JP4035568B2 - Atmospheric pressure large area plasma generator - Google Patents

Description

  The present invention relates to an atmospheric pressure plasma generator for generating a thermal plasma gas by converting an atmospheric gas into a plasma gas by microwave excitation. More specifically, a plurality of plasma generation sources are combined in parallel and fed back to each other. The present invention relates to an atmospheric pressure / large area plasma generation apparatus that enables generation of a large area plasma at atmospheric pressure by performing control and driving.

  Thermal plasma is used almost synonymously with atmospheric pressure plasma. In the 1970s, development for industrial applications became active. Applications include industrial materials melting, fusing, joining, refining, metallurgy, spraying, and other industrial materials processing, lighting fields such as light sources for displays that use plasma-generated light, fine particle generation, induction This is a field of chemical analysis of trace sample components using plasma as a means of ionization, and a field of cleaning surface treatment of semiconductor process materials.

  In the 1980s, it was noticed by using it for removing the causative substances of air pollution. Tepla RF plasma source and ARIOS atmospheric pressure plasma source have been developed and used. The former has a low plasma conversion efficiency because the high frequency for exciting the gas into the plasma state is relatively low at 13.56 MHz. In addition, the apparatus has become large due to the frequency relationship.

  With reference to FIG. 17, the atmospheric pressure plasma source of ARIOS will be described. In this apparatus, a microwave that oscillates near an excitation frequency of 2.45 GHz is used as a plasma source. A microwave waveguide 1710 is used as means for supplying microwaves to a plasma cavity inside a microwave plasma source 1701 that generates plasma gas. The impedance when the load side is viewed from the microwave oscillator 1707 changes greatly before and after the plasma is lit. In order to supply appropriate power to the plasma source, a stub tuner 1711 is provided in the middle of the waveguide 1710, and the stub tuner 1711 is automatically controlled to stably supply power. However, the use of a waveguide increases the size of the device. For this reason, the diameter of the plasma cavity is relatively large at 15 cm. Further, in order to automatically control the stub tuner 1711, a pulse motor that performs mechanical control is required.

Since the above-mentioned apparatus is a microwave oscillator that outputs oscillation power of 1 KW to 5 KW using one large magnetron, the power supply requires a large power supply. Therefore, the power supply device becomes large.
In addition, since a waveguide is used to supply microwaves from the microwave generation source, the positional relationship between the plasma source (processing apparatus) and the microwave source is mechanically fixed. For this reason, it is not easy to change the arrangement of the apparatus.
Moreover, it is necessary to match the frequency on the load side with the oscillation frequency of the magnetron, and a complicated and expensive tuning mechanism is required.
The microwave generation source uses a water-cooled cooling method because it generates a large amount of heat due to microwave power that oscillates continuously. This cooling increases the size of the device. In addition, careful maintenance is always required. All of the inventions shown in the following documents supply microwave power using a waveguide.
JP 2001-257097 A JP 2002-280196 A

Recently, there has been a demand for an apparatus capable of uniformly maintaining a plasma distribution over a wide area in order to uniformly clean a wide area.
Therefore, many proposals to generate plasma in the container by emitting microwaves from the same microwave generation source as described above to the container from many antennas formed on a disk etc. Has been made. However, even if various considerations are given to the arrangement and shape of slot antennas such as disks as described in Patent Document 3, it is extremely difficult to maintain a uniform plasma distribution in a wide region.
In particular, the following two points are serious problems in a plasma generator using microwaves.
1) The electromagnetic wave (microwave) mode in the apparatus (chamber or resonator) changes greatly before and after the plasma is generated, so that the apparent impedance changes and the electromagnetic wave is reflected. Therefore, an expensive and complicated automatic impedance matching device is required.
2) No matter how uniform the electromagnetic wave in the chamber is before plasma is generated, once the plasma is generated, it becomes non-uniform.
The cause of this is as follows. 1. Use a chamber that is much larger than the wavelength; A mode in the device (chamber or resonator) due to a significant change in the boundary condition of the electromagnetic wave due to plasma is a complicated pattern. For these reasons, it is difficult to produce a uniform plasma in an apparatus (chamber or resonator) sufficiently larger than the wavelength.
JP 2002-299330 A

As described above, it is difficult for the conventional method to realize an apparatus capable of maintaining the plasma distribution uniformly in a wide region. Therefore, in the present invention, a system capable of preparing a plurality of plasma generation sources or plasma generation locations (antennas) and individually or similarly controlling the microwave power supplied to these plasma generation sources or plasma generation locations. Is to provide.
A main object of the present invention is to provide an atmospheric pressure large-area plasma generator that can be used not only for a coaxial resonator but also for other types of resonators and is easy to handle.
Another object of the present invention is to generate a plasma operating at atmospheric pressure stably and with a small apparatus, and combine a plurality of plasma generators to supply a uniform plasma distribution over a wide area. An object of the present invention is to provide an atmospheric pressure large area plasma generator.
The meaning of atmospheric pressure used in the present invention does not strictly mean standard atmospheric pressure, but is used to mean that extreme pressure reduction is not required.
Another object of the present invention is to provide a microwave plasma generator capable of freely moving the arrangement of the plasma head and the like by further reducing the size of the plasma generator (plasma head) using a coaxial resonator. Accordingly, an object of the present invention is to provide an atmospheric pressure and large area plasma generator that supplies a uniform plasma distribution over a wide area.
Another object of the present invention is to convert the impedance before and after the generation of the plasma by optimizing the direction and shape of the antenna and the structure of the chamber in order to solve the problem of the uniformity of the plasma generated in the apparatus described above. It is to make it a structure that can automatically cause.
Another object of the present invention is to provide the above-mentioned many antennas, dispose a plasma detection probe in each antenna portion, and independently control the power supplied to each antenna in both time and space. It is to maintain the uniformity of the plasma.

In order to achieve the above object, an atmospheric pressure large area plasma generator according to claim 1 according to the present invention comprises:
A microwave-excited plasma gas generator for exciting a plasma generating gas under atmospheric pressure,
A microwave oscillator including a VCO circuit having a variable oscillation frequency;
A microwave modulator including a pulse circuit, an isolator, and an amplifier connected to the microwave oscillator and configured to vary the oscillation duration and the oscillation interval of the microwave output by the microwave oscillator;
A plurality of unitized microwave power amplifiers connected to the output of the microwave modulator;
A cavity resonator in which a plasma generating gas is introduced into the cavity or a part of the cavity, and a plurality of coupled antennas for supplying power from the microwave power amplifier to the cavity are disposed on the cavity wall;
A plurality of antennas and a plurality of plasma sensors arranged in relation to plasma gas generation positions of the cavity resonator;
Wherein the traveling wave incident microwave plasma source of several microwave plasma generating source by measuring the phase of the reflected wave reflected oscillation frequency of the microwave oscillator of the plurality of microwave plasma source Resonance maintenance control section that controls to match the resonance frequency of one microwave plasma generation source, and the pulse that adjusts the oscillation duration and the oscillation interval of the microwave according to either the output of the plasma sensor or a specified value voltage maintenance control unit to maintain the overall output voltage by controlling the circuit, and the microwave power amplifier control according to the measurement results of plasma sensors arranged in connection with the microwave plasma source, the space specific A power adjustment control unit for amplifying the amplitude of the microwave output by the microwave modulator according to the plasma state of A control unit digits, and a.
The atmospheric pressure large area plasma generator according to claim 2 of the present invention is the atmospheric pressure large area plasma generator according to claim 1,
The antennas are two-dimensionally arranged such that the distance between the antennas adjacent to the cavity wall is about a quarter of the in-tube wavelength of the excitation microwave.

An atmospheric pressure large area plasma generator according to claim 3 of the present invention comprises:
A microwave-excited plasma gas generator for exciting a plasma generating gas under atmospheric pressure,
A microwave oscillator including a VCO circuit having a variable oscillation frequency;
A microwave modulator including a pulse circuit, an isolator, and an amplifier connected to the microwave oscillator and configured to vary the oscillation duration and the oscillation interval of the microwave output by the microwave oscillator;
A plurality of unitized microwave power amplifiers connected to the output of the microwave modulator;
It is composed of a pair of cavities coupled by opposing elongated gaps, and has a dielectric passage for passing a plasma generating gas in a direction perpendicular to the gap between the gaps, and supplies power from the microwave power amplifier to the cavities. A cavity resonator in which a plurality of coupled antennas are disposed on the cavity wall;
A plurality of plasma sensors arranged at the plasma gas outlet of the dielectric passage;
The output of the plasma sensor is connected;
The phase of the traveling wave incident on the plurality of microwave plasma generation sources and the reflected wave reflected by the microwave plasma generation source are measured, and the oscillation frequency of the microwave oscillator is one of the plurality of microwave plasma generation sources. Resonance maintenance control unit that controls to match the resonance frequency of two microwave plasma generation sources, and the pulse circuit that adjusts the oscillation duration and interval of the microwave according to either the output of the plasma sensor or a specified value A voltage maintaining controller that controls the entire output voltage by controlling the microwave power amplifier according to a measurement result of a plasma sensor disposed in association with the microwave plasma generation source, and plasma in a specific space A power adjustment control unit that amplifies the amplitude of the microwave output by the microwave modulator according to the situation. A control unit digits, and a.

The atmospheric pressure large area plasma generator according to claim 4 of the present invention is the atmospheric pressure large area plasma generator according to claim 3,
The plurality of coupled antennas are disposed on the cavity wall along the direction of the gap.
The atmospheric pressure large area plasma generator according to claim 5 of the present invention is the atmospheric pressure large area plasma generator according to claim 1 or 3,
The microwave oscillator uses a solid-state semiconductor oscillator.
The atmospheric pressure large area plasma generator according to claim 6 of the present invention is the atmospheric pressure large area plasma generator according to claim 1 or 3,
The microwave power amplifier includes an AC power supply in the circuit.
The atmospheric pressure large area plasma generator according to claim 7 of the present invention is the atmospheric pressure large area plasma generator according to claim 1 or 3,
The plasma sensor for measuring the plasma is a Langmuir probe.

  According to the present invention, microwave power to a plurality of plasma generation sources or a plurality of plasma excitation points (antennas) can be controlled simultaneously or individually. As a result, a uniform and large-area plasma generation region can be obtained. In addition, the intensity of the plasma can be controlled according to the use environment and purpose. Such a uniformity cannot be ensured or controlled by a conventional apparatus.

  Hereinafter, an embodiment of an atmospheric pressure large area plasma generator according to the present invention will be described with reference to the drawings. FIG. 1A is a block diagram of an atmospheric pressure large area plasma generator of the present invention configured by combining a plurality of independent plasma heads. The present inventor has proposed a microwave plasma generator that can be used as the plasma head in Japanese Patent Application Laid-Open No. 2004-172044. FIG. 1B is a block diagram of an atmospheric pressure large area plasma generator of the present invention using a plurality of independent plasma antennas (microwave supply sources) in combination.

First, the atmospheric pressure large area plasma generator of the present invention shown in FIG. 1A will be described. The atmospheric pressure large area plasma generator comprises a microwave oscillator 1, a microwave modulation circuit 2, a power amplifier 3, a plasma generator group 4, a control circuit 5 and a manual operation keyboard 6. Furthermore, the power amplifying device 3 includes _N power amplifiers numbered 3 ₁ , 3 ₂ , 3 ₃ ,..., 3 _N−1 , 3 _N.

  FIG. 2 shows an internal circuit of the microwave oscillator 1. As shown in FIG. 2, the microwave oscillator 1 includes an oscillation circuit 13 and an amplifier 15. The oscillation circuit 13 is composed of a solid semiconductor element, and generates a high-frequency microwave used for plasma excitation. The oscillation circuit 13 is composed of a VCO circuit, and the microwave oscillation frequency is changed by a frequency control signal CFT (such as the CFT1 signal 3E shown in FIG. 4A) connected to the terminal 14.

FIG. 3 shows the microwave modulation circuit 2. The microwave modulation circuit 2 includes a modulator 22, an isolator 23, and an amplifier 25. The modulator 22 is a modulation circuit composed of a PIN diode, and is modulated by a control signal CTPT applied to the terminal 24. FIG. 7 shows the CTPT signal. The CTPT signal is a pulse signal, the pulse width of the pulse signal is t, and the repetition time is T. By changing the pulse width t and the period time T of the CTPT signal, the oscillation duration time and the oscillation interval of the microwave are made variable .
When this pulse signal is applied to the modulator 22, as shown in FIG. 8, the waveform of the microwave is converted into an output signal having an oscillation time t and a repeating time T (periodic time interval).
The pulse-modulated microwave passes through the isolator 23 and the amplifier 25 and is output to the output terminal 26. The output of the modulated microwave is applied to the input terminal 31 of the power amplifier 3 ₁ shown in FIG. 4A. Next, the isolator 23 is used to cut off the reflected power due to a large load fluctuation before and after the formation of the plasma state. As a result, the oscillation frequency of the microwave oscillator 1 is not affected by the load and maintains stable oscillation.

The output signal having the stabilized frequency is connected to the power amplifying device 3 (the power amplifiers 3 _{1 to} 3 _N ).
Figure 4A, shows a state of being connected to an input terminal 31 of the power amplifier 3 _1. Outputs of the power amplifiers 3 _{1 to} 3 _N are connected to corresponding generators (41S to 4NS) in the plasma generator group 4. The power amplifiers 3 _{1 to} 3 _N have the same configuration, and an attenuator 32 for adjusting the amplitude voltage of the microwave, amplifiers 34 and 35, an isolator 36, a directional coupler 37, a control circuit 39 for controlling the attenuator 32, An AC / DC voltage conversion circuit 3A for supplying a DC voltage consumed by the power amplifier and a microwave frequency stabilization feedback circuit 3D are included. The power amplifier is composed of a solid-state semiconductor element such as a microwave LDMOS (Laterally Diffused Metal Oxide Semiconductor), and has a small size and high reliability.

  The attenuator 32 is composed of a PIN diode, and adjusts the amplitude voltage of the microwave. The attenuator 32 controls the attenuation amount of the transmitted amplitude voltage of the microwave by a control signal from the control circuit 39 incorporating the CPU. A DC voltage is applied to the PIN diode of the attenuator 32 to control the amount of attenuation with respect to the microwave AC signal. The amplifiers 34 and 35 amplify the microwave signal and supply power required by the plasma generator. Further, as described above, the isolator 36 cuts off the reflected power from the load side.

The operation of the microwave frequency stabilization feedback circuit 3D using the directional coupler 37 will be described.
A traveling wave and a reflected wave are output to the a terminal and the b terminal of the directional coupler 37, respectively. The reflected wave is applied to the 3db coupler through the phase shifter. By adjusting this reflected wave with a phase shifter, the phase difference between the reflected wave and the traveling wave can be set to zero at the resonance frequency. On the other hand, the traveling wave is applied to the 3 db coupler, supplied from the output terminal of the coupler to the detector, and converted into a DC voltage. The DC voltage converted from the traveling wave and the DC voltage converted from the reflected wave are supplied to the input section of the differential amplifier. When the phase difference between the reflected wave and the traveling wave becomes zero at the resonance frequency, the two DC voltages are equal, so the output voltage of the differential amplifier becomes zero. This operation is described in more detail in the aforementioned Japanese Patent Application Laid-Open No. 2004-172044.

The output voltage of this differential amplifier is the control signal 3E (CFT1) shown in FIG. 4A, which is used to stabilize the microwave frequency.
At the above-described resonance frequency, the control signal CFT1 becomes zero. For example, when the frequency is higher than the resonance frequency, the control signal CFT1 is positive. When the frequency is lower than the resonance frequency, the control signal CFT1 is negative. As described above, the oscillation frequency of the oscillation circuit 13 always maintains the resonance frequency by the action of this negative feedback (negative feedback).

When the gas is not in a plasma state at a central portion in an arbitrary coaxial cavity (4K) of the microwave plasma generator group 4, it is set to operate at a resonance frequency. When the gas changes to the plasma state, the electric field distribution in the coaxial cavity (4K) changes, the load state changes greatly , and the resonant frequency of the coaxial cavity (4K) also fluctuates , but the dimensional design of the cavity is optimized. By measuring this, the frequency change before and after the plasma formation can be sufficiently reduced.
If this load condition changes, the above optimization causes this frequency to be slightly different from the inherent resonant frequency of the cavity, but this frequency difference is reduced.

Each power amplifier contains an AC power supply. For example, the power amplifier 3 ₁ can convert this AC voltage into a DC voltage and supply it up to the maximum consumed DC power used by the power amplifier 3 ₁ .
When it is necessary to increase the number of plasma generators, that is, to increase the power amplifier 3 _1. It is unnecessary.
The plasma generator has a great advantage that it can cope with various plasma cleaning by a simple operation by inserting a standardized power amplifier unit.

FIG. 9 is a perspective view showing a cooling mechanism of the power amplifier.
Heat is generated from the amplifier circuit chips 63a and 63b of the power amplifier. An air groove 64 is provided on the side surface of the cooling fin 61 in close contact with the amplifier circuit chips 63a and 63b.
Cooling air 65 is sent to the air groove 64 to cool it. The cooling mechanism is not a water cooling system but an air cooling system, thereby improving the reliability and simplicity of the apparatus.

Each of the power amplifiers 3 _{1 to} 3 _N excites the corresponding one of the plasma generators 41 to 4N. Therefore, when cleaning a wide area with plasma, a large number of plasma generators 41 to 4N are arranged in combination.
In order to excite the multiple plasma head generators, the power amplifiers 3 _{1 to} 3 _N are configured in parallel as shown in FIG. 1A.

As described above, it is very easy to select the number and combination of plasma generators corresponding to the size of the cleaning region.
FIG. 5 shows an example in which the plasma generator group 4 is arranged in combination from the plasma generator 41 to the plasma generator 4N. Plasma gas is supplied from above the coaxial axis of each of the plasma generators 41 to 4N. And a microwave is input from the coaxial side surface of each plasma generator 41-4N. A sample 400 to be cleaned with plasma gas is uniformly contacted with the plasma gas. Detectors 41S to 4NS for detecting the intensity of plasma are arranged in the plasma gas. The detector uses a Langmuir probe with a simple structure of two deep needles. A direct current voltage is applied between the deep hands, and the flowing current is measured. The current flowing between the deep hands is converted into a voltage. For example, the voltage converted from the detector 41S arranged in the plasma generator 41 is D1.

FIG. 6 shows the control circuit 5. The voltage D1 is converted into a digital signal by the control circuit 5 and converted into control signals CTD and CTPT. The voltage D <b> 1 is amplified by the amplifier 52 and input to the multiplexer 53. The multiplexer 53 rearranges the voltages D1 to DN into a series voltage string and inputs it to the A / D converter 54. The voltage from D1 to DN is converted into digital data.
The CPU 56 calculates these digital data, and converts the digital data into an analog voltage CTD1 by the D / A converter 57. The analog voltage CTD1 is input to the input terminal 3B of the power amplifier 3 ₁ shown in FIG. 4A, thereby controlling the intensity of individually microwave power.

２）図１Ａに示すキーボード６から入力する一定の値にＤを固定する。
以上、図１Ａに示したプラズマ発生装置の一例を説明した。 Next, in this embodiment, the CTPT signal is the same signal for all the power amplifying devices 3 as shown in FIG. 1A. The CTPT signal in FIG. 1A is connected to the microwave modulation circuit 2. In this embodiment, the CTPT signal defines the average power of the entire plasma generator. The control of the average power is effective depending on the environment in which the plasma generator is used, and at the time of power control at the time of starting the apparatus and during steady operation.
In general, the following control method is selected.

1) The CTPT signal is determined from the average value of D1 to DN.

2) D is fixed to a fixed value input from the keyboard 6 shown in FIG. 1A.
The example of the plasma generator shown in FIG. 1A has been described above.

First, the frequency control of the microwave oscillator 1 has been briefly described. Finally, the frequency control of the entire system will be described.
A directional coupler is built in each circuit of the power amplifier shown in FIGS. 1A and 4A.
Therefore, frequency control signals CFT1, CFTn are output from this circuit. The circuit shown at the bottom of the control circuit 5 shown in FIG. 6 is a circuit for processing signals such as CFT1.
This circuit includes a multiplexer 5E, an amplifier circuit 5F, a D / A converter circuit 5G, a control CPU 5H, an analog switch 5I, and an amplifier circuit 5J.
The operation of this circuit will be described below with reference to FIG. There are the following three control methods.
1) A method in which the frequency is set finely and key input is performed at the stage of studying plasma generation in order to investigate and study the conditions of plasma generation. This process is the process 1 shown in FIG.
2) A method for selecting one of the signals from CFT1 to CFTn. This process is process 2 shown in FIG.
This signal is input to the amplifier 5D from the input terminal 5C of the CFT1. The multiplexer 5E outputs one of the signals CFT1 to CFTn according to the control signal SELA of the CPU 5H. The signal passes through the amplifier circuit 5F and is input to the analog switch 5I. In response to a control signal from the CPU 5H, the analog switch 5I transmits the output signal of the amplifier circuit 5F to the output of the analog switch 5I.
This signal passes through the amplifier circuit 5J and outputs a CFT control signal to the output terminal 5K. This control signal CFT is applied to the input terminal 14 of the microwave oscillator 1 to control the oscillation frequency.
By this negative feedback control, a constant frequency can be maintained.
Which of the CFT1 to CFTn signals is selected can be determined from the CPU or the keyboard.
3) A method in which the CPU controls the frequency according to a certain program. This process is the process 3 shown in FIG.
The frequency is shifted in anticipation of the frequency shift by the frequency at the time of plasma generation and the temperature change after the plasma generation, thereby improving the oscillation effect.
The frequency shift is measured in advance by an experimental test, and the data is programmed in a program.
In this case, the CPU 5H transfers the digital data to the D / A conversion circuit 5G and outputs an analog voltage to the output terminal of the D / A conversion circuit 5G. At the same time, the analog switch 5I transmits the output signal of the D / A conversion circuit 5G to the output of the analog switch 5I by the control signal SELB from the CPU 5H. This CFT control signal changes the oscillation frequency of the microwave oscillator 1.
As described above, it is possible to increase the oscillation efficiency by executing the flexible and complicated control corresponding to the use state by using the control of the CPU.

Next, the atmospheric pressure / large area plasma generator shown in FIG. 1B according to the second embodiment of the present invention will be described. This embodiment is also a plasma gas generator having the same function as the microwave-excited plasma gas generator that excites the plasma generating gas under the atmospheric pressure shown in FIG. 1A.
Microwave oscillator 1 are those oscillation frequency comprising a variable VCO circuits.
Microwave modulator 2 also includes a modulator 22 and an isolator 23 and an amplifier 25 for varying the oscillation duration and an oscillation interval of the microwaves connected to microwave oscillator 1.
The microwave power amplifying device 3 includes a plurality of unitized microwave power amplifiers 3 _{1 to} 3 _N connected to the output of the microwave modulator 2.
As shown in FIGS. 10 and 11, the cavity resonator 8 is composed of a pair of cavities 8a and 8b that are coupled by opposing elongated gaps. Between the gaps, a plasma generating gas is passed in a direction perpendicular to the gaps. Microwave power amplifier 3 _{1 to} 3 _N having a dielectric path to pass through Coupling antennas 81 to 8N for supplying electric power from the cavities to the cavities are arranged on the cavity wall of one of the cavities 8a along the gap direction.
A plurality of plasma sensors 81S to 8NS are disposed at the plasma gas discharge port of the dielectric passage.
The control circuit 5 is connected output of the plasma sensor controls the output of the microwave modulator 2 controls the oscillation duration and the oscillation period of the microwave. The control circuit 5 has a program for controlling the supplied power, and the control signal is sent to the microwave oscillator 1 , the microwave modulator 2, or the microwave power amplifiers 3 _{1 to} 3 _N according to the program. Connect to.

The control circuit 5 is almost the same as the circuit described in the embodiment of FIG. 1A. However, there are some differences, so the differences will be supplemented below.
The microwave plasma generator configured by the plasma antenna shown in FIG. 1B is partially different from the power amplifying device 3 in FIG. 1A.
A phase control circuit 33 is added to the circuit of FIG. 4B. The phase control circuit 33 is activated by the control signal of the control circuit 39 incorporating the CPU to change the phase of the microwave.
The characteristic of this apparatus is that the elements of the plasma generator are arranged in a line, and the distance between them is a length (λ _g / 4) of the wavelength in the microwave tube in the microwave waveguide (chamber). 4). Naturally, the length of the row of elements is sufficiently long with respect to the wavelength λ _{g in the} microwave tube.

The modes before and after plasma generation in the plasma generator are shown in FIGS. 11A and 11B and FIGS. 12A and 12B . First, an electric field mode before plasma is generated, as shown in FIG. 11 A, an electric field is generated between chambers slit. Since Q in the chamber is high, the coupling is brought close to 1 by exciting with an antenna perpendicular to the electric field. As a result, the maximum power is supplied and the plasma is promoted.

Next, in the electric field mode after the plasma is generated, an electric field is generated between the antenna side and the slit of the chamber, as shown in FIG. 12A. Since plasma is generated, the Q in the chamber becomes low. Since this electric field is excited in the same direction as the antenna, the coupling is also close to unity. As a result, sufficient electric power is supplied from the antenna, and strong plasma is maintained.
The equivalent circuit before plasma generation in the plasma generator is represented by the circuit shown in FIG. 11B. The Q in the chamber is very high and the conductance G ₁ is very small. At this time, the resonance frequency is ω ₁ and Q is Q ₁ . The coupling coefficient when the antenna output supplies power to the chamber is k ₁ . The equivalent circuit after plasma generation is represented by the circuit shown in FIG. 12B. When plasma is generated, the conductance G ₂ in the chamber increases. The resonance frequency at this time is ω ₂ and Q is Q ₂ .
In the present invention, it is important to optimize the antenna shape and the chamber shape so that the condition (ω ₁ ≈ω ₂ ) and the condition (k ₂ / k ₁ ) ≈ (G ₂ / G ₁ ) are satisfied. Oh Ru.
By optimizing the circuit conditions, the resonance frequency is kept constant before and after plasma generation, and the plasma is maintained stably. The condition is satisfied by changing the electric field mode described above before and after the plasma generation.
Thus, the structure of this plasma generator is characterized by a structure suitable for plasma generation.

FIG. 4B is a circuit diagram showing a power amplifying device in the atmospheric pressure / large area plasma generator according to the second embodiment of the present invention. In this circuit, a phase control circuit 33 is added in addition to the circuit shown in FIG. 4A. The phase control circuit 33 operates by the control signal of the control circuit 39 incorporating the CPU shown in FIG. 6 to change the phase of the microwave. As shown in the upper part of FIG. 13, this apparatus is characterized in that the plasma antennas are arranged in a line, and the interval is set to a length λ _g / 4 of a quarter of the microwave wavelength in the microwave chamber. Set. With this interval, the waveform of the standing wave inside the chamber is 90 degrees as shown in the lower part of FIG. 13, so that the influence of interference between adjacent antennas is suppressed. Can do. However, since the phase of the standing wave changes due to the change in the impedance in the chamber before and after the plasma generation, the phase adjustment is performed by the phase control circuit 33 in order to control this. Further, there is a feature that the average of the electric field for a certain time is constant with respect to the length direction of the chamber (the length direction of the row of elements). This indicates that the electric power is constant with respect to the length direction of the chamber, and the sample can be uniformly irradiated.
Of course the length of the row of antenna elements has a sufficient length to microwave wavelength lambda _g. Therefore, the reflected wave from the wall side is reduced.
The antenna used for the plasma generator can be a monopole antenna, a dielectric horn antenna, a patch antenna, a helical antenna, or the like.

(Application Example of the First Embodiment) FIG. 14 is a perspective view of an example applied to a microwave plasma generation source that cleans a wide area in a short time according to the first embodiment (FIG. 1A) of the present invention. is there. FIG. 15A is a perspective view showing another application example.
In each application example, a plurality of microwave plasma generation sources (coaxial resonators) 41... Are arranged by a support structure 7 toward a specific space.
In the previous example shown in FIG. 14, a plurality of microwave plasma generation sources (coaxial resonators) 41, 42,...
In the example shown in FIG. 15A, a plurality of microwave plasma generation sources (coaxial resonators) 41... Are arranged in a disk shape by the support structure 7 to form a plasma generator that cleans a wide area simultaneously. In this case, a large-scale element is required, but a plasma generator capable of cleaning in a short time can be constructed.
In the example shown in FIG. 15B, microwave plasma generation sources (coaxial resonators) 41... Constituted by a plurality of plasma antennas are arranged in a disk shape by the support structure 7, and the distance between each plasma antenna is approximately four quarters of the in-tube wavelength. The plasma generating apparatus is formed so as to clean a wide area at the same length λ _g / 4. In this case, a large-scale element is required, but a plasma generator capable of cleaning in a short time can be constructed.

  The devices according to the two embodiments described in detail above can be applied to a wide range of applications because the devices can be downsized and have excellent portability.

In the microwave plasma generation apparatus of the present invention, a solid-state element can be used as the microwave generation source, and a microwave plasma generation apparatus having a small size, high reliability, and a long lifetime can be obtained. In addition, since the circuit is composed of a solid-state element such as a microwave LDMOS, it can be operated with high conversion efficiency. There is no mechanical ancillary circuit, and it is small and has high output and can be used in a wide range of fields.
In particular, when the microwave power for plasma excitation is supplied from a power amplifier composed of a solid state device, the oscillation output power of the microwave oscillator can be as low as several milliwatts, and stable oscillation can be obtained.
Since the micro-generation source can be a solid-state oscillator, the apparatus can be further miniaturized and the whole can be configured to be portable.
A microwave plasma generator that generates a plasma gas by exciting a gas close to atmospheric pressure with a microwave, is easy to handle, and can operate stably.

Next, the power amplifier 3 ₁ incorporates an AC power supply, converts this AC voltage into a DC voltage, and supplies the maximum consumed DC power used by the power amplifier 3 ₁ .
Since an AC power supply is built into one power amplifier 3 ₁ , it is not necessary to install an AC power supply when it is necessary to add a plasma generator, ie, an additional power amplifier 3 _1. It is.
For various types of plasma cleaning, the plasma generator has the advantage that it can be handled with a simple operation by simply inserting a standardized power amplifier unit.

When it is necessary to increase the number of plasma generators, that is, to increase the number of power amplifiers in response to the demand for plasma cleaning in a wide area by means of incorporating an AC power source in one power amplifier, it is not necessary to newly install an AC power source.
Depending on the size of the cleaning region, even if the number of plasma generators is increased, the number of power amplifier units associated therewith can be easily increased.

  The atmospheric pressure large area plasma generator according to the present invention is a processing field of industrial materials such as melting, fusing, joining, refining, metallurgy, and spraying of industrial materials, a light source for a display using light generated by plasma, etc. It can be widely used in the field of illumination, the generation of fine particles, the field of chemical analysis of trace sample components using induced plasma as ionization means, and the field of surface treatment cleaning in semiconductor process materials.

1 is a block diagram of a torch plasma type atmospheric pressure large area plasma generator according to a first embodiment of the present invention. FIG. It is a block diagram of an antenna plasma type atmospheric pressure large area plasma generator according to a second embodiment of the present invention. It is a figure which shows the Example of the circuit of the microwave oscillator which excites the microwave plasma in the atmospheric pressure large area plasma generator by this invention. It is a figure which shows the Example of the microwave modulation circuit in the atmospheric pressure large area plasma generator by this invention. It is a circuit diagram which shows the power amplifier in the atmospheric pressure large area plasma generator which is 1st Embodiment by this invention. It is a circuit diagram which shows the power amplification apparatus in the atmospheric pressure large area plasma generator which is 2nd Embodiment by this invention. It is a figure which shows the plasma generator group comprised by the N plasma generators in the atmospheric pressure large area plasma generator of the torch plasma which is 1st Embodiment by this invention. It is a figure which shows the plasma intensity measurement circuit using the Langmuir (Langmuir) probe in the atmospheric pressure large area plasma generator by this invention. It is a figure which shows a CTPT signal. It is a figure which shows the modulated microwave waveform. It is a figure which shows the structure of the air cooling system of the power amplifier circuit of this invention. It is a figure which shows the microwave plasma generation source of the antenna plasma type which is 2nd Embodiment of a different structure from the said microwave plasma generation source by this invention. It is a figure which shows distribution of the excitation electric field in an example microwave plasma generation source just before generation | occurrence | production of the antenna plasma type plasma which is 2nd Embodiment by this invention. It is the equivalent circuit schematic of the microwave plasma generation source about one antenna and the resonator immediately before the plasma generation of the antenna plasma type which is 2nd Embodiment by this invention. It is a figure which shows distribution of the excitation electric field in an example microwave plasma generation source immediately after the plasma generation of the antenna plasma type which is 2nd Embodiment by this invention. It is the equivalent circuit schematic of the microwave plasma generation source about one antenna and resonator immediately after the plasma generation of the antenna plasma type which is 2nd Embodiment by this invention. It is a figure which shows the space | interval of the antenna plasma type antenna which is 2nd Embodiment by this invention, and a figure which shows distribution of the standing wave in the antenna plasma type chamber by this invention. It is a perspective view of the example applied to the microwave plasma generation source which plasma-processes the wide area | region which is the 1st Embodiment of this invention in a short time. It is a perspective view of the other example applied to the microwave plasma generation source which plasma-processes the wide area | region which is the 1st Embodiment of this invention in a short time. It is a perspective view of the other example applied to the microwave plasma generation source which plasma-processes the wide area | region which is the 2nd Embodiment of this invention for a short time. It is a flowchart figure which shows the process for CPU by this invention to control a stable oscillation frequency. It is a figure which shows the example of the conventional microwave plasma generator.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Microwave oscillator 2 Microwave modulation circuit 3 Power amplifier 4 Plasma generator group 5 Control circuit 6 Manual operation keyboard 7 Support structure 8 Cavity resonator 8a, 8b Upper cavity, lower cavity 81-8N Cavity excitation antenna 81S-8NS Detector (plasma sensor)
DESCRIPTION OF SYMBOLS 13 Oscillation circuit 14 Input terminal of frequency control signal CFT 15 Amplifier 16 Output terminal 21 Input terminal of microwave modulation circuit 23 Isolator 25 Amplifier 26 Output terminal of microwave modulation circuit 31 Input terminal of power amplifier 32 Attenuator 33 Phase control circuit 34 , 35 Amplifier 36 Isolator 37 Directional coupler 38 Power amplifier output 39 Control circuit 3A AC / DC voltage conversion circuit 3B Control signal CTD input 3C AC voltage input 3D Microwave frequency control circuit 3E CFT control signal output End 40 Plasma gas supply device 41, 42, ..., 4N Plasma generator 41S, 42S, ..., 4NS detector (plasma sensor)
400 Sample 51 D1 signal input terminal 52 Amplifier
53 Multiplexer
54 A / D conversion circuit
55 Control circuit with built-in CPU
56 CPU
57 D / A converter circuit
59 input 5D amplifier 5E multiplexed output terminal 5C CFT1 of CTPT signal output terminal 5A buffer 5B CTD1 Lexar 5F amplifier 5G D / A conversion circuit 5H CPU
5I Analog Switch Circuit 5J Amplifier 5K CFT Output Terminal 61 Cooling Fin 62 Power Amplifier 63a, 63b Amplifier Circuit Chip 64 Air Groove 65 Cooling Air 1707 Microwave Oscillator 1708 Isolator 1710 Microwave Waveguide 1711 Pulse Motor Control 3 Stub Tuner

Claims (7)

A microwave-excited plasma gas generator for exciting a plasma generating gas under atmospheric pressure,
A microwave oscillator including a VCO circuit having a variable oscillation frequency;
A microwave modulator including a pulse circuit, an isolator, and an amplifier connected to the microwave oscillator and configured to vary the oscillation duration and the oscillation interval of the microwave output by the microwave oscillator;
A plurality of unitized microwave power amplifiers connected to the output of the microwave modulator;
A cavity resonator in which a plasma generating gas is introduced into the cavity or a part of the cavity, and a plurality of coupled antennas for supplying power from the microwave power amplifier to the cavity are disposed on the cavity wall;
A plurality of antennas and a plurality of plasma sensors arranged in relation to plasma gas generation positions of the cavity resonator;
Wherein the traveling wave incident microwave plasma source of several microwave plasma generating source by measuring the phase of the reflected wave reflected oscillation frequency of the microwave oscillator of the plurality of microwave plasma source Resonance maintenance control section that controls to match the resonance frequency of one microwave plasma generation source, and the pulse that adjusts the oscillation duration and the oscillation interval of the microwave according to either the output of the plasma sensor or a specified value voltage maintenance control unit to maintain the overall output voltage by controlling the circuit, and the microwave power amplifier control according to the measurement results of plasma sensors arranged in connection with the microwave plasma source, the space specific A power adjustment control unit for amplifying the amplitude of the microwave output by the microwave modulator according to the plasma state of And a control device digits,
An atmospheric pressure large area plasma generator. 2. The atmospheric pressure large area plasma generation according to claim 1, wherein the antenna is two-dimensionally arranged such that a distance between antennas adjacent to the cavity wall is about a quarter of an in-tube wavelength of the excitation microwave. apparatus. A microwave-excited plasma gas generator for exciting a plasma generating gas under atmospheric pressure,
A microwave oscillator including a VCO circuit having a variable oscillation frequency;
A microwave modulator including a pulse circuit, an isolator, and an amplifier connected to the microwave oscillator and configured to vary the oscillation duration and the oscillation interval of the microwave output by the microwave oscillator;
A plurality of unitized microwave power amplifiers connected to the output of the microwave modulator;
It is composed of a pair of cavities coupled by opposing elongated gaps, and has a dielectric passage for passing a plasma generating gas in a direction perpendicular to the gap between the gaps, and supplies power from the microwave power amplifier to the cavities. A cavity resonator in which a plurality of coupled antennas are disposed on the cavity wall;
A plurality of plasma sensors arranged at the plasma gas outlet of the dielectric passage;
The output of the plasma sensor is connected;
The phase of the traveling wave incident on the plurality of microwave plasma generation sources and the reflected wave reflected by the microwave plasma generation source are measured, and the oscillation frequency of the microwave oscillator is one of the plurality of microwave plasma generation sources. Resonance maintenance control unit that controls to match the resonance frequency of two microwave plasma generation sources, and the pulse circuit that adjusts the oscillation duration and interval of microwaves according to either the output of the plasma sensor or a specified value A voltage maintaining controller that controls the entire output voltage by controlling the microwave power amplifier according to a measurement result of a plasma sensor disposed in association with the microwave plasma generation source, and plasma in a specific space A power adjustment control unit that amplifies the amplitude of the microwave output by the microwave modulator according to the situation. And a control device digits,
An atmospheric pressure large area plasma generator. The atmospheric pressure large-area plasma generator according to claim 3, wherein the plurality of coupled antennas are arranged on the cavity wall along the direction of the gap . The atmospheric pressure large area plasma generator according to claim 1 or 3, wherein the microwave oscillator uses a solid-state semiconductor oscillator . The atmospheric pressure large area plasma generator according to claim 1 or 3, wherein the microwave power amplifier includes an AC power supply in a circuit . The atmospheric pressure large area plasma generator according to claim 1 or 3, wherein the plasma sensor for measuring plasma is a Langmuir probe .

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