WO2020231136A1 - Plasma-generating substrate and plasma-generating apparatus - Google Patents

Abstract

An embodiment of the present invention is to provide a plasma-generating substrate and apparatus capable of generating a large area plasma with low power at atmospheric pressure by improving an electrode structure and a plasma emission structure provided on a PCB substrate. A plasma-generating substrate, according to an embodiment of the present invention, comprises: a plate disposed in a gas supply path; a first line, on one side of the plate, having one side connected to a high frequency power supply portion, and the other side having a first discharge electrode portion; and a second line having a second discharge electrode portion on one side thereof that is spaced apart from the first discharge electrode portion by a preset distance so as to form a discharge gap, wherein the plate has a plasma discharge hole penetrating one side and the other side of the plate in a discharge gap, and may guide plasma generated from the discharge gap such that the plasma is discharged outside through the plasma discharge hole.

Description

Plasma generator board and generator

The present invention relates to a plasma generator substrate and a generator.

Recently, researches on biomedical applications such as sterilization, hemostasis, and tooth whitening using atmospheric pressure plasma have been actively studied by domestic and foreign research institutes, and excellent effects are being proven. Among various atmospheric pressure plasma discharge methods, in the case of microwave plasma using a high frequency of 1,000 MHz to 3,000 MHz, there is no thermal damage to the object to be treated in terms of its characteristics. And due to the low discharge voltage, the electrical risk is low and the power efficiency is high. In addition, it has a higher possibility as a plasma equipment for biomedical applications compared to low-frequency plasma equipment such as excellent effect due to high plasma components.

However, in the case of the currently developed microwave plasma equipment, the size of the equipment is large due to the matching box used for effective power transmission, and high power must be used for plasma discharge. In addition, a large processing area is required in fields such as hemostasis, wound healing, and skin care, but when high-frequency power is used, the wavelength of the power used is very short, making it difficult to create a uniform electric field over a large area and to supply a uniform gas. Accordingly, there is a need to develop an apparatus that more easily generates a plasma of a large area with low power.

An embodiment of the present invention is to provide a plasma generator substrate and a generator capable of generating a large area plasma with low power under atmospheric pressure by improving an electrode structure and a plasma emission structure provided on a PCB substrate.

The plasma generation substrate according to the embodiment of the present invention includes a plate disposed in a gas supply path, a first line connected to a high frequency power supply on one side of the plate and a first discharge electrode on the other side, and a first discharge electrode. It includes a second line having a second discharge electrode part on one side that is spaced apart at a set interval to form a discharge gap, and the plate has a plasma discharge hole penetrating one side and the other side of the plate at the discharge gap, and is created at the discharge gap. The generated plasma can be guided to be discharged to the outside through the plasma emission hole.

The first line includes a matching part provided with a ground via hole connected to a ground part provided on the other surface of the plate, and the ground via hole may be provided at a position having a length of λ/4 of the high frequency power operation frequency from the discharge gap. The second line may include a ground line whose other side is connected to a ground portion provided on the other surface of the plate. The second line may include an ignition power supply line with the other side connected to the ignition power supply. The plate may include a printed circuit board (PCB). The plate may be formed in a flexible shape capable of bending. The first line and the second line may be provided on one surface of the plate. A plurality of plasma emission holes may be provided, and a plurality of first and second lines may be provided and disposed at positions corresponding to the corresponding plasma emission holes to form a plurality of plasma emission units. The first line includes a high-frequency power distribution line, and the high-frequency power distribution line is provided on one surface of the plate and is connected to a high-frequency power input unit connected to a high-frequency power supply unit and a high-frequency power input unit to obtain a length of λ/4 at the operating frequency of the high-frequency power. A power distribution unit having a distribution point connected to a resistor unit to distribute the high frequency power in parallel, and a pair of resonators resonantly coupled to the distribution points of the power distribution unit to supply high frequency power distributed in parallel. The resonator includes a matching part provided with a ground via hole connected to a ground part provided on the other surface of the plate, and the ground via hole may be provided at a position having a length of λ/4 of the high frequency power operating frequency from the discharge gap.

On the other hand, the plasma generating device is a plate disposed in the gas supply path, a first line connected to a high frequency power supply on one side of the plate and a first discharge electrode on the other side, and spaced apart from the first discharge electrode at a set interval. A plasma generating substrate including a second line having a second discharge electrode portion forming a discharge gap on one side, and a gas supply guide provided in the gas supply path to guide the flow of gas to at least the discharge gap, plasma The generating substrate may have a plasma emission hole penetrating one surface and the other surface of the plate in the discharge gap, and may guide plasma generated in the discharge gap to be discharged to the outside through the plasma emission hole. The gas supply guide portion is formed in a shape surrounding one surface of the plate so that at least the plasma emission hole is included therein, has a gas storage space, and may include a chamber for generating plasma at atmospheric pressure. The chamber may have a gas supply path connected to a position facing one surface of the plate. The chamber may include a plasma discharge hole provided at a position corresponding to the plasma discharge hole of the plate and communicating with the outer space of the chamber. The other surface of the plate may form any one of the outer walls of the chamber. The chamber is formed in the shape of a box with one side open to have a rim, a body having a gas filling space therein, and having a plurality of fastening holes on the other side facing one side, and coupled to the rim of the main body, It may include a cover portion for supporting the plate coupled to. The cover portion includes an edge portion of the body and a contact portion corresponding to each other, and at least a pair of contact portions facing each other may have a predetermined curvature and may be formed in a round shape.

By implementing a curved large-area microwave plasma generator using a PCB and a generator, it has a compact size and can easily generate plasma even under low power atmospheric pressure conditions. Plasma for a wide area such as skin treatment by generating a plurality of plasmas There is an effect that the treatment can be carried out more safely and easily.

1 is a diagram schematically showing the basic structure of a plasma generating substrate according to an embodiment of the present invention.

2 is a diagram showing an applied structure of FIG. 1.

3 is a diagram showing an arrangement structure of a discharge electrode portion and a plasma emission hole provided in a discharge gap.

4 is a view showing a plate provided with a plurality of plasma emission holes.

5 is a view showing a curved chamber structure according to an embodiment of the present invention.

6 is a cross-sectional view taken along line B-B of FIG. 5.

The terminology used herein is for reference only to specific embodiments and is not intended to limit the invention. Singular forms as used herein also include plural forms unless the phrases clearly indicate the opposite. The meaning of "comprising" as used in the specification specifies a specific characteristic, region, integer, step, action, element and/or component, and other specific characteristic, region, integer, step, action, element, component and/or group It does not exclude the existence or addition of

Although not defined differently, all terms including technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms defined in a commonly used dictionary are additionally interpreted as having a meaning consistent with the related technical literature and the presently disclosed content, and are not interpreted in an ideal or very formal meaning unless defined.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art may easily implement the present invention. However, the present invention may be implemented in various different forms and is not limited to the embodiments described herein.

1 is a view schematically showing a basic structure of a plasma generating substrate according to an embodiment of the present invention, and FIG. 2 is a view showing an applied structure of FIG. 1. 3 is a view showing an arrangement structure of a discharge electrode portion and a plasma emission hole provided in the discharge gap. 1 to 3, the plasma generating substrate according to the embodiment of the present invention is disposed in the gas supply path and provided in the plate 10 having the plasma emission hole 12 and the plate 10 to supply high frequency power. It includes the supplied first line 100 and the second line 110 forming a discharge gap. Here, the plate 10 may include a printed circuit board (PCB). In addition, the plate 10 may include a dielectric material having a relatively high dielectric constant. The dielectric material of the plate 10 may include a ceramic compound, TEFLON, polytetrafluoroethylene (PTFE), polymer, glass, quartz, and combinations thereof. In addition, the gas may include one or more of helium gas, argon gas, nitrogen gas, oxygen, and complex gas. The gas supply path may include a gas supply unit 30 and a gas supply line. In addition, it may further include a gas supply guide (30a) provided separately in the gas supply path to guide the flow of gas to at least the discharge gap. Referring to FIG. 2, by providing the gas supply guide 30a, it is possible to intensively guide the gas supply flow around the plasma emission hole 12 provided in the discharge gap. Meanwhile, the gas supply path may further include a gas supply control unit for uniformly supplying gas to the discharge gap. The gas supplied to the discharge gap through the gas supply control unit may be uniformly adjusted through at least one supply path and then supplied to the corresponding discharge gap through a plurality of supply paths.

On the other hand, the plate 10 may include a plasma emission hole 12 penetrating through one surface and the other surface of the plate 10 in the discharge gap. When gas is supplied to the plasma emission hole 12 provided in the discharge gap and power corresponding to the first line 100 and the second line 110 is supplied, the first line 100 close to the discharge gap and Discharge may occur due to an electric field between the second lines 110. In this state, the gas supplied to the discharge gap may be ionized to generate plasma P. In this way, the plasma P generated in the discharge gap of the plate 10 may be discharged to the outside through the plasma discharge hole 12 along the flow of the continuously supplied gas. Here, the plasma emission hole 12 may be provided in the form of a slot or a via hole.

A first line 100 and a second line 110 may be provided on one surface of the plate 10. Here, the first line 100 may have one side connected to the high frequency power supply unit 20 through the high frequency power input connector 20a and the other side as the first discharge electrode unit 100a. The first line 100 is a matching part 102 provided with a ground via hole 104 connected to a ground part provided on the other surface of the plate 10 at a position having a length of λ/4 at the operating frequency of the high frequency power from the discharge gap. ) Can be included. The total length l of the pattern including the matching part 102 in the first line 100 may be formed as l _l +l ₂ and may be frequency tuned to λ/4. And it is possible to match the input impedance to 50Ω by adjusting the length ratio of l _l and l ₂ .

The second line 110 may have a second discharge electrode part 110a spaced apart from the first discharge electrode part 100a at a set interval to form a discharge gap on one side. The first line 100 and the second line 110 may include a metal strip. In the discharge gap, the distance between the first discharge electrode part 100a and the second discharge electrode part 110a may be maintained at 0.1mm to 1mm to create a high electric field. The front side of the first discharge electrode part 100a and the second discharge electrode part 110a is formed to be sharper toward the other end, so that the concentration of electrons is high. In the discharge gap, the structure adjacent to the first discharge electrode part 100a and the second discharge electrode part 110a is improved to a sharp and narrower space, so that the electric field can be strengthened. As the electrical concentration increases, plasma generation is easy and stability can be increased.

The second line 110 may include a ground line whose other side is connected to a ground portion provided on the other surface of the plate 10. The second line 110 may correspond to the first line 100 and may be provided with a conductor capable of replacing the ground portion. However, when the second line 110 is provided as a ground line or a conductor capable of electrical connection without a separate ignition line, the high frequency power supplied through the first line 100 must be relatively high in the discharge gap. Plasma P can be generated. Accordingly, the second line 110 may include an ignition power supply line with the other side connected to the ignition power supply. When the second line 110 is provided as an ignition power supply line, there is little effect on matching as a result of a high frequency structure simulator (HFSS), and plasma is generated without increasing the high frequency power supplied to the first line 100. Can ignite. The ignition power may be a low frequency (~kHz) signal having a high voltage (~kV). As the ignition power is applied, an arc discharge occurs in the discharge gap, and the resulting seed electrons are accelerated by the high-frequency power to ionize the gas in the discharge gap to ignite the plasma. After ignition, the plasma state can be maintained even by relatively low high frequency power. In addition, the second line 110 may be provided in a pattern similar to the first line 100, and the first line 100 and the second line 110 may be provided on one surface of the plate 10. Various types of patterns can be implemented.

4 is a view showing a plate provided with a plurality of plasma emission holes. Referring to FIG. 4, the plate 10 may have a plurality of discharge gaps. A plurality of discharge gaps provided in the plate 10 may be arranged to be adjacent to each other or to generate continuous plasma P on the same line. In addition, a plasma emission hole 12a provided in each discharge gap may be provided, and through the first line 100 to which high frequency power is supplied through the high frequency power input unit 410 and the ignition power input units 420 and 420a. The second line 110 to which the ignition power is supplied may be provided in plural and disposed at a position corresponding to the corresponding plasma emission hole 12a. For example, the plate 10 may include a plurality of plasma generation units including an ignition line, a high frequency power distribution line, and a resonator, and including a discharge gap and a plasma discharge hole 12a at corresponding positions. Referring to FIG. 4, the plasma generating unit may include eight plasma generating units so as to be symmetrical to each other with respect to the top, bottom, left and right of the plate 10. For example, in the eight plasma generating units, the first plasma generating unit P1 may include an eleventh ignition line 422, an eleventh power distribution unit 412a1, and an eleventh resonator 432. The second plasma generating unit P2 may include a twelfth ignition line 424, an eleventh power distribution unit 412a1, and a twelfth resonator 434. A third plasma generating unit P3 may be provided at a lower portion symmetrical to the first plasma generating unit P1, and a fourth plasma generating unit P4 may be provided at a lower portion symmetrical to the second plasma generating unit P2. have. In addition, the fifth plasma generating unit P5 to the eighth plasma generating unit P8 may be provided on the right side symmetrical to the first plasma generating unit P1 to the fourth plasma generating unit P4. In this case, 8 plasma emission holes 12a may also be provided. Accordingly, a large-area plasma generating apparatus can be implemented by having eight plasma emission holes 12a in one plate 10.

The first line 100 may include a high frequency power distribution line. The high frequency power distribution line is provided on one side of the plate 10 and is connected to the high frequency power input unit 410 and the high frequency power input unit 410 connected to the high frequency power supply unit 20 to achieve a length of λ/4 at the operating frequency of the high frequency power. And a power distribution unit having a distribution point connected to the resistor unit 402 to distribute the high frequency power in parallel, and a pair of resonators that are resonantly coupled to the distribution points of the power distribution unit to supply high frequency power distributed in parallel. I can.

The power distribution unit may form a pattern branching from the main power distribution unit 412 to a distribution structure. Reference numeral 412a denotes a first power distribution unit connected in a distribution structure from the main power distribution unit 412, and an eleventh power distribution unit 412a1 and a twelfth power distribution unit 412a2 are distributed from the first power distribution unit. Can be connected to. Reference numeral 412b denotes a second power distribution unit connected from the main power distribution unit 412 in a distribution structure, and the 21st power distribution unit 412b1 and the 22nd power distribution unit 412b2 are distributed from the second power distribution unit. Can be connected to. In addition, the resonators include an eleventh resonator 432 and a twelfth resonator 434 connected to the eleventh power distribution unit 412a1, and a thirteenth resonator 432a and a 14th resonator connected to the twelfth power distribution unit 412a2. 434a), the 21st resonator 436 and the 22nd resonator 438 connected to the 21st power distribution unit 412b1, the 23rd resonator 436a and the 24th resonator connected to the 22nd power distribution unit 412b2 438a).

The second line 110 may include a first ignition power supply line connected to the first ignition power input unit 420 and a second ignition power supply line connected to the second ignition power input unit 420a as needed. . The first ignition power supply line is the eleventh ignition line 422 corresponding to the eleventh resonator 432, the twelfth ignition line 424 corresponding to the twelfth resonator 434, and the thirteenth resonator 432a. A thirteenth ignition line 422a and a fourteenth ignition line 424a corresponding to the fourteenth resonator 434a may be included. And the second ignition power supply line corresponds to the 21st ignition line 426 corresponding to the 21st resonator 436, the 22nd ignition line 428 corresponding to the 22nd resonator 438, and the 23rd resonator 436a. The 23rd ignition line 426a and the 24th ignition line 428a corresponding to the 24th resonator 438a may be included.

Meanwhile, the resonator includes a matching part provided with a ground via hole 404, and the resonator may be electrically connected through the ground part and the ground via hole 404 at a position having a length of λ/4 at the operating frequency of the high frequency power from the discharge gap. have. In order to distribute high frequency power, a separate distribution circuit is required, and a high frequency power distribution circuit can be formed with a Wilkinson Power Divider. High frequency power can be distributed by distributing a transmission line of λ/4 from the input in parallel in consideration of impedance and line length and connecting a resistor between points where the high frequency power is distributed. A plurality of resonators may be provided throughout the plate 10. The matching unit and the ground via hole 404 provided in the resonator may be located at a location that satisfies an input impedance of 50Ω according to a frequency used from the discharge gap. The length from the matching unit to the discharge gap may have a length corresponding to 1/4 of the operating high frequency wavelength. Due to the electrical characteristics of the resonator, a high electric field may be concentrated at the end of the discharge gap.

As described above, a process of generating a large-area plasma P by driving the plasma generator using the plate 10 will be described. First, in order to supply the plate 10 of the high frequency power, the high frequency power is supplied to the high frequency power input terminal of the plate 10 by turning on the power of the high frequency power supply unit 20. The high frequency power supplied to the high frequency power input terminal may be supplied to the corresponding first discharge electrode unit 100a through a power distribution unit and a resonator. Here, in order to facilitate plasma generation, an inert gas (argon gas), which is an ignition gas, may be supplied into the gas supply path or the interior of the chamber 500 under preset supply conditions. In this state, power of the ignition power supply unit may be turned on and the boosted ignition power may be supplied to the corresponding second discharge electrode unit 110a through the second line 110. Then, an arc is generated in the discharge gap due to the voltage difference between the second discharge electrode part 110a and the first discharge electrode part 100a, which is an ignition electrode, and the generated arc is plasma in a plurality of electric field regions formed by high frequency. It can cause discharge. Accordingly, a large-area microwave plasma generating apparatus using the plate 10 can be implemented.

As described above, the plasma generating apparatus according to the embodiment of the present invention applies the same high-frequency power source to the plate 10 to generate plasma P in a narrow area, and a plurality of plasmas P ) Can be generated to implement a large-area plasma generator. Here, the high frequency power source may include a microwave source. In addition, since it is not necessary to separately use a separate power distributor and gas distributor to implement a large-area plasma generator, it is possible to relatively reduce the volume, weight, and manufacturing cost of the plasma generator.

The gas supply guide portion may include a chamber that is formed in a shape surrounding one surface of the plate 10 so that at least the plasma emission hole 12 is included therein, has a gas storage space, and generates plasma P at atmospheric pressure. Here, the chamber may be formed in a hexahedral shape having a gas filling space, and a gas supply connector may be connected to a connection connection surface of the chamber corresponding to a position facing one surface of the plate 10. In addition, a high frequency power supply connector connected to the high frequency power supply unit 20, an ignition power supply connector having an ignition power line electrically connected to the ignition power supply unit, a gas supply connector to which a gas supply hose is connected, etc. Can be further combined. In order to generate a more stable large-area plasma P by using the plate 10, a chamber in which the plate 10 is embedded was formed to perform an ignition test. Gas supplied into the chamber to ignite the gas using the chamber may include argon (Ar) gas. When plasma P is generated using the chamber, the supply of gas can be controlled. For example, a first step of filling gas into the chamber and a second step of generating plasma P may be divided into a first step of filling gas into the chamber, and a supply flow rate of the gas supplied into the chamber may be controlled. More specifically, in the first step of filling the gas into the chamber having the 0.1 liter storage space, the gas flow rate supplied to the interior of the chamber is injected at 1 slm to fill the gas for about 6 seconds. And in the second stage of plasma generation, since the gas inside the chamber has been filled, the flow rate of the gas supplied to the chamber is lowered to 0.1 slm and the generated plasma (P) is kept in an ignition state to continuously generate plasma (P). can do.

Meanwhile, the chamber may include a plasma discharge hole provided at a position corresponding to the plasma discharge hole 12 of the plate 10 and communicated with the outer space of the chamber. When one surface of the chamber is partially opened to have a plate coupling surface to which the plate 10 is coupled, one surface of the chamber may be replaced with the plate 10. For example, the other surface of the plate 10 may form any one of the outer walls of the chamber. In this case, the plasma P generated inside the chamber may be discharged to the outside of the chamber through the plasma emission hole 12 of the plate 10.

On the other hand, the plate 10 may be formed in a flexible form in the shape of a thin plate capable of bending. In this case, the shape of the chamber may be variously implemented using the bending characteristics of the plate 10.

5 is a diagram showing a curved chamber structure according to an embodiment of the present invention, and FIG. 6 is a cross-sectional view taken along line B-B of FIG. 5. 5 and 6, it is possible to implement a curved large-area plasma generating apparatus using a plate 10 capable of bending. Here, the chamber 600 may be formed in a box shape having an rim portion by opening one surface. The chamber 600 may include a body 610 and a cover part 620. The main body 610 may have a gas filling space therein and may include a plurality of fastening holes 610a on the other surface facing one surface. A high frequency power connector, a gas supply connector, an ignition power connector, and the like may be fastened to the plurality of fastening holes 610a. The cover part 620 is coupled to the rim of the body 610 and may support the plate 10 coupled to the plate coupling part 600a provided between the body 610 and the body 610. The plate 10 may be easily combined with a curved surface by using a thin PCB substrate to be suitable for the curved chamber 600. The cover part 620 includes contact portions 622 and 622a corresponding to each other with an edge portion of the main body 610, and at least a pair of contact portions 622 and 622a facing each other have a predetermined curvature and are formed in a round shape. Can be. Since the cover portion 620 is formed in a round shape, it is possible to easily contact round or curved portions such as arms and legs of a human body. Accordingly, as the external shape of the chamber 600 is improved, it is easy to biologically process the circular portion, and various use environments can be provided.

Although preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications can be made within the scope of the claims, the detailed description of the invention, and the accompanying drawings, and this is also It is natural to fall within the scope of the present invention.

Claims (14)

1. A plate disposed in the gas supply path,

   A first line connected to a high frequency power supply on one side of the plate and a first discharge electrode on the other side, and

   A second line provided with a second discharge electrode unit on one side that is spaced apart from the first discharge electrode unit at a set interval to form a discharge gap

   Including,

   The plate has a plasma emission hole passing through one surface and the other surface of the plate in the discharge gap, and guides the plasma generated in the discharge gap to be discharged to the outside through the plasma emission hole.
2. In claim 1,

   The first line includes a matching part provided with a ground via hole connected to a ground part provided on the other surface of the plate, and the ground via hole is provided at a position having a length of λ/4 of a high frequency power operation frequency from the discharge gap. Plasma generator substrate.
3. In claim 1,

   The second line includes a ground line connected to a ground portion provided on the other surface of the plate.
4. In claim 1,

   The second line includes an ignition power supply line connected to the other end of the ignition power supply.
5. In any one of claims 1 to 4,

   The plate is a plasma generating substrate including a flexible printed circuit board (PCB) capable of bending a curved surface.
6. In clause 5,

   The plasma generation substrate is provided with a plurality of plasma emission holes, and a plurality of the first line and the second line are each provided, and are disposed at positions corresponding to the corresponding plasma emission holes to form a plurality of plasma emission units.
7. In paragraph 6,

   The first line includes a high frequency power distribution line,

   The high frequency power distribution line

   A high frequency power input unit provided on one surface of the plate and connected to the high frequency power supply unit,

   A power distribution unit connected to the high frequency power input unit and having a length of λ/4 at an operating frequency of the high frequency power and having a distribution point connected to a resistance unit to distribute the high frequency power in parallel, and

   A pair of resonators that are resonantly coupled to the distribution points of the power distribution unit to supply the high-frequency power distributed in parallel,

   The resonator includes a matching part provided with a ground via hole connected to a ground part provided on the other surface of the plate, and the ground via hole is a plasma provided at a position having a length of λ/4 of the high frequency power operating frequency from the discharge gap. Generator substrate.
8. On one side of the plate disposed in the gas supply path, one side is connected to a high frequency power supply and the other side is a first line having a first discharge electrode part, and a second line that is spaced apart from the first discharge electrode part at a set interval to form a discharge gap. A plasma generator substrate including a second line having a discharge electrode portion on one side, and

   A gas supply guide provided in the gas supply path to guide the flow of the gas to at least the discharge gap

   Including,

   The plasma generating substrate includes a plasma emission hole penetrating one surface and the other surface of the plate in the discharge gap, and guides the plasma generated in the discharge gap to be discharged to the outside through the plasma emission hole.
9. In clause 8,

   The gas supply guide portion is formed in a shape surrounding one surface of the plate so that at least the plasma emission hole is included therein, has a gas storage space, and includes a chamber for generating plasma at atmospheric pressure,

   The plasma generating apparatus in which the gas supply path is connected to a position in the chamber facing one surface of the plate.
10. In claim 9,

    The chamber is

    The main body is formed in the shape of a box with one side open to have an edge portion, has a gas filling space therein, and has a plurality of fastening holes on the other side facing the one side, and

    It is coupled to the edge portion of the main body, and includes a cover portion for supporting the plate coupled between the main body,

    The cover portion includes a contact portion corresponding to the edge portion of the main body, and at least a pair of contact portions that face each other have a predetermined curvature and are formed in a round shape.
11. In clause 8,

    The second line comprises an ignition power supply line connected to the other end of the ignition power supply.
12. In any one of claims 8 to 11,

    The plate generator substrate is a plasma generator comprising a flexible printed circuit board (PCB) capable of bending a curved surface.
13. In claim 12,

    The plasma generating apparatus is provided with a plurality of plasma emission holes, and the first line and the second line are provided in plural, respectively, and disposed at positions corresponding to the corresponding plasma emission holes to form a plurality of plasma emission units.
14. In claim 13,

    The first line includes a high frequency power distribution line,

    The high frequency power distribution line

    A high frequency power input unit provided on one surface of the plate and connected to the high frequency power supply unit,

    A power distribution unit connected to the high frequency power input unit and having a length of λ/4 at an operating frequency of the high frequency power and having a distribution point connected to a resistance unit to distribute the high frequency power in parallel, and

    A pair of resonators that are resonantly coupled to the distribution points of the power distribution unit to supply the high-frequency power distributed in parallel,

    The resonator includes a matching part provided with a ground via hole connected to a ground part provided on the other surface of the plate, and the ground via hole is a plasma provided at a position having a length of λ/4 of the high frequency power operating frequency from the discharge gap. Generator.

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