KR20220142667A - Mist spraying device using nano bubble water - Google Patents

Abstract

A mist spraying device using nano-bubble water according to an aspect of the present invention can include: a bubble generating unit for generating nano-bubble water using supplied water; a spraying unit connected to the bubble generating unit and spraying nano-bubble water; and a control unit for controlling the bubble generating unit and the spraying unit by being linked to the bubble generating unit and the spraying unit.

Description

Mist spraying device using nano bubble water

The present invention relates to a mist spraying device using nano-bubble water, and more particularly, to a mist spraying device using nano-bubble water capable of optimizing a heating and cooling system and improving air quality.

In general, spaces with many users, such as bus stops, buildings, streets and park plazas, have a lot of fine dust and air quality deteriorates due to air pollution, which adversely affects the health of users.

In summer, when the weather is hot, heat island generation occurs in the city center, and in particular, in spaces with many users such as bus platforms, buildings, streets and park plazas, there is an urgent need to reduce heat island, remove fine dust, and improve air quality.

Accordingly, devices for spraying cooling mist have been developed to alleviate heat islanding in the city, to remove fine dust and to improve air quality, but there are problems in that the effectiveness is not great in the actual use process and the usability is poor.

Republic of Korea Patent Publication No. 10-2189472 (2020.12.14)

The present invention has been devised to solve the above problems, and an object of the present invention is to provide a mist spraying device using nano-bubble water capable of optimizing a heating and cooling system and improving air quality.

The mist spraying device using nano-bubble water according to an embodiment of the present invention for achieving the above object includes a bubble generating unit that generates nano-bubble water by using supplied water, and is connected to the nano-bubble generating unit. It may include an injection unit for spraying bubble water, and a control unit connected to the bubble generation unit and the injection unit to control the bubble generation unit and the injection unit.

The bubble generating unit includes a water tank in which supplied water is temporarily stored, a first pump connected to the water tank to move water in one direction, and a nano-bubble water connected to the first pump to generate nano-bubble water and a second pump connected to the water tank to move the water recovered through the nano-bubble water generator to the spray unit.

The first pump and the second pump may be sequentially operated after water is supplied.

The jetting unit includes a body elongated in the vertical direction, a plurality of jetting nozzles provided on the body to spray the water recovered through the bubble generating unit, and a lighting device provided at the upper end of the body to help secure visibility at night can be provided.

A measuring device for measuring the concentration and temperature of fine dust in connection with the control unit is further provided, and the measuring device may include a concentration measuring sensor for measuring the fine dust concentration and a temperature measuring sensor for measuring the external temperature.

The control unit adjusts the supply pressure from the bubble generating unit to the injection unit according to the fine dust concentration measured through the concentration measurement sensor, and controls the operation of the injection unit according to the external temperature measured through the temperature measurement sensor. have.

The bubble generating unit may be provided with a filter for removing foreign substances contained in the supplied water, and a UV sterilization device for sterilizing the water from which the foreign substances are removed through the filter.

According to the mist spraying device using the nano-bubble water according to the present invention, it is possible to optimize the heating and cooling system and improve the air quality.

1 is a conceptual diagram showing a mist spraying device using nano-bubble water according to an embodiment of the present invention.
Figure 2 is a block diagram showing a mist spraying device using the nano-bubble water shown in Figure 1;
Figure 3 is a graph showing the fine dust removal rate of the mist spraying device using the nano-bubble water shown in Figure 1;
Figure 4 is a conceptual diagram showing a modified example of the mist spraying device using the nano-bubble water shown in Figure 1;

Hereinafter, a mist spraying device using nano-bubble water according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a conceptual diagram showing a mist spraying device using nanobubble water according to an embodiment of the present invention, FIG. 2 is a block diagram showing a mist spraying device using nanobubble water shown in FIG. 1, FIG. It is a graph showing the fine dust removal rate of the mist spraying device using the nano-bubble water shown in 1 .

1 to 3, the mist spraying device 10 using nano-bubble water according to an embodiment of the present invention uses the supplied water to generate the nano-bubble water using the bubble generating unit 100 and , The bubble generating unit 100 and the injection unit 200 for spraying nano-bubble water is connected to the bubble generation unit 100 and the injection unit 200 in connection with the bubble generation unit 100 and the injection unit 200 It may be provided with a control unit 300 for controlling the.

Looking at the bubble generating unit 100 in detail, the bubble generating unit 100 is connected to a water tank 110 in which supplied water is temporarily stored, and the water tank 110 to allow water to move in one direction. A pump 120, a nano-bubble water generating device 130 that is connected to the first pump 120 to generate nano-bubble water using water and then recovers it to the water tank 110, and a water tank 110 and It may be provided with a second pump 140 that is connected to move the water recovered through the nano-bubble water generator 130 to the injection unit 200 .

The water tank 110 is not for long-term storage of supplied water, but for the recovery of the nano-bubble water generated through the nano-bubble water generating device 130, and is not for the purpose of water storage, so it may be provided in a small size.

The nano-bubble water generating device 130 is small in size, so it can be used in living spaces such as apartment houses, and in addition to the cooling function in the spray unit 200, it is capable of optimizing the heating and cooling system and improving air quality by exerting a function to remove fine dust and bacteria. can

The first pump 120 moves the nano-bubble water generator 130 to the water supplied to the water tank 110 , and the first pump 120 sprays the nano-bubble water recovered to the water tank 110 . It serves to move to 200 , and after water supply, the first pump 120 and the second pump 140 operate sequentially so that water supply, nano-bubble water generation, and nano-bubble water supply to the injection unit 200 are smooth. can make it happen.

On the other hand, the injection unit 200 is provided with a body 210 elongated in the vertical direction, and a plurality of injection nozzles 220 provided on the body 210 to spray the water recovered through the bubble generating unit 100 and , may be provided with a lighting device 230 provided on the upper end of the body 210 to help secure a night vision.

The spraying unit 200 can simultaneously exhibit a function of removing fine dust and bacteria through the nano-bubble water and a cooling function through mist spraying by spraying the nano-bubble water supplied from the bubble-generating unit 100 in the form of mist.

The length of the body 210, the number of spray nozzles 220, specifications, spray angle, discharge pressure, etc. may vary depending on the location where the spray unit 200 is installed or the required performance of removing fine dust and bacteria, and The lighting device 230 may be omitted in the injection unit 200 installed in a position where pedestrians do not pass or may cause light pollution.

On the other hand, the mist spraying device 10 using nano-bubble water according to an embodiment of the present invention may further include a measuring device 400 for measuring the concentration and temperature of fine dust in connection with the control unit 300, and The device 400 may include a concentration measuring sensor 410 for measuring the concentration of fine dust and a temperature measuring sensor 420 for measuring an external temperature.

The control unit 300 adjusts the supply pressure from the bubble generating unit 100 to the injection unit 200 according to the fine dust concentration measured through the concentration measuring sensor 410, and the outside measured through the temperature measuring sensor 420. The operation of the injection unit 200 may be controlled according to the temperature.

For example, when the concentration measuring sensor 410 for measuring the concentration of fine dust measures that the concentration is thicker than usual or the concentration is temporarily increased, the control unit 300 controls the second pump ( 140) can be controlled to adjust the supply pressure to the injection unit 200, and in addition, increase the amount of water supplied to the water tank 110 and increase the amount of nano-bubbles generated through the nano-bubble water generating device 130 to increase the amount of water supplied to the injection unit ( 200), it is possible to flexibly respond according to the concentration of fine dust by increasing the amount of nanobubbles supplied.

In addition, when the temperature measurement sensor 420 for measuring the external temperature continuously maintains a low temperature or temporarily lowers the temperature, such as in winter or rain, when it is measured that the temperature is temporarily lowered, the control unit 300 controls the injection unit 200 to By preventing the injection itself from being sprayed through the injection unit 200, it is possible to prevent problems such as freezing of the injection nozzle 220 due to unnecessary injection in advance, and to prevent inconvenience of passage to pedestrians. .

Meanwhile, the mist spraying device 10 using nano-bubble water according to an embodiment of the present invention verified the fine dust removal efficiency through an experiment, and the experimental results were derived as shown in FIG. 3 .

Looking at the experimental results, it was shown that the mist spraying device 10 using nano-bubble water according to an embodiment of the present invention showed a fine dust removal rate of 50% or more compared to natural attenuation, thereby exhibiting a fine dust removal effect more than twice compared to natural attenuation. it can be seen that

Next, a modified example of the mist spraying device 10 using nano-bubble water according to an embodiment of the present invention will be described. In the following description, only parts different from the above-described embodiments will be described in detail, and detailed descriptions of the same or extremely similar parts will be omitted.

4 is a conceptual diagram showing a modified example of the mist spraying device using the nano-bubble water shown in FIG. 1 .

1 to 4 , the mist spraying device 10 using nano-bubble water according to an embodiment of the present invention uses the supplied water to generate the nano-bubble water using the bubble generating unit 100 and the bubbles The injection unit 200 connected to the generator 100 to spray nano-bubble water, and the bubble generation unit 100 and the injection unit 200 are linked to control the bubble generation unit 100 and the injection unit 200 . A control unit 300 may be provided.

In addition, the bubble generating unit 100 includes a water tank 110 for temporarily storing supplied water, a first pump 120 connected to the water tank 110 to move water in one direction, and a first pump ( 120) is connected to the nano-bubble water generator 130 that generates nano-bubble water using water and then recovers it to the water tank 110, and the nano-bubble water generator 130 connected to the water tank 110 A second pump 140 is provided to move the recovered water to the spraying unit 200, and the spraying unit 200 is provided in the body 210 and the body 210 elongated in the vertical direction. A plurality of injection nozzles 220 for spraying water recovered through the bubble generating unit 100, and a lighting device 230 provided at the upper end of the body 210 to help secure visibility at night may be provided.

On the other hand, the bubble generating unit 100 is additionally provided with a filter 150 for removing foreign substances contained in the water supplied and a UV sterilization device 160 for sterilizing the water from which the foreign substances are removed through the filter 150, By removing and sterilizing foreign substances in the water before water is supplied from the tap water to the water tank 110 , clean water can be sprayed through the bubble generating unit 100 and the spraying unit 200 .

As described above, the mist spraying device 10 using nanobubble water according to an embodiment of the present invention exhibits the cooling function of mist spraying and the fine dust and bacteria removal function of the nanobubble water generating device 130. It can optimize heating and cooling systems and improve air quality.

In the above, the mist spraying device using nano-bubble water according to an embodiment of the present invention has been described, but the spirit of the present invention is not limited to the embodiments presented herein. And those skilled in the art who understand the spirit of the present invention will be able to easily propose other embodiments by addition, change, deletion, addition, etc. of components within the scope of the same spirit, but this is also said to be within the scope of the present invention. will be.

10: Mist spraying device using nano-bubble water
100: bubble generating unit 110: water tank
120: first pump 130: nano-bubble water generator
140: second pump 150: filter
160: UV sterilizer 200: spray unit
210: body 220: spray nozzle
230: lighting equipment 300: control unit
400: measuring device 410: concentration measuring sensor
420: temperature sensor

Claims (7)

A bubble generating unit that generates nano-bubble water by using the supplied water;
a spraying part connected to the bubble generating part to spray nano-bubble water;
Mist spraying device using nano-bubble water including a control unit connected to the bubble generating unit and the injecting unit to control the bubble generating unit and the injecting unit.
The method of claim 1,
The bubble generating unit includes a water tank in which the supplied water is temporarily stored;
a first pump connected to the water tank to move water in one direction;
a nano-bubble water generator connected to the first pump to generate nano-bubble water using water and then recover it to the water tank;
and a second pump connected to the water tank to move the water recovered through the nano-bubble water generator to the spray unit.
3. The method of claim 2,
The first pump and the second pump is a mist injection device using nano-bubble water, characterized in that it operates sequentially after water supply.
4. The method of claim 3,
The spraying unit includes a body elongated in the vertical direction;
A plurality of spray nozzles provided in the body to spray the recovered water through the bubble generating part;
Mist spraying device using nano-bubble water, characterized in that it is provided on the upper end of the body and includes a lighting device to help secure visibility at night.
5. The method of claim 4,
A measuring device for measuring fine dust concentration and temperature in connection with the control unit is further provided,
The measuring device is a mist spraying device using nano-bubble water, characterized in that it comprises a concentration measuring sensor for measuring the concentration of fine dust and a temperature measuring sensor for measuring the external temperature.
6. The method of claim 5,
The control unit adjusts the supply pressure from the bubble generating unit to the injection unit according to the fine dust concentration measured through the concentration measurement sensor, and controls the operation of the injection unit according to the external temperature measured through the temperature measurement sensor. Mist spraying device using nano-bubble water as a feature.
7. The method of claim 6,
A filter for removing foreign substances contained in the water supplied to the bubble generating unit;
A mist spraying device using nano-bubble water, characterized in that a UV sterilization device for sterilizing water from which foreign substances have been removed through the filter is provided.

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