 112, including a vertical vertical surface, and the inclined surface formed to be inclined downward from the upper end of the vertical surface It is composed. At this time, the inclined surface of the body-side downward rotation block 113 rotates the frame 210 by a predetermined angle about the body 110 when the frame 210 is lowered, so that the frame-side upward rotation block when the frame 210 is raised again 212 and the body-side upward rotation block 112 to slide against each other inclined surface.

Therefore, when the frame 210 descends, the inclined surfaces of the body side downward rotation block 113 and the frame side downward rotation block 113 slide with each other, and the frame 210 rotates, thereby causing the body side upward rotation block 112 to fall. The inclined surface of the frame-side upward rotation block 212 and the inclined plane of the frame-side upward rotation block 212 at the time of the rise of the frame 210 by preventing the inclined surface of the frame-side upward rotation block 212 completely overlap each other when viewed from above. The inclined surfaces of the sliding surfaces come into contact with each other and are rotated by buoyancy. By repeating this process, the frame 210 can pulsate up and down and continuously rotate.

Meanwhile, the body side upward rotation block 112 and the body side downward rotation block 113 are formed to have the same thickness so that the frame 210 is as close to the body 110 as possible, and the sum of the thicknesses is the body stepped portion ( It is preferable to be the same as the step depth of 111, but is not limited thereto.

In addition, a plurality of body holes 120 may be formed in the lower side surface of the body step part 111 of the body 110 so as to discharge bubbles therein when the frame 210 rises to the outside. The body hole 120 can easily check the operating state of the frame 210 by discharging or blocking the bubbles inside the outside during the pulsation movement of the frame 210.

The air pipe 150 is provided at the lower end of the body 110 to serve to supply bubbles into the body 110. To this end, the air pipe 150 receives air through the blower pipe 160 from an air pump (not shown) located outside the exhalation tank, and supplies a plurality of pipe supports 130 extending from the inner circumference of the bottom of the body 110. By the body 110 is installed in the center of the lower end. On the other hand, the air pipe 150 may adjust the position up and down to adjust the supply position of the bubble. In this case, the length adjusting part 140 is further provided between the air pipe 150 and the pipe support 130, and the air pipe 150 and the length adjusting part 140 are connected to the air pipe 150 as shown in FIG. 4. The thread 151 is formed to be coupled by a bolt coupling method or by a coupling method (not shown) by a protrusion and a groove to adjust the bubble supply position inside the body 110. The air pipe 150 can adjust the granularity of the bubble by adjusting the vertical position in the body 110.

The diffuser 200 is guided to the body 110 to be moved up and down by bubbles rising inside the body 110, a plurality of blades 230 are provided to serve to split the bubbles finely.

For this purpose, the diffuser 200 includes a ring-shaped frame 210, a blade 230 provided below the frame 210, a shaft 220 and a shaft 220 fixing the blade 230. It is configured to include a plurality of shaft support 221 fixed to the frame 210.

The frame 210 is formed in a ring shape to surround the body step 111 of the body 110, and a plurality of shaft supports 221 are formed to extend inward to form a shaft at a center point of the shaft supports 221. 220) can be combined.

The lower inner periphery of the frame 210 is provided with a serrated frame side upward rotation block 212 and a triangular block shape frame side downward rotation block 213.

To explain this in more detail, the frame side upward rotation block 212 is formed in a sawtooth shape continuous to the lower end of the inner frame 210, the body side upward rotation block 112 when the frame 210 is raised By sliding it serves to allow the frame 210 to rotate. To this end, the frame-side upward rotation block 212 is formed to protrude in a sawtooth shape on the inner periphery of the lower end of the frame 210, and is formed vertically from the lower end of the frame 210, and inclined downward from the upper end of the longitudinal plane. It is configured to include an inclined surface. At this time, the vertical surface and the inclined surface of the frame-side upward rotation block 212 are formed to be engaged with the longitudinal surface and the inclined surface of the body-side upward rotation block 112, respectively, when the frame 210 is fully raised, the forming direction of each inclined surface is It is formed in the same direction as the rotation direction of the frame 210. In other words, the vertical surface of the frame-side upward rotation block 212 is in close contact with the longitudinal surface of the body-side upward rotation block 112 when the frame is raised, thereby determining the angle at which the frame 210 rotates once when the frame 210 is pulsated up and down. The inclined surface of the frame-side upward rotation block 212 determines the rotation direction so that the frame 210 can continue to rotate in the same direction at the time of rotation.

The frame-side upward rotation block 212 slides due to buoyancy in a state where the inclined surface of the body-side upward rotation block 112 and the inclined surface of the frame-side upward rotation block 212 are shifted from each other when the frame 210 is raised. As a result, the frame 210 is configured to rotate about the body 110 as a result, and when the frame 210 is lowered at the same position when the frame 210 is raised and lowered, the body side of the upwardly rotating block 112 again rises. Since the inclined surface and the inclined surface of the frame-side upward rotation block 212 are meshed again without being misaligned with each other, the frame 210 cannot be rotated.

Accordingly, the frame 210 can be rotated in the rotational direction even when the frame 210 is lowered, so that the frame 210 can be continuously rotated when the frame 210 performs the pulsating motion of repeatedly raising and lowering. A separate rotation configuration is needed.

In order to achieve the above object, in the present invention, the frame 210 further includes a frame side downward rotation block 213.

The frame-side downward rotation block 213 is provided to correspond to each other in the same number as the teeth of the frame-side upward rotation block 212 on the inner circumference of the frame 210, so that the frame 210 can rotate when descending. Play a role. To this end, the frame-side downward rotation block 213 is formed to protrude in a triangle on the inner periphery of the frame 210, and comprises a vertical vertical surface and an inclined surface formed to be inclined upward from the lower end of the vertical surface. At this time, the inclined surface of the frame-side downward rotation block 213 rotates the frame 210 a predetermined angle about the body 110 when the frame 210 is lowered, so that the frame-side upward rotation block when the frame 210 is raised again 212 and the body-side upward rotation block 112 to slide against each other inclined surface.

Therefore, when the frame 210 descends, the inclined surfaces of the frame side downward rotation block 213 and the body side downward rotation block 113 slide with each other, and the frame 210 rotates, thereby causing the frame side upward rotation block 212. The inclined surface and the inclined surface of the body-side upward rotation block 112 does not overlap with each other when viewed from above, so that the inclined surface and the body-side upward rotation block 112 of the frame-side upward rotation block 212 at the time of rise of the frame 210. The inclined surfaces of the sliding surfaces come into contact with each other and are rotated by buoyancy. By repeating this process, the frame 210 can pulsate up and down and continuously rotate.

Meanwhile, the frame side upward rotation block 212 may have the same thickness as the sum of the thicknesses of the body side upward rotation block 112 and the body side downward rotation block 113 so that the frame 210 may be as close as possible to the body 110. The thickness of the frame-side downward rotation block 213 is preferably formed to have the same thickness as the body-side downward rotation block 113, but is not limited thereto.

In addition, the body side upward rotation block 112 so that the direction in which the frame 210 rotates when the frame 210 is rotated and the direction in which the frame 210 rotates when the frame 210 is rotated in the same direction are mutually rotated. ), The body-side downward rotation block 113, the frame-side upward rotation block 212 and the frame-side downward rotation block 213 forming direction is preferably determined, but is not limited to this, the frame 210 It is a matter of course that the agitation of the raw water in the body 110 can be implemented in various forms by reversing the rotational direction of the rising and falling.

The shaft support 221 has a plurality of radially extending from the inner peripheral upper end of the frame 210 into the frame 210 to have a radial shape, and the shaft 220 is fixed to the center frame 210 so that the shaft 220 is fixed to the center. To lock in place.

The lower end of the shaft support 221, like the blade 230 to be described below, some of the rising bubbles may be collected.

On the other hand, bubbles rising from the bottom is mostly passed through the hollow portion inside the body 110, the upper part of the blade 230 is preferably collected only at the lower end of the blade 230 or the lower end of the shaft support 221. This is to prevent the phenomenon that the acid base portion is not lowered by the bubble because there are a lot of bubbles rising from the bottom, so that only a portion of the air bubble 200 is a pulsating motion.

The shaft 220 is fixedly installed downward from the frame 210 by the shaft support 221, and serves to fix the blade 230. To this end, the shaft 220 is configured to further include a joint 221, the joint 221 is formed detachably in a form that is fixed through the shaft 220, four blades 230 cross-shaped To be coupled to the axis 220 in a radial or symmetrical manner. At this time, the joint 221 is fixed to the mutual installation angle is shifted so that the blades 230 coupled to each joint 221 does not overlap each other when viewed from above. This is to allow the bubbles split by the lower blade 230 to be split again by the upper blade 230, and the number of layers of the blade 230 and the angle between the blades 230 vary depending on the required dissolved oxygen amount in the aerobic tank. Can be changed.

On the other hand, the lower end of the shaft 220 is coupled to the head end of the window 240, the head 240 is positioned above the air pipe 150 vertically so that the bubble supplied from the air pipe 150 is the head 240 To be split first.

The blade 230 is coupled to the shaft 220 by the joint 221 to serve to chop the bubbles rising from the bottom. To this end, the blade 230 includes a blade-shaped blade body 231 and blade grooves 232 formed on both sides of the blade body 231.

The lower end of the blade body 231 is formed in the shape of a sharp blade so that bubbles rising from the bottom can be contacted and split, and the upper end portion is formed thicker and thicker so that the upper end portion is formed thicker than the lower end portion. The blade body 231 has a shape that is bent upward toward the outside in order to prevent attachment of contaminants such as hairs, which may be included in raw water. In addition, the blade body 231 may be formed such that the length of the cross section becomes shorter toward the outside.

The blade 230 may also be formed with a blade groove 232 in the blade body 231 to better break the air bubbles, the blade groove 232 is a circular groove by the groove from the upper side to the lower end of the blade body It can be shaped like a carving knife. The blade groove 232 may be configured to adjust the movement distance of the split bubbles so that the split bubbles are lifted up the side of the blade body 231 when the bubbles are split by the blade body 231 so that they do not merge again at the top of the blade body 231. As a configuration for different from each other, it is preferable to alternately form the blade body 231 to the left and right to be zigzag alternately to the left and right. Therefore, when the blade body 231 is viewed from below by the blade groove 232, the blade shape of the lower end of the blade body 231 is formed in a zigzag like a knives.

The blade groove 232 also serves to remove the foreign matter of the blade 230 by inducing the vortex of the raw water when the blade 230 ascends and descends, the effect of further air bubbles by the vortex generated at this time Can be generated.

These blades 230 are four are fixedly coupled to the shaft 220 by a pair of joints 221 to form a single layer, the installation angle of the blades 230 for each floor is installed so as not to overlap each other when viewed from above It is preferable to do so, so that the bubbles that are split and rise by the lower blade 230 can be split again by the upper blade 230.

On the other hand, the blade 230 is installed on the lowermost layer is the shortest and the length of the blade 230 is preferably configured to be longer as you go up the upper layer, which is involved in the process of the bubble split by the head 240 rises This is to more smoothly the pulsating motion of the radiator 200 by excluding the range that does not.

On the other hand, in addition to the bubbles moved upward by the blade 230, bubbles are attached to the side of the blade body 231, etc., most of the bubbles are raised to the top via the blade 230, but these attached few The buoyancy is generated in the blade 230 by the bubble. Therefore, the shaft 220 to which the blade 230 is coupled is also lifted by the buoyancy force acting on the blade 230, and the frame 210 coupled to the shaft 220 is also lifted upward.

Looking at the action of the diffuser 200 made of the above-described configuration, some of the air bubbles chopped by the blade 230 accumulates on the side of the blade 230 or the lower end of the shaft support 221 to gain buoyancy and rise During the ascending, the inclined surface of the frame-side upward rotation block 212 of the frame 210 comes in contact with the inclination surface of the body-side upward rotation block 112 to slide and rotate, and the vertical surface of the frame-side upward rotation block 212 is raised. When the frame side upward rotation block 212 and the body side upward rotation block 112 are completely engaged with each other, when the vertical surface of the body side upward rotation block 112 is in close contact with each other, the rotational ascending speed of the frame is increased. Becomes 0 and bubbles generated in the blades 230 and the shaft support 221 are separated by the impact generated, and thus the diffuser 200 loses buoyancy and descends. During the descending of the diffuser 200, the inclined surface of the frame side downward rotation block 213 of the frame 210 comes into contact with the inclined surface of the body side downward rotation block 113, slides and rotates, and is lowered, and the lower end of the frame 210. Alternatively, the lower end of the frame-side upward rotation block 212 is caught by the lower end of the body step 111 of the body 110, and the lowering movement is finished. The descending portion 200 is completed by the falling silver is raised by some of the bubbles rising from the bottom again, and rotates around the body to move up and down.

The diffuser 200 is rotated around the body 110 while the pulsating movement of the ascending and descending repeats, so the blade 230 also serves to stir the raw water in addition to the splitting of the air bubbles finely. It can be done in parallel.

In addition, when the agitator 200 agitates the raw water by pulsation and rotation while discharging bubbles, the raw water inside the body 110 of the supply unit 100 rises to the top, and the raw water outside the body 110 is lowered. The lower portion of the body 110, the lower end of the circumference in the form of a skirt so as to be mixed with the bubbles and discharged to the top to discharge the upper portion may take the shape that gradually increases in diameter. The skirt-like body 110 has a side effect of causing a synergistic effect by collecting the air bubbles in the lower end portion to the upper end portion to smoothly stir in the aerobic tank.

100: supply unit 110: body
112: body side upward rotation block 113: body side downward rotation block
120: body hole 150: air pipe
200: diffuser 210: frame
212 frame side upward rotation block 213 frame side downward rotation block
220: axis 221: joint
230: Blade

Claims (13)

A supply unit including a cylindrical body and an air pipe provided at a lower end of the body to supply bubbles into the body; And
A ring-shaped frame which is lifted up and down by air bubbles supplied to the body and supplied inside the body, and surrounds the body, an axis provided inside the frame, and a shaft support fixing the axis to the frame. And a blade coupled to the shaft, the blade comprising a blade that splits the bubble that is supplied from the supply and rises.
Low energy micro-bubble generating device, characterized in that configured to include. The method of claim 1,
The diffuser, low energy micro-bubble generating device characterized in that the plurality of blades are coupled to the axis in a radial or symmetrical manner. 3. The method of claim 2,
The diffuser unit, the low-energy micro-bubble generating device further comprises a removable joint for coupling the blade to the shaft. The method of claim 3, wherein
The diffuser is provided with a plurality of joints, so that the blade forms a plurality of layers, the low-energy microbubble generating apparatus. 5. The method of claim 4,
The diffuser is a low-energy microbubble generator, characterized in that the blades of each layer are configured so as not to overlap each other when viewed from above. The method of claim 5, wherein
The diffuser, low-energy microbubble generating device, characterized in that the blade length of the upper layer is formed longer than the blade length of the lower layer. The method of claim 1,
The blade body lower end of the blade is formed in a sharp blade shape, the low-energy microbubble generating apparatus, characterized in that the thickness of the upper end is formed thicker than the thickness of the lower end. The method of claim 7, wherein
The blade is a low-energy microbubble generating device, characterized in that the blade groove is formed from the side of the blade body to the lower end. The method of claim 1,
The body is configured to further include a serrated body-side upward rotation block on the outer periphery, the frame is configured to further include a serrated frame-side upward rotation block on the inner periphery,
The body side upward rotation block is formed to protrude in a sawtooth shape continuous to the outer periphery of the body, and comprises a vertical vertical surface, and the inclined surface formed to be inclined upwardly from the lower end of the vertical surface,
The frame side upward rotation block is formed to protrude in a sawtooth shape continuous to the inner circumference of the frame, and comprises a vertical vertical surface and an inclined surface formed to be inclined downward from the upper end of the vertical surface,
And an inclined surface of the frame-side upward rotating block and an inclined surface of the body-side upward rotating block are in close contact with each other when the frame is raised, thereby sliding the frame about the body. The method of claim 9,
The body is configured to further include a triangular block-shaped body-side down rotation block on the outer periphery, the frame is configured to further include a frame-side down rotation block of the triangular block shape on the inner periphery,
The body side downward rotation block is configured to include a vertical surface and an inclined surface formed to be inclined downward from the upper end of the vertical surface,
The frame side downward rotation block is configured to include a vertical surface and an inclined surface formed to be inclined upwardly from the lower end of the vertical surface,
When the frame is lowered, the inclined surface of the frame-side downward rotation block and the inclined surface of the body-side downward rotation block is in close contact with each other and slide, so that the frame is rotated around the body. 11. The method of claim 10,
Low energy micro-bubble generating device, characterized in that the direction of rotation when the frame is raised and the direction of rotation when the frame is lowered. The method of claim 1,
The body is a low-energy micro-bubble generating device, characterized in that the diameter of the lower end portion is widened toward the lower portion. The method of claim 1,
The supply unit further comprises a pipe support extending from the inner circumference of the body to fix the air pipe inside the body, the air pipe and the air to adjust the bubble supply position of the air pipe up and down Low-energy micro-bubble generator, characterized in that further comprising a length adjusting portion between the pipe support.

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