KR20200051516A - Ring electrode structure for additional removal of ultrafine particles in electrostatic spray cyclone - Google Patents

Abstract

The present invention is provided with an exhaust gas inlet pipe for guiding exhaust gas containing particulate contaminants, the cylindrical portion of which is formed an internal space; The upper portion is connected to the lower portion of the cylindrical portion, the lower portion is provided with a liquid outlet, a conical portion of the upper and lower strait structure in which an inner space is formed; A cover provided on the cylindrical portion; One side protrudes to the outside through the cover, the other side is a cylindrical gas discharge pipe located in the interior space of the cylindrical portion; A plurality of liquid supply members arranged around the cylindrical gas discharge pipe; And it relates to an air purifying apparatus using electrostatic spray and electrostatic precipitating, characterized in that it comprises a main wire for connecting the liquid supply member.

Description

Ring electrode structure for additional removal of ultrafine particles in electrostatic spray cyclone

The present invention relates to a dust collecting device using electrostatic spraying and electrostatic precipitation, and more specifically, to remove particulate contaminants contained in exhaust gas by using electrostatic spraying primarily to a dust collecting device having a cyclone structure, and secondaryly The present invention relates to an electrostatic spray that can remove particulate contaminants that are not removed in the electrostatic spray step using electrostatic dust collection and a dust collecting device using electrostatic dust collection.

Gases emitted during incineration of thermal power plants or wastes contain various air pollutants, and among them, particulate pollutants with a small particle size enter the human body and cause respiratory diseases as well as harmful effects on the environment, such as suppressing plant growth. Insane.

Among these air pollutants, in order to manage fine dust (PM2.5) with a diameter of less than 2.5 μm, which is known to be particularly harmful, the US Environmental Protection Agency (EPA) and the European Union (EU) have entered into force in 2013, and Korea has been in law since 2015. It is a situation where the environmental regulations on these substances are strengthened by revising.

Gravity dust collection, inertial dust collection, filter dust collection, cleaning dust collection, and electrostatic dust collection techniques are generally known dust collection technologies. Gravity dust collection technology is a technology that precipitates particles naturally while air moves using the gravity of particles, and inertial dust collection technology is a technology that uses the principle of collecting dust by inertia at a turning point by rapidly changing the direction of gas flow. , It is effective for removing relatively large particles, but can hardly remove fine particles.

On the other hand, it is known that a filtration technology that removes particles by passing gas through a filter having fine pores and an electrostatic precipitation technology that removes electricity by applying a charge to dust to remove dust. However, in the case of filtration technology, since the particles block the fine pores, the throughput of the exhaust gas is drastically reduced, and the frequent replacement of the filter is directly related to the increase in the exhaust gas treatment cost.

In addition, among the electrostatic precipitating techniques, the dry method is performed in the order of particle charging, particle attachment to the dust collecting electrode, desorption of particles attached to the dust collecting electrode, and removal of particles accumulated in the collecting electrode, but unstable corona discharge and electrical characteristics of particles Depending on the electrical resistivity (Particle's resistivity), re-scattering, back corona, etc. occur, and there is a problem in that the dust collection efficiency is lowered. The use of water, the formation of a non-uniform water film in the dust collection, and corrosion have been pointed out as major problems.

Therefore, in order to effectively remove the above-mentioned air pollutants, especially small particles, to achieve an enhanced air quality standard, there is an urgent need to develop a new dust collection device that is economical and has high removal efficiency.

Republic of Korea Registered Patent Publication No. 0150707 Republic of Korea Patent Publication No. 2015-0045068

The present invention has been made to solve the above-mentioned problems, and an object thereof is to provide an air purifying device capable of effectively removing even small particles contained in exhaust gas.

In addition, an object of the present invention is to provide an air purifying device that is simple in operation, simple in structure, and capable of minimizing the amount of secondary pollutants.

An air purifying apparatus using electrostatic spraying and electrostatic dust collection according to an embodiment of the present invention for solving the above problems is provided with an exhaust gas inlet pipe 110 for guiding exhaust gas containing particulate contaminants, and an internal space The cylindrical portion 100 is formed; The upper portion is connected to the lower portion of the cylindrical portion 100, the lower portion is provided with a liquid discharge port 210, the inner space is formed conical portion 200 of the narrow tube structure; A cover 300 provided on the cylindrical portion 100; One side protrudes to the outside through the cover 300, the other side is a cylindrical gas discharge pipe 400 located in the inner space of the cylindrical portion 100; A plurality of liquid supply members 500 arranged around the cylindrical gas discharge pipe 400; And a main wire 600 connecting the liquid supply member 500.

The liquid supply member 500 includes a first liquid supply member 510, a second liquid supply member 520 and a third liquid supply member 530, wherein the first liquid supply member 510 is one side Is projected to the outside through the cover 300, the other side is mounted on the first liquid injection pipe 511 and the first liquid injection pipe 510 in the shape of a rod extending to the inner space of the cylindrical portion 100 It is made of a first injection nozzle 512 positioned to face the inside of the cylindrical portion 100, the second liquid supply member 520, one side penetrates the cover 300 to protrude to the outside, and The side is mounted on the second liquid injection pipe 521 and the second liquid injection pipe 520 in the shape of a rod extending to the inner space of the cylindrical portion 100, the second to be positioned to face the inside of the cylindrical portion 100 It is made of an injection nozzle 522, the third liquid supply member 530, one side penetrates through the cover 300 and protrudes to the outside, the other side is inside the cylindrical portion 100 It is made of a third liquid injection pipe (531) having a rod shape extending to the liver and a third injection nozzle (532) mounted on the third liquid injection pipe (530) and positioned to face the inside of the cylindrical portion (100). , The main wire 600 is characterized in that it is a polygon connecting the other end of the first liquid injection pipe 510, the second liquid injection pipe 520 and the third liquid injection pipe 530.

The liquid supply member 500 includes a first liquid supply member 510, a second liquid supply member 520, a third liquid supply member 530 and a fourth liquid supply member 540, The liquid supply member 510, one side protrudes to the outside through the cover 300, the other side is a first liquid injection pipe 511 in the shape of a rod extending to the inner space of the cylindrical portion 100 and the agent 1 is made of a first injection nozzle 512 is mounted on the liquid injection pipe 510 and positioned to face the inside of the cylindrical portion 100, the second liquid supply member 520, one side is the cover 300 It is projected to the outside through, and the other side is mounted on the second liquid injection pipe 521 and the second liquid injection pipe 520 in the shape of a rod extending to the inner space of the cylindrical portion 100, the cylindrical portion 100 ) Is made of a second injection nozzle 522 positioned to face the inside, the third liquid supply member 530, one side protrudes to the outside through the cover 300, the other side 3rd injection which is mounted on the third liquid injection pipe 531 and the second liquid injection pipe 520 in the shape of a rod extending to the inner space of the base cylindrical portion 100 and positioned to face the inside of the cylindrical portion 100 Made of a nozzle 532, the fourth liquid supply member 540, one side penetrates the cover 300 and protrudes to the outside, the other side is a rod-shaped agent extending to the inner space of the cylindrical portion 100 4 is composed of a fourth injection nozzle 542 mounted on the liquid injection pipe 541 and the fourth liquid injection pipe 540 and positioned to face the inside of the cylindrical portion 100, the main wire 600 is The first liquid injection pipe 510, the second liquid injection pipe 520, the third liquid injection pipe 530 and the fourth liquid injection pipe 541 is a polygon connecting the other end.

The main wire 600 is characterized in that it is circular or polygonal.

In the main wire 600, three or more auxiliary wires 610 formed of a circular or polygonal shape are further provided.

The auxiliary wire 610 is characterized in that three or more auxiliary wires 610 are arranged in a radial shape around one circular auxiliary wire 610.

The main wire 600 is characterized in that one or more first electrode guide rods 601 facing the cone 200 are further provided.

The auxiliary wire 610 is characterized in that at least one second electrode guide rod 611 facing the conical portion 200 is further provided.

A '+' lead wire 810 is connected to the cylindrical portion 100, and a '-' lead wire 820 is connected to the liquid supply member 500.

In order to prevent the cylindrical portion 100 and the liquid supply member 500 from being electrically energized, the insulating member 700 is further provided.

The air purifying apparatus using electrostatic spraying and electrostatic dust collection according to an embodiment of the present invention generates fine droplets by applying a high voltage and makes contact with these fine droplets and exhaust gas, thereby improving the removal efficiency of particles with small particle diameters. There are advantages.

In addition, since the droplets generated during electrostatic spraying are minute, it is possible to minimize the amount of waste liquid collecting particles, thereby reducing the secondary processing cost.

Since the main wire and the auxiliary wire are provided at the center of the cylindrical portion, the particulate contaminants that are not collected through the fine droplets can be collected once again before being discharged to the gas discharge pipe, thereby improving the dust collection efficiency. .

In addition, since the plurality of liquid supply members are electrically connected by the main wire, even if the lead wires are connected to only one liquid supply member, the effect of connecting the lead wires to the respective liquid supply members can be obtained. Efficiency can be improved.

1 is a schematic diagram of an air purifying apparatus using electrostatic spraying and electrostatic dust collection according to a first embodiment of the present invention.
2 is a view showing a connection form of a liquid supply member and a main wire and an auxiliary wire according to a second embodiment of the present invention.
3 is a view showing a connection form of a liquid supply member and a main wire and an auxiliary wire according to a third embodiment of the present invention.
4 is a view showing a connection form of a liquid supply member and a main wire and an auxiliary wire according to a fourth embodiment of the present invention.
5 is a view showing a connection form of a liquid supply member and a main wire and an auxiliary wire according to a fifth embodiment of the present invention.
FIG. 6 is a schematic diagram illustrating an operating state of the air purifying apparatus shown in FIG. 1.

Hereinafter, an air purifying apparatus using electrostatic spraying and electrostatic dust collection according to the present invention will be described with reference to the accompanying drawings.

In this application, the terms "comprises", "have" or "have" are intended to indicate that there are features, numbers, steps, elements, parts or combinations thereof described in the specification, but one or more other. It should be understood that features or numbers, steps, actions, components, parts or combinations thereof are not excluded in advance.

In addition, unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by a person skilled in the art to which the present invention pertains. Terms, such as those defined in a dictionary used in general, should be interpreted as having meanings consistent with meanings in the context of related technologies, and should not be interpreted as ideal or excessively formal meanings unless explicitly defined in the present application. Does not.

1 is a schematic diagram of an air purifying apparatus using electrostatic spraying and electrostatic dust collection according to a first embodiment of the present invention.

Referring to Figure 1, the air purifying apparatus according to the first embodiment of the present invention, the cylindrical portion 100, the cone portion 200, the cover 300, the gas discharge pipe 400, the liquid supply member 500, And a main wire 600.

The cylindrical portion 100 is a long cylindrical shape having a predetermined height and inner diameter, and is made of a conductive material, and it is obvious that the height and inner diameter may vary depending on the air purification treatment capacity.

The conical portion 120 is an upper and lower strait structure in which a cross-sectional area gradually decreases as it goes down, and the upper portion of the conical portion 120 is connected to a lower portion of the cylindrical portion 100. Specifically, the conical portion 120 is formed to extend to communicate with the cylindrical portion 100 at the bottom of the cylindrical portion 100 and has a structure in which the diameter gradually decreases in the lower direction.

The lower portion of the conical part 200 is provided with a liquid outlet 210 through which the particulate matter contained in the exhaust gas and the liquid to be described later are discharged together.

An exhaust gas inlet pipe 110 connected to the outside is provided on the upper side of the cylindrical portion 100.

Exhaust gas containing various particulate contaminants flows into the cylindrical portion 100 through the exhaust gas inlet pipe 110 and falls while turning in the cylindrical portion 100.

A cover 300 made of an insulating material is attached to the upper portion of the cylindrical portion 100 to seal the cylindrical portion 100. Of course, the cover 300 may be omitted and the upper portion of the cylindrical portion 100 may be made of a closed type, but it is more advantageous in terms of maintenance or maintenance to separately provide the cover 300.

The gas discharge pipe 400 is a long cylindrical shape with an empty interior, and is made of a conductive material.

The gas discharge pipe 400 is located near the center of the cover 300, one end is through the cover 300 to protrude outside the cylindrical portion 100, the other end of the cylindrical portion 100 It is located inside.

A plurality of liquid supply members are arranged in a space between the cylindrical portion and the gas discharge pipe, and the liquid supply member 500 includes a liquid injection pipe and a spray nozzle.

The liquid supply member may be provided in two or more, preferably three or more, more preferably four or more, the number may vary depending on the size of the cylindrical portion and the auxiliary wire 610 to be described later.

The liquid supply member according to an embodiment of the present invention comprises a first liquid supply member 510, a second liquid supply member 520, a third liquid supply member 530, and a fourth liquid supply member 540 Can be.

Specifically, the first liquid supply member 510, one side protrudes to the outside through the cover 300, the other side is a first liquid injection pipe in the shape of a rod extending to the inner space of the cylindrical portion 100 ( 511) and the first injection nozzle 512 is mounted to the first liquid injection pipe 510 and positioned to face the inside of the cylindrical portion 100.

The second liquid supply member 520, one side protrudes to the outside through the cover 300, the other side is a rod-shaped second liquid injection pipe 521 extending to the inner space of the cylindrical portion 100 It is mounted on the second liquid injection pipe 520 is made of a second injection nozzle 522 positioned to face the inside of the cylindrical portion 100, the third liquid supply member 530, one side is the cover ( 300) is projected to the outside through, the other side is mounted on the third liquid injection pipe 531 and the second liquid injection pipe 520 of the rod-shaped extending to the inner space of the cylindrical portion 100, the cylindrical portion It is composed of a third injection nozzle 532 positioned to face the inside (100).

In addition, as in the first to third liquid supply members 510, 520, and 530, the fourth liquid supply member 540 also protrudes outward through the cover 300 and the other side is the cylindrical portion 100. ) To the fourth injection nozzle 542 which is mounted to the fourth liquid injection pipe 541 in the shape of a rod extending to the inner space and the fourth liquid injection pipe 540 and positioned to face the inside of the cylindrical portion 100. Is done.

Here, the liquid injection pipes 511, 521, 531, and 541 are passages through which the ionized liquid moves, and have an elongated pipe shape.

Intermittently or non-intermittently interposing the liquid to the liquid supply member 500 by connecting a tube (not shown) and a liquid supply pump (not shown) communicating with one end of the liquid injection pipes 511, 521, 531, and 541. Can supply.

Here, the liquid is not particularly limited as long as it is an ionizable liquid, but is preferably pure water or an ionic liquid that is soluble in water.

Each injection nozzle (512, 522, 532, 542) may be provided with one or more, preferably two or more along the longitudinal direction of each of the liquid injection pipe (511, 521, 531, 541).

In addition, the nozzle tip of the spray nozzle may be a nozzle tip formed of any one of a circular, triangular, square, polygonal, and amorphous shape, and the diameter range of the nozzle may be 0.02 mm to 2 mm.

When a high voltage is applied while supplying liquid to the liquid supply member 500 having the above-described configuration, fine droplets are generated between the inner wall surface of the cylindrical portion 100 and the liquid supply member. When explaining the principle of the electrospray method using a high voltage, applying positive (+) and negative (-) high voltage while passing the conductive liquid through the nozzle, the ions in the nozzle and liquid are liquid by repulsive force and attractive force. Will move to the surface. At this time, when the Coulomb repulsive force becomes more than the surface tension, it is sprayed as a fine droplet, and when the voltage across the electrode is small, the droplets are not sprayed because the electric force acting on the liquid curved surface and the repulsive force of positive ions are less than the liquid surface tension. When increased, the electric force acting on the curved surface of the liquid and the repulsive force of the cations become larger than the surface tension of the liquid, and the droplet is sprayed from the capillary tip.

In the dust collecting apparatus using the conventional liquid spraying method, it is difficult to collect particles having a small particle size because of the large amount of droplets to be sprayed, and there is a problem in that the secondary treatment cost increases due to the use of excess liquid.

However, in the present invention, since droplets are generated using the electrostatic spraying method as described above, the diameter of the droplets is very small, and the generated droplets have the same polarity as the pole applied to the nozzle and have a very high charge amount, causing aggregation between droplets. Since it does not appear, it is possible to maintain the initial diameter for a long time, and it is also possible to collect fine particles having a particle diameter of 0.1 μm or less.

Meanwhile, the main wire 600 is connected to the other ends of the first liquid injection pipe 510, the second liquid injection pipe 520, the third liquid injection pipe 530, and the fourth liquid injection pipe 541, The main wire 600 may be circular or polygonal.

In addition, a first electrode guide rod 601 is attached to the main wire 600 to maximize discharge efficiency. Specifically, the first electrode guide rod 601 has a pin shape having a predetermined length, and a plurality of the main wires 600 are spaced apart from each other at predetermined intervals so as to face the cone 200.

Since the first electrode guide rod 601 can freely adjust the spacing, it is possible to design a large inner diameter of the cylinder, and consequently, the capacity of the air purifying device can be increased.

The first electrode guide rod 601 is preferably formed of a corrosion-resistant and electrically conductive metal material. For example, the first electrode guide rod 601 may be formed of stainless steel, but is not limited thereto. .

Each of the liquid supply members 510, 520, 530, and 540 is electrically connected through the main wire 600.

When a corona discharge is formed by applying a (-) voltage to the main wire, the particulate contaminants passing through the main wire are charged to (-), and the charged particulate contaminants are (+) cylindrical by Coulomb force. It is collected on the inner wall of the wealth.

Due to the above structure, particulate contaminants are first collected in fine droplets formed by the electrostatic spraying method, and even if there are particulate contaminants that have not yet been collected, they are re-used in the main wire 600 before being discharged to the gas discharge pipe 400. The charged microparticles can be recaptured by discharging in the ascending orbiting airflow by the attraction force with the cyclone wall by applying a charge to the microparticles, thereby improving the overall dust collection efficiency.

Specifically, among the microparticles introduced into the cyclone, particles having a size of 2.5 µm or more are mostly collected in the electrostatic spraying step, but particulate matters of 0.3 µm or more and less than 2.5 µm that are not reliably collected can be further collected by the above structure.

Particularly, the particulate contaminants collected on the inner wall of the cylindrical portion do not require a separate desorption process because the droplets generated from electrostatic spraying function are cleaned, and in addition, the main wires 600 connect the liquid supply members 500 to each other. Since it is electrically connected, there is an advantage in that operation is possible even when power is supplied to only one of the plurality of liquid supply members.

The cylindrical portion 100 is further provided with an insulating member 700 to prevent the liquid supply member 500 from being electrically energized.

Figure 2 is a view showing the connection form of the liquid supply member and the main wire and the auxiliary wire according to the second embodiment of the present invention, Figure 3 is a liquid supply member and the main wire and the auxiliary wire according to the third embodiment of the present invention It is a diagram showing the connection form.

Referring to FIG. 2, four auxiliary wires 610 in which a second electrode guide rod 611 is formed are disposed inside the main wire 600, and referring to FIG. 3, the main wire 600 Three or more auxiliary wires 610 are disposed in a radial shape centering on one auxiliary wire 610 in the center of.

When only the main wire 600 is provided, particulate pollutants in the exhaust gas passing through the center of the cylindrical portion 100 may be difficult to be charged to (-).

However, as shown in FIGS. 2 and 3, if a plurality of auxiliary wires 610 equipped with a second electrode guide rod 311 are provided inside the main wire 600, the center of the cylindrical portion 100 is uniformly negative (-) voltage. As it can be applied, it is possible to achieve an efficient electrostatic precipitating effect even when the diameter of the cylindrical portion is increased.

That is, it is possible to obtain the same high dust collection efficiency by adjusting the size and number of auxiliary wires according to the capacity of the air cleaning device.

Here, the auxiliary wire 610 may be the same material as the main wire 600, and the size and number of the auxiliary wires 610 may vary depending on the size of the air purifying device.

On the other hand, although not shown in the drawing, the auxiliary wire 610 may be a polygon, unlike the one shown in FIG. 3. For example, the auxiliary wire 610 may be any one or more of a honeycomb shape, a spiral shape, and a radial shape.

4 is a view showing a connection form of the liquid supply member and the main wire and the auxiliary wire according to the fourth embodiment of the present invention, and FIG. 5 is a liquid supply member, the main wire and the auxiliary wire according to the fifth embodiment of the present invention It is a diagram showing the connection form of.

4, it is also possible to provide two main wires 600 in the vertical direction along the liquid supply member 500. Of course, it is obvious that three or more main wires 600 may be provided, and at this time, the auxiliary wires 610 having the shapes shown in FIG. 2 or 3 may be additionally connected.

In addition, as illustrated in FIG. 5, the second electrode guide rod 611 provided in the auxiliary wire 610 may be provided to face different directions. Specifically, one side may face the conical portion 200 and the other side may face the central portion of the auxiliary wire 610.

When the second electrode guide rod 611 is provided in the shape as described above, since the ultra-fine particles are more easily charged, the dust collection efficiency of the ultra-fine particles is further improved. Of course, although not shown in the drawings, the first electrode guide rod 601 provided on the main wire 600 may also be provided in the same shape as the second electrode guide rod 611.

FIG. 6 is a schematic diagram illustrating an operating state of the air purifying apparatus shown in FIG. 1.

Referring to FIG. 6, the '+' lead wire 810 connects the cylindrical portion 100 and the '-' lead wire 820 to the liquid supply member 500 and supplies high voltage while supplying liquid to the liquid supply member 500. When applied, fine droplets are generated between the inner wall surface of the cylindrical portion 100 and the liquid supply member.

With or after the above operation, when the exhaust gas is introduced into the side inlet pipe 110 of the cylindrical portion 100, particulate contaminants in the exhaust gas are collected in fine droplets and discharged to the liquid outlet 210. In addition, the particulate contaminants that cannot be collected through the fine droplets are collected on the inner wall of the cylindrical portion 100 and / or the conical portion 200 by electric dust collection of the main wire and the auxiliary wire, and then fall down with the droplets to the liquid discharge port ( 210), the gas from which particulate contaminants are removed is discharged to the outside through the gas discharge pipe 400.

Meanwhile, the high voltage for electrostatic spraying may be electrostatic spraying and is not particularly limited as long as it is a voltage at which the heat transfer of the insulating material is destroyed, but may be specifically 10 kV to 50 kV.

Since the specific parts of the present invention have been described in detail above, to those skilled in the art, these specific techniques are only preferred embodiments, and the scope of the present invention is not limited thereby. It is apparent to those skilled in the art that various changes and modifications can be made within the scope of the scope and technical thought, and it is natural that such modifications and modifications fall within the scope of the appended claims.

According to an embodiment of the present invention, the particulate contaminants contained in the exhaust gas are primarily removed by using electrostatic spraying on a dust collecting device having a cyclone structure, and secondly, the particulate matter that is not removed in the electrostatic spraying step by using electrostatic dust collection. An air purifying device capable of removing contaminants can be provided.

100: cylindrical part
200: cone
210: liquid discharge unit
300: cover
400: gas discharge pipe
500: liquid supply member
510: first liquid supply member
511: first liquid injection pipe 512: first injection nozzle
520: second liquid supply member
521: 2nd liquid injection pipe 522: 2nd injection nozzle
530: third liquid supply member
531: 3rd liquid injection pipe 532: 3rd injection nozzle
540: fourth liquid supply member
541: 4th liquid injection pipe 542: 4th injection nozzle
600: main wire
601: first electrode guide rod
610: auxiliary wire
611: second electrode guide rod
700: insulating member
800: power supply
810: '+' lead wire (810)
820: '-' lead wire (820)

Claims (10)

An exhaust gas inlet pipe 110 for guiding exhaust gas containing particulate contaminants, the cylindrical portion 100 having an inner space formed therein;
The upper portion is connected to the lower portion of the cylindrical portion 100, the lower portion is provided with a liquid discharge port 210, the inner space is formed conical portion 200 of the narrow tube structure;
A cover 300 provided on the cylindrical portion 100;
One side protrudes to the outside through the cover 300, the other side is a cylindrical gas discharge pipe 400 located in the inner space of the cylindrical portion 100;
A plurality of liquid supply members 500 arranged around the cylindrical gas discharge pipe 400; And
Air purification device using electrostatic spray and electrostatic dust collection, characterized in that it comprises a main wire (600) for connecting the liquid supply member (500). According to claim 1,
The liquid supply member 500 includes a first liquid supply member 510, a second liquid supply member 520 and a third liquid supply member 530,
The first liquid supply member 510, one side penetrates the cover 300 and protrudes to the outside, and the other side is a rod-shaped first liquid injection pipe 511 extending to the inner space of the cylindrical portion 100 It is made of a first injection nozzle 512 is mounted to the first liquid injection pipe 510 and positioned to face the inside of the cylindrical portion 100,
The second liquid supply member 520, one side penetrates through the cover 300 and protrudes to the outside, and the other side is a rod-shaped second liquid injection pipe 521 extending to the inner space of the cylindrical portion 100 It is made of a second injection nozzle 522 mounted on the second liquid injection pipe 520 and positioned to face the inside of the cylindrical portion 100,
The third liquid supply member 530, one side protrudes to the outside through the cover 300, the other side is a rod-shaped third liquid injection pipe 531 extending to the inner space of the cylindrical portion 100 It is mounted on the third liquid injection pipe 530 is made of a third injection nozzle 532 positioned to face the inside of the cylindrical portion 100,
The main wire 600 is electrostatic spraying and electricity, characterized in that it is a polygon connecting the other end of the first liquid injection pipe 510, the second liquid injection pipe 520 and the third liquid injection pipe 530 Air purification system using dust collection. According to claim 1,
The liquid supply member 500 includes a first liquid supply member 510, a second liquid supply member 520, a third liquid supply member 530 and a fourth liquid supply member 540,
The first liquid supply member 510, one side penetrates the cover 300 and protrudes to the outside, and the other side is a rod-shaped first liquid injection pipe 511 extending to the inner space of the cylindrical portion 100 It is made of a first injection nozzle 512 is mounted to the first liquid injection pipe 510 and positioned to face the inside of the cylindrical portion 100,
The second liquid supply member 520, one side penetrates through the cover 300 and protrudes to the outside, and the other side is a rod-shaped second liquid injection pipe 521 extending to the inner space of the cylindrical portion 100 It is made of a second injection nozzle 522 mounted on the second liquid injection pipe 520 and positioned to face the inside of the cylindrical portion 100,
The third liquid supply member 530, one side protrudes to the outside through the cover 300, the other side is a rod-shaped third liquid injection pipe 531 extending to the inner space of the cylindrical portion 100 It is made of a third injection nozzle 532 mounted on the second liquid injection pipe 520 and positioned to face the inside of the cylindrical portion 100,
The fourth liquid supply member 540, one side protrudes to the outside through the cover 300, the other side is a fourth liquid injection pipe 541 in the shape of a rod extending to the inner space of the cylindrical portion 100 It is made of a fourth injection nozzle 542 mounted on the fourth liquid injection pipe 540 and positioned to face the inside of the cylindrical portion 100,
The main wire 600 is a polygon connecting the other end of the first liquid injection pipe 510, the second liquid injection pipe 520, the third liquid injection pipe 530 and the fourth liquid injection pipe 541 Air purifying apparatus using electrostatic spray and electrostatic dust collection, characterized in that. The method of claim 2 or 3,
The main wire 600 is a circular or polygonal air purifying apparatus using electrostatic spray and electrostatic dust collection. The method of claim 4,
An air purifying apparatus using electrostatic spraying and electrostatic dust collection, wherein three or more auxiliary wires 610 formed of a circular or polygonal shape are further provided inside the main wire 600. The method of claim 5,
The auxiliary wire 610 is an air purifying apparatus using electrostatic spraying and electrostatic dust collection, characterized in that three or more auxiliary wires 610 are arranged in a radial shape around one circular auxiliary wire 610. The method of claim 2 or 3,
An air purifying apparatus using electrostatic spraying and electrostatic dust collection, characterized in that the main wire 600 is further provided with at least one first electrode guide rod 601 facing the conical portion 200. The method of claim 5,
The auxiliary wire (610) is an air purifying apparatus using electrostatic spraying and electrostatic dust collection, characterized in that at least one second electrode guide rod (611) facing the conical portion (200) is further provided. The method according to any one of claims 1 to 3,
An air purifying apparatus using electrostatic spraying and electrostatic dust collection, characterized in that a '+' lead wire 810 is connected to the cylindrical portion 100 and a '-' lead wire 820 is connected to the liquid supply member 500. The method according to any one of claims 1 to 3,
An air purifying apparatus using electrostatic spraying and electrostatic dust collection, further comprising an insulating member 700 to prevent the cylindrical portion 100 and the liquid supply member 500 from being electrically energized.

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