KR20200140137A - Outdoor Particulate Matter Purifier and Outdoor Particulate Matter Purification System Having the Same - Google Patents

Abstract

Disclosed are an outdoor fine dust purifier to minimize damage caused by fine dust, and an outdoor fine dust purification system including the same. According to the present invention, the outdoor fine dust purifier comprises: an air layer separation unit disposed on the upper part of the outdoor fine dust purifier and spraying air supplied from the outside at a predetermined height and a predetermined distance to form a sectioned layer to allow the air purified and discharged from the outdoor fine dust purifier to stay in a predetermined area; a suction unit disposed on the lower side of the air layer separation unit and sucking the air from the atmosphere in accordance with a wind direction; a purification unit connected to one end of the suction unit and purifying the air sucked through the suction unit in an electric dust collection method; an air discharge unit connected to one end of the purification unit and discharging the air purified in the purification unit to the outside in accordance with a wind direction; a fine dust layer removing unit removing a fine dust layer generated in a purification process of the purification unit; a collection unit connected to one end of the air discharge unit and collecting the fine dust layer removed by the fine dust layer removing unit; and a discharge unit connected to one side of the collection unit and discharging the collected fine dust layer to the outside.

Description

Outdoor Particulate Matter Purifier and Outdoor Particulate Matter Purification System Having the Same}

The present invention relates to an outdoor fine dust purifier and an outdoor fine dust purification system including the same, and more particularly, after inhaling and purifying contaminated air existing in a breathing area 2.5 meters from the ground, which is a human activity space, By forming a discharge partition layer so that the air can be discharged to the same area, damage due to fine dust is minimized, and R-type and L-type operations are performed according to the air flow, which is useful for removing outdoor fine dust, and is adsorbed to the dust collecting pole. The formed fine dust film can be automatically removed by the operation of the outdoor fine dust purifier, thus preventing the increase in the shape of the outdoor fine dust purifier or the difficulty that a person has to control it directly, and the replacement of the dust collecting electrode is not required. As the outdoor fine dust purifiers work in conjunction with each other, one large flow of air compatible with the atmospheric flow can be formed, and thus an outdoor fine dust purifier capable of forming an area of fresh and unpolluted air in a partition layer of a predetermined height. It relates to an outdoor fine dust purification system including this.

In general, air contains a large amount of fine particles that are harmful to the human body.

The factors for generating such fine dust are divided into artificial and natural factors.

Anthropogenic factors include fixed sources such as coal-fired power plants and industrial complexes, mobile sources such as urban automobiles, marine vessels, and heavy equipment at construction sites, and sporadic sources such as construction sites, forest fires, and waste incineration.

Natural factors include soil dust, salting of sea water, and plant pollen.

Of these, coal power plants, which are the main cause of fine dust, will be newly expanded by 4 units (8 gigawatts) in Korea by 2022, and 460 units (259 gigawatts) in China will be newly expanded, rather than reducing fine dust over the next few years. The situation is expected to increase continuously.

According to medical standards, ultrafine dust with PM2.5㎍/㎥ or less is designated as a first-class carcinogen by the World Health Organization (WHO), warning of human damage.

In addition, during acute exposure, coughing and breathing difficulties occur due to irritation of the airways, asthma worsens, and arrhythmia occurs. Chronic exposure can reduce lung function, increase chronic bronchitis, and increase mortality. In particular, people with heart or lung disease, children, the elderly, and pregnant women are more affected by exposure to fine dust, and even healthy adults are affected by exposure to high concentrations.

When the concentration of fine dust increased by 10㎍/㎥, the mortality rate increased by 27 times for myocardial infarction, 20 times for diabetes, and 25 times for people with heart transition. There have been reports of direct deaths of children close to ships and even from high concentrations of fine dust. In women of childbearing age, it causes damage such as childbirth and premature birth.

The Organization for Economic Cooperation and Development (OECD) stated that the number of premature deaths due to air pollution will increase from 3 million globally in 2010 to 6 million to 9 million in 2060, and increase in medical expenses and crop harvest due to air pollution-related diseases. As a result, it is predicted that a loss of about 315 trillion won, which is about 1% of global GDP, will occur in 2060.

In addition, by 2060, the number of premature deaths due to air pollution will increase rapidly in India, China, and Uzbekistan, including Korea, and if not properly responded, the early mortality rate in Korea in 2060 will more than triple to 1,109 per 1 million people. It warned that Korea will be the only country with more than a thousand OECD member countries in 2060.

According to the 2018 National Statistical Office report, more than 8 people per 10 citizens have anxiety about fine dust, and the degree to which they feel anxiety is more severe than radioactivity and chemicals. As such, fine dust not only directly damages the human body of the people, but also causes great damage psychologically.

The government has also tried various methods such as artificial rainfall research, issuing fine dust reduction measures, and monitoring industrial sites as a countermeasure for fine dust damage, but in the end, it is limited to recommending people to wear masks and refrain from going out to high-risk groups.

Examples of outdoor fine dust purifiers can be seen overseas, and are installed in Italy (Urban Pure Zone), the Netherlands (Smog Free Tower), and China (Cian Smog Tower).

China's 20-story Xi'an Smog Tower is known to have a facility area of about half the area of a soccer field and the height of the purification tower is 100m. The purification tower is made of filters on the walls of the glass greenhouse. With or without sunlight, performance will deteriorate.

China installed an air purification tower in Xi'an, excluding land purchase costs, and spent more than $2 million and 2.2 billion won in installation costs.

In the case of the Netherlands, the Smog Free Tower air purification tower, which is 23 feet (7m) high and costs 54,000 dollars (about 60 million won) to install, is an air purifier installed outdoors, and it Reduces dust by 45%. Although it can filter 30,000㎥ of air per hour by the electric dust collection type, it revealed a problem with maintaining the purification power after the initial stage.

A research team at the Eindhoven Technical University in the Netherlands revealed that there is an effect of reducing fine dust (PM10) by 45% and ultrafine dust (PM25) by 25% to a distance of 10m from the tower, but the effect of reducing fine dust decreases when the wind blows.

The Italian Urban Pure Zone is installed with a campaign concept rather than the effectiveness of fine dust purification and aims to inform the seriousness of fine dust.

As such, outdoor fine dust purifiers are expensive or too large, and have various problems such as effectiveness problems that do not meet the planned performance under natural conditions such as outdoors, meticulous maintenance burden to maintain performance, and restrictions on installation where necessary. .

In addition, until now, the approach has taken the form of a very small amount of dilution for the entire contaminated and infinite atmosphere, rather than as a direct means of reducing damage to the human body by design. Laid.

There is a need for a more direct and effective solution to human damage in outdoor fine dust pollution.

Korean Patent Registration No. 10-1112441

The present invention was conceived to solve the above problems, and an object of the present invention is that after the contaminated air existing in the breathing area 2.5 meters from the ground, which is a human activity space, is inhaled and purified, the purified air is the same. It is to provide an outdoor fine dust purifier capable of minimizing damage due to fine dust by forming a discharge partition layer so that it can be discharged to an area.

Another object of the present invention is to provide an outdoor fine dust purifier capable of removing fine dust even if the wind blows in any direction, since the R-type operation and the L-type operation are performed according to the air flow.

Another object of the present invention is to automatically remove the fine dust film adsorbed on the dust collecting electrode by the operation of the outdoor fine dust purifier, thereby preventing an increase in the shape of the outdoor fine dust purifier or the difficulty that a person has to control it directly, It is to provide an outdoor fine dust purifier that does not require replacement of the dust collecting electrode.

Another object of the present invention is that a plurality of outdoor fine dust purifiers work in conjunction with each other, so that one large flow of air compatible with the air flow can be formed, and thus a region of fresh and uncontaminated air in a partition layer having a predetermined height. It is to provide an outdoor fine dust purification system in which it is formed.

The outdoor fine dust purifier according to the present invention for achieving the above object is provided above the outdoor fine dust purifier, and sprays air introduced from the outside at a predetermined height and a predetermined distance, and is purified from the outdoor fine dust purifier and discharged. An atmospheric layer separation unit that forms a partition layer so that the air can stay in a predetermined area, an intake unit that is formed under the atmospheric layer separation unit and operates to inhale air in the atmosphere according to the direction of the wind, and is connected to one end of the intake unit And a purification unit that purifies the air inhaled through the intake unit by an electric dust collection method, and an exhaust unit connected to one end of the purification unit and operating to exhaust the air purified by the purification unit to the outside according to the direction of the wind , A fine dust film removal unit configured to remove the fine dust film generated through the purification process in the purification unit, a collecting unit connected to one end of the exhaust unit and collecting the fine dust film removed by the fine dust film removing unit, And a discharge part connected to one side of the collecting part and discharging the collected fine dust film to the outside.

The atmospheric layer separation unit includes an R-type accelerator that inhales air and injects it in a right direction when the wind blows from left to right, and the inhaled air forms a vortex to increase the injection speed, an R-type turbine circulator, And an L-type turbine circulator having an L-type accelerator that inhales air and injects it in a left direction when the wind flows from the right to the left, and the inhaled air forms a vortex to increase the injection speed. have.

The intake part is formed on one side of the outdoor fine dust purifier, an R-type first intake part that inhales air when wind blows from left to right, and is formed on the other side of the outdoor fine dust purifier, An L-type first intake part that inhales air when blowing from right to left, and an R-type agent that inhales air when the wind blows from left to right. 2 an intake part, an L-type second intake part formed at a lower side in a diagonal direction of the L-type first intake part, and inhaling air when wind blows from right to left, and the R-type first intake part, the It may include an R-type second intake part, the L-type first intake part, and a main intake part through which the air sucked through the L-type second intake part moves.

The R-type first intake part, an R-type first intake detection sensor that measures the level of fine dust in the air, an R-type first intake pipe through which the inhaled air moves, and allowing the inhaled air to move to the main intake part It may include an R-type first intake valve.

The L-type first intake part, an L-type first intake sensor that measures the level of fine dust in the air, an L-type first intake pipe through which the inhaled air moves, and the inhaled air are allowed to move to the main intake part. It may include an L-shaped first intake valve.

The R-type second intake unit includes an R-type second intake detection sensor that measures the level of fine dust in the air, an R-type second intake pipe through which the inhaled air moves, and allows the inhaled air to move to the main intake unit. It may include an R-type second intake valve.

The L-type second intake part, an L-type second intake detection sensor that measures the level of fine dust in the air, an L-type second intake pipe through which the inhaled air moves, and the inhaled air are allowed to move to the main intake part. It may include an L-shaped second intake valve.

The main intake part includes a main intake pipe, a first intake fan positioned below the main intake pipe and increasing a moving speed of air inhaled from the L-type second intake part and the R-type second intake part, and It is located above the main intake pipe, and may include a second intake fan to increase the moving speed of the air intake from the R-type first intake portion and the L-type first intake portion.

The purification unit includes at least one discharge electrode for imparting an electric charge to the fine dust in the air inhaled through the intake unit, and a plurality of dust collecting electrodes for adsorbing the fine dust charged by the discharge electrode, and the plurality of dust collection Each of the poles may have protrusions located on a different axis.

The exhaust unit is formed on one side of the outdoor fine dust purifier, an L-shaped first exhaust unit that discharges air purified by the purifying unit when the wind blows from right to left, and on the other side of the outdoor fine dust purifier. It is formed, and is formed on the lower side in the diagonal direction of the R-type first exhaust part and the L-type first exhaust part that discharges the air purified by the purification part when the wind blows from left to right. An L-type second exhaust unit that discharges the air purified from the purification unit when blowing to the left, is formed at the lower end of the R-type first exhaust unit in a diagonal direction, and the purifying unit when the wind blows from left to right An R-type second exhaust unit for discharging the air purified from the air, and the air purified by the purification unit is accommodated, and the L-type first exhaust unit, the R-type first exhaust unit, and the L-type second exhaust unit , And a chamber for distributing and moving the purified air to the R-type second exhaust unit, and a main exhaust unit having one end connected to the chamber and discharging the purified air accommodated in the chamber to the outside. have.

The L-type first exhaust unit includes an L-type first exhaust detection sensor that measures fine dust in the purified and discharged air, an L-type first exhaust pipe having one end connected to the chamber and through which the purified air moves, and the L An L-type first exhaust fan provided at a predetermined position of the first-type exhaust pipe and increasing the moving speed of the purified air, and the purified air accommodated in the chamber are allowed to move to the L-type first exhaust pipe. It may include an L-shaped first exhaust valve.

The R-type first exhaust unit includes an R-type first exhaust detection sensor that measures fine dust in the purified and discharged air, an R-type first exhaust pipe having one end connected to the chamber and moving the purified air, and the R An R-type first exhaust fan provided at a predetermined position of the type first exhaust pipe and increasing the moving speed of the purified air, and the purified air accommodated in the chamber are allowed to move to the R-type first exhaust pipe. It may include an R-type first exhaust valve.

The L-type second exhaust unit includes an L-type second exhaust detection sensor for measuring fine dust in the purified and discharged air, an L-type second exhaust pipe having one end connected to the chamber and moving the purified air, and the L An L-type second exhaust fan provided at a predetermined position of the second-type exhaust pipe and increasing the moving speed of the purified air, and the purified air accommodated in the chamber are allowed to move to the L-type second exhaust pipe. It may include an L-shaped second exhaust valve.

The R-type second exhaust unit includes an R-type second exhaust detection sensor that measures fine dust in the purified and discharged air, an R-type second exhaust pipe having one end connected to the chamber and moving the purified air, and the R An R-type second exhaust fan provided at a predetermined position of the second-type exhaust pipe and increasing the moving speed of the purified air, and the purified air accommodated in the chamber are allowed to move to the R-type second exhaust pipe. It may include an R-type second exhaust valve.

The chamber has one end connected to the purification unit, and may include a heating pipe positioned in the chamber, a heating coil provided in the heating pipe, and a temperature sensor provided at a predetermined position in the chamber.

The main exhaust unit includes a main exhaust pipe having one end connected to the chamber, a main exhaust fan provided at a predetermined position of the main exhaust pipe and increasing a moving speed of the purified air, and purified air accommodated in the chamber. It may include a main exhaust valve allowing the movement to the main exhaust pipe.

The fine dust film removal unit may include a water collecting tank located above the atmospheric layer separation part, one end connected to the water collecting tank, and the other end connected to the purification part, and provided at a location where the water collecting tank and the water collecting pipe are connected. A first inlet valve, a second inlet valve provided at a position where the water collecting pipe and the purification unit are connected, and located between a plurality of dust collecting electrodes in the purification unit, and removing fine dust films adsorbed on the plurality of dust collecting electrodes It may include a plurality of bidirectional fans.

The collecting unit may include a collecting valve connected to the exhaust unit, a collecting filter positioned below the collecting valve and collecting the removed fine dust film, and a fan for removing the fine dust film collected by the collecting filter. I can.

The discharge unit is connected to the collecting unit, a discharge pipe through which the fine dust film collected in the collecting unit is moved and discharged, a first discharge valve formed at one end of the discharge pipe, and a first discharge valve formed at the other end of the discharge pipe. 2 The discharge valve, and formed at the lower end of the discharge pipe, may include a strainer for filtering fine dust passing through the second discharge valve.

The discharge unit further includes a reverse flow pipe positioned below the discharge pipe in a direction parallel to the discharge pipe, a reverse flow valve provided at a connection portion between the discharge pipe and the reverse flow pipe, and a water level sensor positioned within the reverse flow pipe. can do.

The outdoor fine dust purification system according to the present invention for achieving the other object is communicatively connected with at least one outdoor fine dust purifier and the at least one outdoor fine dust purifier, and the at least one outdoor fine dust A server for receiving predetermined data from the purifier, storing and analyzing the predetermined data, and a center communicatively connected to the server and receiving the predetermined data and analysis data from the server may be included. .

The predetermined data and analysis data include the installation location of the outdoor fine dust purifier, the fine dust value in the air by time, the fine dust value in the purified air, temperature, humidity, the malfunction of the outdoor fine dust purifier, and the outdoor fine dust purifier. Can include impact detection.

The at least one outdoor fine dust purifier includes a master outdoor fine dust purifier and a slave outdoor fine dust purifier that is installed at a location spaced apart from the master outdoor fine dust and operates in conjunction with the master outdoor fine dust purifier. In addition, the master outdoor fine dust purifier and the slave outdoor fine dust purifier may operate in conjunction with each other according to the direction of the wind to form a flow of air compatible with the air flow.

According to the present invention, there is an advantage of minimizing damage to the human body due to fine dust by forming a discharge partition layer through an atmospheric layer separator so that purified air can be discharged to a person's outdoor activity space.

In addition, since the purification process by the R-type operation and the purification process by the L-type operation are performed according to the direction of the wind, there is an advantage in that fine dust can be removed even if the wind blows in any direction.

In addition, since the fine dust adsorbed on the dust collecting electrode can be removed by the operation of the fine dust removal unit, there is no need to replace the dust collecting electrode to remove the fine dust film adsorbed on the dust collecting electrode, and as a result, convenience of maintenance and Economic feasibility can be pursued.

In addition, since a plurality of outdoor fine dust purifiers work in conjunction with each other, one large flow of air compatible with the air flow can be formed, and thus, an area of fresh and unpolluted air is formed in the partition layer at a predetermined height. have.

1 schematically shows the exterior of an outdoor fine dust purifier according to an embodiment of the present invention.
2 is a schematic cross-sectional view of an outdoor fine dust purifier according to an embodiment of the present invention.
3 schematically shows an atmospheric layer separation part of an outdoor fine dust purifier according to an embodiment of the present invention.
4 schematically shows an intake part of an outdoor fine dust purifier according to an embodiment of the present invention.
5 schematically shows a purification part of an outdoor fine dust purifier according to an embodiment of the present invention.
6 schematically shows one of the plurality of dust collecting electrodes shown in FIG. 5.
7 schematically shows an exhaust part of an outdoor fine dust purifier according to an embodiment of the present invention.
8 schematically shows a process of intake of external air and exhaust of purified air (R-type operation) when wind blows from left to right.
9 schematically shows the purification process (R-type operation) when the wind blows from left to right.
10 schematically shows a process of intake of external air and exhaust of purified air (L-type operation) when wind blows from right to left.
11 schematically shows a purification process (L-type operation) when the wind blows from right to left.
12 schematically illustrates a chamber part according to an embodiment of the present invention.
13 schematically illustrates a part of a fine dust film removing part of an outdoor fine dust purifier according to an embodiment of the present invention.
14 schematically shows a collecting part and a discharge part of an outdoor fine dust purifier according to an embodiment of the present invention.
15 is a diagram schematically illustrating a fine dust film removing unit, a collecting unit, and a discharge unit according to an embodiment of the present invention.
16 schematically shows a discharge unit according to another embodiment according to the present invention.
17 is a schematic view of a collecting part, a discharge part, and a sample collecting part of an outdoor fine dust purifier according to an embodiment of the present invention.
18 schematically illustrates an outdoor fine dust purification system according to an embodiment of the present invention.
FIG. 19 schematically illustrates a state in which the master outdoor fine dust purifier and the slave outdoor fine dust purifier according to an embodiment of the present invention operate in conjunction with each other.

It should be noted that technical terms used in the present specification are only used to describe specific embodiments, and are not intended to limit the present invention. In addition, the technical terms used in the present specification should be interpreted as generally understood by those of ordinary skill in the technical field to which the present invention belongs, unless otherwise defined in the present specification, and excessively comprehensive It should not be construed as a human meaning or an excessively reduced meaning. In addition, when a technical term used in the present specification is an incorrect technical term that does not accurately express the spirit of the present invention, it should be replaced with a technical term that can be correctly understood by those skilled in the art.

In addition, general terms used in the present invention should be interpreted as defined in the dictionary or according to the context before and after, and should not be interpreted as an excessively reduced meaning.

In addition, the singular expression used in the present specification includes a plurality of expressions unless the context clearly indicates otherwise. In the present application, terms such as "consist of" or "include" should not be construed as necessarily including all of the various elements or various steps described in the specification, and some of the elements or some steps It may not be included, or it should be interpreted that it may further include additional elements or steps.

Hereinafter, the present invention will be described in more detail through examples, but the scope of the present invention is not limited to the following examples.

1 schematically shows the exterior of an outdoor fine dust purifier according to an embodiment of the present invention. 2 is a schematic cross-sectional view of an outdoor fine dust purifier according to an embodiment of the present invention.

1 and 2, the outdoor fine dust purifier 1000 according to an embodiment of the present invention includes a main body M, an atmospheric layer separation unit 100, an intake unit 200, a purification unit 300, and an exhaust unit. It may include 400, a fine dust film removing unit 500, a collecting unit 600, and a discharge unit 700.

The outside of the main body M may include a measurement display unit that displays a color change according to the concentration of air pollution in the atmosphere.

The atmospheric layer separation unit 100 is provided above the outdoor fine dust purifier 1000, and strongly injects air introduced from the outside at a predetermined distance, so that when the purified air is discharged to the outside, the purified air is only in a predetermined area. A predetermined partition layer is formed so as to stay.

When people are active outside, the height of the active area is limited. When the atmospheric layer separation unit 100 strongly injects air, the air that is purified and discharged to the outside stays in the active area (height) of the people. As a result, it is possible to minimize the damage caused by fine dust when people do outside activities.

The intake part 200 is formed under the atmospheric layer separating part 100 and flexibly inhales air in the atmosphere according to the direction of the wind.

The purification unit 300 purifies the air inhaled through the intake unit 200 using an electric dust collection method.

The exhaust unit 400 exhausts the air purified by the purification unit 300 to the outside.

The fine dust film removal unit 500 is generated through a purification process in the purification unit 300 to remove the fine dust film adsorbed on the dust collecting electrode of the purification unit 300.

The collecting part 600 collects the removed fine dust film.

The discharge part 700 is connected to one side of the collecting part, and discharges the collected fine dust film to the outside.

Hereinafter, each component of the outdoor fine dust purifier 1000 will be described in more detail.

3 schematically shows an atmospheric layer separation part of an outdoor fine dust purifier according to an embodiment of the present invention.

Referring to FIG. 3, the atmospheric layer separation unit 100 may include an R-type turbine circulator 110 and an L-type turbine circulator 120.

When the wind blows from left to right, the R-type turbine circulator 110 inhales air and injects it in the right direction.

The R-type turbine circulator 110 may include an R-type intake port 111, an R-type intake and exhaust pipe 112, an R-type accelerator 113, and an R-type exhaust port 114.

The process of injecting air through the R-type turbine circulator 110 will be described as follows.

When the wind blows from left to right, external air is inhaled into the R-type inlet 111, and the inhaled air moves through the R-type intake and exhaust pipe 112.

At this time, the inhaled air passes through the R-type accelerator 113 provided in the R-type intake and exhaust pipe 112 and a vortex is formed to increase the moving speed, and the air with an increased movement speed is the R-type exhaust port 114) is sprayed to the outside at high speed.

When the wind blows from right to left, the L-type turbine circulator 120 inhales air and injects it to the left.

The L-type turbine circulator 120 may include an L-type intake port 121, an L-type intake and exhaust pipe 122, an L-type accelerator 123, and the L-type exhaust port 124.

The process of injecting air through the L-type turbine circulator 120 is the same only as the process of injecting air through the R-type turbine circulator 110 and the direction thereof are the same, so a description thereof will be omitted.

As described above, according to the present invention, since air is strongly injected from the outdoor fine dust purifier through the atmospheric layer separation unit to form a predetermined partition layer from the ground to a predetermined height, the air purified by the outdoor fine dust purifier and discharged to the outside is within the predetermined partition side. You will be able to stay. As a result, clean air can stay in a predetermined area from the ground where people are mainly active, thereby reducing damage due to fine dust.

4 schematically shows an intake part of an outdoor fine dust purifier according to an embodiment of the present invention.

3, the intake part 200 includes an R-type first intake part 210, an L-type first intake part 220, an R-type second intake part 230, and an L-type second intake part 240. ), and a main intake part 250.

The R-type first intake part 210 is formed on one side of the outdoor fine dust purifier, and inhales air when the wind blows from left to right.

The R-type first intake part 210 includes an R-type first intake detection sensor 211 that detects the level of fine dust in the air, an R-type first intake pipe 212 through which the inhaled air moves, and the inhaled air. May include an R-type first intake valve 213 that enables movement to the main intake part 250.

The L-shaped first intake unit 220 is formed on the other side of the outdoor fine dust purifier, and inhales air when the wind blows from right to left.

The L-type first intake part 220 includes an L-type first intake detection sensor 221 that detects a level of fine dust in the air, an L-type first intake pipe 222 through which the inhaled air moves, and the inhaled air. It may include an L-shaped first intake valve 223 that enables movement to the main intake part 250.

The R-type second intake part 230 is formed at the lower end in the diagonal direction of the R-type first intake part 210 and inhales air when the wind blows from left to right.

The R-type second intake unit 230 includes an R-type second intake detection sensor 231 that detects a level of fine dust in the air, an R-type second intake pipe 232 through which the inhaled air moves, and the inhaled air. It may include an R-type second intake valve 233 that enables movement to the main intake part 250.

The L-shaped second intake part 240 is formed at the lower side in the diagonal direction of the L-shaped first intake part 220 and inhales air when the wind blows from right to left.

The L-type second intake part 240 includes an L-type second intake detection sensor 241 that detects a level of fine dust in the air, an L-type second intake pipe 242 through which the inhaled air moves, and the inhaled air. It may include an L-shaped second intake valve 243 to be movable to the main intake part 250.

The main intake part 250 may include a main intake pipe 251, a first intake fan 252, and a second intake fan 253.

The main intake pipe 251 includes the R-type first intake part 210, the R-type second intake part 230, the L-type first intake part 220, and the L-type second intake part ( 240, the R-type first intake part 210, the R-type second intake part 230, the L-type first intake part 220, and the L-type second intake part 240 ) Through the intake air is moved.

The first intake fan 252 is located under the main intake pipe 251, and the moving speed of the air inhaled from the L-type second intake part 240 and the R-type second intake part 230 Increase

The second intake fan 253 is located above the main intake pipe 251, and the moving speed of the air inhaled from the R-type first intake part 210 and the L-type first intake part 220 Increase

Fine dust in the air is removed by the R-type first intake sensor 211, the L-type first intake sensor 221, the R-type second intake sensor 231, and the L-type first intake sensor 241. When measured, the measured value may be displayed on the display unit D (FIG. 1) provided on the outer surface of the outdoor fine dust purifier 1000 (FIG. 1). In addition, in the lighting unit on the outer surface of the outdoor fine dust purifier 1000, the measured value may be classified into stages (good, normal, bad, very bad, etc.) and lighted.

In addition, measured values of air pollutants such as volatile organic compounds or nitrogen oxides may be displayed on the display unit D.

5 schematically shows a purification part of an outdoor fine dust purifier according to an embodiment of the present invention.

Referring to FIG. 5, the purification unit 300 may include at least one discharge electrode 310 and a plurality of dust collecting electrodes 320.

The at least one discharge electrode 310 imparts charge to fine dust in the air inhaled through the intake part 200.

Fine dust charged by the discharge electrode 310 is adsorbed to the plurality of dust collecting electrodes 320.

In the present embodiment, as shown in FIG. 5, the at least one discharge electrode 310 includes a first discharge electrode 311 and a second discharge electrode 312, but is not limited thereto, and one discharge electrode, 3 It may include more than one discharge electrode.

In addition, in this embodiment, the plurality of dust collecting electrodes 320 are the first dust collecting electrode 321, the second dust collecting electrode 322, the third dust collecting electrode 323, the fourth dust collecting electrode 324, and the fifth dust collecting electrode. It consists of (325), but is not necessarily limited thereto, it is possible if there are two or more.

6 schematically shows one of the plurality of dust collecting electrodes shown in FIG. 5.

Referring to FIG. 6, the dust collecting electrode 321 according to an embodiment of the present invention may include four brackets 321a, 321b, 321c, and 321d.

Looking at the enlarged drawing of one bracket (321a), a plurality of triangular protrusions (A, B, C, E, F, G, H, I, J, K, L, M) are formed on the bracket (321a) Has been.

In the case of the protrusions (A, E, H, K) arranged in the longitudinal direction, they are not located on the same axis, but are located on different axes, thus forming an asymmetric structure.

The same asymmetric structure can be formed in each of the protrusions B, F, I, and L arranged in the longitudinal direction and the protrusions C, G, J, and M arranged in the longitudinal direction.

In addition, in the case of the front and rear brackets, a spiral structure can be formed.

In this embodiment, a shape having a triangular protrusion, but in an alternative embodiment, as shown in FIG. 6, a protrusion T having a shape of overlapping two triangles may be provided, and such protrusions may be provided with a plurality of brackets. Can be formed in

7 schematically shows an exhaust part of an outdoor fine dust purifier according to an embodiment of the present invention.

Referring to FIG. 7, the exhaust part 400 includes an L-type first exhaust part 410, an R-type first exhaust part 420, an L-type second exhaust part 430, and an R-type second exhaust part ( 440, a chamber 450 and a main exhaust part 460 may be included.

The L-shaped first exhaust unit 410 is formed on one side of the outdoor fine dust purifier, and may discharge the air purified by the purifying unit 300 when wind blows from right to left. The detailed configuration of the L-shaped first exhaust part 410 is as follows.

The L-type first exhaust part 410 includes an L-type first exhaust detection sensor 411, an L-type first exhaust pipe 412, an L-type first exhaust fan 413, and an L-type first exhaust valve 414 It may include.

The L-type first exhaust detection sensor 411 may measure the level of fine dust in air that is purified and discharged to the outside.

One end of the L-shaped first exhaust pipe 412 is connected to the chamber 450, and the purified air moves.

The L-shaped first exhaust fan 413 is provided at a predetermined position of the L-shaped first exhaust pipe 412 and may increase a moving speed of the purified air.

When the L-shaped first exhaust valve 414 is opened, the purified air accommodated in the chamber 450 is allowed to move to the L-shaped first exhaust pipe 412.

The R-type first exhaust part 420 is formed on the other side of the outdoor fine dust purifier, and when wind blows from left to right, the air purified by the purifying unit 300 may be discharged. The detailed configuration of the R-type first exhaust part 420 is as follows.

The R-type first exhaust part 420 includes an R-type first exhaust detection sensor 421, an R-type first exhaust pipe 422, an R-type first exhaust fan 423 and an R-type first exhaust valve 424 It may include.

The R-type first exhaust detection sensor 421 may measure the level of fine dust in air that is purified and discharged to the outside.

The R-type first exhaust pipe 422 has one end connected to the chamber 450, and the purified air moves.

The R-type first exhaust fan 423 is provided at a predetermined position of the R-type first exhaust pipe 422 and may increase a moving speed of the purified air.

When the R-type first exhaust valve 424 is opened, the purified air accommodated in the chamber 450 is allowed to move to the R-type first exhaust pipe 422.

The L-type second exhaust part 430 is formed at the lower side in the diagonal direction of the L-type first exhaust part 410, and when the wind blows from right to left, the air purified by the purification part 300 Can be discharged. The detailed configuration of the L-shaped second exhaust part 430 is as follows.

The L-type second exhaust part 430 includes an L-type second exhaust detection sensor 431, an L-type second exhaust pipe 432, an L-type second exhaust fan 433, and an L-type second exhaust valve 434. It may include.

The L-shaped second exhaust sensor 431 may measure the level of fine dust in the air that is purified and discharged to the outside.

One end of the L-shaped second exhaust pipe 432 is connected to the chamber 450, and the purified air moves.

The L-shaped second exhaust fan 433 is provided at a predetermined position of the L-shaped second exhaust pipe 432 and may increase a moving speed of the purified air.

When the L-shaped second exhaust valve 434 is opened, the purified air accommodated in the chamber 450 is allowed to move to the L-shaped second exhaust pipe 432.

The R-type second exhaust part 440 is formed at the lower side in the diagonal direction of the R-type first exhaust part 420, and the air purified by the purification part 300 when wind blows from left to right Can be discharged. The detailed configuration of the R-type second exhaust part 440 is as follows.

The R-type second exhaust part 440 includes an R-type second exhaust detection sensor 441, an R-type second exhaust pipe 442, an R-type second exhaust fan 443 and an R-type second exhaust valve 444 It may include.

The R-type second exhaust sensor 441 may measure the level of fine dust in the air that is purified and discharged to the outside.

The R-type second exhaust pipe 442 has one end connected to the chamber 450, and the purified air moves.

The R-type second exhaust fan 443 is provided at a predetermined position of the R-type second exhaust pipe 442 and may increase the moving speed of the purified air.

When the R-type second exhaust valve 444 is opened, the purified air accommodated in the chamber 450 is allowed to move to the R-type first exhaust pipe 442.

In the purified air by the R-type first exhaust detection sensor 421, L-type first exhaust detection sensor 411, R-type second exhaust detection sensor 441, and L-type second exhaust detection sensor 431 When the fine dust is measured, the measured value may be displayed on the display unit D (FIG. 1) provided on the outer surface of the outdoor fine dust purifier 1000 (FIG. 1).

The chamber 450 accommodates the air purified by the purification unit 300, and converts the recirculated air into an L-type first exhaust unit 410, an R-type first exhaust unit 420, and an L-type second exhaust. It can be distributed and moved to the base 430 and the R-type second exhaust part 440.

The chamber 450 may include a heating tube 451, a heating coil 452, and a temperature sensor 453.

One end of the heating pipe 451 is connected to the purification unit 300 and may be located in the chamber 450.

The heating coil 452 may be provided in the heating tube 451.

The temperature sensor 453 is provided at a predetermined position in the chamber 450, and at least one or more of the temperature sensors 453 may be provided.

The chamber 450 may further include a heating pipe valve 454. When water enters the heating pipe 451, the heating coil 452 and the water come into contact, and as a result, a fire may occur due to a short circuit. In order to prevent this, the heating pipe valve 454 needs to be installed.

One end of the main exhaust part 460 is connected to the chamber 450 and may move purified air accommodated in the chamber 450.

The detailed configuration of the main exhaust part 460 is as follows.

The main exhaust part 460 may include a main exhaust pipe 461, a main exhaust fan 462, and a main exhaust fan 463.

One end of the main exhaust pipe 461 is connected to the chamber 450.

The main exhaust fan 462 is provided at a predetermined position of the main exhaust pipe 461 and may increase the moving speed of the purified air.

When the main exhaust valve 463 is opened, the purified air accommodated in the chamber 450 is allowed to move to the main exhaust pipe 461.

The exhaust part 400 may further include an exhaust circulation first intake valve 471 and an exhaust circulation pipe 472. When the cleanliness of the purified air in the high-concentration state is insufficient, it flows back into the intake pipe so that a series of purification processes can be performed again.

Hereinafter, a process of inhaling external air through an intake unit, a purification unit, and an exhaust unit according to an embodiment of the present invention, purifying fine dust, and exhausting the purified air will be described.

8 schematically shows a process of intake of external air and exhaust of purified air (R-type operation) when wind blows from left to right. 9 schematically shows the purification process (R-type operation) when the wind blows from left to right.

Referring to FIGS. 8 and 9, when the measured value of fine dust in the air measured by the R-type first intake sensor 211 (FIG. 4) exceeds a preset value, the outdoor fine dust purifier starts to operate.

The air inhaled through the R-type first intake part 210 moves to the R-type first intake pipe 212. The R-type first intake valve 213 located between the R-type first intake pipe 212 and the main intake pipe 251 is controlled to be opened, and the R-type first intake valve 213 is opened. The air in the first intake pipe 212 moves to the main intake pipe 251 of the main intake part 250.

At this time, the moving speed of the air moved to the main intake pipe 251 is increased by the second intake fan 253 positioned above the main intake pipe 251.

Air that has moved through the main intake pipe 251 is introduced into the purification unit 300.

The air introduced into the purification unit 300 passes through the first discharge electrode 311 and the second discharge electrode 312, whereby electric charges are applied to fine dust in the air.

The first discharge electrode 311 and the second discharge electrode 312 may be operated simultaneously or selectively according to a measurement value of fine dust by the R-type first intake sensor 211.

For example, if the measured value of the fine dust is less than or equal to a predetermined value, only the first discharge electrode 311 is operated, and if it exceeds a predetermined value (when the concentration of fine dust is high), the first discharge electrode 311 and the second discharge electrode 312 All of this can work.

Air containing fine dust to which electric charges are applied passes through the plurality of dust collecting electrodes 320, wherein the fine dust to which electric charges are applied is adsorbed to the plurality of dust collecting electrodes 320. In this embodiment, the plurality of dust collecting electrodes 320 are the first dust collecting electrode 321, the second dust collecting electrode 322, the third dust collecting electrode 323, the fourth dust collecting electrode 324, and the fifth dust collecting electrode ( 325).

The amount of fine dust adsorbed on the dust collecting electrode gradually decreases from the first dust collecting electrode 321 to the fifth dust collecting electrode 325.

The first dust collecting electrode 321, the second dust collecting electrode 322, the third dust collecting electrode 323, and the fourth dust collecting electrode 324 according to the measured value of the fine dust by the R-type first intake sensor 211 The operation of the fifth dust collecting electrode 325 may be performed simultaneously or selectively.

For example, when the measured value of the fine dust is less than or equal to a predetermined value, only the first dust collecting electrode 321, the third dust collecting electrode 323, and the fifth dust collecting electrode 325 are operated, and when it exceeds a predetermined value (fine dust concentration is Severe case) All of the first dust collecting electrode 321, the second dust collecting electrode 322, the third dust collecting electrode 323, the fourth dust collecting electrode 324, and the fifth dust collecting electrode 325 may be operated.

On the other hand, by the operation of the first intake fan 252, external air is sucked into the R-shaped second intake unit 230. The inhaled air moves to the R-type second intake pipe 232. The R-type second intake valve 233 located between the R-type second intake pipe 232 and the main intake pipe 251 is controlled to be opened, and the R-type second intake valve 233 is opened. The air in the second intake pipe 232 moves to the main intake pipe 251 of the main intake part 250.

At this time, the moving speed of the air moved to the main intake pipe 251 is increased by the first intake fan 252 positioned below the main intake pipe 251.

Air that has moved through the main intake pipe 251 is introduced into the purification unit 300.

Since the purification process in the purification unit 300 is the same as described above, a description thereof will be omitted.

The air from which fine dust has been removed from the purification unit 300 moves into the chamber 450.

The air moved into the chamber 450 is moved to the L-type first exhaust part 410, the L-type second exhaust part 430, and the main exhaust part 460 and is discharged to the outside.

First, the process of exhausting air through the L-type first exhaust part 410 will be described in more detail, the L-type first exhaust valve 414 is controlled to be opened, and the opened L-type first exhaust valve 414 is Through this, the air in the chamber 450 moves to the L-shaped first exhaust pipe 412. The moved air is increased in its moving speed by the L-shaped first exhaust fan 413. Air moving in the L-shaped first exhaust pipe 412 is discharged to the outside through an opening of the L-shaped first exhaust pipe 412.

When the process of exhausting air through the L-type second exhaust part 430 is described in detail, the L-type second exhaust valve 434 is controlled to be opened, and a chamber through the opened L-type second exhaust valve 434 is described in detail. The air in 450) moves to the L-shaped second exhaust pipe 432. The moved air is increased in its moving speed by the L-shaped second exhaust fan 433. Air moving in the L-shaped second exhaust pipe 432 is discharged to the outside through the opening of the L-shaped second exhaust pipe 432.

When the process of exhausting air through the main exhaust unit 460 is described in detail, the main exhaust valve 463 is controlled to be opened, and the air in the chamber 450 through the opened main exhaust valve 463 is transferred to the main exhaust pipe 461 Move to ). The movement speed of the moved air is increased by the main exhaust fan 462. Air moving in the main exhaust pipe 461 is discharged to the outside through an opening of the main exhaust pipe 461.

10 schematically shows a process of intake of external air and exhaust of purified air (L-type operation) when wind blows from right to left. 11 schematically shows a purification process (L-type operation) when the wind blows from right to left.

10 and 11, air inhaled through the L-type first intake unit 220 moves to the L-type first intake pipe 222. The L-type first intake valve 223 positioned between the L-type first intake pipe 222 and the main intake pipe 251 is controlled to be opened, and an L-type through the opened L-type first intake valve 223 The air in the first intake pipe 212 moves to the main intake pipe 251 of the main intake part 250.

At this time, the moving speed of the air moved to the main intake pipe 251 is increased by the second intake fan 253 positioned above the main intake pipe 251.

Air that has passed through the second intake fan 253 is introduced into the purification unit 300.

A plurality of dust collecting electrodes 321 to 325 are adsorbed to the fine dust contained in the air while undergoing the purification process in the purification unit illustrated in FIG. 11. Since the detailed description of the purification process is the same as that described above, the description will be omitted.

On the other hand, external air is sucked into the L-shaped second intake part 240 by the operation of the first intake fan 252. The inhaled air moves to the L-shaped second intake pipe 242. The L-type second intake valve 243 positioned between the L-type second intake pipe 242 and the main intake pipe 251 is controlled to be opened, and the L-shaped second intake valve 243 is opened. The air in the second intake pipe 242 moves to the main intake pipe 251 of the main intake part 250.

At this time, the moving speed of the air moved to the main intake pipe 251 is increased by the first intake fan 252 positioned below the main intake pipe 251.

The air that has passed through the first intake fan 252 passes through the main intake pipe 251 and the second intake fan 253 and is then introduced into the purification unit 300.

Since the purification process through the removal of fine dust in the purification unit 300 is the same as described above, a description thereof will be omitted.

Air from which fine dust has been removed from the purification unit 300 moves into the chamber 450.

The air moved into the chamber 450 is moved to the R-type first exhaust unit 420, the R-type second exhaust unit 440, and the main exhaust unit 460 and is discharged to the outside.

First, the process of exhausting air through the R-type first exhaust unit 420 will be described in more detail, the R-type first exhaust valve 424 (Fig. 7) is controlled to be opened, and the opened R-type first exhaust valve ( Air in the chamber 450 through 424 moves to the R-type first exhaust pipe 422. The moved air is increased in its moving speed by the R-type first exhaust fan 423. Air moving in the R-type first exhaust pipe 422 is discharged to the outside through the opening of the R-type first exhaust pipe 422.

When the process of exhausting air through the R-type second exhaust part 440 is described in detail, the R-type second exhaust valve 444 is controlled to be opened, and the chamber is cooled through the opened R-type second exhaust valve 434. The air in 450) moves to the R-type second exhaust pipe 442. The moved air is increased in its moving speed by the R-type second exhaust fan 443. Air moving in the R-type second exhaust pipe 442 is discharged to the outside through the opening of the R-type second exhaust pipe 442.

When the process of exhausting air through the main exhaust unit 460 is described in detail, the main exhaust valve 463 is controlled to be opened, and the air in the chamber 450 through the opened main exhaust valve 463 is transferred to the main exhaust pipe 461 Move to ). The movement speed of the moved air is increased by the main exhaust fan 462. Air moving in the main exhaust pipe 461 is discharged to the outside through an opening of the main exhaust pipe 461.

As described above, according to the present invention, when the direction of the wind blows from left to right, the purification process by the R-type operation is performed, and when the direction of the wind blows from right to left, the purification process by the L-type operation is performed, There is an advantage that outdoor fine dust can be easily removed no matter which direction the wind blows.

In addition, since the above-described operation of forming a partition layer by the atmospheric layer separation unit 100 is also performed, the purified air discharged to the outside stays in the active area of the people, thereby minimizing damage due to outdoor fine dust.

Next, a process of heating the air exhausted through the outdoor fine dust purifier in winter will be described.

12 schematically illustrates a chamber part according to an embodiment of the present invention.

Referring to FIG. 12, a heating tube 451 is formed in the chamber 450, and a heating coil 452 is provided in the heating tube 451.

In addition, a temperature sensor 453 is provided outside the heating tube 451 in the chamber 450. In this embodiment, two temperature sensors 453 are provided in the chamber 450, but in an alternative embodiment, one or three or more temperature sensors may be provided.

The temperature of the purified air in the chamber is measured by the temperature sensor 453. When the measured value exceeds the preset value, it is controlled to apply a voltage to the heating coil 452 and heating is started.

The purified air accommodated in the chamber 450 is heated by the heating, and the heated air is an R-type first exhaust part 420, an R-type second exhaust part 440, and an L-type first exhaust part 410. ), the L-shaped second exhaust unit 430, and the main exhaust unit 460 are discharged to the outside.

When the heated air is discharged to the outside, not only does not feel cold when it comes into contact with the human body, but also convection caused by overdiffusion of air can be suppressed.

13 schematically illustrates a part of a fine dust film removing part of an outdoor fine dust purifier according to an embodiment of the present invention.

Referring to FIG. 13, the fine dust film removing unit 500 includes a water collecting tank 510, a water collecting pipe 520, a first inlet valve 530, a second inlet valve 540, and a plurality of bidirectional fans 550. It may include.

The water collecting tank 510 may be located above the atmospheric layer separation unit 100 (FIG. 3).

One end of the water collecting pipe 520 may be connected to the water collecting tank 510, and the other end may be connected to the purification part 300.

The first intake valve 530 may be provided at a position where the water collecting tank 510 and the water collecting pipe 520 are connected.

The second intake valve 540 may be provided at a position where the water collecting pipe 520 and the purification unit 300 are connected.

The plurality of bidirectional fans 550 are positioned between a plurality of dust collecting electrodes 320 (FIG. 5) in the purification unit 300 and serve to remove fine dust films adsorbed on the plurality of dust collecting electrodes 320. do.

According to another alternative embodiment, the fine dust film removing unit of the present invention may further include at least one water level sensor in a region where the dust collecting electrode is located.

The water level sensor senses how much water is supplied from the water collecting tank in the location of the dust collecting electrode. Based on this sensing value, the amount of water supplied from the water collecting tank may be adjusted.

14 schematically shows a collecting part and a discharge part of an outdoor fine dust purifier according to an embodiment of the present invention.

Referring to FIG. 14, the collection unit 600 includes a collection valve 610, a collection filter 620 and a fan 630, a detection sensor 640, a detection sensor valve 650, and a water level sensor 660. Can include.

The collection valve 610 is connected to the chamber 450 (FIG. 7) of the exhaust part 400. In the present embodiment, the collection valve 610 includes a first collection valve 611 and a second collection valve 612, but is not limited thereto.

The collection filter 620 is located under the collection valve 610 and collects the removed fine dust. In the present exemplary embodiment, the collection filter 620 includes a first collection filter 621 and a second collection filter 622, but is not limited thereto.

The fan 630 is located under the collection filter 620 and removes the collected fine dust. In the present embodiment, the fan 630 includes a first fan 631 and a second fan 632, but is not limited thereto.

The detection sensor 640 measures the accumulated value of fine dust collection of the collection unit.

The detection sensor valve 650 is controlled to be opened when the collection accumulated value is measured by the detection sensor 640.

The water level sensor 660 measures the level of the amount of water in the collection unit.

In another alternative embodiment, the collection unit 600 may omit the detection sensor 640, the detection sensor valve 650, and the water level sensor 660.

Meanwhile, the discharge unit 700 may include a first discharge valve 710, a discharge pipe 720, a second discharge valve 730, and a strainer 740.

The first discharge valve 710 is connected to the collecting part 700.

The discharge pipe 720 is connected to the first discharge valve 710 and is a pipe through which fine dust moves.

The second discharge valve 730 is provided at a lower end of the discharge pipe 720 on the opposite side of the first discharge valve 710.

The strainer 740 serves to filter fine dust that has passed through the second discharge valve 730 and is provided at the lowermost end of the discharge pipe 720.

Hereinafter, a process of removing and discharging the fine dust film through the fine dust film removing unit, the collecting unit, and the discharge unit according to an embodiment of the present invention will be described.

15 is a diagram schematically illustrating a fine dust film removing unit, a collecting unit, and a discharge unit according to an exemplary embodiment of the present invention.

9 and 15, when the purification process in the purification unit 300 is performed, fine dust is adsorbed to the plurality of dust collecting electrodes 321 to 325 to form a fine dust film.

This fine dust film can be largely removed in two ways.

One method is to generate wind by operating a plurality of bidirectional fans 550 provided between the plurality of dust collecting electrodes 321 to 325, and formed on the plurality of dust collecting electrodes 321 to 325 by the generated wind. It can be removed by brushing off the existing fine dust film.

According to another method, water (tap water, rain, etc.) accommodated in the water collecting tank 510 is discharged to the water collecting pipe 520 while the first inlet valve 530 is opened, and water flowing through the water collecting pipe 520 Is introduced into the purification unit 300 through the second inlet valve 540. At this time, since the third inlet valve 560 located at the end of the discharge electrode 310 of the purification unit 300 is controlled to be closed, the water flowing into the purification unit 300 is directed toward the discharge electrode 310 The flow does not flow in the direction in which the plurality of dust collecting electrodes 321 to 325 are installed.

In addition, in the process of removing the fine dust film, since the exhaust valve 330 of the purification unit 300 is controlled to be closed, the water introduced into the purification unit 300 flows out in the direction of the chamber 450 of the exhaust unit 400. Instead, it stays in the area where the plurality of dust collecting electrodes 321-325 are installed.

As a predetermined time elapses, the fine dust film to which the plurality of dust collecting electrodes 321 to 325 are adsorbed is soaked by water, and the soaked fine dust film is separated from the plurality of dust collecting electrodes 321 to 325. At this time, when the plurality of bidirectional fans 550 are operated, a vortex is generated in the still water, so that the removal efficiency of the fine dust film may be further improved.

The fine dust film thus removed is moved to the collecting unit 600 through the chamber 450.

The collection valve 610 of the collection part 600 is open, and the removed fine dust film passes through the collection valve 610 and is collected by the collection filter 620.

The fine dust film collected by the collection filter 620 is discharged through the discharge unit 700.

At this time, the detection sensor valve 650 is opened and the accumulated collection value is measured by the detection sensor 640. When the measured accumulation accumulation value exceeds the preset value, the collection valve 610 is closed and the fan 630 is operated. Thereafter, the fine dust film collected by the collection filter 620 is discharged through the discharge unit 700.

When the process of discharging the fine dust film through the discharge unit 700 is described in more detail, the first discharge valve 710 of the discharge unit 700 is controlled to open, and the fine dust film passes through the first discharge valve 710 And moves to the discharge pipe 720. The second discharge valve 730 is also controlled to open so that the fine dust film passes through the second discharge valve 730.

At this time, a filter screen 740 is installed at the rear end of the second discharge valve 730, so that the fine dust film is filtered through the filter screen 740, and only water is discharged to the outside.

Next, the process of drying the water after removing the fine dust film will be described.

Referring to FIG. 12 again, in winter, when water remains in the chamber 450, a voltage is applied to the heating coil 452 of the chamber 450 to start heating. The water remaining in the chamber 450 is dried by the heating.

16 schematically shows a discharge unit according to another embodiment according to the present invention.

Referring to FIG. 16, the discharge unit 800 includes a first discharge valve 810, a discharge pipe 820, a second discharge valve 830, a strainer 840, and a reverse flow pipe 850, and a reverse flow valve 860. ), and a water level sensor 870.

The first discharge valve 810, the discharge pipe 820, the second discharge valve 830, and the sieve 840 are the first discharge valve 710, the discharge pipe 720, and the second discharge described with reference to FIG. 14. Since the configuration of the valve 730 and the sieve 740 is the same, a description thereof will be omitted.

The reverse flow pipe 850 is provided below the discharge pipe 720 in a direction parallel to the discharge pipe 720. A backflow valve 860 is provided at a connection portion between the discharge pipe 720 and the backflow pipe 850.

The water level sensor 870 is located in the backflow pipe 850.

The discharge unit 800 is for preventing the occurrence of malfunction and damage of the outdoor fine dust purifier due to reverse flow of the sewer pipe during the summer rainy season.

For example, during or immediately after rainfall, before operating the process of removing the fine dust film, the check valve 860 is opened and measurement by the water level sensor 870 is started. When the measured value exceeds the preset measured value, the first discharge valve 810 and the second discharge valve 830 may be closed, and a backflow alarm signal may be transmitted to the control center.

The control center receiving the backflow alarm signal analyzes the video screen around the outdoor fine dust purifier. When the risk of flooding is identified, all valves in the outdoor fine dust purifier can be closed and all functions of the outdoor fine dust purifier can be stopped.

FIG. 17 schematically shows a collecting part, a discharge part, and a sample collecting part of an outdoor fine dust purifier according to an embodiment of the present invention.

Referring to FIG. 17, the outdoor fine dust purifier may include a collecting unit 600, a discharge unit 700, and a sample collecting unit 900.

Since the configurations of the collection unit 600 and the discharge unit 700 are the same as those described with reference to FIG. 14, a description thereof will be omitted.

The sample collection unit 900 may include a sample collection pipe 910, a first sample collection valve 920, and a second sample collection valve 930.

The first sample collecting valve 920 is formed at one end of the sample collecting pipe 910, and the second sample collecting valve 930 is formed at the other end.

The first sample collection valve 920 is located at a portion connected to the collection unit 600.

18 schematically illustrates an outdoor fine dust purification system according to an embodiment of the present invention.

Referring to FIG. 18, an outdoor fine dust purification system 2000 according to an embodiment of the present invention may include at least one outdoor fine dust purifier, a server, a center, and a terminal.

The at least one outdoor fine dust purifier 2100 is interlocked with each other.

The at least one outdoor fine dust purifier 2100 may include a master outdoor fine dust purifier 2100a and a slave outdoor fine dust purifier 2100b connected to the master outdoor fine dust purifier 2100a.

In this embodiment, a configuration including one master outdoor fine dust purifier and a plurality of slave outdoor fine dust purifiers, but in an alternative embodiment, it may be a configuration of one master outdoor fine dust purifier, or one master outdoor fine dust purifier. It may be a configuration consisting of a fine dust purifier and a single slab outdoor fine dust purifier.

The server 2200 is communicatively connected to the at least one outdoor fine dust purifier 2100, more specifically, a master outdoor fine dust purifier 2100a, and is connected to the master outdoor fine dust purifier 2100a. Thus, predetermined data is received from the at least one outdoor fine dust purifier 2100, and the predetermined data is stored and analyzed.

The center 2300 is communicatively connected with the server 2200, receives the predetermined data from the server 2200, and based on the received data, the operation status of the outdoor fine dust purifier or fine dust It transmits a signal to check the value and take appropriate action.

At this time, the predetermined data includes the installation location of the outdoor fine dust purifier, the number of fine dust in the air per hour, the number of fine dust in the purified air, temperature, humidity, malfunction of the outdoor fine dust purifier, and the impact detection of the outdoor fine dust purifier. Can include.

The terminal 2400 is communicatively connected to the server 2200, and receives the predetermined data from the server 2200. Through the terminal 2400, even a worker outside the center can easily check the operation status of the outdoor fine dust purifier or the measurement of fine dust.

In this embodiment, the terminal 2400 is included, but in an alternative embodiment, the terminal 2400 can be omitted.

19 schematically illustrates a state in which a master outdoor fine dust purifier and a slave outdoor fine dust purifier according to an embodiment of the present invention operate in conjunction with each other.

Referring to FIG. 19, slave outdoor fine dust purifiers 2100b are installed at positions spaced a predetermined distance from both sides of the master outdoor fine dust purifier 2100a.

For example, when the direction of the wind blows from left to right, the master outdoor fine dust purifier 2100a determines the R-type operation, and commands the slave outdoor fine dust purifier 2100b to operate the R-type.

When the master outdoor fine dust purifier 2100a and the slave outdoor fine dust purifier 2100b start the R-type operation, the atmospheric part separation unit 100 (FIG. 3) also starts the R-type operation. As a result, one large flow of air compatible with the atmospheric flow is formed, a region of fresh and uncontaminated air (F) is formed in the partition layer at a predetermined height, and the polluted atmosphere is formed on the upper portion of the predetermined partition layer. A region P is formed.

Therefore, since only fresh and uncontaminated air exists in an area where people are mainly active, there is an advantage of minimizing damage caused by outdoor fine dust.

100 atmospheric layer separation
110 R-type turbine circulator 120 L-type turbine circulator
200 intake
210 R-type first intake part 220 L-type first intake part
230 R-type second intake part 240 L-type second intake part
250 main intake
300 purification section
310 Discharge electrode 320 Dust collecting electrode
400 exhaust
410 L-type first exhaust part 420 R-type first exhaust part
430 L-type second exhaust part 440 R-type second exhaust part
450 chamber 460 main exhaust
500 Fine dust film removal unit
510 Collector 520 Collector
530 First inlet valve 540 Second inlet valve
550 bidirectional fan
600 collector
610 Collection valve 620 Collection filter
630 fan 640 sensor
650 sensor valve 660 water level sensor
700 discharge
710 first discharge valve 720 discharge pipe
730 second discharge valve 740 strainer

Claims (25)

In the outdoor fine dust purifier,
main body;
An intake unit mounted on both sides of the main body and operative to intake air in the atmosphere according to the direction of the wind;
A purification unit connected to one end of the intake unit and purifying the air inhaled through the intake unit through an electric dust collection method;
An exhaust unit connected to one end of the purification unit and operating to exhaust the air purified by the purification unit to the outside according to the direction of the wind;
A fine dust film removal unit configured to remove the fine dust film generated through the purification process in the purification unit;
A collecting part connected to one end of the exhaust part and collecting the fine dust film removed by the fine dust film removing part; And
And a discharge unit connected to one side of the collecting unit and discharging the collected fine dust film to the outside. The method of claim 1,
Separation of the atmospheric layer, which is provided on the top of the outdoor fine dust purifier, and forms a partition layer so that the air purified and discharged from the outdoor fine dust purifier can stay in a predetermined area by spraying air introduced from the outside at a predetermined height and a predetermined distance Part; outdoor fine dust purifier, characterized in that it further comprises. The method of claim 2,
The atmospheric layer separation unit,
An R-type turbine circulator having an R-type accelerator that inhales air and injects it in a right direction when the wind blows from left to right, and the inhaled air forms a vortex to increase the injection speed; And
When the wind flows from the right to the left, the air is inhaled and injected in the left direction, and the inhaled air forms a vortex to increase the injection speed by forming an L-type accelerator, an L-type turbine circulator including; Outdoor fine dust purifier characterized by. The method of claim 1,
The intake part,
An R-type first intake part formed on one side of the outdoor fine dust purifier and inhaling air when wind blows from left to right;
An L-shaped first intake part formed on the other side of the outdoor fine dust purifier and inhaling air when wind blows from right to left;
An R-type second intake part formed at a lower side in a diagonal direction of the R-type first intake part and inhaling air when wind blows from left to right;
An L-shaped second intake part formed at a lower side in the diagonal direction of the L-shaped first intake part and inhaling air when wind blows from right to left; And
And a main intake part through which the air inhaled through the R-type first intake part, the R-type second intake part, the L-type first intake part, and the L-type second intake part moves. Outdoor fine dust purifier. The method of claim 4,
The R-type first intake part,
R-type first intake sensor for measuring the level of fine dust in the air;
An R-type first intake pipe through which the inhaled air moves; And
And an R-type first intake valve that allows inhaled air to move to the main intake part. The method of claim 4,
The L-shaped first intake part,
An L-type first intake air sensor for measuring the level of fine dust in the air;
An L-shaped first intake pipe through which the inhaled air moves; And
And an L-shaped first intake valve that allows inhaled air to be moved to the main intake part. The method of claim 4,
The R-type second intake part,
R-type second intake air sensor for measuring the level of fine dust in the air;
An R-type second intake pipe through which the inhaled air moves;
And an R-type second intake valve that allows the inhaled air to move to the main intake part. The method of claim 4,
The L-shaped second intake part,
L-type second intake air sensor for measuring the level of fine dust in the air;
An L-shaped second intake pipe through which the inhaled air moves; And
And an L-shaped second intake valve that allows inhaled air to move to the main intake part. The method of claim 4,
The main intake part,
Main intake pipe;
A first intake fan located below the main intake pipe and increasing a moving speed of the air inhaled from the L-type second intake part and the R-type second intake part; And
And a second intake fan positioned above the main intake pipe and configured to increase a moving speed of the air sucked from the R-type first intake part and the L-type first intake part. Purifier. The method of claim 1,
The purification unit,
At least one discharge electrode for imparting an electric charge to fine dust in the air inhaled through the intake part; And
Including; a plurality of dust collecting electrodes for adsorbing fine dust charged by the discharge electrode,
Each of the plurality of dust collecting electrodes has a protrusion positioned on a different shaft. The method of claim 1,
The exhaust unit,
An L-shaped first exhaust unit formed on one side of the outdoor fine dust purifier and discharging the air purified by the purifying unit when wind blows from right to left;
An R-type first exhaust unit formed on the other side of the outdoor fine dust purifier and discharging the air purified by the purifying unit when wind blows from left to right;
An L-shaped second exhaust unit formed at a lower side in the diagonal direction of the L-shaped first exhaust unit and configured to discharge the air purified by the purification unit when wind blows from right to left;
An R-type second exhaust part formed at a lower side in the diagonal direction of the R-type first exhaust part and discharging the air purified by the purification part when wind blows from left to right; And
The air purified by the purification unit is accommodated, and the purified air is distributed and moved to the L type first exhaust unit, the R type first exhaust unit, the L type second exhaust unit, and the R type second exhaust unit. Making chamber; And
And a main exhaust unit having one end connected to the chamber and discharging the purified air accommodated in the chamber to the outside. The method of claim 11,
The L-shaped first exhaust part,
L-type first exhaust detection sensor for measuring fine dust in the purified and discharged air;
An L-shaped first exhaust pipe having one end connected to the chamber and through which the purified air moves;
An L-type first exhaust fan provided at a predetermined position of the L-type first exhaust pipe and increasing a moving speed of the purified air; And
And an L-type first exhaust valve that allows the purified air accommodated in the chamber to be moved to the L-type first exhaust pipe. The method of claim 11,
The R-type first exhaust part,
An R-type first exhaust sensor for measuring fine dust in the purified and discharged air;
An R-type first exhaust pipe having one end connected to the chamber and through which the purified air moves;
An R-type first exhaust fan provided at a predetermined position of the R-type first exhaust pipe and increasing a moving speed of the purified air; And
And an R-type first exhaust valve that allows the purified air accommodated in the chamber to be moved to the R-type first exhaust pipe. The method of claim 11,
The L-shaped second exhaust unit,
L-type second exhaust detection sensor for measuring fine dust in the purified and discharged air;
An L-shaped second exhaust pipe having one end connected to the chamber and through which the purified air moves;
An L-shaped second exhaust fan provided at a predetermined position of the L-shaped second exhaust pipe and increasing a moving speed of the purified air; And
And an L-type second exhaust valve that allows the purified air accommodated in the chamber to be moved to the L-type second exhaust pipe. The method of claim 11,
The R-type second exhaust part,
R-type second exhaust detection sensor for measuring fine dust in the purified and discharged air;
An R-type second exhaust pipe having one end connected to the chamber and through which the purified air moves;
An R-type second exhaust fan provided at a predetermined position of the R-type second exhaust pipe and increasing a moving speed of the purified air; And
And an R-type second exhaust valve that allows the purified air accommodated in the chamber to be moved to the R-type second exhaust pipe. The method of claim 11,
The chamber,
A heating pipe having one end connected to the purification unit and positioned in the chamber;
A heating coil provided in the heating tube; And
And a temperature sensor provided at a predetermined position in the chamber. The method of claim 11,
The main exhaust unit,
A main exhaust pipe having one end connected to the chamber;
A main exhaust fan provided at a predetermined position of the main exhaust pipe and increasing a moving speed of the purified air; And
And a main exhaust valve allowing the purified air contained in the chamber to move to the main exhaust pipe. The method of claim 1,
The fine dust film removal unit,
A water collecting tank located above the atmospheric layer separation unit;
A collection pipe having one end connected to the water collecting tank and the other end connected to the purification part;
A first inlet valve provided at a location where the water collecting tank and the water collecting pipe are connected;
A second inlet valve provided at a location where the water collecting pipe and the purification unit are connected; And
And a plurality of bidirectional fans positioned between a plurality of dust collecting electrodes in the purification unit and configured to remove fine dust films adsorbed on the plurality of dust collecting electrodes. The method of claim 1,
The collection unit,
A collecting valve connected to the exhaust part;
A collection filter positioned below the collection valve and collecting the removed fine dust film; And
And a fan for removing the fine dust film collected by the collection filter. The method of claim 1,
The discharge unit,
A discharge pipe connected to the collecting unit and through which the fine dust film collected in the collecting unit is moved and discharged;
A first discharge valve formed at one end of the discharge pipe;
A second discharge valve formed at the other end of the discharge pipe; And
And a strainer formed at a lower end of the discharge pipe to filter fine dust that has passed through the second discharge valve. The method of claim 20,
The discharge unit,
A reverse flow pipe positioned below the discharge pipe in a direction parallel to the discharge pipe;
A backflow valve provided at a connection portion between the discharge pipe and the backflow pipe; And
The outdoor fine dust purifier further comprises a; water level sensor located in the backflow pipe. The method of claim 1,
An outdoor fine dust purifier, characterized in that it further comprises a measurement display unit that displays a color change according to the concentration of air pollution in the atmosphere outside the body. At least one outdoor fine dust purifier according to any one of claims 1 to 22; And
A server communicatively connected to the at least one outdoor fine dust purifier, receiving predetermined data from the at least one outdoor fine dust purifier, and storing and analyzing the predetermined data; And
And a center that is communicatively connected to the server and receives the predetermined data and analysis data from the server. The method of claim 23,
The predetermined data and analysis data,
It characterized in that it comprises the installation location of the outdoor fine dust purifier, the amount of fine dust in the air by time, the number of fine dust in the purified air, temperature, humidity, malfunction of the outdoor fine dust purifier, and impact detection on the outdoor fine dust purifier. Outdoor fine dust purification system. The method of claim 23,
The at least one outdoor fine dust purifier
Master outdoor fine dust purifier; And
Including; a slave outdoor fine dust purifier installed at a location spaced apart from the master outdoor fine dust, and operating in conjunction with the master outdoor fine dust purifier,
The outdoor fine dust purification system, wherein the master outdoor fine dust purifier and the slave outdoor fine dust purifier work in conjunction with each other according to the direction of the wind to form a flow of air compatible with the air flow.

Images