KR100337533B1 - Micro bubble generator and air flotation system using the same - Google Patents

Abstract

The present invention relates to a micro-bubble generating device used in the induction air floating separation apparatus, and more particularly, having a plurality of sealing means and a fresh water supply means by the foreign matter contained in the waste water microbubble generating device It relates to a micro-bubble generating device that prevents the damage and the induced air floating separator using the same.

The present invention is an air tube to which the air is transported, a motor for rotating the air tube, the air injection wing is formed integrally at the bottom of the air tube to discharge the air at the same time stirring the waste water, rotatably supporting the air tube A micro-bubble generating device consisting of a plurality of bearings, a plurality of bearing housings for fixing the plurality of support tubes to protect the air tube at the same time the bearing is received, the protective cap coupled to the lower portion of the bearing housing, A first sealing means composed of a plurality of seals installed to prevent waste water from flowing into the protective cap; A second sealing means composed of a mechanical seal for preventing wastewater introduced into the protective cap from entering the bearing housing and damaging the bearing; It includes a fresh water supply means for supplying fresh water into the protective cap to prevent the waste water from flowing into the protective cap and to prevent the second sealing means from being damaged by excessive frictional heat.

Description

Micro bubble generator and air flotation system using the same

The present invention relates to a micro-bubble generating device used in the induction air floating separation apparatus, and more particularly, having a plurality of sealing means and a fresh water supply means by the foreign matter contained in the waste water microbubble generating device It relates to a micro-bubble generating device that prevents the damage and the induced air floating separator using the same.

Rapid industrial development has resulted in increased water consumption, causing water pollution in rivers and coastal areas. Therefore, various techniques for preventing water pollution are being developed, which are mainly based on physical, chemical and biological treatment. Air Flotation System is a technology for separating wastewater into solids and treated water by applying chemical and physical treatment methods.

In general, the flotation separator is to remove floating solids, oil components and colloidal substances contained in municipal sewage and industrial wastewater, and is particularly effective for removing suspended solids that are difficult to settle. In other words, by putting chemicals such as flocculant into the waste water to make the contaminants into small flocs, and supplying microbubbles in various ways to the lower part of the flotation tank to adsorb bubbles to the contaminant mass, the contaminants with high buoyancy surface It comes to mind. Then, to remove the scum with a scraper installed on the upper part of the float separation tank. Therefore, it is very important for the flotation separator to continuously generate fine bubbles of appropriate size and to evenly adsorb the solid particles.

Accordingly, the flotation separator is classified into a pressurized air flotation separator, a vacuum flotation separator, and an induction air flotation separator according to the method of supplying bubbles. The pressurized air flotation separator is configured to supply air to the pressurized tank using an air compressor or ejector. After the blow, the wastewater is introduced into a pressurized tank to dissolve air in the wastewater, and then sent to a separation tank to separate the flocculation tank and the reaction tank. In addition, the vacuum flotation device is a decompression method in the pressurized air flotation method, and when the wastewater is introduced into the flotation tank in a vacuum state, the saturated air is adsorbed to the solid particles in the form of small air bubbles, and the facility is complicated. It is difficult to operate and there is a problem of excessive investment.

1 is a cross-sectional view showing a conventional pressure flotation separation apparatus to which a pressurized air flotation method is applied, and as shown in the drawing, a cylindrical flotation separation tank 50 and a chamber (inside the upper portion of the flotation separation tank 50). 51 and the inner partition 52 formed higher than the level of the float separation tank 50, the storage tank 53 formed so as to receive the processing water overflowed from the floating separation tank 50, and the storage tank 53 The waste water is fixed in the discharge tank 56 and the floating separation tank 50 to supply the pressurized water generating device 55 and a part of the treated water discharged from the circulation through the circulation pipe (54). Consists of a bubble container 58 is connected to the inlet pipe (57) so that is drawn. In addition, the scum skimmer 61 is provided on the upper cover 60 of the storage tank 53 to push the scum floating by the air bubbles generated in the bubble tank 58 into the scum discharge cylinder 59. In addition, a bottom rotating bar 62 is installed to collect the sludge that sinks to the bottom of the floating separation tank 50, and a bottom plate 63 for collecting the sludge is installed.

On the other hand, the pressurized water generating device 55 is a pressurized water pipe 64 connected to the inlet pipe 57 and provided with a pressure reducing valve and a pressurized pump installed to supply pressurized water to the pressurized water pipe 64. 65), the pressure tank 66, and the like. In this way, the pressure flotation separator is not only complicated, but also requires a separate pressurized pump and a pressurized tank to supply high-pressure air to the flotation tank, which requires a lot of manufacturing cost and high power consumption. There is a problem.

On the other hand, the induction air floating separator separates the treated water and the solid by floating the solids by mixing them by mixing them with coagulant while making fine air bubbles in the micro bubble generator and supplying them to the wastewater. Since bubbles are generated, mixed with solids, bubbles are attached, and agglomerated at the same time, the operation is simple and unmanned automatic operation is possible, and the structure is simple, which reduces the required area of the treatment plant and maintains continuous processing efficiency. It is characterized by low operation and maintenance costs.

Therefore, various types of microbubble generators are installed in the guided air separation apparatus. FIG. 2 is a partially cut perspective view showing an example of the microbubble generator according to the prior art. As shown, the microbubble generating device 5 installs the air jet wing 15 at the bottom of the air tube 18 and the air jet wing when the motor 17 installed on the top of the air tube 18 operates. Atmospheric air is injected into the wastewater by the centrifugal force generated at (15), and at the same time, microbubbles are generated by the stirring action of the air jetting wings (15).

However, since the conventional micro bubble generator 5 is installed and operated in wastewater containing various foreign substances such as sand, plastic chips, metal powder, etc., the foreign matter contained in the wastewater and the wastewater may be air tubes 18 or bearings ( 13) to block the flow of air or to damage the bearing (13). Therefore, by installing a cap-shaped protective cap 30 at the end of the micro-bubble generating device 5 or by installing a plurality of seals in the lowermost bearing housing 14 to block the inflow of wastewater and foreign matter. However, these seals are worn out over time, so the operation must be stopped and replaced from time to time. If the management is incorrect, there is a problem that the waste water enters the bearing and breaks.

In order to solve the above-mentioned problems of the present invention, the main object of the present invention is to install the mechanical sealing means at the bottom of the bearing housing to compensate for the sealing of the microbubble generating device that wears out over time. In order to prevent the mechanical sealing means from being damaged by foreign matter or excessive frictional heat, it is to provide a micro bubble generator capable of continuously supplying fresh water to the mechanical sealing means.

In addition, the present invention by forming at least one air outlet in order to prevent the fresh water to be supplied to the mechanical sealing means in the early stage of the operation of the microbubble generating device by the air trapped in the chamber by the mechanical sealing means by excessive frictional heat It is to provide a micro-bubble generating device to prevent damage.

The present invention also uses a pressurized tank, a pressurized pump, etc. installed for supplying air by installing a microbubble generating device that adsorbs microbubbles to solids by agitating the wastewater and the microbubbles while simultaneously generating microbubbles on one side of the floating separation tank. Since it does not require a component such as a valve, it aims to provide an induction air floating separation device that simplifies the configuration and convenient operation and improved foreign matter removal efficiency.

1 is a cross-sectional view showing a pressurized air floating separator according to the prior art,

2 is a partially cut perspective view of a micro-air generator according to the prior art,

3 is a perspective view of a micro-air generator according to the present invention,

4 is a cross-sectional view of the micro-air generator according to the present invention,

5 is a partially enlarged cross-sectional view of the micro-air generator according to the present invention;

Figure 6 is a cross-sectional view showing the air discharge means applied to the micro-air generator according to the present invention;

7 is a cross-sectional view of the induction air floating separation apparatus according to the present invention,

8 is a plan view of the induction air floating separator according to the invention,

9 is a side view of the induction air floating separator according to the present invention.

* Explanation of symbols for the main parts of the drawings

5: fine air generator 12: support tube

13: bearing 14: bearing housing

15: Air jet wing 16: Suction hole

17: motor 18: air tube

19: communication hole 20: first sealing means

24, 25 sealing 35: chamber

43: purified water supply tube 70: retainer

73: air discharge means 80: second sealing means

83: spring 97,89: mechanical seal

101: flotation tank 102: first discharge screw

103: scraper 104: second discharge screw

In order to achieve the above object, the present invention is the air tube to which the air is transported, the motor for rotating the air tube, the air injection wing which is formed integrally with the lower end of the air tube to agitate the waste water at the same time to discharge the air, A microbubble generating device comprising a plurality of bearings rotatably supporting the air tube, and a plurality of bearing housings for holding the bearings and fixing a plurality of support tubes for protecting the air tubes. A first sealing means composed of a protective cap coupled to and a plurality of seals installed to prevent waste water from flowing into the protective cap; A second sealing means composed of a mechanical seal for preventing the wastewater introduced into the protective cap from being introduced into the bearing housing and coming into contact with the bearing; It comprises a fresh water supply means for preventing the waste water from flowing into the protective cap and at the same time prevent the second sealing means from being damaged by excessive frictional heat.

The present invention also comprises at least one air discharge means installed in communication with the protective cap to smoothly discharge the air trapped inside the protective cap.

The first sealing means according to the present invention comprises a protective cap coupled to the lower portion of the bearing housing, a central hole installed in the center of the protective cap so that the rotating air tube passes, the inner circumferential surface of the center hole and the outer circumferential surface of the air tube It comprises a sleeve provided between, and an inner seal provided on the inner peripheral surface of the sleeve and an outer seal provided on the outer peripheral surface.

In addition, the second sealing means according to the present invention is a retaining cap integrally coupled to the lower portion of the bearing housing, a protective cap to form a predetermined chamber between the air tube while being coupled to the lower portion of the retainer, and the chamber And a mechanical seal positioned within and installed in close contact with the retainer by a spring interposed between the retainer and the sleeve.

The present invention further includes a purified water supply means including a purified water supply tube and a purified water storage tank and pump in communication with the purified water supply tube installed to supply fresh water into the chamber formed by the protective cap.

In addition, the present invention is a rectangular floating separation tank, the first discharge screw is rotated by the motor to discharge the foreign matter is installed on the bottom surface of the above-mentioned floating separation tank, and the scum rising to the upper surface of the floating separation tank in one direction to push the A scraper installed on the upper surface of the floating separation tank, a second discharge screw rotated by a motor so as to discharge the scum pushed to one side by the scraper to the outside, and installed in the floating separation tank upright as well as external air It is characterized in that it comprises a micro-bubble generating device configured to supply air to the bottom of the floating separation tank by suction.

Hereinafter, with reference to the accompanying drawings will be described a specific embodiment of the micro-bubble generating device 5 and the induced air floating separator 100 according to the present invention. First, as shown in FIGS. 3 and 4, the microbubble generating device 5 according to the present invention includes an air tube 18 through which air is largely conveyed, and a motor 17 for rotating the air tube 18 at high speed. It is formed integrally with the lower end of the air tube 18, the air injection wing 15 and the air tube 18 to rotate the air injection wing (15) to generate fine bubbles by stirring the waste water at a high speed while at the same time suction / discharge the air by centrifugal force It consists of a plurality of bearings 13 to support the plurality of bearings, a plurality of bearing housings 14 for fixing the plurality of support tubes 12 for protecting the air tube 18 at the same time the bearing 13 is received.

That is, the microbubble generating device 5 according to the present invention has a support tube 12 that combines two hollow tubes having a predetermined length, and a plurality of bearings 13 therein while combining the support tube 12. It consists of a plurality of bearing housings 14 and air tubes 18 provided inside the support tube 12 so as to be rotatable by the bearing 13. And the air injection blade 15 is integrally installed at the end of the air tube 18 and the rotary shaft of the motor 17 is coupled to the other end to rotate the air dispersion blade 15 when the motor 17 is operated. It is configured to be.

At this time, the suction hole 16 through which the outside air can be introduced is formed at the upper end of the air tube 18, and the air injection wing 15 is composed of a plurality of rotary blades with a hollow formed therein, and the air dispersion wing 15 rotates. When the air of the atmosphere is sucked through the suction hole 16 and the air tube 18 is discharged into the waste water through the rotary blades of the air dispersal wing (15).

On the other hand, such a micro-bubble generating device (5) is installed in the floating separation tank, so that the air dispersion wing 15 and the lower bearing housing 14 and a portion of the support tube 12 is always operated in a state of submerged waste water. . Therefore, since the waste water and foreign matter contained in the waste water can flow into the bearing 13 of the bearing housing 14, the microbubble generating device 5 according to the present invention has double and triple sealing means.

That is, the first sealing means 20 according to the present invention is a protective cap 30 is coupled to the lower portion of the bearing housing 14, a plurality of installed to prevent the waste water flows into the protective cap 30 It is composed of a sealing, the second sealing means 80 is a retainer 70 for preventing the waste water introduced into the protective cap 30 is introduced into the bearing housing 14 to damage the bearing 13 ) And mechanical sealing. In addition, fresh water supply means 40 for preventing wastewater from flowing into the protective cap 30 and preventing the second sealing means from being damaged by excessive frictional heat, and air trapped inside the protective cap 30. It is composed of an air discharge means (73) to smoothly discharge the fresh water to flow smoothly.

4 and 5, the first sealing means 20 includes a protective cap 30 coupled to a lower portion of the bearing housing 14, and a rotating air tube 18 to penetrate. The center hole 31 installed in the center of the protective cap 30, the sleeve 23 provided between the inner peripheral surface of the center hole 31 and the outer peripheral surface of the air tube 18, and the sleeve 23 of It consists of an inner seal 24 provided on the inner circumferential surface and an outer seal 25 provided on the outer circumferential surface of the sleeve 23. That is, the first sealing means 20 is a sleeve (Sleeve) between the protective cap 30 and the air tube 18 in order to prevent waste water from flowing into the protective cap 30 installed under the bearing housing 14. It is sealing through 23). Meanwhile, the protective cap 30 is fixed through the fastening means 93.

In addition, the second sealing means 80 is formed between the retainer 70 integrally coupled to the lower portion of the bearing housing 14 and the air tube 18 while being coupled to the lower portion of the retainer 70. Mechanical seals 87 and 89 which are always in close contact with the retainer 70 by a protective cap 30 forming the chamber 35 and a spring 83 interposed between the retainer 70 and the sleeve 23. It is configured to include). Therefore, in the microbubble generating device 5 according to the present invention, even when the first sealing means 80 is worn out and the wastewater flows into the chamber 35, the foreign matter contained in the wastewater and the wastewater flows into the bearing housing 14. Prevent it.

That is, the seals 24 and 25 of the first sealing means 20 are gradually worn out as the air tube 18 rotates, so that the sealing ability decreases, and thus the inflow of wastewater cannot be completely blocked. However, since the mechanical seals 87 and 89 of the second sealing means 80 move toward the retainer 70 by the thickness worn by the restoring force of the spring 83, the waste water is prevented from entering the bearing housing 14. do.

On the other hand, when the air tube 18 rotates at a high speed while the inflow of wastewater is completely blocked by the first sealing means 20, excessive frictional heat is generated between the mechanical seals 87 and 89, The mechanical seals 87 and 89 can be fused. Therefore, it is necessary to absorb or reduce frictional heat by injecting a lubricating material into the mechanical seals 87 and 89. To this end, when petroleum-based lubricating oil is used, the lubricating oil flows into the wastewater according to the wear of the first sealing means 20. There is a problem that pollutes the waste water. Accordingly, the microbubble generating device 5 according to the present invention lubricates the mechanical seals 87 and 89 by supplying clean water, for example, tap water or purified water, into the protective cap 30.

For this purpose, as shown in FIGS. 3 and 5, the purified water supply tube 43 is installed outside the support tube 12 to supply fresh water to the interior of the chamber 35 formed by the protective cap 30. In addition, a purified water storage tank and a pump (not shown) are connected to the end portion thereof so that purified water can be supplied as necessary.

As such, when fresh water is supplied into the protective cap 30 sealed by the first sealing means 20 and the second sealing means 80 according to the present invention, the chamber 35 of the protective cap 30 is provided. The filled air is not discharged and moved to the upper portion of the chamber 35 to block the fresh water introduced into the mechanical seals 87 and 89. If the air tube 18 is rotated at a high speed in this state, a high temperature frictional force is generated in the mechanical seals 87 and 89 and serious damage occurs.

Therefore, the micro-bubble generating device 5 according to the present invention is provided with an air discharge means 73 so as to communicate with the protective cap so as to smoothly discharge the full air in the chamber 35 of the protective cap 30. As shown in FIG. 6, the air discharging means 73 is fixed to the porous filter 75 and the porous filter 75 having a plurality of fine pores in which air is smoothly discharged and fresh water is not discharged or introduced. It comprises a fastening bolt 76 that can be fastened to the air discharge path formed in the retainer 70 and a plurality of discharge holes 77 formed in the fastening bolt 76. Therefore, the air filled in the protective cap 30 is discharged to the outside through the porous filter 75 and the discharge hole 77 by increasing the internal pressure as fresh water is injected, while the external wastewater is porous filter It is prevented from entering inside by 75.

On the other hand, the sleeve 23 according to the present invention is a cylindrical cylindrical body formed with a seating groove in which a cylindrical spring 83 can be supported and seated on the inner circumferential surface and the outer circumferential surface of each of the plurality of annular seals 24 and 25. This is installed. And the inner circumferential surface of the retainer 70 is formed with a coupling portion in which the mechanical seal 89 is integrally coupled. The mechanical seals 87 and 89 are made of a ceramic material having excellent heat resistance and abrasion resistance.

7, 8, and 9 are cross-sectional views, a plan view, and a side view of the induction air floating separator 100 employing the microbubble generator 5 according to the present invention. And, the first separation screw 102 is installed on the bottom surface of the floating separation tank 101 to discharge the foreign substances falling, and the floating separation tank to push the scum rising to the upper surface of the floating separation tank 101 in one direction. (101) the scraper 103 installed on the upper surface, the second discharge screw 104 installed to discharge the scum pushed to one side by the scraper 103 to the outside, and is installed upright in the floating separation tank 101 And it is composed of a micro-bubble generating device (5) configured to supply air to the bottom of the floating separation tank 101 by sucking the outside air with rotation.

Of course, the first and second discharge screws 102 and 104 and the scraper 103 are configured to be rotated by the motor 106, and the scraper 103 is rotated by the sprocket 107. It consists of many moving plates 109 which push the scum in 108, and the flexible rubber plate 110 attached thereto. In addition, since the guide plate 111 is installed on the front of the second discharge screw 104 so that the scum pushed by the scraper 103 is collected by the second discharge screw 104, the rubber plate 110 is The scum is pushed by the second discharge screw 104 while being in contact with the guide plate 111.

Referring to the operation and effect of the present invention as described above, in order to remove the foreign matter contained in the waste water, the waste water is introduced into the flotation separation tank 101 and a flocculant is added to form a scum. At this time, the motor 17 of the microbubble generating device 5 is in a state of being rotated. As the air tube 15 is rotated by the rotation of the motor 17, the outside air is sucked through the suction hole 16. Will be inhaled.

That is, the outside air is sucked by the rotation of the air jet wing 15, the intake air is injected into the waste water from the air jet wing 15, the air becomes fine bubbles and sticks to the foreign matter of the waste water It floats to the upper surface of the float separation tank (101). Here, although the sealing means seals the bearing housing 14 and the air tube 18 when the air jet wing 15 is rotated, wastewater may seep due to the limitation of the mechanical structure, but the chamber 35 Since the purified water continuously supplied to the inside is discharged to the outside through the gap of the sealing to prevent the waste water from flowing into the protective cap (30).

That is, the microbubble generating device 5 sucks outside air by the rotation of the air jet vanes 15 in a state where there is no complicated device such as a separate compressor, and discharges the microbubbles into the wastewater. Wear / breakage of the bearing 13 by wastewater during rotation of the air jet wing 15 is prevented by the purified water supply and sealing means.

Subsequently, the scum injured by the microbubble generating device 5 is located on the upper surface of the flotation separation tank 101. As the scraper 103 is rotated, the scum 103 is moved by the moving plate 109 and the rubber plate 110. The scum is pushed toward the discharge screw 104 side, and the scum collected by the second discharge screw 104 is discharged to the outside. Here, the scum is collected by the guide plate 111 to the second discharge screw 104 and the second discharge screw 104 is stored in the guide plate 111, so that the scum is discharged to the outside. .

In addition, a large foreign material that does not float to the upper surface of the floating separation tank 101, such as the scum sinks to the bottom of the floating separation tank, which is discharged to the outside by the first discharge screw (102). When scum and foreign matter are filtered out of the waste water by the first and second discharge screws 102 and 104, the purified water is discharged to the outside and stored or purified again.

As described above, the present invention is provided with mechanical sealing means and fresh water supply means at the lower part of the bearing housing to compensate for the sealing worn with the passage of the operating time, the microbubble generating device is damaged by the foreign matter contained in the wastewater and wastewater. It is effective to prevent that.

The present invention also provides at least one air outlet to prevent fresh water to be supplied to the mechanical sealing means at the beginning of the operation of the microbubble generating device by the air trapped in the chamber. To prevent breakage.

In addition, the present invention also provides a pressurized tank, a pressurized pump, etc. installed for supplying air by installing a microbubble generating device for adsorbing microbubbles to solids by stirring the waste water and the microbubbles while generating microbubbles on one side of the floating separation tank. By eliminating the need for components such as valves because they are not used, there is an effect of simplifying the configuration and convenient operation and improving foreign matter removal efficiency.

Claims (7)

Air tube for transporting air, a motor for rotating the air tube, an air jet wing that is integrally formed at the lower end of the air tube to discharge the air and agitate waste water, and a plurality of rotatably supporting the air tube In the micro-bubble generating device comprising a bearing, a plurality of bearing housings for holding the bearing and at the same time to secure a plurality of support tubes for protecting the air tube, A first sealing means comprising a protective cap coupled to a lower portion of the bearing housing, and a plurality of seals installed to prevent waste water from flowing into the protective cap; A second sealing means composed of a mechanical seal for preventing wastewater introduced into the protective cap from entering the bearing housing and damaging the bearing; It characterized in that it comprises a fresh water supply means for supplying clean water into the protective cap to prevent the waste water from flowing into the protective cap and to prevent the second sealing means from being damaged by excessive frictional heat Micro bubble generator. The method of claim 1, The micro-bubble generating device further comprises at least one air discharge means in communication with the protective cap so as to smoothly discharge the air trapped inside the protective cap. The method of claim 1, The first sealing means has a protective cap coupled to the lower portion of the bearing housing, a central hole installed in the center of the protective cap so that the rotating air tube penetrates, and a slitting provided between the inner circumferential surface of the central hole and the outer circumferential surface of the air tube. Micro air generating apparatus comprising an eve, an inner seal provided on the inner circumferential surface of the sleeve and an outer seal provided on the outer circumferential surface. The method of claim 1, The second sealing means may include a retainer integrally coupled to the lower portion of the bearing housing, a protective cap coupled to the lower portion of the retainer to form a predetermined chamber between the air tubes, and between the retainer and the sleeve. Microbubble generating device comprising a mechanical seal that is always in close contact with the retainer by an intervening spring. The method of claim 1, Microbubble characterized in that it further comprises a purified water supply means comprising a purified water supply tube and a pump connected to the purified water supply tube and the purified water supply tube installed to supply fresh water into the chamber formed by the protective cap Generator. A float separation tank having a rectangular shape, a first discharge screw rotated by a motor so as to discharge foreign substances that are installed on the bottom of the float separation tank, and an upper surface of the float separation tank to push the scum rising to the top surface of the float separation tank in one direction. And a second discharge screw rotated by a motor to discharge the scum pushed to one side by the scraper to the outside, and installed upright in the floating separation tank, and sucking the outside air together with the rotation to lower the floating separation tank. Induced air floating separator characterized in that it comprises a micro-bubble generating device configured to supply air to the. The method of claim 6, The microbubble generating device comprises: a first cap comprising a protective cap coupled to a lower portion of a bearing housing, and a plurality of seals installed to prevent waste water from flowing into the protective cap; A second sealing means composed of a mechanical seal for preventing wastewater introduced into the protective cap from entering the bearing housing and damaging the bearing; It characterized in that it comprises a fresh water supply means for supplying clean water into the protective cap to prevent the waste water from flowing into the protective cap and to prevent the second sealing means from being damaged by excessive frictional heat Induction air floating separator.