JP4577684B2 - Plasma generator and method for optimizing its power supply efficiency - Google Patents

Description

  The present invention relates to an atmospheric pressure plasma source, and more particularly, to a plasma generator using microwaves and a method for optimizing power supply efficiency for the device.

As a plasma generator using a microwave, for example, there are conventional devices described in Patent Document 1, Patent Document 2, or Patent Document 3 below.
These conventional devices are configured using a large magnetic coil, a pressure reducing mechanism, or the like.

Patent No. 3224443 Japanese Patent No. 3174981 Special table 2003-502822

However, these conventional devices have the following drawbacks.
(1) Since it is assumed that plasma is used in vacuum or low pressure, it may be disadvantageous in the following points.
(A) A magnetic coil and a pressure reducing mechanism are indispensable.
(B) When a high temperature is required, a process under high pressure such as atmospheric pressure (sputtering, etching, etc.) is often more advantageous.
(2) Since the apparatus tends to be large, it is disadvantageous in the following points.
(A) Equipment cost is difficult to suppress.
(B) Transportation and handling are not always easy.

  In other words, it is often desirable that the atmospheric pressure plasma apparatus is small in size, light, or easy to handle. However, conventional apparatuses that sufficiently satisfy these conditions are currently available. I can't find it.

The present invention has been made to solve the above-described problems, and an object of the present invention is to realize downsizing of an atmospheric pressure plasma generator using microwaves.
A further object of the present invention is to facilitate optimization of power supply efficiency for the atmospheric pressure plasma generator.
However, it is sufficient that the above individual objects are achieved individually by at least one of the individual means of the present invention, and the individual invention of the present application (the individual means described below) It does not necessarily guarantee that there is a specific embodiment that solves all of the above problems at the same time.

In order to solve the above problems, the following means are effective.
That is, the first means of the present invention is a plasma generating apparatus using a microwave having a cylindrical cavity for guiding a microwave, and a hollow cylindrical metal outer member forming an outer shell portion of the cavity. and the conductor, the whole or at least partially disposed inside said outer conductor, an insulator of the outer conductor coaxial cylindrical heat resistance, part of which is arranged inside said insulator, an outer conductor A cylindrical metal plasma material gas introduction pipe coaxial with the outer conductor, and an outer conductor disposed inside the outer conductor and on the outer periphery of the insulator, and radiating microwaves to the cavity. A coaxial coupling antenna having a coaxial loop, and a metal discharge antenna disposed inside the insulator and in front of the gas outlet of the plasma material gas introduction pipe. Atmospheric pressure plasma is emitted from the front opening end It is when.

However, as the insulating material of the above heat resistance, for example, may be used quartz, quartz glass, ceramics and the like.
Hereinafter, in the present specification, the side from which the atmospheric pressure plasma is emitted is the front of the plasma generator of the present invention. Therefore, the introduction port into which the plasma material gas is introduced in the plasma material gas introduction pipe is located behind the plasma generator of the present invention.

The second means of the present invention, in the first means described above, the circular frustum-shaped sidewall portion that having a through hole through which the above-mentioned insulator on the axis, front portion of the outer conductor Is to form.

  According to a third means of the present invention, in the first or second means, the loop of the coaxially coupled antenna is disposed on a bisector of the axial total length of the cavity. is there. However, this trisection point is the internal division point of the full length.

  Although there are two internal dividing points, the above-described coaxially-coupled antenna loop may be disposed on either one, or the above-described coaxially-coupled antennas may be disposed on both bisectors. However, when the above coaxially coupled antennas are arranged on both halves, a delay circuit is required because the phases of both microwaves must be shifted by π / 2. Therefore, it is desirable to provide the above coaxially coupled antenna in one place in terms of simplification of structure, size reduction, and weight reduction.

  According to a fourth means of the present invention, in any one of the first to third means described above, a protrusion protruding in a direction to emit atmospheric pressure plasma is provided on the discharge antenna, and the protrusion is provided. It is arrange | positioning on the axis | shaft of said insulator.

A fifth means of the present invention is the plasma generating apparatus according to any one of the first to fourth means, wherein the discharge antenna is a spiral filament.
According to a sixth means of the present invention, in any one of the first to fifth means, the discharge antenna is made of tungsten mixed with thorium.

  According to a seventh means of the present invention, in any one of the first to sixth means, the coaxial coupling antenna is fed with a coaxial cable.

  According to an eighth means of the present invention, in any one of the first to seventh means, the plasma material gas introduction pipe is provided with a variable mechanism whose axial position can be adjusted. is there.

According to a ninth means of the present invention, in the step of optimizing the power supply efficiency for the plasma generator according to claim 8, the microwave reflectivity of the coaxially coupled antenna is minimized by the variable mechanism. Is to set.
By the above means of the present invention, the above-mentioned problem can be effectively or rationally solved.

The effects obtained by the above-described means of the present invention are as follows.
That is, according to the first means of the present invention, since a high electric field is generated in the cavity by the microwave and the electric field is concentrated on the discharge antenna, the plasma material gas introduced from the plasma material gas introduction tube Becomes a plasma state efficiently. At this time, since the inside of the plasma material gas introduction pipe and the above-described insulator pipe is substantially atmospheric pressure, by optimizing the injection flow rate of the plasma material gas, a plasma gas with good purity is introduced in front of the apparatus. Can be released. Since the coaxially coupled antenna is used, microwaves can be supplied to the coaxially coupled antenna using a coaxial cable without using a waveguide, so that the apparatus can be made compact.

  In addition, according to the second means of the present invention, the electric field is concentrated well in the vicinity of the through hole, so that the electric field is more efficiently concentrated on the discharge antenna. For this reason, the electric power consumed for plasma generation can be suppressed.

  Further, according to the third means of the present invention, it is possible to efficiently supply the microwave to the discharge antenna while ensuring a short overall length of the axial device. Therefore, according to the third means of the present invention, both miniaturization and power saving of the apparatus can be rationally achieved.

  Further, according to the fourth means of the present invention, since the direction in which the plasma is generated coincides with the direction in which the plasma should be emitted, the generated plasma is immediately released while eliminating waste such as extinction and attenuation of the generated plasma as much as possible. can do. Further, according to the fifth means, since the discharge antenna is a spiral filament, it is possible to easily generate plasma by concentrating microwaves on this portion. According to the sixth means, since the discharge antenna is made of tungsten mixed with thorium, electrons are easily emitted by heating with microwaves, so that plasma can be easily generated in this portion. .

The coaxial cable is flexible and can be bundled in a small size, and is easy to handle. Therefore, according to the seventh means of the present invention, it is possible to input a microwave to the apparatus through a coaxial cable, which is easy to handle and far more than the case of introducing the microwave through a waveguide or the like. A compact apparatus can be configured. A microwave can be easily supplied to the cavity by the coaxially coupled antenna.
Further, if an N-type coaxial connector or the like is used, it is easy to attach and detach, and furthermore, these parts are standardized or commercially available, so that the design and manufacture of the apparatus are simplified.

Further, according to the eighth means of the present invention, the reflectance of the microwave to the cavity of the coaxially coupled antenna can be minimized by adjusting the position of the plasma material gas introduction pipe in the axial direction. (Ninth means of the present invention)
Usually, the optimum conditions for impedance matching between the cavity and the coaxially coupled antenna differ depending on whether plasma is generated or not. However, since the impedance matching can be easily optimized by using the variable mechanism as needed, it is possible to always realize a plasma generator with high power use efficiency.

Hereinafter, the present invention will be described based on specific examples.
However, the embodiments of the present invention are not limited to the following examples.

  FIG. 1A is a cross-sectional view on the axis of the plasma generator 10 of the first embodiment. This plasma generator 10 emits plasma from the front opening end 4a of the high heat resistance insulator 4 made of ceramics. A substantially cylindrical metal outer conductor 2 with a narrowed tip forms an outer shell portion of the coaxial cavity R. The outer conductor 2, the insulator 4, and the metal plasma material gas introduction pipe 1 are all formed in a cylindrical shape so as to be coaxial with each other, and the insulator 4 and the plasma material gas are disposed around this axis. The introduction pipe 1 is located. The outer conductor 2 and the plasma material gas introduction pipe 1 are electrically connected (conductive) in the vicinity of the variable mechanism 6.

  The inlet 1a of the plasma material gas inlet tube 1 is disposed at the rearmost part of the plasma generator 10, while the gas outlet 1b of the plasma material gas inlet tube 1 is disposed on the opposite side. A metallic discharge antenna 5 is disposed further in front of the gas outlet 1b. That is, the discharge antenna 5 is fixed to the inner wall of the insulator 4 and is arranged coaxially with the shaft in the insulator 4. The discharge antenna 5 is formed in a ring shape whose peripheral portion is joined to the inner wall of the insulator 4, and has a projection 51 whose central axis protrudes to the plasma emission side. In the vicinity of the discharge antenna 5, the plasma material gas introduction tube 1 is not provided in the outer direction with respect to the axis, and the following truncated cone-shaped side wall portion 2 a is provided. With such an arrangement, the electric field tends to concentrate on the discharge antenna 5. FIG. 1B shows a front view of the discharge antenna 5.

The front portion of the outer conductor 2 is formed from a substantially truncated cone side wall portion 2 a having a through-hole through which the insulator 4 penetrates on the axis. The structure in which the vicinity of the through hole of the side wall 2a is narrowed forward also contributes to concentrating the generated electric field on the discharge antenna 5.
The front end of the coaxially coupled antenna 3 has a loop shape as shown in FIG. The insulator 4 passes through the loop, and at the same time, the plasma material gas introduction pipe 1 passes through the loop.

  The variable mechanism 6 for adjusting the position of the plasma material gas introduction pipe 1 is formed by using a fixing bracket or the like. The variable mechanism 6 allows the plasma material gas introduction pipe 1 to be attached to the inner wall surface of the insulator 4. Guided, the position can be changed in the axial direction (ie in the front-rear direction). The N-type coaxial connector 7 provides an electrical connection interface for connecting a coaxial cable (not shown). The coaxial cable is used to feed microwaves, whereby high frequency power input from the N-type coaxial connector 7 is transmitted to the coaxial coupling antenna 3. The coaxially coupled antenna 3 radiates microwaves having a predetermined frequency to the coaxial cavity R based on this feeding. At this time, the microwave generates a high electric field in the coaxial cavity R.

  The plasma material gas flowing in from the inlet 1a of the plasma material gas introduction tube 1 passes through the gap s of the discharge antenna 5 and reaches the vicinity of the protrusion tip t of the discharge antenna 5. Since the electric field is concentrated in the vicinity of the projection tip t, the plasma material gas can be ionized. In this state after ionization, atmospheric pressure plasma is emitted from the front opening end 4a in accordance with the inflow speed of the plasma material gas.

The above-described coaxially coupled antenna 3 is disposed on a bisector of the entire length (axial length) of the coaxial cavity R. The total length of the coaxial cavity R is set to 3/4 of the above-mentioned microwave guide wavelength λ.
The outer diameter D of the outer conductor 2 and the outer diameter d of the plasma material gas introduction pipe 1 may be, for example, about D = 30 mm and d = 3.2 mm, respectively.
As the plasma material gas, for example, a commonly used gas such as argon (Ar), oxygen (O ₂ ), hydrogen (H ₂ ), or the like can be used. In the case of the plasma generator 10, the gas flow rate is suitably about 0.1 to 10 liters / minute.
Further, the power supplied to the coaxially coupled antenna 3 may be about 100 W.

  According to the above configuration, a very compact plasma generator (the present plasma generator 10) having a total length of about 100 mm can be configured. Since such a plasma generator is much smaller and lighter than the conventional apparatus, its handling is much easier than before.

Further, the reflectivity of the microwave with respect to the coaxial cavity R of the coaxially coupled antenna 3 can be minimized by the variable mechanism 6 that adjusts the position of the plasma material gas introduction tube 1 (the ninth aspect of the present invention). means).
Normally, the optimum conditions for impedance matching between the cavity and the coaxially coupled antenna differ depending on whether plasma is generated or not. However, if the variable mechanism 6 is used, the optimum impedance matching can be easily performed. Can be achieved.

  The discharge antenna 5 may be made of a metal material that easily emits electrons. In particular, the discharge antenna 5 is preferably made of tungsten mixed with thorium. 1A is disposed at the position where the discharge antenna shown in FIG. 1A is disposed (at the tip of the introduction tube 1 and inside the insulator 4), as shown in FIG. May be provided. The filament 52 is tungsten mixed with thorium. With this configuration, the filament 52 is heated by microwaves, and electrons can be effectively emitted, and plasma can be easily generated at this portion.

  The plasma generator of the present invention can be used for known applications such as surface cleaning, CVD, surface modification, and etching.

Sectional drawing on the axis | shaft of the plasma generator 10 of Example 1. FIG. Front view of discharge antenna 5 provided in plasma generator 10 Front view of coaxially coupled antenna 3 provided in plasma generator 10 Sectional drawing on the axis | shaft of the plasma generator 10 which concerns on another Example Configuration diagram of a discharge antenna showing another example

10: plasma generator 1: a plasma material gas introduction pipe 1a: inlet 1b: gas outlet 2: outer conductor 2a: circular cone trapezoidal side wall portion (the outer conductor 2 front)
3: Coaxial coupling antenna 4: the heat resistance insulator 4a: front open end 5 of the insulator 4: discharge Antenna 6: variable mechanism 7 for adjusting the position of the plasma gas feed pipe 1: N-type coaxial connector R: Coaxial cavity 51: Projection 52: Discharge antenna

Claims (9)

In a plasma generator using a microwave having a cylindrical cavity for guiding a microwave,
A hollow cylindrical metal outer conductor forming the outer shell of the cavity;
A cylindrical heat-resistant insulator coaxial with the outer conductor, the whole or at least a part of which is disposed inside the outer conductor;
A cylindrical metal plasma material gas introduction pipe coaxial with the outer conductor, a part of which is disposed inside the insulator and is electrically connected to the outer conductor;
A coaxial coupling antenna having a loop coaxial with the outer conductor, disposed inside the outer conductor and on the outer periphery of the insulator, and radiates the microwave to the cavity;
A metal discharge antenna disposed inside the insulator and in front of the gas outlet of the plasma material gas introduction pipe;
A plasma generating apparatus for emitting atmospheric pressure plasma from a front opening end of the insulator. The front part of the outer conductor is
The plasma generating apparatus according to claim 1, characterized in that it is formed from a circular cone trapezoidal side wall portions that have a through-hole for penetrating the insulation on the axis. The loop of the coaxially coupled antenna is
The plasma generating apparatus according to claim 1, wherein the plasma generating apparatus is disposed on a bisector of the overall length of the cavity in the axial direction. The discharge antenna is
Having a protrusion protruding in the direction of emitting the atmospheric pressure plasma,
The protrusion is
The plasma generating apparatus according to claim 1, wherein the plasma generating apparatus is disposed on an axis of the insulator. The plasma generating apparatus according to claim 1, wherein the discharge antenna is a spiral filament. The plasma generating apparatus according to any one of claims 1 to 5, wherein the discharge antenna is made of tungsten mixed with thorium. The coaxial coupling antenna is
The plasma generator according to any one of claims 1 to 6, wherein power is supplied by a coaxial cable. The plasma material gas introduction pipe is
The plasma generator according to any one of claims 1 to 7, further comprising a variable mechanism capable of adjusting a position in an axial direction. A method for optimizing the power supply efficiency for the plasma generator according to claim 8,
A method for optimizing feeding efficiency, characterized in that the reflectivity of the microwave in the coaxially coupled antenna is set to a minimum by the variable mechanism.