JP2008130503A - Atmospheric pressure plasma jet apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an atmospheric pressure plasma jet apparatus capable of lengthening the plasma plume that can efficiently reform the surface irrespective of the surface shape of the material. <P>SOLUTION: An atmospheric pressure plasma jet generating means 3 generates an atmospheric pressure plasma jet 25, by using a raw material gas composed of a single kind of gas, or two or more kinds of gases that hardly react with one another in a plasma. The upper part 31 and the lower part 33 of a processing chamber as inclusion preventing means prevents an ambient gas from being included into the atmospheric pressure plasma get 25. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an atmospheric pressure plasma jet apparatus used for cleaning various material surfaces and improving hydrophilicity, for example.

Until now, low-pressure plasma has been used in the industry for cleaning various material surfaces and improving hydrophilicity, but recently, the use of atmospheric pressure plasma jet (see Patent Document 1) instead of low-pressure plasma has increased. ing. The reason is that if an atmospheric pressure plasma jet is used, the processing speed is fast, and since a vacuum vessel and a vacuum exhaust device are not required, the cost of the device is much cheaper. Because an inexpensive gas such as nitrogen can be used, the operating cost is low.
Special Table 2002-542586

  However, in the conventional atmospheric pressure plasma jet apparatus, the plasma is strongly attenuated at about 1 to 2 cm from the tip of the jet nozzle. Therefore, the surface modification effect can be expected only to the same distance from the tip of the jet nozzle. As atmospheric pressure plasma jets are increasingly used in the industry, there is an increasing demand for surface modification of materials having a concavo-convex shape as deep as several centimeters on the surface. In order to meet this requirement, the length of the plasma plume ejected from the plasma jet must be further increased.

  The present invention has been made in view of the above points, and an object of the present invention is to provide an atmospheric pressure plasma jet apparatus capable of efficiently modifying the surface even when the plasma plume is long and the material has various surface shapes. .

(1) The invention of claim 1
An atmospheric pressure plasma jet generating means for generating an atmospheric pressure plasma jet using a source gas composed of a single gas species or two or more gas species that are difficult to chemically react with each other in the plasma; A gist of an atmospheric pressure plasma jet device comprising: a mixing prevention means for preventing mixing of atmospheric gas.

  The atmospheric pressure plasma jet apparatus of the present invention includes a mixing prevention means for preventing the atmospheric gas from mixing into the atmospheric pressure plasma jet, so that the plasma plume becomes long. Therefore, even when the surface of the object to be processed has deep unevenness, the plasma plume reaches the bottom of the recess and the surface can be efficiently modified. In addition, when atmospheric pressure plasma is ejected onto a processing object having a sphere or polyhedron shape, a long plasma plume wraps around the side surface of the processing object and further back to the surface, and the surface can be efficiently modified to those parts. .

  Among the source gases, examples of a single gas species include oxygen, nitrogen, inert gas (for example, argon) and the like. Further, among the source gases, those composed of two or more gas species that are difficult to chemically react with each other in plasma include, for example, an inert gas (eg, argon) and another gas (eg, oxygen, nitrogen, etc.). The thing which consists of is mentioned.

The atmospheric gas is a gas that fills the periphery of the atmospheric pressure plasma jet apparatus, and examples thereof include air.
(2) The invention of claim 2
The mixing preventing unit includes a storing unit that stores at least a part of the atmospheric pressure plasma jet, and a supply unit that supplies the source gas into the storing unit so that the inside of the storing unit is filled with the source gas. And an atmospheric pressure plasma jet device according to claim 1.

  In the atmospheric pressure plasma jet apparatus of the present invention, since at least a part of the atmospheric pressure plasma jet is filled with the raw material gas, it is possible to prevent the atmospheric gas from being mixed into the atmospheric pressure plasma jet in that portion. As a result, the atmospheric pressure plasma jet device of the present invention can generate a long plasma plume.

  It is preferable that the inside of the accommodating means is the source gas and has a positive pressure with respect to the outside. In this case, since the external atmospheric gas is difficult to be mixed into the inside of the housing means, it is possible to more effectively prevent the atmospheric gas from being mixed into the atmospheric pressure plasma jet.

Moreover, it is preferable that the said accommodating means has a raw material gas discharge port in the range in which the inside becomes a positive pressure with the raw material gas. By doing so, the discharge of the gas used for the operation of the plasma jet is not hindered.
(3) The invention of claim 3
The accommodating means is a cylindrical member, and the opening on one side of the cylindrical member is an introduction port for introducing the atmospheric pressure plasma jet, and is opposite to the one side of the cylindrical member. The gist of the atmospheric pressure plasma jet apparatus according to claim 2, wherein the opening on the side is a lead-out port for deriving the atmospheric pressure plasma jet that has passed through the cylindrical member.

  In the atmospheric pressure plasma jet apparatus of the present invention, as shown in FIG. 1, an atmospheric pressure plasma jet is introduced from an inlet which is an opening on one side of a cylindrical member, and is guided at an opening rear on the opposite side. An atmospheric pressure plasma jet is led out from the outlet. That is, the cylindrical member accommodates a part of the atmospheric pressure plasma jet (in FIG. 1, from the upstream side to a position of 60 mm), and the inside is filled with the source gas of the atmospheric pressure plasma jet. .

  Since the atmospheric pressure plasma jet is not easily attenuated inside the cylindrical member filled with the source gas, the maximum distance reached by the atmospheric pressure plasma jet is increased at least by the length of the cylindrical member. Therefore, even when the surface of the object to be processed has deep unevenness, the plasma plume reaches the bottom of the recess and the surface can be efficiently modified.

The cylindrical member is preferably connected to the atmospheric pressure plasma jet generating means without any gap. By doing so, it is possible to more effectively prevent the atmospheric gas from being mixed into the cylindrical member. The cylindrical member and the atmospheric pressure plasma jet generating means are preferably electrically insulated by a method such as through an insulating member. By doing so, leakage from the electrode of the atmospheric pressure plasma jet generating means to the cylindrical member can be prevented.
(4) The invention of claim 4
The gist of the atmospheric pressure plasma jet apparatus according to claim 3, wherein a cross-sectional shape of the opening on the opposite side of the cylindrical member is an elongated slit shape.

By making the cross-sectional shape of the opening of the cylindrical member into a long and narrow slit shape, the range in which the atmospheric pressure plasma jet is ejected is widened, and it is possible to greatly widen the width of surface modification at a time.
(5) The invention of claim 5
The said accommodating means is provided with the process chamber which can accommodate the process target object of an atmospheric pressure plasma jet process, and the inlet which introduces the said atmospheric pressure plasma jet into the said process chamber. The atmospheric pressure plasma jet apparatus is the gist.

If the atmospheric pressure plasma jet apparatus of the present invention is used, a long plasma plume can be injected into the processing chamber 29 as shown in FIG. For this reason, even when the surface of the processing object 39 has deep irregularities, the plasma plume reaches the bottom of the recess, and the surface can be efficiently modified. In addition, a wide surface of the processing object 39 can be surface-modified at a time.
(6) The invention of claim 6
The said accommodation means is equipped with the process target object entrance and exit which can be used for the introduction | transduction to the said process chamber of the said process target object, and / or taking out of the said process target object from the said process chamber. The atmospheric pressure plasma jet apparatus is the gist.

As shown in FIG. 3, the atmospheric pressure plasma jet apparatus of the present invention includes processing object entrances 40 and 41, and the processing object 39 can be taken in and out therefrom. It is not necessary to open the processing chamber 29 entirely. Therefore, there is no need to replace the inside of the processing chamber 29 with the source gas every time the processing object 39 is put in and out, and the surface treatment process can be speeded up.
(7) The invention of claim 7
The atmospheric pressure plasma jet apparatus according to claim 6, wherein the processing object inlet / outlet is provided on one side of the processing chamber and on the side opposite to the one side of the processing chamber. And

As shown in FIG. 4, the atmospheric pressure plasma jet apparatus of the present invention has processing object entrances 40, 41 on one side in the processing chamber 29 and on the side opposite to the one side in the processing chamber 29, respectively. 45, 46, for example, when the processing object 39 is introduced into the processing chamber 29 from one of the processing object entrances and exits and the surface modification is completed, the processing object 39 in the processing chamber 29 is reversed. It can be taken out from the processing object entrance on the side. By doing so, the surface modification process can be further accelerated.
(8) The invention of claim 8
The gist of the atmospheric pressure plasma jet apparatus according to claim 6, further comprising an opening area adjusting unit that adjusts an opening area at the processing object entrance and exit.

  In the atmospheric pressure plasma jet apparatus of the present invention, for example, when the surface modification of the processing object is performed by the atmospheric pressure plasma jet, the opening area at the processing object entrance / exit can be reduced by the opening area adjusting means. By doing so, the outflow of the source gas from the processing chamber is reduced, and the source gas pressure in the processing chamber is kept high, so that the atmospheric gas can be more effectively prevented from being mixed into the atmospheric pressure plasma jet.

In addition, when the processing object is taken in and out, the opening area adjusting means can increase the opening area at the processing object entrance and exit, thereby facilitating the loading and unloading of the processing object.
(9) The invention of claim 9
The gist of the atmospheric pressure plasma jet apparatus according to any one of claims 1 to 8, wherein the source gas is one of nitrogen and oxygen.

  The present invention illustrates a source gas.

The present invention will be specifically described based on examples.

1. Configuration of Atmospheric Pressure Plasma Jet Apparatus The atmospheric pressure plasma jet apparatus 1 includes an atmospheric pressure plasma jet generating means 3 and a cylindrical member 5 as shown in FIG.

  The atmospheric pressure plasma jet generating means 3 generates an atmospheric pressure plasma jet as follows. That is, the source gas is blown obliquely from the upper end of the plasma jet cylinder 7 with the central axis removed so that the source gas swirls in the plasma jet cylinder 7. Using the pulse power supply 9, a high voltage pulse having a pulse width of about 20 microseconds is applied between the internal electrode 11 and the external electrode 13 at a repetition frequency of 16 kHz. The average input power at this time is 0.7 to 1 kW. The first discharge starts at a small distance between the electrodes at the top of the plasma jet cylinder 7. Since the time interval from one pulse discharge to the next pulse discharge is short, the plasma generated in the previous discharge remains as afterglow plasma until the next pulse discharge. Therefore, the next discharge is easily performed through the afterglow plasma. However, since the source gas constantly flows, the plasma also moves to the vicinity of the tip of the downstream plasma jet nozzle 15 together with the source gas. And it is maintained as a stable discharge plasma 17 between the tip of the internal electrode 11 and the tip of the plasma jet nozzle 15. At this time, since the discharge is a pulse discharge, the path of the discharge current remains inside the plasma jet cylinder 7. Then, afterglow plasma is ejected out of the plasma jet nozzle 15 as an atmospheric pressure plasma jet 25.

  The cylindrical member 5 is a stainless steel pipe having an inner diameter of 5 mm, an outer diameter of 7 mm, and a length of 6 cm. The inlet 21 which is the upper opening of the cylindrical member 5 is connected to the plasma jet nozzle 15 of the atmospheric pressure plasma jet generating means 3 through an insulating ring 23 made of an insulating material without leaving a gap. . Further, the cylindrical member 5 includes an outlet 27 for the atmospheric pressure plasma jet 25 on the lower side thereof. The outlet port has a circular cross-sectional shape.

2. Method of Using Atmospheric Pressure Plasma Jet Apparatus 1 The atmospheric pressure plasma jet 25 was generated by the atmospheric pressure plasma jet generating means 3 with the type of source gas being nitrogen and the flow rate of the source gas being 40 L / min. At this time, the plasma plume reached 2 cm away from the outlet 27 of the cylindrical member 5.
3. Effects of the Atmospheric Pressure Plasma Jet Device 1 Since the source gas is introduced from the inlet 23 of the cylindrical member 5 together with the atmospheric pressure plasma jet 25, and the inside of the cylindrical member 5 becomes a positive pressure with the source gas, Air does not enter the inside of the cylindrical member 5. Since the atmospheric pressure plasma jet 25 introduced from the introduction port 23 is not easily attenuated inside the cylindrical member 5 filled with the raw material gas, it reaches the outlet 27 of the cylindrical member 5 and further downwards therefrom. Is injected. As a result, the maximum distance that the atmospheric plasma jet 25 reaches is at least as long as the cylindrical member 5. Moreover, since the outer diameter of the cylindrical member 5 is thin, it can be inserted into a minute gap. Therefore, the cylindrical member 5 is inserted into a concave portion existing on the surface of the object to be processed, and the atmospheric pressure plasma jet 25 is ejected from the outlet 27 of the cylindrical member 5 so that the surface can be easily modified to the depth of the concave portion. it can.

  Since the plasma jet nozzle provided in the conventional plasma jet apparatus has a diameter of about 10 to 20 mm, it is difficult to insert the plasma jet nozzle into the recess.

1. Configuration of Atmospheric Pressure Plasma Jet Device As shown in FIG. 2, the atmospheric pressure plasma jet device 1 includes an atmospheric pressure plasma jet generating means 3 and a processing chamber 29. The configuration of the atmospheric pressure plasma jet generating means 3 is the same as that in the first embodiment.

  The processing chamber 29 is composed of a rotating paraboloid upper portion 31 having an open bottom and a flat lower portion 33. In the center of the upper part 31, an introduction port 35 communicating with the plasma jet nozzle 15 of the atmospheric pressure plasma jet generating means 3 is provided. Further, a slight gap 37 is formed between the upper portion 31 and the lower portion 33. The material of the upper portion 31 is resin, the inner diameter of the opening at the lower end is 17 cm, and the distance from the inlet 35 to the lower portion 33 is 10 cm. The material of the lower part 33 is glass.

2. Method of Using Atmospheric Pressure Plasma Jet Apparatus 1 A PET sheet 39 was placed as an object to be processed on the upper side of the lower portion 33 in the processing chamber 29. The size of the PET sheet 39 is substantially equal to the opening surface of the upper portion 31. Then, atmospheric pressure plasma was generated by the atmospheric pressure plasma jet generating means 3 with the type of the source gas being nitrogen and the flow rate of the source gas being 40 L / min. Then, the atmospheric pressure plasma jet 25 was ejected from the introduction port 35 toward the inside of the processing chamber 29. As shown in FIG. 5, the atmospheric pressure plasma jet 25 reached the PET sheet 39 and further spread in the lateral direction. The atmospheric pressure plasma jet 25 was jetted for 10 seconds, and then the PET sheet 39 was taken out.

3. Effects of the atmospheric pressure plasma jet apparatus 1 After the atmospheric pressure plasma jet 25 was jetted as described above, the hydrophilicity improving effect of the PET sheet 39 was examined. As a result, the upper surface of the PET sheet 39 was remarkably hydrophilic over the entire surface. It was sex.

  Moreover, when a PET sheet was affixed to each part of the material having irregularities on the surface and a similar experiment was performed, a sufficiently high surface modification effect was confirmed when the atmospheric pressure plasma jet 25 touched even a little. .

  As shown in FIG. 5, the reason why the plume of the atmospheric pressure plasma jet 25 becomes longer is considered to be that air does not enter the inside of the processing chamber 29 from the outside. That is, nitrogen gas as a raw material gas is introduced from the introduction port 35 of the processing chamber 29 together with the atmospheric pressure plasma jet 25, and the inside of the processing chamber 29 becomes a positive pressure with the nitrogen gas. Air does not get mixed in. Since the atmospheric pressure plasma jet 25 introduced from the introduction port 35 is not easily attenuated inside the processing chamber 29 filled with nitrogen gas, it reaches the lower portion 33 and further spreads laterally therefrom.

  As described above, a minute gap 37 is formed between the upper portion 31 and the lower portion 33 and functions to discharge excess nitrogen gas to the outside. However, the inside of the processing chamber 29 is made of nitrogen gas. Since the pressure is positive, air does not enter the processing chamber 29 from the gap 37.

1. Configuration of Atmospheric Pressure Plasma Jet Apparatus Basically the same as in the second embodiment, but a rectangular opening 40 having a height of 3 cm and a width of 11 cm is provided on the right side of the processing chamber 29. A rectangular duct 41 having a size cross section and a horizontal length of 13 cm is connected. A shutter (opening area adjusting means) 43 for adjusting the opening area is provided at the outlet of the rectangular duct 41. The opening 40 and the rectangular duct 41 can be used for introducing a processing object into the processing chamber 29 and for taking out the processing object from the processing chamber 29.

2. How to Use Atmospheric Pressure Plasma Jet Device 1 The shutter 43 is fully opened, and a processing object is introduced into the processing chamber 29 through the rectangular duct 41. Thereafter, the shutter 43 is lowered to reduce the opening area of the rectangular duct 41. Next, as in the second embodiment, an atmospheric pressure plasma jet is injected into the processing chamber 29 to perform a hydrophilic treatment. When the hydrophilic treatment is finished, the shutter 43 is opened, and the processing object is taken out from the processing chamber 29 through the rectangular duct 41.

3. Operation and Effect of Atmospheric Pressure Plasma Jet Device 1 The atmospheric pressure plasma jet device 1 of the third embodiment includes an opening 40 and a rectangular duct 41, and the processing object can be taken in and out therefrom. In this case, it is not necessary to open the entire processing chamber 29. Therefore, there is no need to replace the inside of the processing chamber 29 with the source gas every time the processing object is taken in and out, and the surface modification process can be speeded up.

  In addition, the atmospheric pressure plasma jet apparatus 1 according to the third embodiment can reduce the opening area of the rectangular duct 41 by the shutter 43 when the surface of the object to be processed is modified by the atmospheric pressure plasma jet 25. By doing so, the outflow of the raw material gas from the processing chamber 29 can be reduced, the pressure of the raw material gas in the processing chamber 29 can be maintained at a positive pressure, and the entry of air into the processing chamber 29 can be more effectively prevented. . Note that it is preferable that the shutter 43 be slightly opened without being fully closed even when the surface of the object to be processed is modified by the atmospheric pressure plasma jet. By doing so, the discharge of the gas used for the operation of the plasma jet is not hindered.

In addition, when the processing object is taken in and out, the opening area of the rectangular duct 41 can be increased by opening the shutter 43, and the processing object can be taken in and out easily.
In Example 3, as in Example 2, a long plasma plume was produced, and the surface modification effect of the object to be treated was achieved.

1. Configuration of Atmospheric Pressure Plasma Jet Apparatus Basically the same as in the third embodiment, but in addition to the provision of the opening 40 and the rectangular duct 41 on the right side of the processing chamber 29, the opening on the left side of the processing chamber 29 is also provided. 45 and a rectangular duct 46. The outlet of the rectangular duct 46 is provided with a shutter (opening area adjusting means) 47 for adjusting the opening area.

2. How to Use Atmospheric Pressure Plasma Jet Device 1 The shutter 43 is fully opened, and a processing object is introduced into the processing chamber 29 through the rectangular duct 41. Thereafter, the shutter 43 is lowered to reduce the opening area of the rectangular duct 41. Next, in the same manner as in the second embodiment, the atmospheric pressure plasma jet 25 is injected into the processing chamber 29 to perform the hydrophilic treatment. When the hydrophilic treatment is finished, the shutter 47 is opened, and the processing object is taken out from the processing chamber 29 through the rectangular duct 46.

3. Operational Effect of Atmospheric Pressure Plasma Jet Device 1 The atmospheric pressure plasma jet device 1 of the fourth embodiment includes openings 40 and 45 and rectangular ducts 41 and 46. For example, the processing is performed through the opening 40 and the rectangular duct 41. Since the object can be introduced into the processing chamber 29 and taken out through the opening 45 and the rectangular duct 46, it is not necessary to open the entire processing chamber 29 when the processing object is taken in and out. Therefore, there is no need to replace the inside of the processing chamber 29 with the source gas every time the processing object is taken in and out, and the surface modification process can be speeded up.

  Further, in the atmospheric pressure plasma jet apparatus 1 of the fourth embodiment, when the surface modification of the processing object is performed by the atmospheric pressure plasma jet 25, the opening areas of the rectangular ducts 41 and 46 are reduced by the shutters 43 and 47. be able to. By doing so, the pressure of the raw material gas in the processing chamber 29 can be maintained at a positive pressure, and mixing of air into the processing chamber 29 can be more effectively prevented. Note that it is preferable that the shutters 43 and 47 be opened slightly rather than fully closed even when the surface modification of the object to be processed is performed by the atmospheric pressure plasma jet 25. By doing so, the discharge of the gas used for the operation of the plasma jet is not hindered.

In addition, when the processing object is taken in and out, the opening areas of the rectangular ducts 41 and 46 can be increased by the shutters 43 and 47 so that the processing object can be taken in and out easily.
In Example 4, as in Example 2, a long plasma plume was produced, and the surface modification effect of the object to be treated was achieved.
(Comparative Example 1)
The cylindrical member 5 was removed from the atmospheric pressure plasma jet device 1 of Example 1 to generate an atmospheric pressure plasma jet. The operating conditions such as the flow rate of the source gas were the same as in Example 1. At this time, the length of the plasma plume was only about 2 cm.
(Comparative Example 2)
Although the structure is basically the same as that of the atmospheric pressure plasma jet apparatus 1 of the first embodiment, the atmospheric pressure plasma jet is generated by changing the type of the source gas to air. The operating conditions such as the flow rate of the source gas were the same as in Example 1. As a result, the atmospheric pressure plasma jet was strongly attenuated inside the cylindrical member 5, and no plasma was observed from the tip of the cylindrical member 5. Further, even when the object to be processed was held close to the tip of the cylindrical member 5, the effect of surface modification was not seen.

This is because in the mixed gas (air) plasma of nitrogen and oxygen, the generated nitrogen atoms and oxygen atoms react vigorously with each other to form NOx, and the lifetime of nitrogen atoms and oxygen atoms is extremely shortened. It is believed that there is.
(Reference Example 1)
In the atmospheric pressure plasma jet apparatus 1 of Example 3, the atmospheric pressure plasma jet 25 was ejected with the shutter 43 fully opened. At this time, the length of the plasma plume was about 4 cm, which was longer than 2 cm, which is the length of the conventional atmospheric pressure plasma jet, but did not reach the length of the plasma plume in Example 3.

The reason for this is considered that the opening area of the rectangular duct 41 was too large, and external air was mixed in the processing chamber 29.
Needless to say, the present invention is not limited to the above-described embodiments, and can be implemented in various modes without departing from the scope of the present invention.

  For example, in the first embodiment, it is possible to greatly widen the width at which the surface can be modified at a time by making the cross-sectional shape of the tip of the cylindrical member 5 not a circular shape but a long and narrow slit shape.

  Moreover, in the said Examples 2-4, two or more atmospheric pressure plasma jet generation means 3 may be attached to the process chamber 29, and you may use them in parallel simultaneously. By doing so, even when the processing object is large or the shape of the processing object is complicated, it is possible to perform processing quickly. In the second to fourth embodiments, it is also effective to provide a plurality of atmospheric pressure plasma jet generating means 3 with outlets in a direction different from the central axis and rotate the plasma jet nozzle around the central axis. Furthermore, each plasma jet nozzle can be rotated about an axis different from the central axis of the nozzle to increase the plasma irradiation area.

  Further, as the mixing prevention means for preventing the mixing of the atmospheric gas, for example, an elongated cylindrical member connected without a gap at the tip of the plasma jet, and a plasma jet ejected in the vicinity of the outlet tip of the cylindrical member And a means for ejecting the same kind of gas as the plasma. This also prevents the atmospheric gas from being mixed into the plasma jet and makes the plasma plume longer.

1 is an explanatory diagram illustrating a configuration of an atmospheric pressure plasma jet device 1. FIG. 1 is an explanatory diagram illustrating a configuration of an atmospheric pressure plasma jet device 1. FIG. 1 is an explanatory diagram illustrating a configuration of an atmospheric pressure plasma jet device 1. FIG. 1 is an explanatory diagram illustrating a configuration of an atmospheric pressure plasma jet device 1. FIG. It is a photograph showing the ejection state of an atmospheric pressure plasma jet.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Atmospheric pressure plasma jet apparatus 3 ... Atmospheric pressure plasma jet generating means 5 ... Cylindrical member 7 ... Plasma jet cylinder 9 ... Pulse electrode 11 ... Internal electrode 13 ... External Electrode 15 ... Plasma jet nozzle 17 ... Discharge plasma 21, 35 ... Inlet 23 ... Insulating ring 25 ... Atmospheric pressure plasma jet 27 ... Outlet 29 ... Processing chamber 31・ ・ Upper part 33 ・ ・ ・ Lower part 37 ・ ・ ・ Gap 39 ・ ・ ・ PET sheet 40, 45 ・ ・ ・ Opening part 41,46 ・ ・ Rectangular duct 43,47 ... Shutter

Claims (9)

An atmospheric pressure plasma jet generating means for generating an atmospheric pressure plasma jet using a source gas composed of a single gas species or two or more gas species that are difficult to chemically react with each other in the plasma;
Mixing prevention means for preventing mixing of atmospheric gas into the atmospheric pressure plasma jet,
An atmospheric pressure plasma jet device comprising: The mixing prevention means includes
Accommodating means for accommodating at least part of the atmospheric plasma jet;
Supply means for supplying the source gas into the storage means so that the inside of the storage means is filled with the source gas;
The atmospheric pressure plasma jet apparatus according to claim 1, further comprising: The housing means is a cylindrical member,
The opening on one side of the cylindrical member is an inlet for introducing the atmospheric pressure plasma jet,
3. The atmospheric pressure according to claim 2, wherein the opening on the opposite side to the one side of the cylindrical member is an outlet for deriving the atmospheric pressure plasma jet that has passed through the cylindrical member. Plasma jet device.   The atmospheric pressure plasma jet apparatus according to claim 3, wherein a cross-sectional shape of the opening on the opposite side of the cylindrical member is an elongated slit shape. The accommodating means is
A processing chamber capable of accommodating an object to be processed by atmospheric pressure plasma jet processing;
An inlet for introducing the atmospheric pressure plasma jet into the processing chamber;
The atmospheric pressure plasma jet apparatus according to claim 2, further comprising:   The said accommodation means is equipped with the process target object entrance and exit which can be used for the introduction | transduction to the said process chamber of the said process target object, and / or taking out of the said process target object from the said process chamber. Atmospheric pressure plasma jet device.   The atmospheric pressure plasma jet apparatus according to claim 6, wherein the processing object entrance / exit is provided on one side of the processing chamber and on the side opposite to the one side of the processing chamber.   The atmospheric pressure plasma jet apparatus according to claim 6 or 7, further comprising an opening area adjusting means for adjusting an opening area at the processing object entrance / exit.   The atmospheric gas plasma jet apparatus according to any one of claims 1 to 8, wherein the source gas is one of nitrogen and oxygen.