KR102500727B1 - Air sterilization and air purification device using plasma generating device having a plurality of grid-type discharge structures, and air sterilization and purification room using the same - Google Patents

Abstract

The present invention relates to a plasma discharge device and an air purifier including the same, and more particularly, to a plasma discharge device and an air purifier using the same.
Plasma module according to the present invention
a top and bottom open conductive tubular case;
a first electrode plate having a plate member in which holes of a predetermined size are perforated and a needle-type electrode fixed to a non-perforated region of the plate member and insulated from the cylindrical case; and
Tubular cells of a predetermined length are arranged horizontally from side to side to form a cell-type plate material, and a second electrode plate is seated inside the tubular case so that the needle-shaped electrodes are inserted into the tubular cells, and conducts electricity to the tubular case. .

Description

Air sterilization and air purification device using plasma generating device having a plurality of grid-type discharge structures, and air sterilization and purification room using the same}

The present invention relates to a plasma discharge device and an air purifier including the same, and more particularly, to a plasma discharge device and an air purifier using the same.

An air purifier that treats dust or bacteria in the air using a large amount of active species generated by plasma discharge is being developed. In such a plasma discharge device, dust is accumulated on the discharge plate during the discharge process, resulting in degradation of performance. Therefore, regular cleaning is required.

However, since the plasma discharge device used in the air purifier is fixed inside the air purifier, the main body needs to be separated for cleaning and maintenance by a professional manager is required. Therefore, it is not easy to use a plasma discharge device for household air purifiers.

In addition, even when maintained by a manager, since the discharge needle and the discharge plate constituting the plasma reactor are integrally formed to maintain a constant distance, there is a problem in that it is not easy to wipe off dust adhered to the narrow gap between the discharge needle and the discharge plate. . When water is used for the convenience of cleaning, there is always a risk of electric leakage due to remaining water.

Due to such management difficulties, it is not easy for conventional plasma discharge devices to implement complex shapes to increase efficiency. For example, Korean Patent Publication No. 10-2020-0064670 'Plasma sterilization module and air purifier having the same' suggests a method of improving the structure of a streamer discharge device to increase discharge efficiency and suppress ozone generation, but the device As the complexity of the structure increases, the maintenance problem increases.

In addition, despite the complex device structure, since the electric field is formed only in the center of the flow path, there is a limit to the configuration of a uniform electric field, and needles gathered in one space interact with each other, making it more difficult to form a uniform electric field.

In addition, since the diameter and flow rate of the flow path vary according to the processing capacity, there is a problem in that a new flow path and plasma device design are required for each processing capacity in order to form a uniform electric field.

An object to be solved in the present invention is to provide a plasma discharge device that can be easily separated from an air purifier main body for easy maintenance.

Another problem to be solved in the present invention is to provide a new plasma reactor that is easily detachable from the main body and easy to clean after separation.

Another problem to be solved by the present invention is to provide a new plasma reactor that has a complicated structure and is easy to maintain.

Another problem to be solved by the present invention is to provide a new plasma reaction device capable of easily passing air and forming a uniform electric field.

In order to solve the above problems, the present invention

Top and bottom open cylindrical case;

a first electrode plate having a plate member in which holes of a predetermined size are perforated and a needle-type electrode fixed to a non-perforated region of the plate member and insulated from the cylindrical case; and

A second electrode plate in which tubular cells of a predetermined length are horizontally arranged from side to side to form a cell-type plate material, and the needle-type electrodes are seated inside the tubular case so as to be inserted into the tubular cell and conduct electricity to the tubular case. Provided is a body retractable plasma module.

In the present invention, the cylindrical case of the plasma module may be a rectangular cylindrical case so that it can be put in and out of a rectangular parallelepiped body in a sliding manner, and may be made of a conductive metal plate.

In the practice of the present invention, the tubular case may have flanges or protruding pieces at the top and bottom of both sides and/or between them for ease of withdrawal and insulation from the main body, and preferably, flanges are provided on the upper and lower ends of both sides in the withdrawal and withdrawal direction. can have

In the present invention, the tubular case may have a ground terminal connected to the ground end of the main body when the main body is inserted, and a high voltage terminal connected to the high voltage end of the main body when inserted.

In the present invention, the tubular case may have a high voltage terminal and a ground terminal on an outer surface, preferably a front side surface, and the high voltage terminal penetrates the tubular case in an insulated state to the first electrode plate insulated from the tubular case. It can be energized, and the ground terminal can be energized with the second electrode plate contacting the inner surface of the cylindrical case by contacting the outer surface of the cylindrical case.

In the present invention, the retractable plasma module may have a first electrode plate, preferably a first insulating member fixed to front and rear ends of the first electrode plate so that the tubular case and the first electrode plate are insulated from each other.

In the present invention, the first insulating member may have a rod-shaped insulating body coupled to the first electrode plate, and insulating protrusions protruding vertically from an end of the insulating body.

In the practice of the present invention, the insulating protrusion constituting the first insulating member may include an upper insulating protrusion and a lower insulating protrusion, and a step may be formed due to a difference in thickness between the upper insulating protrusion and the lower insulating protrusion.

In the present invention, the first electrode plate may have a plate member and needles, and the plate member may include a rectangular plate member in which a plurality of rectangular holes are arranged, and a needle-type electrode vertically fixed to a non-perforated area of the plate member. there is.

In the practice of the present invention, the rectangular plate portion may be screwed to the lower surface of the insulating projection of the inner wall insulating member fixed to the inner wall of the tubular case.

In the practice of the present invention, the needle-type electrode may be a needle-type electrode in which four needles protrude in a horizontal direction in the front, rear, left, and right directions of a vertical plate material.

In the practice of the present invention, the needle-type electrode may be disposed at the center of the tubular cells of the second electrode plate to form a uniform electric field inside the cell, and more preferably, the needle-type electrode is located at the center. The electrode is configured such that the distance from the end of the needle to the second electrode plate forming the counter electrode is substantially the same.

In a preferred embodiment of the present invention, the tubular cells may be polygonal, preferably rectangular, and more preferably square cells, and the needles may be disposed one on each inner wall of the tubular cell.

In the present invention, the first electrode plate may be in contact with a high voltage terminal penetrating one side wall of the tubular case in a state in which it is fixed to the inner wall insulating member, so that a high voltage may be applied.

In the present invention, the second electrode plate is made of a cell-type plate material, and the cell-type plate material may have a shape in which rectangular tubular cells having a predetermined length are horizontally disposed on the left and right sides. The cell-type plate material may have the same shape and size as the tubular cells so as to form a uniform electric field. For example, tubular cells having a rectangular cross section of the same size, more preferably a square cross section may be used.

In the practice of the present invention, the second electrode plate includes a cell-type plate, a conducting member for conducting an upper end of the cell-type plate to a cylindrical case, and a second insulating member for insulating the cell-type plate from the first electrode plate. can do.

In one embodiment of the present invention, the conducting member may be a square ring-shaped conducting member that contacts the upper surface of the cell-shaped plate member and the upper surface of the tubular case.

In one embodiment of the present invention, the second insulating member is attached to the side surface of the cell-type plate member to prevent the side surface of the cell-type plate material from contacting the inner surface of the rectangular cylindrical case, and the side insulation portion protrudes from the side insulation portion to form a cell shape. A lower surface insulating portion may be included to prevent the lower surface of the plate material from contacting the first electrode plate.

In the present invention, the retractable plasma module may further include a main body insulation member for insulation from the main body. The main body insulating member may be attached to the outer surface of the cylindrical case to prevent the cylindrical case from contacting the main body except for the high voltage terminal and the insulating terminal, preferably on the upper surface, lower surface, or side surface of the cylindrical case. It may be attached to, preferably, it may be a plastic member attached to the upper and lower surfaces of the flanges formed on the upper and lower sides of the cylindrical case.

In the practice of the present invention, the retractable plasma module is insulated from the air purifier body by a body insulation member, and power can be applied only through the high voltage end and the ground end.

In the present invention, the retractable plasma module may be a plasma generating device by streamer discharge.

In one aspect, the present invention

Top and bottom open cylindrical case;

a first electrode plate having a plate member in which holes of a predetermined size are perforated and a needle-type electrode fixed to a non-perforated region of the plate member and insulated from the cylindrical case; and

Tubular cells of a predetermined length are arranged horizontally from side to side to form a cell-type plate, and the needle-type electrodes are seated inside the tubular case so that they are inserted into the tubular cells, and the second electrode plate is energized to the tubular case; including The retractable plasma module provides an air purifier built into the body of the air purifier in a retractable type.

In the present invention, the withdrawable plasma module is vertically inserted into and pulled out of the flow path of the main body of the air purifier, and may be seated in the plasma module accommodating groove through the withdrawing and withdrawing opening formed on the side of the main body.

In the practice of the present invention, the air purifier body in which the retractable plasma module is seated has an air inlet at the bottom, an air outlet at the top, a flow path through which air rises is formed, and a plasma module is formed on one side. It has an opening for withdrawing and withdrawing, and may have a module accommodation groove inside. In the practice of the present invention, the plasma module may be taken in and out of the main body in a sliding manner.

In the present invention, a pre-filter and a flow path of the main body of the air purifier; a dust collection device including a discharge unit including a linear discharge electrode and a dust collection unit configured to collect dust charged in the discharge unit; an ozone removal device that removes ozone generated from a plasma module and/or a dust collector installed in a conduit of the body; More fans may be included.

In one aspect, the present invention

Top and bottom open cylindrical case;

a first electrode plate having a plate member in which holes of a predetermined size are perforated and a needle-type electrode fixed to a non-perforated region of the plate member and insulated from the cylindrical case; and

Tubular cells of a predetermined length are arranged horizontally from side to side to form a cell-type plate, and the needle-type electrodes are seated inside the tubular case so that they are inserted into the tubular cells, and the second electrode plate is energized to the tubular case; including A retractable plasma module provides a large-capacity air treatment device including a plurality of air purifiers built into an air purifier body in a retractable type.

In the main body retractable plasma module according to the present invention, needles are divided into cells, and interference between needles is reduced to form a uniform electric field, thereby increasing processing efficiency.

In addition, in the body retractable plasma module according to the present invention, the needles are arranged in the center of the cells so that the distance between the needles and the inner wall of the cell is constant,

In addition, the main body retractable plasma module according to the present invention has a complicated internal structure and is easy to separate from the main body, and after separating the first electrode plate and the second electrode plate from the separated plasma module, they can be washed respectively. , self-management by the user is easy.

1 is a view showing a perspective view of a retractable plasma module according to the present invention.
2 is a view showing a lower perspective view of a retractable plasma module according to the present invention.
3 is a view showing a state in which an external insulating member is removed and a rectangular cylindrical case is separated from a retractable plasma module according to the present invention, and is shown in the opposite direction to that of FIG. 1 .
4 is a perspective view showing a first electrode plate of a retractable plasma module according to the present invention.
5 is a perspective view showing a second electrode plate of a retractable plasma module according to the present invention.
6 is a drawing showing the coupling relationship of the retractable plasma module according to the present invention.
7 is a front perspective view showing the appearance of the air purifying device according to the present invention.
8 is a view showing the rear of the air purifying device according to the present invention.
9 is a view showing an exploded perspective view of the front direction of the air purifying device according to the present invention.
10 is a view showing an exploded perspective view of the rear direction of the air purifying device according to the present invention.

Hereinafter, the present invention will be described in detail through examples. The following examples are intended to illustrate the present invention and are not intended to limit the present invention.

FIG. 1 shows an upper perspective view of the retractable plasma module discharge device 10, and FIG. 2 shows a lower perspective view of the retractable plasma module discharge device 10. In the embodiment of the present invention, 'front side' means the front side in the direction of entry and exit, 'rear side' means the rear side in the direction of entry and exit, and 'both sides' means both sides parallel to the direction of entry and exit. means The upper part means a direction in which air is discharged, and the lower part means a direction in which air is introduced.

As shown in FIGS. 1 and 2 , the retractable plasma module discharge device 10 includes a rectangular cylindrical case 100 forming an enclosure made of a conductive metal plate material opened up and down;

The ratio between the lower plate part 210, which is insulated from the square cylindrical case 100, fixed to the inner lower end of the square cylindrical case 100, and has a plurality of square 211 holes perforated, and the lower plate part 210. A needle-shaped electrode 220 fixed vertically to the perforated area and a first insulating member 230 coupled to the lower plate member 210 to insulate the first electrode plate 100 from the rectangular cylindrical case 100 A first electrode plate 200 including; and

A cell-type plate 310 composed of cells having a square cross-section and a predetermined height, and a conducting member 320 coupled to the cell-type plate 310 and energizing the cell-type plate 310 to the rectangular cylindrical case 100, A second electrode plate 300 including a second insulating member 330 coupled to the cell-type plate 310 to insulate the cell-type plate 310 from the first electrode plate 200, The needle-shaped electrodes 220 of the electrode plate 200 are fixed to the inner upper end of the rectangular cylindrical case 100 so that they are inserted into the tubular cells, and the second electrode plate 300 is electrically connected to the rectangular cylindrical case 100. ) has

As shown in FIGS. 3 and 4, the square cylindrical case 100 is formed by combining a front plate 110, a rear plate 120, and both side plates 130, and the front plate 110 has a terminal board ( 140) are combined.

A rectangular front hole 111 is formed in the front plate 110, and the front hole 111 is covered by a terminal plate 140. In addition, a first support piece 112 protruding inward to support the first insulating member 230 is formed on the front plate 110 . The first support piece 112 is formed by cutting a portion of the front plate member in a V-shape and then bending it inward.

Among the four side plates constituting the rectangular cylindrical case 100, flanges 111 extending along the withdrawal direction are formed at the upper and lower ends of the plates 110 on both sides parallel to the withdrawal direction for convenience of withdrawal and withdrawal. .

The back plate 120 is formed with a holding plate 121 bent inward to support the first insulating member 230 .

A second support piece 132 for supporting the second insulating member 330 is provided at the front and rear lower ends of the both sides of the plate 130, and the second support piece 132 forms both sides of the plate in an ∩ shape. It is formed by incising and then bending it inward. Both side plate material cutouts 133 for exposing upper side surfaces of the second insulating member 330 are formed at the upper ends of the front and rear sides of the plate material 110 on both sides.

A terminal plate 140 made of plastic is attached to the front of the front plate 110 to cover the front hole 111 . A ground terminal 141 and a high voltage terminal 142 made of a rectangular metal plate are formed on the terminal plate 140 .

When the main body is inserted, the ground terminal 141 extends from the ground piece 141' connected to the ground end of the main body and the ground piece 141' and penetrates the terminal plate 140 to form a front plate of the rectangular cylindrical case 100. It consists of a ground extension 141" that contacts 110.

When the main body is inserted, the high voltage terminal 142 extends after being bent from the high voltage piece 142′ connected to the high voltage end of the main body, and passes through the terminal plate 140 and the front hole 111 to pass through the first It consists of a high voltage extension 142" that contacts the electrode plate 200.

The upper and lower corners of the rectangular cylindrical case 100 include corner insulating members 150 attached to insulate them from the main body. The corner insulating member 150 is made of non-conductive plastic and has a 'L'-shaped side cross section.

As shown in FIGS. 5 and 6 , the first electrode plate 200 includes a lower plate portion 210 in which a plurality of rectangular lower holes 211 are bored, and a non-perforated area of the lower plate portion 210 ( 212) and a plurality of first insulating members 230 for insulating the front and rear ends of the first electrode plate 200 from the inner surface of the rectangular cylindrical case 100.

In the non-perforated region 212 of the lower plate portion 210, needle-type electrode fixing holes 221 for fixing the needle-type electrode 220 are bored in alignment at predetermined intervals. The needle fixing holes 221 may be changed according to the cell positions of the second electrode plate, and are arranged to be located at the center of the cells.

The needle-shaped electrode 220 fixed to the lower plate portion 210 includes a needle horizontal plate 222 fixed to the needle-shaped electrode fixing hole 221 and a needle vertical plate extending vertically from the needle horizontal plate 222. 223, and four triangular needles 224 formed in the front and rear left and right directions on the top of the needle vertical plate 223, and the four triangular needles 224 have the ends of each needle to pass through the cell-type plate 210. It is arranged so as to face one by one on the four walls of the tubular cells that make up.

The needle-shaped electrodes 220 may be installed in numbers corresponding to the number of cells of the second electrode plate 300 so that discharge occurs for each cell, and an area where discharge is not required, for example, where air flow is small. It may not be installed on the edge part.

The first insulating member 230 installed at the front and rear ends of the lower plate part 210 is on the upper surface of the lower plate part 220 to insulate the first electrode plate 200 and the second electrode plate 300. combined, and has a rod-shaped insulating body 231 having a predetermined thickness on which the cell-shaped plate 310 of the second electrode plate 300 is seated, and to insulate the first electrode plate from the rectangular cylindrical case 100. A lower insulating protrusion 232 vertically protruding downward and an upper insulating protrusion 233 protruding upward are formed at an end of the rod-shaped insulating body 231 . A step 224 is formed between the lower insulating protrusion 232 and the upper insulating protrusion 233 .

In the first electrode plate 200, the first insulating member 230' installed at the front end of the lower plate member 210 is supported by the step 234 being caught on the first support piece 112, and the lower plate member 230 is supported. The lower end of the lower insulating protrusion 232 of the first insulating member 230 "installed at the rear end of the part 210 is supported by the hooking piece 121 of the rear plate 120, so that it is insulated from the rectangular cylindrical case 100. fixed in a state of

In the first electrode plate 200, the center of the lower surface of the front end of the lower plate member 200 is seated on the high-voltage extension piece 142", and the high-voltage end of the main body is energized through the high-voltage terminal 142.

As shown in FIG. 7 , the second electrode plate 300 includes a cell-type plate 310, an upper conduction member 320 covering the upper edge of the cell-type plate 310, and the cell-type plate 310. It consists of a second insulating member 330 attached to the left and right sides.

The cell-type plate 310 is a lattice-shaped square or rectangular plate in which tubular cells having the same size and square cross-section are repeatedly arranged in the front-back and left-right directions, and are open up and down.

The upper conduction member 320 has a larger outer diameter than the cell-type plate 310 and an inner diameter in the form of a square ring than the cell-type plate, and is screwed onto the upper surface of the second insulating member 330 attached to the side surface of the cell-type plate 310. It is fixed. The upper conductive member 320 contacts the upper surface of the rectangular cylindrical case 100 to conduct electricity between the second electrode plate 300 and the rectangular cylindrical case 100, and the ground attached to the front surface of the rectangular cylindrical case 100. It is grounded to the body through the terminal.

The second insulating member 330 is attached to the side surface 311 of the cell-type plate material to prevent the side surface 311 of the cell-type plate material from contacting the inner surface of the rectangular cylindrical case 100, the side insulation portion 331, The bottom insulation portion 332 protrudes from the side insulation portion 331 to prevent the lower surface 312 of the cell-shaped plate from contacting the first electrode plate 200, and the side insulation portion 331 extends downward It consists of a leg part 333 seated on the second support piece 132 of the rectangular cylindrical case 100 .

As shown in FIGS. 8 and 9 , the first electrode plate 200 is insulated from the second electrode plate 300 by the first insulating member 230 and the second insulating member 330 . The first insulating member 230 is coupled to the front and rear ends of the first electrode plate 200, and the rod-shaped insulating body 231 of the first insulating member 230 is connected to the first electrode plate 200 and the second electrode. It is sandwiched between the plates 300, the second insulating member 330 is coupled to both sides of the second electrode plate 300, and the lower surface of the second insulating member 330 the insulating portion 332 is the first electrode plate ( 200) and the second electrode plate 300 are sandwiched and insulated.

10 and 11, in the first electrode plate 200 and the second electrode plate 300, the needle-type electrode 220 is inserted between the tubular cells of the cell-type plate material 310, and the insulating members Insulated by a predetermined interval and coupled. The distance between the ends of the four triangular needles 224 formed on the top of the needle-shaped electrode 220 and the wall surface of the tubular cell 301 is substantially so that the electric field 303 is uniformly formed inside the tubular cell 301. are arranged to be equal to

When a voltage is applied to the needle-shaped electrode 220 and the cell-shaped plate 310, an electric field is formed in the front, rear, left, and rear directions of the tubular cell 301, and air flows through the lower hole 211 formed in the lower plate portion 210. Incoming air is treated by the uniformly generated electric field 303, and the treated air is discharged to the top of the tubular cell 301.

As shown in FIGS. 12 and 13, the air purification module 1000 including the retractable plasma module discharge device 10 according to the present invention has a unit body portion 1100 having a rectangular parallelepiped body, An air outlet 1101 is formed on the upper surface of the unit body portion, an air inlet 1102 is formed on the lower surface, and an openable door 1103 is formed on one side surface.

Inside the unit body portion 1100, a retractable plasma module discharge device 10 is installed horizontally. A pre-filter 20 is installed at a predetermined interval in the lower portion of the retractable plasma module discharge device 10, and a pre-filter 20 is installed at a predetermined interval in the upper portion of the retractable plasma module discharge device 10, and a dust collector 30 and , an ozone removal catalytic device 40 for absorbing and removing ozone, a light irradiation device 50 for ozone removal, and an air fan 60 are sequentially installed. Four short brace legs 1103 for spacing from the bottom surface are attached to the lower part of the upper unit body 1100. A pre-filter 20 built into the unit body 1100, a retractable plasma module discharge device 10, a dust collector 30, an ozone removal catalytic device 40 that absorbs and removes ozone, and ozone The light irradiation device 50 for removal uses a replaceable device that is put in and out in a sliding manner.

In the unit body part 1100, the plasma module discharge device 10 is a streamer discharge device, and the flow of high-energy electrons generated during the streamer discharge strikes and inactivates harmful substances such as viruses contained in the air, In addition, active species containing radicals generated by the streamer discharge react with the virus to inactivate the virus.

The plasma module discharge device 10 is made of a tubular cell type, and needles are arranged to face each wall of a unit cell, and a uniform electric field can be formed throughout the flow path, and a uniform electric field can be formed even inside the tubular cell. It is possible, and harmful species such as viruses are effectively inactivated.

The pre-filter 20 primarily filters dust or dust introduced by the air fan 60 and is composed of a mesh filter having a size that allows fine particles such as viruses or fine dust to pass through.

Harmful substances such as viruses deactivated in the plasma module discharge device 10 are moved to the dust collector 30 located at the top by the air fan 60 . The dust collecting device 30 includes a discharge unit configured to ionize inactivated virus or fine dust and a dust collection unit including a plurality of dust collection plates to collect the inactivated virus or fine dust ionized by the discharge unit. A general corona discharge may be used for the discharge of the discharge unit, and it is effective to use a linear discharge electrode in which yan-shaped metal wires twisted with stainless nano metal wires are arranged at predetermined intervals.

The catalytic device 40 for removing ozone treats ozone generated from the discharge unit of the plasma module discharge device 10 and/or the dust collector 30, and tubular cells filled with catalyst particles are connected left and right to form a horizontal plate material. It is a catalyst plate forming a catalyst plate, and the tubular cells of the catalyst plate may be honeycomb-shaped tubular cells, and meshes are attached to the lower and upper surfaces to enable catalyst release and air permeation.

The light irradiation device 50 for removing ozone is a device capable of irradiating UV to a gas, and the UV is irradiated by an LED. For example, a plate material in which UV LED chips are aligned is attached.

The air fan 60 uses a general rotary fan with rotary blades.

As shown in FIG. 14 , a large-capacity air purifying device may be realized by mounting a plurality of air purifying modules 1000 in one external case 2000 . The exterior case 2000 has an inner space capable of accommodating a plurality of air purifying modules 1000 and a lower inlet 2100 and an upper outlet 2200 for sending air to the air purifying module 1000.

10: air filter
100: square cylinder case
110: front plate
120: back plate
130: both side plates
140: terminal board
141: ground terminal
142: high voltage terminal
200: first electrode plate
210: lower plate part
220: needle type electrode
230: first insulating member
300: second electrode plate
310: cell type plate
320: energized absence
330: second insulating member

Claims (9)

A conductive rectangular cylindrical case made of a front plate, a rear plate, and a side plate and opened up and down;
a first electrode plate having a plate member in which holes of a predetermined size are perforated and a needle-type electrode fixed to a non-perforated region of the plate member and insulated from the rectangular cylindrical case; and
Tubular cells of a predetermined length are arranged horizontally from side to side to form a cell-type plate, and the needle-type electrodes are seated inside the rectangular tubular case so as to be inserted into the tubular cell, and a second electrode plate is electrically connected to the tubular case. Wherein, the tubular cells are polygonal tubular cells, the needle-shaped electrode has a plurality of needles facing each wall of the polygonal tubular cell, and a discharge generating plasma between the first electrode plate and the second electrode plate This takes place, and treating the air with a plasma module for killing viruses that passes the virus inactivated by the plasma;
Collecting the air treated with the virus-killing plasma module using a dust collection device including a discharge unit including a discharge electrode and a dust collector including a dust collection unit that collects dust charged in the discharge unit, wherein the discharge electrode is linear a discharge electrode, and
Ozone removal step of removing ozone generated from the plasma module and/or dust collector
Air sterilization and purification method comprising a. According to claim 1,
Air sterilization and purification method, characterized in that the distance between the plurality of needles and each wall surface of the polygonal tubular cell is substantially equal to each other. According to claim 1,
The air sterilization and purification method, characterized in that the square tubular case has a ground terminal connected to the ground terminal of the air purifier into which the plasma module is inserted, and a high voltage terminal connected to the high voltage terminal. According to claim 1,
An insulating terminal plate is formed on one surface of the rectangular cylindrical case,
An air sterilization and purification method, characterized in that the terminal plate is formed with a ground terminal that conducts electricity to the tubular case and the second electrode plate and a high-voltage terminal that conducts electricity to the first electrode plate. According to claim 1,
The method of sterilizing and purifying air, characterized in that the first electrode plate further comprises a first insulating member for insulating the first electrode plate from the second electrode plate and the rectangular cylindrical case. According to claim 1,
The second electrode plate further comprises a second insulating member for insulating the second electrode plate from the first electrode plate and a current conducting member for conducting the second electrode plate with the rectangular cylindrical case. method. According to claim 1,
The square tubular case is a rectangular parallelepiped tubular case having a rectangular cross section, and insulating plastic members are attached to upper and lower surfaces of flanges formed on upper and lower side surfaces of the tubular case Air sterilization and purification method, characterized in that. According to claim 1,
The plasma module is an air sterilization and purification method, characterized in that the plasma generator by streamer discharge. According to claim 1,
Air sterilization and purification method, characterized in that the air moves from the bottom to the top.

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