KR101114524B1 - Air supply device - Google Patents

Abstract

PURPOSE: An air supplying apparatus is provided to increase the contact frequency of air and wastewater by preventing the rotating orbits of a plurality of air discharging holes on a wing part from being overlapped. CONSTITUTION: An air supplying apparatus includes a water storing tank(100), a rotary shaft(200), an air supplying part(400), a wing part(500), and a driving part(600). The water storing tank includes a water storing space(110). The rotary shaft is installed in the water storing tank, and a hollow part is formed in the rotary shaft. The air supplying part supplies air to the hollow part. The wing part includes a plurality of stirring wings. The driving part rotates the rotary shaft. The stirring wings are radially expanded based on the rotary shaft. A plurality of air discharging holes of intervals is formed along the longitudinal directions of the stirring wings.

Description

Air supply device

The present invention relates to an air supply device and to an air supply device for supplying air to a device for treating organic wastewater.

There are various methods of treating various kinds of household wastewater, livestock wastewater, wastewater discharged from various factories, and leachate generated from various landfills, such as chemical treatment, biological treatment, and a combination thereof.

As a chemical treatment method, as disclosed in Patent Publication No. 96-9386, after the leachate is reacted with the iron salt-based chemicals, the step of condensation using a polymer coagulant and the precipitated suspended solids precipitated, and the step of filtering and removing the fine suspended solids And, there is a leachate treatment method of the inorganic sludge landfill site consisting of a step of oxidizing with a chlorine-based oxidant, and adjusting the pH.

Biological treatment, in particular, the treatment of wastewater using aerobic microorganisms removes various organic substances contained in the wastewater by ingesting them in the aeration tank in the presence of dissolved oxygen. Most of them are oxidized, decomposed, aggregated, and adsorbed. And physical and chemical treatments such as precipitation. Generally these

The method is called biologically active sludge method.

There are various methods of the biologically active sludge method, but in each method, the microorganisms present in the influent wastewater ingest and decompose organic substances to supply oxygen required for powder growth.

As an oxygen supply method, a method of injecting oxygen into wastewater using a surface aeration device or blowing fine bubble air or pure oxygen into water using various acidic devices is used.

However, as in the conventional method of supplying oxygen, a structure in which an air discharge port is introduced into water and then oxygen is supplied to the pipe, and since oxygen is simply raised to the surface at a predetermined position, air bubbles are not generated. In the non-formed portion, there is a disadvantage in that oxygen is not dissolved.

Even in the case of the structure of rotating the pipe in the waste water, the rotation trajectory of the air outlet formed in the pipe is the same or overlapping, there is a disadvantage that the oxygen solubility is low because oxygen is not evenly distributed in the waste water.

An object of the present invention is to provide an air supply device capable of increasing the amount of dissolved oxygen in the waste water by evenly distributing air in the tank containing the waste water.

An air supply device according to the present invention for achieving the above object is a storage tank provided with a storage space, a rotating shaft rotatably installed in the storage tank and a hollow portion formed therein, and air to supply air to the hollow portion It is connected to the lower portion of the supply shaft, and is installed adjacent to the bottom of the water storage tank is formed on a plane orthogonal to the longitudinal direction of the rotation axis and extends radially around the rotation axis and the hollow portion and An air passage communicating with the air is formed, and the outer circumferential surface includes a plurality of stirring vanes formed with a plurality of air discharge holes spaced apart from each other along the longitudinal direction such that air moving from the hollow portion to the air passage is discharged into the water storage space. A driving unit coupled to an upper portion of the blade and the rotary shaft to rotate the rotary shaft; The distance from the center of the rotation shaft to the respective air discharge holes is set differently so that the rotation trajectories of the respective air discharge holes do not overlap each other when rotated by the rotary shaft.

The wing portion includes a first stir blade, a second stir blade, a third stir blade and a fourth stir blade disposed at a predetermined angle, and the first stir blade includes a plurality of first air discharge holes at the center of the rotation shaft. A first distance along the longitudinal direction of the first stirring blade at a position spaced apart from the first distance from the first stirring blade, and the second stirring blade has a plurality of second air discharge holes at a second distance from the center of the rotating shaft. The second stirring blade is formed to be spaced apart by a second interval along the longitudinal direction of the second stirring blade, and the third stirring blade is a position where a plurality of third air discharge holes are spaced apart from the center of the rotation axis by a third distance In the third stirring blade is formed spaced apart by a third interval in the longitudinal direction, the fourth stirring wing has a plurality of fourth air discharge holes by a fourth distance from the center of the rotation axis It is formed to be spaced apart by a fourth interval in the longitudinal direction of the fourth stirring blade in the spaced position, wherein the first distance, the second distance, the third distance and the fourth distance are each set to a different length, The first interval, the second interval, the third interval, and the fourth interval are set to the same length.

The wing portion includes a first stir blade, a second stir blade, a third stir blade and a fourth stir blade formed in a direction orthogonal to each other on a plane orthogonal to a longitudinal direction of the rotation axis, wherein the first stir blade includes: A plurality of first air discharge holes are formed to be spaced apart by a first interval in the longitudinal direction of the first stirring blade at a position spaced apart from the center of the rotation axis by a first distance, the second stirring blade in the plurality of second Air discharge holes are formed to be spaced apart by a second interval in the longitudinal direction of the second stirring blade at a position spaced apart from the center of the rotation axis by a second distance, the third stirring blade has a plurality of third air discharge holes The third stirring blade is formed to be spaced apart from the center of the rotation axis by a third distance along the longitudinal direction of the third stirring blade, and the fourth stirring blade is a plurality of fourth Air discharge holes are formed to be spaced apart by a fourth interval in the longitudinal direction of the fourth stirring blade at a position spaced apart by a fourth distance from the center of the rotation axis, the first distance, the second distance and the third distance And the fourth distance is set to the same length, and the first interval, the second interval, the third interval, and the fourth interval are each set to different lengths.

The wing part includes a first wing part and a second wing part spaced apart at predetermined intervals along an axial direction of the rotation shaft, and the first wing part and the second wing part are installed to cross each other.

According to the air supply device according to the present invention, the plurality of air discharge holes provided in the wing portion while the wing portion is rotated by the rotation axis to form the rotation trajectories through the entire reservoir space without overlapping each other air discharge holes The frequency of contact between the air discharged from the wastewater and the wastewater contained in the reservoir can be increased.

Accordingly, as the frequency of contact between air and wastewater increases, the amount of oxygen that can be dissolved in the wastewater increases, thereby increasing the dissolved oxygen contained in the wastewater.

1 is a schematic view showing an air supply apparatus according to a first embodiment of the present invention,
2 is a plan view showing the rotational trajectory of the wing portion and the air discharge holes of FIG.
3 is a plan view showing another embodiment of the wing unit according to the present invention,
Figure 4 is an excerpt perspective view showing another embodiment of the wing unit according to the present invention,
Figure 5 is a side view showing another embodiment in which the nozzle unit is mounted to the air discharge hole of the wing portion shown in FIG.

Hereinafter, an air supply apparatus according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 to 2 show an air supply apparatus according to a first embodiment of the present invention.

1 to 2, the air supply device includes a water storage tank 100, a rotation shaft 200, an air supply unit, a wing unit 500, and a driving unit 600.

The reservoir tank 100 has a cylindrical shape with an open upper portion, and a reservoir space 110 is formed to accommodate livestock wastewater, industrial wastewater (hereinafter referred to as 'wastewater'), and the like.

In the storage space 110, a support frame 120 extending from one side of the storage tank 100 to the other side across the center is fixed at a position spaced apart from the bottom of the storage tank 100 by a predetermined height. The support frame 120 is preferably formed to have a predetermined width so that the support member 240 and the driver 600 which will be described later are installed.

The rotary shaft 200 is rotatably installed on the support member 240 fixed on the support frame 120, the hollow portion 210 is formed therein and the top is closed, the upper portion of the drive unit 600 to be described later A driven sprocket 230 coupled to the chain 630 to rotate in conjunction with the drive motor 610 is coupled.

The support member 240 is screwed onto the support frame 120 and is coupled through the bearing and the rotating shaft 200 so that the rotating shaft 200 is rotatable.

The upper portion of the rotary shaft 200 is coupled to the rotary connecting member 300 for supplying air to the hollow portion 210 of the rotary shaft 200 from the air supply unit 400 to be described later without being rotated in conjunction with the rotary shaft 200 . In this embodiment, the rotary connection member 300 may be a rotary joint.

One side of the rotary connection member 300 is coupled to the air supply.

The air supply unit supplies air to the hollow portion 210 of the rotating shaft 200, and the air supply tank 410 and the air supply tank 410 are coupled to one end and the other end of the coupling groove 320 of the rotary connection member 300. It is fastened to the) includes a transfer pipe 420 for transferring air from the air supply tank 410 to the receiving space (310).

The wing 500 is coupled to the lower portion of the rotation shaft 200 is installed adjacent to the bottom of the water storage tank 100, is formed on a plane orthogonal to the longitudinal direction of the rotation shaft 200 and the rotary shaft 200 It includes a plurality of stirring wings extending radially to the center.

Each stirring wing has an air passage communicating with the hollow portion 210 therein, respectively, along the extending direction, and the air moving from the hollow passage 210 to each air passage on the outer circumferential surface of the reservoir space 110 from the air passage. Air discharge holes are discharged to each other are formed to be spaced apart from each other along the longitudinal direction of the stirring blades.

As shown, the air discharge holes may be formed in the upper portion of each stirring blade, or alternatively, may be formed in the lower portion of the stirring blade.

When the wing unit 500 is rotated by the rotation shaft 200, the distances from the center of the rotation shaft 200 to the respective air discharge holes are set differently so that the rotation trajectories of the air discharge holes do not overlap each other.

The wing part 500 may include a first stir blade 510, a second stir blade 520, a third stir blade 530, and a fourth stir blade 540 disposed to be spaced apart from each other at a predetermined angle. Include.

The first stirring blade 510 has a plurality of first air discharge holes 511 in the longitudinal direction of the first stirring blade 510 at a position spaced apart from the center of the rotation shaft 200 by a first distance X1. As a result, they are formed to be spaced apart by the first interval Y1.

The second stirring blade 520 has a plurality of second air discharge holes 521 along the longitudinal direction of the second stirring blade 520 at a position spaced apart from the center of the rotation shaft 200 by a second distance X2. It is formed to be spaced apart by the second interval Y2.

The third stirring blade 530 has a plurality of third air discharge holes 531 in the longitudinal direction of the third stirring blade 530 at a position spaced apart from the center of the rotation shaft 200 by a third distance X3. As a result, they are formed to be spaced apart by the third interval Y3.

The fourth stirring blade 540 has a plurality of fourth air discharge holes 541 extending in the longitudinal direction of the fourth stirring blade 540 at a position spaced apart from the center of the rotation shaft 200 by a fourth distance X4. As a result, they are formed to be spaced apart by the fourth interval Y4.

Here, the first distance (X1), the second distance (X2), the third distance (X3) and the fourth distance (X4) are set to different lengths, respectively, the first interval (Y1) and the second interval ( Y2), the third interval Y3 and the fourth interval Y4 are set to the same length.

In the first stirring blade 510, the first distance X1, which is the distance from the first air discharge hole 511, which is located closest to the central axis of the rotation shaft 200, and the fourth stirring blade 540. The first air discharge hole 541 of the first stir blade 510 has a difference of the fourth distance X4 which is a distance from the fourth air discharge hole 541 located at the closest distance from the central axis of the rotation shaft 200. It is preferable to form shorter than the space | interval Y1 of the inside.

When the difference between the first distance X1 and the fourth distance X4 is longer than the first distance Y1, the third air discharge holes 531 of the third stirring blade 530 or the fourth stirring blade ( This is to prevent the rotation trajectories of the fourth air discharge holes 541 of the 540 and the rotation trajectories of the first air discharge holes 511 of the first stir blade 510 overlap.

As shown in the drawing, the rotation trajectories of the first air discharge holes 511 of the first stir blade 510 are rotated and the second trajectories of the second air discharge holes 521 of the adjacent second agitator wings 520. The rotational trajectories of the fourth air discharge holes 541 of the four stirring blades 540 are set so as not to overlap.

That is, each air discharge hole of each stirring blade is formed so as to have the same distance along the longitudinal direction of each stirring blade from the position away from each other from the rotation axis 200, so that each stirring when rotated by the rotating shaft 200 Rotational trajectories of the air exhaust holes of the blades do not overlap each other.

According to the air supply device according to the present invention as described above, while the wing portion 500 is rotated by the rotation shaft 200, a plurality of air discharge holes form rotation trajectories through the entire storage space 110 without overlapping each other. Therefore, the frequency of contact between the air discharged from the respective air discharge holes and the wastewater accommodated in the storage space 110 may be increased.

Accordingly, as the frequency of contact between the air and the wastewater increases, oxygen that can be dissolved in the wastewater also increases, thereby increasing the dissolved oxygen contained in the wastewater.

On the other hand, the wing 500 is not limited to the structure having only four stirring wings as shown, a structure having a smaller or more number of stirring wings may be applied.

The driving unit 600 includes a driving motor 610, a driving sprocket 620, and a chain 630.

The drive motor 610 is fixed to the support frame 120, the drive sprocket 620 is coupled to the shaft of the drive motor 610, the chain 630 is driven sprocket 230 and the drive sprocket 620 ) Are combined.

3 shows another embodiment of the wing 500.

The wing part 500 includes a first stir blade 510, a second stir blade 520, a third stir blade 530, and a fourth stir blade 540.

Each stirring blade is formed in a direction orthogonal to each other on a plane orthogonal to the longitudinal direction of the rotating shaft 200 and has a different number of air discharge holes.

The first stirring blade 510 includes a plurality of first air discharge holes 511 along a length direction of the first stirring blade 510 at a position spaced apart from the center of the rotation shaft 200 by a first distance X1. It is formed to be spaced apart by one interval Y1.

The second stirring blade 520 includes a plurality of second air discharge holes 521 along the length direction of the second stirring blade 520 at a position spaced apart from the center of the rotation shaft 200 by a second distance X2. It is formed so as to be spaced apart by two intervals Y2.

The third stirring blade 530 includes a plurality of third air discharge holes 531 along the longitudinal direction of the third stirring blade 530 at a position spaced apart from the center of the rotation shaft 200 by a third distance X3. It is formed so as to be spaced apart by three intervals Y3.

The fourth stirring blade 540 includes a plurality of fourth air discharge holes 541 along the longitudinal direction of the fourth stirring blade 540 at a position spaced apart from the center of the rotation shaft 200 by a fourth distance X4. It is formed to be spaced apart by four intervals Y4.

Here, the first distance (X1), the second distance (X2), the third distance (X3) and the fourth distance (X4) are set to the same length, and the first interval (Y1) and the second interval (Y2) and The third interval Y3 and the fourth interval Y4 are set to different lengths, respectively. Here, the first interval Y1, the second interval Y2, the third interval Y3, and the fourth interval Y4 are preferably set to a number where multiples of the intervals do not overlap each other.

As shown in the drawing, the air discharge holes of each of the stirring blades located at the closest distance to the rotating shaft 200 are all formed at the same distance from the rotating shaft 200, but the respective air discharge holes formed in the respective stirring wings are mutually The intervals between the two are set differently so that the rotation trajectories of the air discharge holes of the respective stirring blades do not overlap.

4 shows another embodiment of the wing 500.

Referring to FIG. 4, the wing part 500 includes a first wing part 550 and a second wing part 560 spaced apart at predetermined intervals along the longitudinal direction of the rotation shaft 200, and the first wing part. The 550 and the second wing 560 are provided to cross each other.

The first wing 550 is the first stirring blade 510 and the third stirring blade 530 extending in a direction away from each other to the center of the rotation axis 200 at a position spaced apart from the lower end of the rotation axis 200 by a predetermined height The second blade portion 560 is coupled to the lower end of the rotary shaft 200, the second stirring blade 520 and the fourth stirring blade 540 extending in a direction away from the center of the rotary shaft 200; Include.

The first stirring blade 510 has a plurality of first air discharge holes 511 in the longitudinal direction of the first stirring blade 510 at a position spaced apart from the center of the rotation shaft 200 by a first distance X1. As a result, they are formed to be spaced apart by the first interval Y1.

The second stirring blade 520 includes a plurality of second air discharge holes 521 along the length direction of the second stirring blade 520 at a position spaced apart from the center of the rotation shaft 200 by a second distance X2. It is formed so as to be spaced apart by two intervals Y2.

The third stirring blade 530 includes a plurality of third air discharge holes 531 along the longitudinal direction of the third stirring blade 530 at a position spaced apart from the center of the rotation shaft 200 by a third distance X3. It is formed so as to be spaced apart by three intervals Y3.

The fourth stirring blade 540 has a plurality of fourth air discharge holes 541 along the longitudinal direction of the fourth stirring blade 540 at a position spaced apart from the center of the rotation shaft 200 by a fourth distance X4. It is formed to be spaced apart by the fourth interval Y4.

Here, the first distance (X1), the second distance (X2), the third distance (X3) and the fourth distance (X4) are set to have different lengths, respectively, the first interval (Y1) and the second interval (Y2), the third interval Y3 and the fourth interval Y4 are set to have the same length.

The distance from the first air discharge hole 511 located at the closest distance from the central axis of the rotary shaft 200 in the first stirring blade 510, that is, the first distance X1 and the fourth stirring blade 540 The difference of the fourth distance X4, which is the distance from the fourth air discharge hole 541 located at the closest distance from the central axis of the rotating shaft 200, is the first air discharge hole 511 of the first stir blade 510. It is preferable to form shorter than the space | interval Y1.

Although not shown in the drawings, the rotation trajectories of the plurality of air discharge holes formed in the first wing part 550 do not overlap with the rotation trajectories of the plurality of air discharge holes formed in the second wing part 560. Rotation trajectories of the air discharge holes of the first stirring blade 510 and the third stirring wing 530 are also not overlapped with each other, and rotation trajectories of the air discharge holes of the second stirring blade 520 and the fourth stirring wing 540 are not overlapped with each other. They do not overlap with each other.

On the other hand, each air discharge hole of the wing portion 500 may be further provided with a nozzle unit 700. Referring to FIG. 5, the nozzle unit 700 is coupled to the air discharge hole, and a screw coupling part 710 having a through hole 700a formed therein to allow air to be discharged from the air passage 500a of the wing part 500. ) And the expansion portion 720 and the inner circumferential side of the expansion portion 720 which are radially expanded and conical to expand the area of the through hole 700a from the screwing portion 710 to connect the through hole 700a. And a closing plate 730 for closing. Here, a screw thread is formed on the inner circumferential surface of the air discharge hole of the wing part 500 so as to be screwable with the screw coupling part 710.

A plurality of protrusions 721 are formed at regular intervals along the circumferential direction of the lower end of the expansion part 720 to provide air supplied from the air supply part in the form of small air bubbles.

The closing plate 730 is to prevent the wastewater, etc. inside the water storage tank 100 from flowing into the air passage 500a, and corresponds to the shape of the expansion part 720 so as to be in close contact with the inner circumferential surface of the expansion part 720. It is formed to be screwed and supported by the support member 740 extending downward from the inner circumferential surface of the screw coupling portion 710 toward the expansion portion 720 direction. The closing plate 730 is preferably formed of a rubber material having a flexible and elastic force.

When air reaches the expansion portion 720 from the air passage 500a through the passage hole 700a, pressure is generated in the passage hole 700a and when the pressure in the passage hole 700a reaches a predetermined level or more. Air in the through hole 700a moves downward toward the lower portion of the expansion portion 720 while pushing the closing plate 730 downward. At this time, the air passing through the closing plate 730 is crushed into a plurality of fine air bubbles by the projections 721 provided on the lower end of the expansion portion 720.

The air supply apparatus of the present invention described above has been described with reference to one embodiment shown in the drawings, but this is merely exemplary, and those skilled in the art will appreciate that various modifications and equivalent embodiments of the present disclosure are I understand that it is possible.

Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

100: reservoir
200: rotation axis
300: rotary connection member
400: air supply unit
500: wing
510: stir wing
520: second stirring wing
530: third stirring wing
540: fourth stirring wing
600: drive unit

Claims (4)

delete A storage tank provided with a storage space;
A rotating shaft rotatably installed in the water storage tank and having a hollow portion formed therein;
An air supply unit supplying air to the hollow part;
It is coupled to the lower portion of the rotary shaft is installed adjacent to the bottom of the water storage tank, is formed on a plane orthogonal to the longitudinal direction of the rotary shaft and extends radially around the rotary shaft and communicates with the hollow portion therein An air passage is formed and a wing portion having a plurality of agitating wings formed on the outer circumferential surface of the plurality of air discharge holes spaced apart from each other along the longitudinal direction such that air moving from the hollow portion to the air passage is discharged to the water storage space. Wow;
And a driving unit coupled to an upper portion of the rotating shaft to rotate the rotating shaft.
When the wing portion is rotated by the rotary shaft, the first stirring blade, the second stirring blade, and the first stirring blade having different distances from the center of the rotation shaft to the respective air discharge holes so that the rotation trajectories of the respective air discharge holes do not overlap each other. Including three stirring wings and the fourth stirring wings,
The first stirring wing is formed with a plurality of first air discharge holes spaced apart by a first interval in the longitudinal direction of the first stirring blade at a position spaced apart from the center of the rotation axis by a first distance,
The second stirring blade is formed to be spaced apart by a second interval along the longitudinal direction of the second stirring blade at a position spaced apart by a second distance from the center of the rotation axis, a plurality of second air discharge holes,
The third stirring blade is formed with a plurality of third air discharge holes spaced apart by a third interval along the longitudinal direction of the third stirring blade at a position spaced apart by a third distance from the center of the rotation axis,
The fourth stirring blade is formed to be spaced apart by a fourth interval along the longitudinal direction of the fourth stirring blade at a position spaced apart by a fourth distance from the center of the rotation axis, a plurality of fourth air discharge holes,
The first distance, the second distance, the third distance, and the fourth distance are each set to different lengths, and the first interval, the second interval, the third interval, and the fourth interval are set to the same length. ,
The screw portion is coupled to the air discharge hole, the screw coupling portion formed with a through hole to allow air to be discharged into the air discharge hole therein, and radially so that the area of the through hole is extended from the screw coupling portion An extension part which is formed in a conical shape and extended at a lower end, a closing plate coupled to an inner circumferential side of the expansion part to close the passage hole, and the screw coupling to support the closing plate on an inner circumferential surface of the extension part. And a nozzle unit comprising a support member extending downwardly of the portion. delete delete

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