The present disclosure relates to an active gas generation apparatus having a parallel plate type electrode structure and generating active gas using dielectric barrier discharge.
In a conventional active gas generation apparatus with a parallel plate type electrode structure in which a dielectric barrier discharge is adopted, a gap between a metal electrode (electrode conductive film) and a dielectric film (electrode dielectric film) facing each other or a gap between dielectric films facing each other serves as a discharge space.
Adopted to the conventional active gas generation apparatus is a parallel plate type dielectric barrier discharge in which a dielectric barrier discharge is generated in a discharge space, and material gas injected in the discharge space is activated to generate the active gas.
For example, an active gas generation apparatus disclosed in Patent Document 1 is an example of an active gas generation apparatus in which the parallel plate type dielectric barrier discharge is adopted.
The active gas generally has a short lifetime as active gas (a period of time during which the active gas keeps high reactivity), thus the active gas needs to be supplied to a space where the active gas is to be used in a short time. The active gas is also inactivated when colliding with the other material, thus it is not preferable to supply the active gas to a space where the active gas is used through a meandering pipe, for example.
Thus, when a processed object (an object onto which the active gas is blown) is large in a space where the active gas is used, a first improvement structure of providing a gas ejecting hole for supplying the active gas to the space where the active gas is to be used and a second improvement structure including a plurality of discharge spaces corresponding to a plurality of gas ejecting holes, respectively.
A method of providing a plurality of through holes in one dielectric film is adopted to the first improvement structure described above. Accordingly, the first improvement structure has a problem that a size of the dielectric film needs to be increased in accordance with the processed object, and a size of an apparatus configuration increases.
In addition, the first improvement structure also has a problem that there is no mechanism of removing heat generated by discharge, and the dielectric film is broken by heat generation by the discharge.
The second improvement structure described above has a problem that a size of an apparatus configuration increases by reason that the plurality of discharge spaces need to be provided.
In the active gas generation apparatus disclosed in Patent Document 1, when differential pressure is applied to the dielectric film, measures such as increase in a thickness of the dielectric film are necessary, and when the thickness of the dielectric film is increased, necessary applied voltage increases. When the applied voltage is increases, there is a problem that measures against insulation breakdown of an unnecessary portion and steps of increasing a size of an introduced terminal are necessary to deal with high voltage.
In addition, the conventional active gas generation apparatus disclosed in Patent Document 1 has a problem that it has less cooling efficiency by reason that the dielectric film is cooled by purge gas. Because, the conventional active gas generation apparatus has a low heat removal ratio due to air cooling.
The present disclosure is to solve the above problems, and an object of the present disclosure is to provide an active gas generation apparatus having a structure of preventing insulation breakdown of at least a dielectric film.
An active gas generation apparatus according to the present disclosure is an active gas generation apparatus activating material gas supplied to a discharge space to generate active gas, comprising: an electrode unit; and a chassis housing the electrode unit in a chassis space and having conductivity, wherein the chassis includes a chassis bottom part including a flat surface and a conductor housing space concaved from the flat surface in a depth direction, the electrode unit includes: a first electrode constituting part; a second electrode constituting part provided on a lower side of the first electrode constituting part; and a reference potential conductor provided on a lower side of the second electrode constituting part and housed in the conductor housing space, the first electrode constituting part includes a first electrode dielectric film and a first electrode conductive film formed on an upper surface of the first electrode dielectric film, the second electrode constituting part includes a second electrode dielectric film and a second electrode conductive film formed on a lower surface of the second electrode dielectric film, the reference potential conductor includes an active gas buffer space on an upper portion, the second electrode constituting part is disposed to cover the active gas buffer space, the second electrode dielectric film includes a dielectric through port passing through the second electrode dielectric film in a region overlapped with the active gas buffer space in a plan view, the second electrode conductive film includes a conductive film opening part in a region overlapped with the active gas buffer space in a plan view, the conductive film opening part is overlapped with the dielectric through port in a plan view, the chassis bottom part includes a gas flow path receiving material gas from an outer portion, a material gas flow space is provided between the reference potential conductor and the conductor housing space of the chassis, a space where the first electrode dielectric film and the second electrode dielectric film face each other is defined as a main dielectric space, the discharge space includes a main discharge space as a region in which the first and second electrode conductive films are overlapped with each other in a plan view in the main dielectric space, material gas is introduced into the discharge space via the gas flow path and the material gas flow space, alternating-current voltage is applied to the first electrode conductive film, the second electrode conductive film is set to have reference potential via the chassis and the reference potential conductor, the active gas generation apparatus further includes: a dielectric film support member provided on the flat surface of the chassis and including a support surface supporting the first electrode dielectric film from a lower side; and a dielectric film suppression member for suppressing the first electrode dielectric film from an upper side, the dielectric film suppression member not being overlapped with the first electrode conductive film in a plan view, a lower surface of the dielectric film suppression member includes a dielectric contact region having contact with an upper surface of the first electrode dielectric film and a dielectric non-contact region not having contact with an upper surface of the first electrode dielectric film, the dielectric contact region is overlapped with a peripheral region of the first electrode dielectric film and the support surface of the dielectric film support member in a plan view, the dielectric non-contact region is overlapped with an intermediate region of the first electrode dielectric film in a plan view, the intermediate region is a region adjacent to a side of the first electrode conductive film from the peripheral region, the dielectric film suppression member has conductivity and is set to have the reference potential, and the first electrode dielectric film is suppressed by the dielectric film suppression member from an upper side in the dielectric contact region.
In the active gas generation apparatus according to the present disclosure, the first electrode dielectric film is suppressed by the dielectric film suppression member from the upper side in the dielectric contact region. Thus, a region where load is applied to the first electrode dielectric film by the dielectric film suppression member can be limited to a lower region of the dielectric contact region.
As a result, the active gas generation apparatus according to the present disclosure can fix the first electrode dielectric film between the dielectric contact region of the dielectric film suppression member and the support surface of the dielectric film support member without unnecessary bending stress applied to the first electrode dielectric film.
Furthermore, the dielectric non-contact region of the dielectric film suppression member set to have the reference potential and having conductivity is overlapped with the intermediate region of the first electrode dielectric film in a plan view.
As a result, electrical field strength of the first electrode conductive film can be reduced to reduce potential of the intermediate region of the first electrode dielectric film, thus an electrode unit in the active gas generation apparatus according to the present disclosure can prevent insulation breakdown in a gap between the first electrode dielectric film and the dielectric film support member.
These and other objects, features, aspects and advantages of the present disclosure will become more apparent from the following detailed description of the present disclosure when taken in conjunction with the accompanying drawings.
As illustrated in
structure of a ground side electrode constituting part E2.
Each of
The active gas generation apparatus 71 according to the embodiment 1 is described hereinafter appropriately with reference to
As illustrated in
As illustrated in
As illustrated in
Each of the electrode units 51 to 53 is housed in the chassis space S1 in the chassis 1 in a state where the ground conductor 6 is disposed in the conductor housing space 6S. As illustrated in
The electrode unit 51 (50) includes a high voltage side electrode constituting part E1 as a first electrode constituting part and the ground side electrode constituting part E2 as a second electrode constituting part provided on a lower side of the high voltage side electrode constituting part E1 as the first electrode constituting part.
The electrode unit 51 further includes the ground conductor 6 as a reference potential conductor provided on a lower side of the ground side electrode constituting part E2 as the second electrode constituting part and housed in the conductor housing space 6S. The ground conductor 6 includes a conductor such as metal as a constituent material.
The high voltage side electrode constituting part E1 includes the high voltage side dielectric film 2 as the first electrode dielectric film and the power supply body 5 as the first electrode conductive film formed on the upper surface of the high voltage side dielectric film 2. The power supply body 5 as the first electrode conductive film is provided on a power supply body arrangement concave part 28 provided in a center of the high voltage side dielectric film 2 as the first electrode dielectric film.
The high voltage side dielectric film 2 includes a dielectric as a constituent material, and the power supply body 5 includes a conductor such as metal as a constituent material. For example, the power supply body 5 is made of metal.
The ground side electrode constituting part E2 includes the ground side dielectric film 3 as the second electrode dielectric film and the conductive film 7 as the second electrode conductive film formed on the lower surface of the ground side dielectric film 3. The conductive film 7 has a small film thickness, thus illustration thereof is omitted in
The ground side dielectric film 3 includes a dielectric as a constituent material, and the conductive film 7 includes a conductor such as metal as a constituent material.
The ground conductor 6 as the reference potential conductor includes an active gas buffer space 9S which does not pass through an upper portion, and the ground side electrode constituting part E2 is disposed to cover the active gas buffer space 9S. Accordingly, a lower surface of the conductive film 7 and an upper surface of the ground conductor 6 have a contact relationship on an outer side of the active gas buffer space 9S.
The ground side dielectric film 3 as the second electrode dielectric film includes a dielectric through port 3h passing through the ground side dielectric film 3 in a region overlapped with the active gas buffer space 9S in a plan view, the conductive film 7 as the second electrode conductive film includes a conductive film opening part 7h in a region overlapped with the active gas buffer space 9S in a plan view, and the conductive film opening part 7h is overlapped with the dielectric through port 3h in a plan view. The chassis bottom part 1a of the chassis 1 includes the gas flow path 21 receiving
the material gas G1 from an outer portion, and a material gas flow space is provided between the ground conductor 6 and the conductor housing space 6S in the chassis 1. As described hereinafter, the material gas flow space includes a material gas buffer space 61, a slit space 62, and a side surface space 63.
The material gas G1 is introduced into a main discharge space of the discharge space 4 through the gas flow path 21 and the material gas flow space described above. As described hereinafter, the main discharge space indicates the discharge space 4 in a dielectric space 18 between the high voltage side dielectric film 2 and the ground side dielectric film 3.
Alternating-current voltage applied from an alternating-current power source 15 is applied to the power supply body 5 as the first electrode conductive film via an electrical connection means such as an electrical wiring or an introduction terminal. Illustration of the electrical connection means is omitted in
In the meanwhile, the chassis 1 is set to have ground potential as reference potential. Accordingly, the conductive film 7 as the second electrode conductive film is set to have ground potential via the chassis 1 and the ground conductor 6.
The electrode unit 51 (50) further includes an auxiliary member such as the dielectric film support member 10, the dielectric film suppression member 11, and the press member 12.
A level difference part 102 of the dielectric film support member 10 includes an upper surface serving as a support surface 10F provided on the flat surface 1F of the chassis 1 to support the high voltage side dielectric film 2 from a lower side. At this time, the dielectric film support member 10 is disposed on the flat surface 1F so that a side surface of the dielectric film support member 10 and a side surface of the conductor housing space 6S on the chassis bottom part 1a of the chassis 1 coincide with each other.
The dielectric film suppression member 11 is a member for suppressing the high voltage side dielectric film 2 from an upper side, and is not overlapped with the power supply body 5 in a plan view. That is to say, an exposed region EX2 where the dielectric film suppression member 11 and the power supply body 5 are not formed is located on the upper surface of the high voltage side dielectric film 2.
As illustrated in
The dielectric contact region 112 is overlapped with a peripheral region of the high voltage side dielectric film 2 and the support surface 10F of the dielectric film support member 10 in a plan view, and the dielectric non-contact region 111 is overlapped with an intermediate region on an inner side of the peripheral region of the high voltage side dielectric film 2. That is to say, the intermediate region is a region adjacent to a side of the power supply body 5 from the peripheral region of the high voltage side dielectric film 2.
The dielectric film suppression member 11 is made of metal etc., has conductivity, and is set to have ground potential as reference potential via the chassis 1, an attachment bolt 31, and the press member 12. The attachment bolt 31 and the press member 12 also have conductivity.
Accordingly, the high voltage side dielectric film 2 is suppressed by the dielectric film suppression member 11 from the upper side in the dielectric contact region 112. A combination structure of the dielectric film support member 10, the dielectric film suppression member 11, and the press member 12 is described in detail hereinafter.
As illustrated in
As illustrated in
In the meanwhile, as illustrated in
As illustrated in
Alternating-current voltage is applied to the power supply body 5 as the first electrode conductive film from the alternating-current power source 15. As illustrated in
The high voltage side dielectric film 2 is disposed on the dielectric film support member 10 while the support surface 10F of the dielectric film support member 10 and the convex part bottom surface 23 of the high voltage side dielectric film 2 have contact with each other. The high voltage side dielectric film 2 and the dielectric film support member 10 have contact with each other via a seal member such as an O ring not shown in the diagrams.
As illustrated in
As illustrated in
As illustrated in
In this manner, the plurality of inner through ports 121h and the plurality of outer through ports 122h are provided in the outer peripheral region 125 of the press member 12. Each of the plurality of inner through ports 121h is a through port made by cutting a tap.
A part of the outer peripheral region 125 in the press member 12 having the above structure is disposed on the dielectric film support member 10, and the dielectric film support member 10 and the press member 12 are fixed to the chassis bottom part 1a of the chassis 1 by the plurality of attachment bolts 31. A screw part of each of the plurality of attachment bolts 31 passes through the plurality of outer through ports 122h and the plurality of through ports 10h, and is attached to the chassis bottom part 1a.
As illustrated in
In the meanwhile, a plurality of suppression auxiliary members 32 are attached to the press member 12 while passing through the plurality of inner through ports 121h of the press member 12. A bolt or a locking screw is considered as the suppression auxiliary member 32. The plurality of suppression auxiliary members 32 attach the dielectric film suppression member 11 to an inner side of the plurality of inner through ports 121h while pressing the dielectric film suppression member 11. The plurality of suppression auxiliary members 32 are provided in positions overlapped with the dielectric contact region 112 of the dielectric film suppression member 11 and the convex part bottom surface 23 of the high voltage side dielectric film 2 in a plan view.
Accordingly, the high voltage side dielectric film 2 is suppressed from the dielectric contact region 112 on an outer side by the dielectric film suppression member 11 receiving suppress strength of the plurality of suppression auxiliary members 32.
As described above, in the electrode unit 50 of the active gas generation apparatus 71 according to the embodiment 1, the high voltage side dielectric film 2 as the first electrode dielectric film is suppressed from the dielectric contact region 112 on the upper side by the dielectric film suppression member 11 receiving suppress strength of the plurality of suppression auxiliary members 32. Thus, a region in which load is applied to the high voltage side dielectric film 2 by the dielectric film suppression member 11 can be limited to a lower region of the dielectric contact region 112.
As a result, the active gas generation apparatus 71 according to the embodiment 1 can stably fix the high voltage side dielectric film 2 between the dielectric contact region 112 of the dielectric film suppression member 11 and the support surface 10F of the dielectric film support member 10 without unnecessary bending stress applied to the high voltage side dielectric film 2.
The dielectric film suppression member 11 is set to have ground potential as reference potential, and has conductivity. The dielectric non-contact region 111 of the dielectric film suppression member 11 is overlapped with the intermediate region of the high voltage side dielectric film 2 in a plan view.
Accordingly, the electrode unit 50 can reduce electrical field strength of the power supply body 5 by the dielectric film suppression member 11 including the dielectric non-contact region 111 to reduce potential of the intermediate region of the high voltage side dielectric film 2, thus potential of the high voltage side dielectric film 2 and the ground side dielectric film 3 in an outer diameter direction can be reduced.
As a result, the electrode unit 50 in the active gas generation apparatus 71 according to the embodiment 1 can reliably prevent insulation breakdown in a gap 20 between the high voltage side dielectric film 2 and the dielectric film support member 10.
As illustrated in
The material gas buffer space 61 is formed into an annular shape in a plan view, and is connected to the gas flow path 21 as illustrated in
The plurality of slit spaces 62 are dispersedly provided around the material gas buffer space 61. As illustrated in
As illustrated in
The dielectric film support member 10 and the ground conductor 6 have a positional relationship as illustrated in
In this manner, the material gas buffer space 61 is provided on the side of the lower surface of the ground conductor 6 to receive the material gas G1 through the gas flow path 21. Each of the plurality of slit spaces 62 is provided on the side of the lower surface of the ground conductor 6, and is connected to the material gas buffer space 61.
The side surface space 63 is provided on a side of the side surface of the ground conductor 6, and is connected to the plurality of slit spaces. As described above, the material gas flow space includes the material gas buffer space 61, the plurality of slit spaces 62, and the side surface space 63.
Accordingly, the material gas G1 supplied to the gas flow path 21 from the outer portion is introduced into the discharge space 4 through the material gas buffer space 61, the slit space 62, and the side surface space 63.
Each of the plurality of slit spaces 62 is set to be a narrow space in which material gas hardly flows compared with the material gas buffer space 61 so that the material gas G1 temporarily remains in the material gas buffer space 61, and then flows into each of the plurality of slit spaces 62. That is to say, the plurality of slit spaces 62 are set to have small conductance as a coefficient expressing a degree of flowability of the material gas G1 compared with the material gas buffer space 61 and the side surface space 63.
As a result, the active gas generation apparatus 71 according to the embodiment 1 can uniformly supply the material gas G1 spatially to the discharge space 4. That is to say, the material gas G1 is uniformly supplied from a peripheral part of the circular dielectric space 18 toward the discharge space 4 in the center in a plan view.
The conductance of the slit space 62 is set to be small, thus differential pressure between the material gas buffer space 61 and the side surface space 63 increases, and fluctuation of a flow amount of the material gas G1 flowing in each of the plurality of slit spaces 62 is reduced. Accordingly, the material gas G1 is uniformly supplied toward the discharge space 4. A flow amount of the material gas G1 is adjusted by a mass flow controller (MFC) provided on an upstream of the gas flow path 21, for example.
Accordingly, when the material gas G1 is not uniformly supplied in a general active gas generation apparatus, a time of the material gas G1 passing through the discharge space 4 is changed, and as a result, a failure of deterioration of generation efficiency of the active gas G2 occurs. The active gas generation apparatus 71 according to the embodiment 1 can uniformly supply the material gas G1, thus the failure described above does not occur.
As described above, the ground side electrode constituting part E2 as the second electrode constituting part includes the ground side dielectric film 3 and the conductive film 7.
As illustrated in
As illustrated in
As illustrated in
Each of the dielectric through port 3h and the conductive film opening part 7h is overlapped with an active gas buffer space 68 in a plan view, and as illustrated in
The conductive film 7 is provided on the lower surface of the ground side dielectric film 3 while a center position of each of the ground side dielectric film 3 and the conductive film 7 coincides with each other. A diameter of the conductive film 7 is set to be substantially the same as that of the ground side dielectric film 3, however, a formation area of the conductive film 7 is smaller than that of the ground side dielectric film 3 by reason that the conductive film opening part 7h larger than the dielectric through port 3h is provided in the center thereof.
A conductive film inner boundary 7e as a circumferential outer peripheral line of the conductive film opening part 7h serves as an end portion of the conductive film 7 on a side of the dielectric through port 3h, and the conductive film 7 is not formed in a region on an inner side of the conductive film inner boundary 7e. The conductive film inner boundary 7e serves as an electrode boundary line of the conductive film 7. Accordingly, as illustrated in
As illustrated in
The cover through port 8h has substantially the same shape as the dielectric through port 3h, and is included in the conductive film opening part 7h, thus has a shape smaller than the conductive film opening part 7h. Accordingly, the cover dielectric film 8 covers the conductive film inner boundary 7e (electrode boundary line) of the conductive film 7. The lower surface of the conductive film 7 which is not covered by the cover dielectric film 8 and the upper surface of the ground conductor 6 have a contact relationship with each other.
As illustrated in
As illustrated in
As illustrated in
The shield dielectric film 9 is provided on the bottom surface 65 of the active gas buffer space 68 while a center position of each of the active gas buffer space 68 and the shield dielectric film 9 coincides with each other.
As illustrated in
As illustrated in
In the active gas generation apparatus 71 according to the embodiment 1 having such a structure, the material gas G1 is supplied from the outer portion of the metal chassis 2 to the discharge space 4 through the gas flow path 21 and the material gas flow space as described above.
When the material gas G1 is supplied to the discharge space 4 where the dielectric barrier discharge occurs, the material gas G1 is activated to be the active gas G2, and passes through the dielectric through port 3h and the cover through port 8h to be introduced into the active gas buffer space 68. The active gas G2 entering the active gas buffer space 68 passes through the plurality of gas ejection ports 69 provided in the bottom surface of the active gas buffer space 68 to be supplied to a processing space in a subsequent stage.
In the active gas generation apparatus 71 according to the embodiment 1 having such a configuration, a main dielectric space where the high voltage side dielectric film 2 as the first electrode dielectric film and the ground side dielectric film 3 as the second electrode dielectric film face each other serves as the dielectric space 18. The dielectric space 18 has a circular shape in a plan view. A space where the high voltage side dielectric film 2 and the shield dielectric film 9 face each other is defined as an auxiliary dielectric space. The discharge space 4 includes a main discharge space where the power supply body 5 and the conductive film 7 are overlapped with each other in a plan view in the dielectric space 18.
The high voltage side dielectric film 2 and the ground side dielectric film 3 are disposed to correspond to each other so as to have a constant distance therebetween in a height direction (Z direction), and the main discharge space described above is located in the dielectric space 18 between the high voltage side dielectric film 2 and the ground side dielectric film 3.
The discharge space 4 further includes an auxiliary discharge space 44 made up of the dielectric through port 3h, the cover through port 8h, and a part of the active gas buffer space 68 on the shield dielectric film 9 in the auxiliary dielectric space described above.
A bottom surface region below the bottom surface 65 of the ground conductor 6 is used as a ground electrode conductive film set to have ground potential, and discharge voltage is applied between the power supply body 5 receiving alternating current voltage from the alternating-current power source 15 and the ground electrode conductive film described above, thus the auxiliary discharge space 44 can be generated.
As described above, the auxiliary discharge space 44 includes the dielectric through port 3h, the cover through port 8h, and a part of the active gas buffer space 68. In this manner, the discharge space 4 formed in the embodiment 1 includes the main discharge space and the auxiliary discharge space 44 in the dielectric space 18.
In the active gas generation apparatus 51 according to the embodiment 1, a path from the auxiliary discharge space 44 to each of the plurality of gas ejection ports 69 is defined as the active gas flow path.
In the active gas generation apparatus 71 according to the embodiment 1, the auxiliary discharge space 44 as a part of the discharge space 4 includes the dielectric through port 3h, the cover through port 8h, and a part of the active gas buffer space 68, thus can suppress the active gas flow path from the auxiliary discharge space 44 to the plurality of gas ejection ports 69 to have a minimum necessary volume to suppress a deactivation amount of the active gas G2.
Furthermore, the cover dielectric film 8 in the ground side electrode constituting part E2 of the electrode unit 50 covers the conductive film inner boundary 7e as the electrode boundary line of the conductive film 7 in the active gas buffer space 68, and is overlapped with the plurality of gas ejection ports 69 in a plan view, thus can suppress a surface deactivation phenomenon in which the active gas G2 gets dissipated due to collision of the active gas G2 with the conductive film 7.
As a result, the active gas generation apparatus 71 according to the embodiment 1 can supply the high concentration active gas G2 from the plurality of gas ejection ports 69 to the processing space in the subsequent stage.
The electrode unit 50 according to the embodiment 1 has the structure described above, thus only the components (the high voltage side dielectric film 2, the ground side dielectric film 3, the cover dielectric film 8, and the shield dielectric film 9) made up of the dielectric serving as the insulator as the constituent material face the discharge space 4. When a metal material faces discharge, it is easily ionized, and metal ions is included in gas, thus causes contamination. In the meanwhile, even when the dielectric faces discharge, it is not easily ionized, thus can prevent contamination in the gas.
As illustrated in
Accordingly, the active gas G2 ejected from the plurality of gas ejection ports 69 is introduced into the processing space on the lower side through the chassis opening part 41.
As illustrated in
In the active gas generation apparatus 71 according to the embodiment 1, the chassis opening part 41 provided in the chassis bottom part 1a of the chassis 1 has the tapered shape with the larger opening area with decreasing distance to the lower side.
Accordingly, the active gas generation apparatus 71 according to the embodiment 1 can suppress loss of the active gas G2 ejected from the plurality of gas ejection ports 69 due to collision of the active gas G2 with the chassis bottom part 1a to a minimum, thus can supply the high concentration active gas G2 to the processing space on the lower side.
The same sign is assigned to the same constituent parts as those in the active gas generation apparatus 71 according to the embodiment 1 illustrated in
In the active gas generation apparatus 72 according to the embodiment 2, three electrode units 51 to 53 as the plurality of electrode units are housed in the chassis space S1 in a chassis 1X. Material gas G1 is supplied to each of the electrode units 51 to 53 through the gas flow path 21.
A cooling path in which a cooling medium flows is further provided in addition to the gas flow path 21 in the chassis bottom part 1a of the chassis 1X in the active gas generation apparatus 72. As illustrated in
The active gas generation apparatus 72 according to the embodiment 2 having the configuration describe above has an effect described hereinafter in addition to the effect in the embodiment 1.
In the active gas generation apparatus 72 according to the embodiment 2, the chassis bottom part 1a of the chassis 1X includes the cooling path 22 in which the cooling medium flows, thus the ground conductor 6 of each of the electrode units 51 to 53 and the ground side dielectric film 3 disposed on the upper side of the ground conductor 6 can be cooled.
Accordingly, heat generated by dielectric barrier discharge in the discharge space 4 can be removed by the ground side dielectric film 3 which has been cooled. As a result, the active gas generation apparatus 72 according to the embodiment 2 can perform discharge at high power in each of the electrode units 51 to 53, thus can achieve a high concentration of the active gas G2.
The active gas generation apparatus 73 according to the embodiment 3 has a feature that the power supply body 5 is replaced with the power supply body 5B in comparison with the embodiment 1. Accordingly, a whole structure of the active gas generation apparatus 73 and a whole structure of the electrode unit 50 (5G10) are similar to the structure according to the embodiment 1 illustrated in
At this time, a lower surface of the power supply body 5B in the electrode unit 50 and the upper surface of the high voltage side dielectric film 2 have a contact relationship with each other via a solution having conductivity. “Galinstan” (registered trademark) is considered as such a solution, for example.
The same sign is assigned to the same constituent parts as those in the active gas generation apparatus 71 according to the embodiment 1, and characterizing portions of the active gas generation apparatus 73 according to the embodiment 3 is mainly described hereinafter.
The power supply body 5B as the first electrode conductive film includes a cooling medium flow path 58 flowing a cooling medium into an inner portion of the power supply body 5B. As illustrated in
The power supply body 5B includes, in a surface thereof, a cooling medium inlet 56 for receiving the cooling medium from the outer portion and supply the cooling medium to the cooling medium flow path 58 and a cooling medium outlet 57 for exhausting the cooling medium flowing in the cooling medium flow path 58 to the outer portion.
In the basic configuration of the embodiment 3, the cooling structure illustrated in
As illustrated in
The current introduction member 14A includes a conduction pipe 141, a flange 142, and an insulator 143 as main constituent elements. The conduction pipe 141 and the flange 142 have conductivity, and the insulator 143 has an insulation property.
The conduction pipe 141 is used as an electrical connection means of electrically connecting the alternating-current power source 15 and the power supply body 5B, and further includes a through port through which the cooling medium can be transported.
In the current introduction member 14A, the conduction pipe 141 and the insulator 143 are joined, the flange 142 and the insulator 143 are joined, thus the conduction pipe 141, the flange 142, and the insulator 143 have an integrated structure. However, the insulator 143 is provided between the conduction pipe 141 and the flange 142, thus an electrical connection between the conduction pipe 141 and the flange 142 is prevented.
Each of the current introduction members 14A and 14B are fixed to the chassis upper part 1c of the chassis 1X by the flange 142.
The current introduction member 14A as the first current introduction member has an electrical connection relationship with the power supply body 5B, and is connected to the power supply body 5B so that the cooling medium can be supplied from the cooling medium inlet 56 to the cooling medium flow path 58 through the conduction pipe 141. That is to say, the current introduction member 14A is electrically connected to the power supply body 5B by the conduction pipe 141, and the cooling medium flowing in the conduction pipe 141 is supplied from the cooling medium inlet 56 to the cooling medium flow path 58.
The current introduction member 14B as the second current introduction member has an electrical connection relationship with the power supply body 5B, and is connected to the power supply body 5B so that the cooling medium can be exhausted to the outer portion from the cooling medium outlet 57 through the conduction pipe 141. That is to say, the current introduction member 14B is electrically connected to the power supply body 5B by the conduction pipe 141, and the cooling medium flowing in the conduction pipe 141 is supplied to the outer portion.
Joining by welding or connection via a joint, for example, is adopted as a means of connecting the conduction pipe 141 and the power supply body 5B in each of the current introduction members 14A and 14B.
The active gas generation apparatus 73 as the basic configuration according to the embodiment 3 having the configuration describe above has an effect described hereinafter in addition to the effect in the embodiment 1.
In the active gas generation apparatus 73 according to the embodiment 3, the power supply body 5B includes the cooling medium flow path 58 therein, thus when the cooling medium supplied from the cooling medium inlet 56 flows into the cooling medium flow path 58 and is then exhausted to the outer portion from the cooling outlet 57, the power supply body 5B and the high voltage side dielectric film 2 provided on the lower side of the power supply body 5B can be cooled.
The current introduction members 14A and 14B further include the cooling structure of circulating the cooling medium to the cooling medium flow path 58 of the power supply body 5B in addition to the current introduction function of providing the alternating-current voltage from the alternating-current power source 15 to the power supply body 5B, thus can cool each of the current introduction members 14A and 14B while reducing the number of components to a minimum necessary.
Allowable current of the current introduction members 14A and 14B is generally determined by an allowable temperature of the current introduction members 14A and 14B, thus the allowable current can be significantly increased even in the current introduction members 14A and 14B in which the conduction pipe 141 made up of a thin conductor is used by the configuration capable of cooling the current introduction members 14A and 14B themselves.
Furthermore, the solution having conductivity is provided between the high voltage side dielectric film 2 and the power supply body 5B, thus thermal conductivity between the power supply body 5B and the high voltage side dielectric film 2 can be increased, and a problem that a minute gap occurs between the power supply body 5B and the high voltage side dielectric film 2 due to a tolerance or surface roughness in processing can be resolved.
According to the effect described above, each of the electrode units 51 to 53 in the active gas generation apparatus 71 according to the embodiment 3 can perform discharge at high power, and a high concentration of the active gas G2 can be achieved.
In the description hereinafter, the cooling medium flow path 58, the cooling medium inlet 56, and the cooling medium outlet 57 of the power supply body 5 in the electrode unit 51 as the first electrode unit are defined as the first cooling medium flow path, the first cooling medium inlet, and the first cooling medium outlet, respectively, for convenience of explanation.
In the similar manner, the cooling medium flow path 58, the cooling medium inlet 56, and the cooling medium outlet 57 in the electrode unit 52 as the second electrode unit are defined as the second cooling medium flow path, the second cooling medium inlet, and the second cooling medium outlet, respectively.
As illustrated in
The buffer conductor 13 as the cooling medium member has conductivity, and includes a relay cooling medium flow path 135 provided in an inner portion and through flow paths 136 and 137 as first and second through flow paths each provided to pass through a lower surface from an upper surface of the buffer conductor 13.
The relay conduction pipes 131 to 134 as the first to fourth relay conduction pipes have conductivity and also have a cooling medium transportation function.
It is preferable that a part of each of the relay conduction pipes 131 to 134 has an accordion shape. The part of each of the relay conduction pipes 131 to 134 preferably has the accordion shape by reason that a deviation of a distance from the buffer conductor 13 to the upper surface of the power supply body 5B caused by a tolerance of components is absorbed, that is to say, a tolerance in manufacturing the active gas generation apparatus 73X is absorbed.
The tolerance described above is obtained by integrating not only a tolerance of lengths of the relay conduction pipes 131 to 134 but also a tolerance of a height of the power supply body 5B and a tolerance of a thickness of the high voltage side dielectric film 2 located on the lower portion of the power supply body 5, for example.
The relay conduction pipes 131 to 134 as the first to fourth relay conduction pipes are disposed between the buffer conductor 131 as the cooling medium relay member and the power supply body 5B of each of the electrode units 51 and 52 to satisfy first to fourth cooling medium flow conditions described hereinafter.
The first cooling medium flow condition . . . A condition that the cooling medium flows between the conduction pipe 141 of the current introduction member 14A and the first cooling medium inlet through the through flow path 136 and the relay conduction pipe 131.
The second cooling medium flow condition . . . A condition that the cooling medium flows between the first cooling medium outlet and the relay cooling medium flow path 135 through the relay conduction pipe 132.
The third cooling medium flow condition . . . A condition that the cooling medium flows between the relay cooling medium flow path 135 and the second cooling medium inlet through the relay conduction pipe 133.
The fourth cooling medium flow condition . . . A condition that the cooling medium flows between the second cooling medium outlet and the conduction pipe 141 of the current introduction member 14B through the relay conduction pipe 134 and the through flow path 137.
In this manner, the current introduction members 14A and 14B are commonly used in the electrode units 51 and 52 in the active gas generation apparatus 73X as the modification example.
The active gas generation apparatus 73X as the modification example of the embodiment 3 having the configuration describe above has an effect described hereinafter in addition to the effect of the basic configuration in the embodiment 1 and the embodiment 3.
In the active gas generation apparatus 73X as the modification example of the embodiment 3, the relay conduction pipes 131 to 134 are disposed between the buffer conductor 13 and the power supply body 5B of each of the electrode units 51 and 52 so as to satisfy the first to fourth cooling medium flow conditions described above. As a result, the active gas generation apparatus 73X of the modification example can circulate the cooling medium to one loop of the cooling medium to cool the power supply body 5B of the electrode unit 51 and the power supply body 5B of the electrode 52 together.
One loop of the cooling medium includes the current introduction member 14A, the through flow path 136, the relay conduction pipe 131, the first cooling medium inlet, the first cooling medium flow path, the first cooling medium outlet, the relay conduction pipe 132, the relay cooling medium flow path 135, the relay conduction pipe 133, the second cooling medium inlet, the second cooling medium flow path, the second cooling medium outlet, the relay conduction pipe 134, the through flow path 137, and the current introduction member 14B.
As a result, in the active gas generation apparatus 73X of the modification example of the embodiment 3, the power supply body 5B of each of the electrode units 51 and 52 and the high voltage side dielectric film 2 can be cooled with the minimum necessary apparatus configuration that the buffer conductor 13 and the relay conduction pipes 131 to 134 are added without increasing the number of relatively expensive current introduction members 14A and 14B.
The modification example illustrated in
The electrode unit 50X has a feature that the high voltage side dielectric film 2 of the electrode unit 50 according to the embodiment 1 is replaced with the high voltage side dielectric film 2.
The same sign is assigned to the same constituent parts as those in the electrode unit 50 according to the embodiment 1, and characterizing portions of the electrode unit 50X according to the embodiment 4 is mainly described hereinafter.
As illustrated in
As illustrated in
Accordingly, as illustrated in
First and second methods described hereinafter are considered as a method of forming the insulator structure part 24. The first method is a method of performing cutting process on a flat upper surface of a basic structure of the high voltage side dielectric film 2B to manufacture the high voltage side dielectric film 2B selectively including the insulator structure part 24 on the upper surface thereof. In a case of the first method, the insulator structure part 24 is made up of the same constituent material as the high voltage side dielectric film 2B.
The second method is a method of selectively bonding the insulator structure part 24 with an adhesive agent on a flat upper surface of a basic structure of the high voltage side dielectric film 2B after separately manufacturing the insulator structure part 24, thereby manufacturing the high voltage side dielectric film 2B. In a case of the second method, the insulator structure part 24 may be made up of the same constituent material as the high voltage side dielectric film 2B, or may also be made up of a different constituent material.
In the active gas generation apparatus 74 according to the embodiment 4, the high voltage side dielectric film 2B of the electrode unit 50X includes the insulator structure part 24 having the concave-convex structure between the dielectric film suppression member 11 and the power supply body 5 on the upper surface thereof, thus can prevent creeping discharge between the power supply body 5 and the dielectric film suppression member 11.
In the embodiment 4 illustrated in
The present disclosure is described in detail, however, the foregoing description is in all aspects illustrative, thus the present disclosure is not limited thereto. It is therefore understood that numerous modification examples not exemplified can be devised without departing from the scope of the present disclosure.
That is to say, each embodiment can be arbitrarily combined, or each embodiment can be appropriately varied or omitted within a scope of the present disclosure.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2022/039029 | 10/20/2022 | WO |