KR101318604B1 - Micro bubble sterilizer - Google Patents

Abstract

PURPOSE: A micro bubble sterilizer is provided to perform a sterilization process using ultraviolet ray and ozone simultaneously with water electrolysis, thereby doubling the efficiency of the existing sterilization method. CONSTITUTION: A micro bubble sterilizer comprises: a device body (10); an electrolysis module (30); and an ultraviolet ray lamp with multiple wavelengths arranged in the upper region of the electrolysis module. The electrolysis module generates micro oxygen bubbles through the electrolysis of the water flowed into the device body. The ultraviolet ray lamp with multiple wavelengths radiates multiple ultraviolet wavelengths. One ultraviolet wavelength among multiple ultraviolet wavelengths reacts with the micro oxygen bubbles to produce ozone. The ultraviolet ray sterilization process and ozone sterilization process are executed simultaneously by the said ozone generation process. A sludge discharging part(16) which discharges the sludge loaded inside the device is formed in the device body. The sludge discharging part opens and closes a valve periodically to automatically return the sludge to raw water. An ozone measurement sensor measuring the amount of the ozone generated within the device body is formed in the upper side of the device body.

Description

Micro bubble sterilizer

The present invention relates to a microbubble sterilizer, and more particularly, to a microbubble sterilizer which can double the sterilization efficiency than before by adding a water electrolysis phenomenon and performing sterilization by ultraviolet and ozone in parallel. will be.

In general, water can be classified into various types such as drinking water, agriculture, or industrial purpose, depending on the purpose of use. Among them, in particular, water used for drinking water or washing face that is closely related to human life, Maintaining is the most important thing.

If the water used for drinking or washing / washing / flushing is not clean, many invisible bacteria can increase the risk of various diseases such as abdominal pain, diarrhea and vomiting.

In order to prevent such diseases from occurring in advance, various filters such as activated carbon filters, micro filters, and membrane filters are conventionally applied to filter out foreign substances contained in raw water, or included in water using ultraviolet (UV) lamps. By sterilizing / treating bacteria such as Escherichia coli present, water can be used with confidence.

However, such a conventional sterilizer has a straight line from the inlet to the sterilizer and the outlet to move the water, and the UV irradiation time is short for the flowing water at high speed to completely remove biological bacteria. There is a problem that can not be sterilized.

For example, as the flow rate flowing from the outside rapidly increases, the flow rate also increases. As a result, the raw water, which has a relatively short time for sterilization, eventually becomes sterilized. Uncompleted discharges through the outlet do not provide sufficient sterilization effect.

In addition, since a large amount of sludge exists in the inner wall of the pipe to which the water moves or in the water, there is a problem that it is difficult to maintain a clean state due to foreign substances even if the water is sterilized and treated by ultraviolet rays. In addition, as the power motor that supplies power to the submersible pump is located close to the device, when flooding, it is frequently caused by the failure of the motor, causing the burden of replacement cost and inconvenience of equipment replacement. .

In order to solve this problem, Korean Patent Office Registration No. 10-0855201 discloses a tube type ultraviolet sterilizer.

The disclosed technology provides a function of sterilizing and disinfecting harmful microorganisms such as E. coli, general bacteria, and bacteria in water by using the germicidal power of an ultraviolet lamp.

However, in view of the fact that the ultraviolet sterilizer according to the prior art, including the technology disclosed in the above document, in general, most of the sterilization action is performed using only an ultraviolet lamp, the sterilization efficiency may not be as expected, There is a need to develop a structure for a more efficient sterilizer.

Korea Patent Office Registration No. 10-0855201

It is an object of the present invention to provide a microbubble sterilization apparatus which can double the sterilization efficiency than before by adding a water electrolysis phenomenon and performing sterilization by ultraviolet and ozone in parallel.

The object is, the apparatus main body; An electrolysis module provided in the apparatus body and generating micro oxygen bubbles through electrolysis of water introduced into the apparatus body; And disposed in an upper region of the electrolysis module, and irradiating a plurality of ultraviolet wavelengths to generate ozone by reacting one of the plurality of ultraviolet wavelengths with the micro oxygen bubble, such that ultraviolet sterilization and ozone sterilization are performed in parallel. It is achieved by a micro bubble sterilizer characterized in that it comprises a multi-wavelength ultraviolet lamp.

The electrolysis module, the upper and lower module casing open; And a pair of electrode plates having different polarities and spaced apart from each other in the module casing to generate the micro oxygen bubbles therebetween.

Each of the pair of electrode plates includes a circular pipe; And it may include a spring wound on the outer wall of the circular pipe.

The electrolysis module includes a pair of electrode plate rotation shafts coupled to the pair of electrode plates, respectively, to form rotation axis cores of the electrode plates; A connecting chain connecting the pair of electrode plate rotating shafts; And an electrode plate rotating motor configured to rotate any one of the pair of electrode plate rotating shafts on the opposite side of the connection chain.

The pair of electrode plates may be supplied with power by a high frequency DC generator installed in the controller.

A quartz tube of transparent or translucent material protecting the ultraviolet lamp; A washing ring coupled to the outer surface of the quartz tube so as to be movable along the longitudinal direction of the quartz tube to wash the outer surface of the quartz tube; And a washing ring moving part connected to the washing ring to move the washing ring along a length direction of the quartz tube, to which an indirect coupling method is applied.

The electrode plate cleaning brush disposed on the outer wall of the electrode plate at one side of the choir module casing for washing the electrode plate may be further included.

It may further include a ring support for supporting the washing ring, the washing ring moving unit, a drive motor; A ball screw connected to the drive motor; And a ball screw nut connected to the ring support and screwed to the ball screw to move along the length direction of the ball screw when the ball screw is rotated.

Between the washing ring and the outer surface of the quartz tube may be further provided with an iron scrubber-type friction washing member to wash the outer surface of the quartz tube.

The upper one side of the device body may be further provided with an ozone measuring sensor that can measure the amount of ozone generated in the device body.

According to the present invention, it is possible to double the sterilization efficiency than before by adding the electrolysis of water to perform the sterilization action by ultraviolet and ozone in parallel.

1 is a side structure diagram of a micro bubble sterilization apparatus according to an embodiment of the present invention,
Fig. 2 is a front view of Fig. 1,
3 is a plan view of the electrolysis module,
4 is a schematic perspective view of FIG. 3;
5 is a front view of FIG. 3;
6 is a schematic perspective view of the washing ring region;
7 is an enlarged view of the area A in Fig.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention.

1 is a side structural view of a micro bubble sterilization apparatus according to an embodiment of the present invention, FIG. 2 is a front view of FIG. 1, FIG. 3 is a plan view of an electrolysis module, FIG. 4 is a schematic perspective view of FIG. 3, and FIG. 5. 3 is a front view of FIG. 3, FIG. 6 is a schematic perspective view of the washing ring region, and FIG. 7 is an enlarged view of region A of FIG. 6.

Referring to these drawings, the microbubble sterilization apparatus of the present embodiment is to add the electrolysis of water to perform the sterilization action by ultraviolet and ozone in parallel to double the sterilization efficiency than before, the apparatus main body 10, An electrolysis module 30, and a multi-wavelength UV lamp 50.

The apparatus body 10 is a structure forming the appearance of the microbubble sterilizing apparatus of this embodiment, and is a pipe through which water to be sterilized, that is, sewage or wastewater.

In the present embodiment, although the device body 10 of the circular pipe shape is disclosed, the shape of the device body 10 does not necessarily have to be a circular pipe shape, for example, may be applied in a polygonal structure. The device body 10 is disposed on the lower support 11.

Water inlet line 12 is formed on one side of the device body (10). The water inflow line 12 is a line for introducing sewage or wastewater into the apparatus body 10. The water inlet line 12 is provided with a first valve 13 to control the flow of water passing over the water inlet line 12.

The water discharge line 14 is formed on the opposite side of the water inlet line 12. The water discharge line 14 forms a line through which the sterilization water after the sterilization treatment is completed in the apparatus body 10. The water discharge line 14 is provided with a second valve 15 to control the flow of water passing over the water discharge line 14.

The sludge discharge part 16 is provided on the other side of the apparatus main body 10. Since the sludge discharge part 16 is provided, sludge may be discharged at regular intervals. The sludge discharge part 16 is also provided with a third valve 17.

Optionally, the sludge loaded on the sludge discharge part 16 may be implemented to be automatically conveyed to the raw water. Therefore, by opening and closing the third valve 17 at regular intervals, the sludge may be introduced back into the raw water and reprocessed by the raw water treatment operation.

The electrolysis module 30 is provided in the apparatus body 10 and serves to generate micro oxygen bubbles through electrolysis of water introduced into the apparatus body 10.

When voltage is applied to the anode (+) and the cathode (-) for the electrolysis of water, when one side is in an overvoltage state, oxygen may be generated and micro oxygen bubbles may be generated. The voltage may be supplied through a high frequency DC generator (not shown) installed in a controller (not shown).

The electrolysis module 30 includes a module casing 31 and a pair of electrode plates 32 having different polarities and spaced apart from each other in the module casing 31 to generate micro oxygen bubbles therebetween. Include.

The module casing 31 is a portion that supports the pair of electrode plates 32, the upper and lower portions of which are open. In other words, since the module casing 31 is composed of a pair of plate bodies 31a and a connection bar 31b connecting corner regions of the pair of plate bodies 31a, the upper and lower portions of the module casing 31 are open.

Micro-oxygen bubbles are generated in region B of FIG. 5, and since the upper and lower portions of the module casing 31 are open, the micro-oxygen bubbles are easily diffused into the apparatus body 10.

Each of the pair of electrode plates 32 spaced apart from each other may include a circular pipe 32a and a spring 32b wound on an outer wall of the circular pipe 32a.

Since the spring 32b is wound, the unit area becomes wider, and thus a lot of micro oxygen bubbles may be generated.

Electrode plate rotation shafts 33 are provided at the centers of the electrode plates 32, respectively. The pair of electrode plate rotating shafts 33 are connected to each other by a connecting chain 34, and one of the electrode plate rotating shafts 33 is connected to the electrode plate rotating motor 35. The power supply of the electrode plate 32 is supplied by the high frequency direct current generator (not shown) mentioned above.

The electrode plate rotating motor 35, the connection chain 34, and the electrode plate rotating motor 35 are used for washing the electrode plate 32 together with the electrode plate cleaning brush 40 to be described later.

The multi-wavelength UV lamp 50 is disposed in the upper region of the electrolysis module 30 in the apparatus body 10, and micro-oxygen bubbles are changed to ozone together with ultraviolet sterilization so that the ozone sterilization can be performed in parallel. It serves to irradiate ultraviolet rays of multiple wavelengths.

As described above, when a voltage is applied to the positive electrode (+) and the negative electrode (-) through a high frequency direct current generator (not shown) for the electrolysis of water, when one side is in an overvoltage state, oxygen is generated and micro oxygen bubbles are generated. It may be generated, by irradiating ultraviolet rays of a specific wavelength, for example, 184.9nm by the multi-wavelength ultraviolet lamp 50 can generate ozone, through which sterilization can proceed.

As a result, in the present embodiment, the sterilization action is proceeded by the generation of ultraviolet rays by the multi-wavelength UV lamp 50, but the electrolysis module 30 is further generated to generate micro oxygen bubbles, and then ozone is generated by irradiating specific ultraviolet rays. Sterilization by ozone is performed in parallel to increase sterilization efficiency.

That is, the multi-wavelength UV lamp 50 of the present embodiment emits wavelengths of various bands, and thus has a UV sterilization function and an ozone generating function at the same time.

In addition, as shown in Figure 1, the upper one side of the device body 10 is further provided with an ozone measuring sensor 90. Therefore, by measuring the amount of ozone generated in the device body 10, by transmitting a signal to the controller not shown to adjust the voltage applied to the electrode plate by a high frequency direct current generator (not shown), by the electrolysis module By adjusting the amount of micro oxygen bubbles generated, it becomes possible to automatically adjust the total amount of ozone generated. Thereby, not only ultraviolet sterilization and ozone sterilization can be performed in parallel, but also there is an advantage that it is possible to adjust the degree of sterilizing power.

The multi-wavelength UV lamp 50 is protected in a quartz tube 60 of transparent or translucent material, as shown in FIG. One or more multi-wavelength UV lamps 50 may be disposed in one quartz tube 60.

Since the quartz tube 60 is a transparent or translucent glass material, the outer surface of the quartz tube 60 may be contaminated by sewage or waste water. If the outer surface of the quartz tube 60 is contaminated, ultraviolet ray irradiation efficiency or UV intensity detection efficiency is bound to fall. To prevent this, the following quartz tube 60 cleaning structure is applied.

Referring to FIG. 6, the outer surface of the quartz tube 60 is provided with a washing ring 70 that is movably coupled along the longitudinal direction of the quartz tube 60 to wash the outer surface of the quartz tube 60. The washing ring 70 may be applied as many as the number of quartz tubes 60. Between the washing ring 70 and the outer surface of the quartz tube 60, an iron scrubber friction cleaning member 71 is inserted to remove fine scale or foreign substances caught on the outer surface of the quartz tube 60. It is desirable to.

The washing rings 70 are supported by the ring support 72. As shown in FIG. 1, a plurality of ring supports 72 may be provided along the longitudinal direction of the quartz tube 60, and a plurality of washing rings 70 may be connected to and supported by each ring support 72. The plurality of ring supports 72 can be connected together and moved together.

The washing ring 70 is connected to the washing ring moving part 80 which moves the washing ring 70 along the longitudinal direction of the quartz tube 60.

The outer surface of the quartz tube 60 may be washed while the washing ring 70 is moved along the longitudinal direction of the quartz tube 60 by the washing ring moving unit 80.

The washing ring moving unit 80 may be applied in various forms, but in the present embodiment, the washing ring moving unit 80 may include a driving motor 81, a ball screw 82 connected to the driving motor 81, and a ring. It includes a ball screw nut 83 connected to the support portion 72 and screwed to the ball screw 82 is moved along the longitudinal direction of the ball screw 82 when the ball screw 82 rotates.

Thus, when the driving motor 81 is operated, the ring support portion 72 is moved by the ball screw nut 83 which is moved along the length direction of the ball screw 82, so that the cleaning rings 70 of the quartz tube 60 are moved. The exterior can be cleaned.

On the other hand, the electrode plate cleaning brush 40 for cleaning the electrode plate 32 in such a structure is disposed on the outer wall of the electrode plate 32 on one side of the module casing 31, in particular the bottom region of the module casing 31. The electrode plate 32 can be washed.

As described above, the electrode plate 32 may be rotated in place by the electrode plate rotating motor 35, the connection chain 34, and the electrode plate rotating motor 35, so that the electrode plate cleaning brush 40 may be rotated. When placed long along the longitudinal direction of the 32 to be in contact with the electrode plate 32, the entire span of the electrode plate 32 can be easily washed by the electrode plate cleaning brush 40.

Accordingly, the phenomenon in which the electrode plate 32 is contaminated and the amount of micro oxygen bubbles generated is reduced can be effectively prevented.

As described above, in the present embodiment, the sterilization action is performed by the generation of ultraviolet rays by the multi-wavelength UV lamp 50, but the electrolysis module 30 is further placed to generate micro oxygen bubbles, followed by the sterilization action by ozone. In parallel, the sterilization efficiency is increased.

As described above, according to the present embodiment, the sterilization effect by ultraviolet rays can be added in addition to the electrolysis of water, thereby increasing the sterilization efficiency than before.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Therefore, such modifications or variations will have to be belong to the claims of the present invention.

10 device main body 11 support body
12: water inlet line 13: the first valve
14 water discharge line 15 second valve
16: sludge discharge portion 17: third valve
30: electrolysis module 31: module casing
32: electrode plate 33: electrode plate rotation axis
34: electrode plate connecting chain 35: electrode plate rotating motor
40: electrode plate cleaning brush 50: multi-wavelength UV lamp
60: quartz tube

Claims (10)

A device body;
An electrolysis module that is modularly coupled to the device body and generates micro oxygen bubbles through electrolysis of water introduced into the device body; And
Disposed in an upper region of the electrolysis module, irradiating a plurality of ultraviolet wavelengths to generate ozone by reacting one of the plurality of ultraviolet wavelengths with the micro-oxygen bubbles, such that ultraviolet sterilization and ozone sterilization are performed in parallel. Includes a multi-wavelength UV lamp,
The electrolysis module,
A module casing with top and bottom open;
A pair of electrode plates having different polarities and spaced apart from each other in the module casing to generate the micro oxygen bubbles therebetween;
A pair of electrode plate rotation shafts respectively coupled to the pair of electrode plates to form a center of rotation of the electrode plates;
A connecting chain connecting the pair of electrode plate rotating shafts;
An electrode plate rotating motor for rotating any one of the pair of electrode plate rotating shafts on the opposite side of the connection chain; And
It further comprises an electrode plate cleaning brush disposed on the outer wall of the electrode plate on one side of the choir module casing to clean the electrode plate as the electrode plate is rotated,
Each of the pair of electrode plates,
Circular pipe; And
It includes a spring wound on the outer wall of the circular pipe,
The sludge discharge part for discharging the sludge loaded therein is further formed in the apparatus main body, the sludge discharge part automatically opens and closes the valve at regular intervals and automatically conveys the sludge to the raw water.
Microbubble sterilizing apparatus further comprises an ozone measuring sensor for measuring the amount of ozone generated in the apparatus main body on the upper side of the apparatus main body.
delete delete delete The method of claim 1,
The pair of electrode plates are microbubble sterilizer, characterized in that the power is supplied by a high frequency DC generator installed in the controller.
The method of claim 1,
A quartz tube made of transparent or translucent material protecting the multi-wavelength ultraviolet lamp;
A washing ring coupled to the outer surface of the quartz tube so as to be movable along the longitudinal direction of the quartz tube to wash the outer surface of the quartz tube; And
Microbubble sterilization apparatus further comprises a washing ring moving unit connected to the washing ring to move the washing ring along the longitudinal direction of the quartz tube is applied an indirect coupling method.
delete The method according to claim 6,
Further comprising a ring support for supporting the washing ring,
The washing ring moving unit,
A drive motor;
A ball screw connected to the drive motor; And
And a ball screw nut connected to the ring support and screwed to the ball screw to move along the length direction of the ball screw when the ball screw is rotated.
The method according to claim 6,
Microbubble sterilizing device between the washing ring and the outer surface of the quartz tube is further provided with an iron scrubber-type friction washing member to wash the outer surface of the quartz tube.
delete

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