KR102649344B1 - High-efficiency microbubble generator for wastewater and sewage treatment equipment - Google Patents

Abstract

The present invention provides a highly efficient microbubble generator (1) for wastewater and sewage treatment equipment, which is installed to generate fine bubbles inside a settling tank or flotation tank (100) to levitate and purify various foreign substances. It is intended to provide an air supply pipe (4) configured to blow out the high-pressure air introduced inside through the blowhole (41), and high-pressure air on the outside of the air supply pipe (4) to cause fine bubbles to flow from the inside to the outside. A ceramic tube (5) formed to have fine pores on the inside to be discharged, a residence space (6) in which the outer surface of the air supply pipe (4) and the inner surface of the outer ceramic tube (5) are spaced apart, an inner air supply pipe (4), and A fastener (7) fixedly installed facing each other to be coupled to both ends of the outer ceramic tube (5), and a fine bubble generating tube (2) with fasteners (7) installed on both ends of the air supply pipe (4) and the ceramic tube (5). It is characterized in that it includes a main body (3) installed at the inner lower part of the settling tank or flotation tank (100) with several installed inside. According to this, the ceramic tube (5), which is relatively weak among the constituent members, is exposed to high pressure air. It is possible to improve durability against blowing pressure and expansion pressure, thereby preventing damage, prolonging life, and maximizing purification efficiency.

Description

{High-efficiency microbubble generator for wastewater and sewage treatment equipment}

The present invention relates to a highly efficient fine bubble generator for purification in a wastewater and sewage treatment device. To describe this in more detail, it is installed to generate fine bubbles inside a settling tank or flotation tank in a wastewater and sewage treatment device. This relates to a highly efficient microbubble generator for wastewater and sewage treatment devices that maximizes purification efficiency by levitating and purifying various foreign substances mixed with wastewater and sewage inside the tank.

In general, in a water treatment system for purifying wastewater or sewage, a number of settling tanks are installed to allow various suspended substances in the water to settle. Among these settling tanks, a bubble generator is installed at the inner lower part to levitate various suspended or settled foreign substances by bubbles. A number of technologies have been developed, and when the bubbles generated from these bubble generators are finely generated into micro-sized particles, the effect of floating foreign substances is improved, and as a result, the water purification and purification efficiency is greatly improved, thereby generating fine bubbles. Various devices for doing so have been developed since long ago.

A membrane diffuser has been developed as a representative example of a conventional microbubble generating device, but as the high-pressure air supply continues, it cannot be used for a long time and the outside is damaged by cracking or tearing, so there is a limit to the generation of microbubble. It had a number of problems, including a short product lifespan due to minor damage and increased maintenance and repair costs due to frequent replacement.

Recently, as published in Republic of Korea Patent No. 84414 (announced on July 4, 2008), it is a ceramic diffuser made of silica or aluminium and is composed of a disk type and a pipe type, and high pressure is pumped inside this ceramic diffuser. A technology has been developed to generate fine bubbles to the outside by injecting air, and as published in Patent Publication No. 2011 No. 109642 (published on October 6, 2011), a ceramic tube is double bonded to the outside of the central tube. When high-pressure air is supplied to the center pipe, a technology has been developed in which high-pressure air comes out of the outside of the center pipe and passes through the outer ceramic pipe (=ceramic diffuser), thereby generating fine bubbles. The structure is such that high-pressure air passes strongly from the inside to the outside of the diffuser, generating fine bubbles to the outside. However, these ceramic diffusers are easily damaged by even a small impact from the outside due to the pressure of the high-pressure air inside. Because the internal pressure could not be overcome, there were frequent cases of damage without external shock. In particular, when used for a long period of time, it was easily broken by continuous high-pressure air, which also limited the product's lifespan, and the damaged ceramic diffuser was rather damaged. There was a problem of foreign substances being generated in the settling tank or flotation tank, and the entire wastewater and sewage treatment device was stopped when replaced due to damage to the conventional ceramic diffuser, thereby reducing the efficiency of the device.

KR 10-0844141 B1 2008. 7. 4. KR 10-2011-0109642 A 2011. 10. 6.

In the present invention, a new technology was created to solve all the problems of the prior art described above. The present invention minimizes damage to the outer ceramic tube due to the blowing pressure or expansion pressure caused by the high-pressure air blowing out from the inner air supply pipe. This invention was completed with the goal of providing a highly efficient microbubble generator for wastewater and sewage treatment devices that improves purification efficiency when treating wastewater and sewage.

In addition, although not separately described, it is within the scope that can be inferred by taking into account the specific content, claims, and drawings for carrying out the following invention, which describes in detail the high-efficiency microbubble generator for wastewater and sewage treatment devices of the present invention. Other purposes are also included in the overall problem of the present invention.

As a specific means for solving the problems of the above-described invention, the present invention constitutes a highly efficient microbubble generator for wastewater and sewage treatment devices. The highly efficient microbubble generator for wastewater and sewage treatment devices of the present invention is supplied from the outside. The supplied high-pressure air is branched into a plurality of branch pipes and supply hoses and connected to communicate with each other internally. An air supply pipe is provided in which the high-pressure air flowing inside is blown out to the outside through a blowhole, and the outside of the air supply pipe is provided. It is surrounded by a ceramic tube that is molded to have fine pores on the inside so that the high-pressure air ejected through the blowhole discharges fine bubbles from the inside to the outside. The outer surface of the inner air supply pipe is spaced apart from the inner surface of the outer ceramic tube. It is configured to be filled with high-pressure air blown out through the blowhole of the air supply pipe and stay there. When the high-pressure air fills and expands, it passes through the outside of the ceramic tube and creates a retention space where fine bubbles are generated, and the stay space is provided between the air supply pipe and the ceramic tube. To ensure that the space is formed uniformly in the circumferential direction, fasteners are installed so that the inner air supply pipe and the outer ceramic pipe face each other and are fixedly installed. The fasteners installed on both ends of the air supply pipe and the ceramic pipe level the air supply pipe and the ceramic pipe. It is fixedly installed in a fixed position, and is characterized by a main body installed at the inner lower part of the settling tank or flotation tank, with several fine bubble generating pipes in which an air supply pipe and a ceramic pipe are combined inside and outside are installed inside.

The ceramic tube is installed at predetermined intervals in the longitudinal direction on the outside of the ceramic tube, and is generated by the blowing pressure generated by blowing out high-pressure air from the blowing hole of the air supply pipe and the expansion pressure generated by the expansion of high-pressure air supplied to the residence space. A suppressing means made of an elastic ring or an elastic band is further provided to suppress the expansion of the ceramic tube, or the inner part of the suppressing means coupled at a predetermined interval in the longitudinal direction to the outer peripheral surface of the ceramic tube is formed in the circumferential direction to be inserted. The means may further include a fixing groove configured to prevent the device from arbitrarily changing its position on the outside of the ceramic tube.

It may further include several elastic support means installed between the lower part of the main body and the inner bottom of the settling tank or floating tank to absorb and offset vibrations generated in the settling tank or floating tank.

A gap maintenance supporter is fixedly installed radially outward on the outside of the air supply pipe and has a support piece formed on the outer end, and is integrally protruded and molded radially inward on the inside of the ceramic pipe to be slidably placed on the support piece of the gap maintenance supporter. It may be characterized in that it is further provided with formed engaging protrusions.

According to a specific means for solving the above-mentioned problem, the high-efficiency microbubble generator for wastewater and sewage treatment equipment of the present invention is a plurality of air arranged to distribute and supply high-pressure air supplied from the outside to the inner lower part of the settling tank or flotation tank. The ceramic tube is spaced apart from the outside of the supply pipe and combined to form a residence space, so that when air is blown out from the air supply pipe, the blowing pressure does not pressurize the ceramic tube locally but applies pressure evenly throughout the interior, thereby increasing the durability of the ceramic tube. It has the effect of preventing damage to the ceramic pipe by increasing the microbubbles and discharging them evenly throughout the entire ceramic pipe, thereby improving purification efficiency when treating wastewater and sewage.

In addition, the present invention consists of a suppressing means having a predetermined gap on the outside of the long ceramic tube, so that the high-pressure air supplied through the air supply pipe stays in the residence space and expands, thereby forming a long ceramic tube inside the long ceramic tube at high pressure. When pressure is applied while passing through the tube, the suppressing means tightens the ceramic tube that is about to expand due to this expansion pressure, which has the effect of further doubling the durability against expansion pressure of the ceramic tube, which was relatively weak due to its long length. have

In addition, in the fine bubble generator of the present invention, an elastic support means is installed between the main body where several fine bubble generating tubes, which are composed of an inner air supply pipe and an outer ceramic tube, are installed, and the inner bottom of the settling tank or floating tank to prevent vibration. It is an invention with great expected effects, including minimizing damage to ceramic tubes.

1 is a front view of the present invention applied to a settling tank or floating tank.
Figure 2 is a plan view of the present invention applied to a settling tank or floating tank.
Figure 3 is a side configuration diagram of the present invention applied to a settling tank or floating tank.
Figure 4 is a plan view showing a preferred example of the present invention and a three-dimensional view of the main part
Figure 5 is a three-dimensional view, a side cross-sectional view, and a partial front cross-sectional view showing another example of the present invention.
Figure 6 is an exemplary diagram showing the loading state of the microbubble generating tube in another example of Figure 5
Figure 7 is a cross-sectional view and an example of operation of an example of a microbubble generating tube in the present invention.
Figure 8 is a cross-sectional view and operation example showing another example of the microbubble generating tube in the present invention.

The present invention is intended to provide a highly efficient microbubble generator for wastewater and sewage treatment equipment, which is installed to generate fine bubbles inside a settling tank or floating tank to levitate and purify various foreign substances. It will be described in more detail with the drawings below, but the attached drawings are only examples for easily explaining the content and scope of the technical idea of the present invention and are not limited thereto, and the terms used also refer to the embodiments in detail. It is for illustrative purposes only and should not be construed as limited to the relevant terms.

The high-efficiency fine bubble generator (1) for wastewater and sewage treatment equipment of the present invention is a settling tank or a sedimentation tank of a wastewater and sewage purification treatment equipment, as shown in the front view of FIG. 1, the top view of FIG. 2, and the side view of FIG. 3. It is installed at the inner lower part of the flotation tank 100, and supplies high-pressure air supplied from the outside to several fine bubble generating tubes 2 installed in the main body 3 to generate bubbles with micro-sized particles in the sedimentation tank. Alternatively, various foreign substances mixed in wastewater and sewage inside the floating tank 100 can be floated to the surface of the water using fine bubbles.

In this invention, as shown in FIG. 4, the fine bubble generating tube (2) fixed to the main body (3) is provided with a retention space (6) between the inner air supply pipe (4) and the outer ceramic tube (5). It is designed to be fastened to the main body (3) by fastening the fasteners (7) at both ends to the main body (3) through the branch pipe (42) and the supply pipe to one side of the fine bubble generating pipe (2). High-pressure air is supplied to the inner air supply pipe (4) through one fastener (7) of each fine bubble generating pipe (2).

To explain this in more detail, the air supply pipe (4) is connected and installed so that high-pressure air supplied from the outside branches off into a plurality of branch pipes (42) and supply hoses (43) and communicates with the inside. High-pressure air is configured to be blown outward through the blowing hole 41, and the ceramic tube 5 is positioned to surround the outside of the air supply pipe 4, so that the high-pressure air blown through the blowing hole 41 is blown from the inside to the outside. It is molded to have fine pores inside so that fine bubbles can be discharged.

Accordingly, the residence space (6) is formed so that the outer surface of the inner air supply pipe (4) and the inner surface of the outer ceramic tube (5) are spaced apart, so that the high-pressure air blown out through the blowing hole (41) of the air supply pipe (4) is filled and stays there. It is configured to be filled with high-pressure air and expand to generate fine bubbles that pass through the outside of the ceramic tube (5), and the fastener (7) stays between the air supply pipe (4) and the ceramic tube (5). The inner air supply pipe (4) and the outer ceramic pipe (5) are fixedly installed facing each other so that the space (6) is formed uniformly in the circumferential direction.

In addition, the main body (3) has fasteners (7) installed on both ends of the air supply pipe (4) and the ceramic pipe (5) so that the air supply pipe (4) and the ceramic pipe (5) are positioned horizontally. (4) and a ceramic tube (5) are combined inside and out. Several microbubble generating tubes (2) are installed inside and at the inner lower part of the settling tank or flotation tank (100). At this time, the main body (3) is installed in the settling tank. Alternatively, when installed on the bottom of the floating tank 100, an elastic support means consisting of a coil compression spring is used to prevent external shock such as vibration from being applied to the ceramic tube 5 of the fine bubble generating tube 2 installed in the main body 3 ( 9) can be provided, and as shown in FIGS. 1 and 3, several elastic support means (9) are installed between the lower part of the main body (3) and the inner bottom of the settling tank or floating tank (100) to form a settling tank. Alternatively, it is configured to absorb and offset vibration generated in the floating tank 100.

In the present invention, the durability of the outer ceramic tube 5 may be weak due to the formation of micropores, so as shown in Figure 5, the ceramic tube 5 is supported from the outside in response to the internal pressure to maintain pressure. A suppressing means (8) is added to further provide a means for suppressing, and the suppressing means (8) is installed at a predetermined interval in the longitudinal direction on the outside of the ceramic pipe (5) and is installed in the air supply pipe ( It is configured to suppress the expansion of the ceramic tube (5) due to the blowing pressure generated by the blowing of high-pressure air from the blowing hole (41) of 4) and the expansion pressure generated by the expansion of the high-pressure air supplied to the residence space (6). It consists of a ring-type elastic ring 81 made of rubber, urethane, etc., or a band-type elastic band 82 made of rubber, urethane, etc.

At this time, as shown in the side cross-sectional view or front cross-sectional view of FIG. 5, the inner part of the suppressing means 8, which is coupled to the outer peripheral surface of the ceramic tube 5 at a predetermined interval in the longitudinal direction, is formed in the circumferential direction to be inserted into the suppressing means 8. A fixing groove 83 may be provided on the outside of the ceramic tube 5 so that its position does not change arbitrarily, and this suppressing means 8 is only used to control the blowing pressure and expansion of the high-pressure air inside the ceramic tube 5. It not only serves to support the ceramic tube (5) from the outside in response to pressure, but also assembles the ceramic tube (5) with the air supply tube (4) into the microbubble generating tube (2), as shown in Figure 6. Before manufacturing only the ceramic tube (5) and loading it for transport, the suppressing means (8) cushions the impact with the neighboring ceramic tube (5) to prevent the ceramic tubes (5) from colliding with each other and being damaged during transport. These functions can be performed together.

The high-efficiency fine bubble generator (1) for the wastewater and sewage treatment device of the present invention, configured as described above, is installed on the inner bottom of the settling tank or flotation tank (100) as described above, and high-pressure air is supplied from an external air-conditioning presser. As shown in FIG. 7, when air is ejected toward the residence space (6) through the blowhole (41) through the inner air supply pipe (4) and stays for a certain period of time, the air fills the residence space (6) and expands. As the high-pressure air penetrates from the inside to the outside of the ceramic tube (5), fine bubbles of micro particle size are generated and discharged to the outside of the ceramic tube (5) of the fine bubble generating tube (2), and are discharged from the inside of the settling tank or flotation tank (100). Various foreign substances mixed with wastewater and sewage are floated to the surface of the water for purification. At this time, the present invention generates fine bubbles to float foreign substances more effectively, resulting in significantly better purification.

In addition, the present invention allows several gap maintenance supports (10) to be provided in the residence space (6) between the inner air supply pipe (4) and the outer ceramic pipe (5), as shown in FIG. The gap maintenance supporter 10 is fixedly installed radially outward on the outside of the air supply pipe 4, and several of them are installed side by side in the longitudinal direction of the air supply pipe 4, and an arc-shaped support piece 11 with an inward swell at the outer end. ) is formed, and at this time, a coupling protrusion 12 is formed to protrude in an inward-bellied arc shape to be slidably placed in the longitudinal direction on the support piece 11 of the gap maintenance supporter 10, and this coupling protrusion 12 is made of ceramic. It is formed to protrude integrally in an inward radial direction on the inside of the tube 5, and is formed to have a reinforcing rib function of the ceramic tube 5 long in the longitudinal direction of the ceramic tube 5.

In the present invention, the ceramic tube (5) is held in and out by a suppressing means (8) on the outside of the ceramic tube (5) and several gap maintenance supports (10) installed in the residence space (6) inside the ceramic tube (5). It is a structure that can maximize the durability of the ceramic tube (5) by supporting the ceramic tube more firmly against the blowing pressure of the air supply pipe (4) or the expansion pressure on the residence space (6).

As described above, the most preferred embodiments of the present invention have been described in the detailed description of the present invention, but various modifications may be made without departing from the technical scope of the present invention. Therefore, the scope of protection of the present invention is limited to the above-mentioned embodiments. Rather than being limited to examples, the scope of protection should be recognized to include the technologies in the patent claims described later and equivalent technical means from these technologies.

1: Microbubble generator
2: Microbubble generation tube
3:Body
4: Air supply pipe 41: Blow hole 42: Branch pipe 43: Supply hose
5: Ceramic tube
6:Residence space
7: Fastener
8: Oppressing means 81: Elastic ring 82: Elastic band 83: Fixing groove
9:Elastic support means
10: Gap maintenance supporter 11: Support piece 12: Combining protrusion
100: Sedimentation tank or floating tank

Claims (5)

The high-pressure air supplied from the outside is branched into a plurality of branch pipes (42) and the supply hose (43) and connected to communicate with the inside, and the high-pressure air introduced inside is blown out to the outside through the blowhole (41). An air supply pipe (4) configured;
A ceramic tube (5) positioned surrounding the outside of the air supply pipe (4) and molded to have fine pores on the inside so that high-pressure air ejected through the blowhole (41) discharges fine bubbles from the inside to the outside;
The outer surface of the inner air supply pipe (4) and the inner surface of the outer ceramic tube (5) are spaced apart, so that the high-pressure air ejected from the blowout hole (41) of the air supply pipe (4) is filled and stays, and is filled with high-pressure air. A residence space (6) in which microbubbles are generated when expanded and pass through the outside of the ceramic tube (5);
A fastener fixedly installed facing the inner air supply pipe (4) and the outer ceramic tube (5) so that the residence space (6) between the air supply pipe (4) and the ceramic pipe (5) is formed uniformly in the circumferential direction. (7);
The fasteners (7) installed on both ends of the air supply pipe (4) and the ceramic pipe (5) are fixed and installed to position the air supply pipe (4) and the ceramic pipe (5) horizontally, and the air supply pipe (4) and the ceramic pipe ( 5) a main body (3) installed at the inner lower part of the settling tank or flotation tank (100) with several microbubble generating tubes (2) coupled inside and outside being installed on the inside;
A high-efficiency microbubble generator for wastewater and sewage treatment devices, characterized in that it includes.
In claim 1;
It is installed at predetermined intervals in the longitudinal direction on the outside of the ceramic tube (5), and the blowing pressure generated by blowing out high-pressure air from the blowing hole (41) of the air supply pipe (4) and the high-pressure air supplied to the residence space (6) Suppression means (8) made of an elastic ring (81) or an elastic band (82) coupled to suppress the expansion of the ceramic tube (5) due to the expansion pressure generated by the expansion of;
A highly efficient microbubble generator for wastewater and sewage treatment devices, characterized in that it includes.
In claim 2;
The inner part of the pressing means (8), which is coupled to the outer peripheral surface of the ceramic tube (5) at a predetermined interval in the longitudinal direction, is formed in the circumferential direction so as to be indented, so that the pressing means (8) can be positioned arbitrarily on the outside of the ceramic tube (5). A fixed groove (83) configured not to change;
A highly efficient microbubble generator for wastewater and sewage treatment devices, characterized in that it includes.
In claim 1;
Elastic support means (9) installed in number between the lower part of the main body (3) and the inner bottom of the settling tank or floating tank (100) and configured to absorb and offset vibration generated in the settling tank or floating tank (100);
A highly efficient microbubble generator for wastewater and sewage treatment devices, characterized in that it includes.
In claim 1;
A gap maintenance supporter (10) fixedly installed radially outward on the outside of the air supply pipe (4) to be interposed between the inner air supply pipe (4) and the outer ceramic pipe (5);
A support piece (11) formed on the outer end of the gap maintenance supporter (10) and installed to contact the inner surface of the ceramic tube (5);
A highly efficient microbubble generator for wastewater and sewage treatment devices, characterized in that it includes.

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