JP6558376B2 - UV radiation device - Google Patents

Description

  The present invention relates to an ultraviolet radiation device, and more particularly to an ultraviolet radiation device suitably used for sterilization treatment and deodorization treatment of skin and the like.

For example, ultraviolet rays are suitably used for sterilization treatment of skin and the like, deodorization treatment, and organic contaminant removal treatment. As an ultraviolet light source, an excimer lamp is widely known (for example, see Patent Document 1).
As an excimer lamp, as shown in FIG. 5, a cylindrical outer tube 52 and an inner diameter of the outer tube 52 arranged along the tube axis in the outer tube 52 are smaller. An arc tube 51 having a double tube structure made of synthetic quartz glass having a cylindrical inner tube 53 having an outer diameter is provided. In the arc tube 51, both end portions of the outer tube 52 and the inner tube 53 are joined by sealing wall members 54A and 54B, and an annular inner space S1 is formed between the outer tube 52 and the inner tube 53. Has been. The internal space S1 is filled with a discharge gas. Further, the arc tube 51 is provided with a net-like outer electrode 55 on the outer peripheral surface of the outer tube 52, and a film-like inner electrode 56 on the inner peripheral surface of the inner tube 53. 56 are each connected to a high-frequency power source 59.
In this excimer lamp 50, when a high frequency high voltage is applied between the outer electrode 55 and the inner electrode 56 by the high frequency power source 59, excimer discharge is generated in the internal space S1, and excimer light is emitted.

In the sterilization treatment with ultraviolet rays (specifically, skin sterilization treatment), ultraviolet rays having a wavelength of around 200 nm, specifically, ultraviolet rays having a wavelength of approximately 200 to 250 nm are used.
Thus, the excimer lamp can adjust the wavelength characteristics (wavelength range) of the light emitted depending on the type of discharge gas. Therefore, by using an appropriate gas as the discharge gas, the excimer lamp has a wavelength around 200 nm. Radiation light (ultraviolet light) having a center wavelength can be obtained. Specifically, as a discharge gas (hereinafter also referred to as “specific discharge gas”) for obtaining synchrotron radiation having a central wavelength in the vicinity of a wavelength of 200 nm, for example, argon fluoride (ArF) gas (radiation obtained) (Central wavelength of light 193 nm), krypton bromide (KrBr) gas (central wavelength of the obtained synchrotron radiation 207 nm), krypton chloride (KrCl) gas (central wavelength of the synchrotron radiation obtained 222 nm), krypton fluoride (KrF) gas ( The obtained synchrotron radiation has a central wavelength of 248 nm), xenon iodide (XeI) gas (the central wavelength of the synchrotron radiation obtained is 253 nm), and chlorine (Cl ₂ ) gas (the central wavelength of the synchrotron radiation to be obtained is 259 nm).

JP-A-9-92225

The emitted light of the excimer lamp can be regarded as monochromatic light in practice, and its spectrum (radiation spectrum) is a line spectrum, but has a certain spectral line width. Therefore, the emitted light of the excimer lamp includes light having a longer wavelength than the center wavelength and light having a shorter wavelength than the center wavelength, as well as light having the center wavelength.
Therefore, in an excimer lamp filled with a specific discharge gas (hereinafter also referred to as “specific excimer lamp”), ozone (O3) is generated when the emitted light contains ultraviolet light having a wavelength of less than 190 nm. To do. This is because ultraviolet rays having a wavelength of less than 190 nm are absorbed by oxygen and generate ozone (hereinafter also referred to as “ozone-generating ultraviolet rays”). Here, ozone is efficiently generated by emitting ozone-generating ultraviolet rays in an oxygen-existing atmosphere. Therefore, when the specific excimer lamp is turned on in the air atmosphere, ozone is generated by absorbing the ozone-generating ultraviolet rays into the oxygen in the air.
Thus, since high-concentration ozone adversely affects the human body, when using a specific excimer lamp particularly in a living space, for example, when using an excimer lamp for sterilization of the skin, for example. Needs to suppress the generation of ozone.

  The present invention has been made on the basis of the circumstances as described above, and its object is to suppress the generation of ozone in the atmospheric air outside the apparatus and to emit ultraviolet light having a wavelength of around 200 nm with high emission intensity. It is providing the ultraviolet radiation device which can be radiate | emitted by this.

The ultraviolet radiation device of the present invention includes an ultraviolet light source that emits light including ultraviolet light having a wavelength that is absorbed by oxygen and generates ozone;
A lamp storage chamber for storing the ultraviolet light source;
An ultraviolet radiation device having a light guide portion for guiding light from the ultraviolet light source,
The light guide portion is closed by an irradiation window having a UV transparent, have a UV-absorbing wavelength for generating is absorbed ozone to the oxygen,
The lamp storage chamber has a cylindrical body;
It has at least one of an exhaust fan and an air supply fan in at least one of the one end and the other end of the cylindrical body .

  In the ultraviolet radiation device of the present invention, it is preferable that an ozone filter is provided in an exhaust path formed by at least one of the exhaust fan and the air supply fan.

In the ultraviolet radiation device of the present invention, an oxygen-containing layer is formed in the light guide portion closed by an irradiation window having ultraviolet transparency, and ultraviolet rays having a wavelength that generates ozone by being absorbed by oxygen (ozone-generating ultraviolet rays). Light from an ultraviolet light source that emits light containing is emitted through the oxygen-containing layer. For this reason, the ozone-generated ultraviolet contained in the light from the ultraviolet light source is selectively absorbed in the oxygen-containing layer. As a result, in the light emitted from the ultraviolet radiation device of the present invention, the emission intensity of ozone-generated ultraviolet light can be reduced without greatly reducing the emission intensity of ultraviolet light other than ozone-generated ultraviolet light.
Therefore, according to the ultraviolet radiation device of the present invention, it is possible to suppress the generation of ozone in the air atmosphere outside the device, and to radiate ultraviolet rays having a wavelength of around 200 nm with high emission intensity.

  Further, ozone generated ultraviolet light contained in the light from the ultraviolet light source is absorbed by the atmosphere in the lamp housing chamber to generate ozone. According to the ultraviolet radiation device in which an ozone filter is provided in the exhaust path, Adsorbed by ozone filter. As a result, ozone discharged to the outside of the apparatus can be reduced.

It is sectional drawing for description which shows an example of a structure of the ultraviolet radiation device of this invention. It is the sectional view on the AA line in the ultraviolet-ray radiation apparatus of FIG. It is a bottom view of the ultraviolet radiation device of FIG. It is a bottom view in another example of the configuration of the ultraviolet radiation device of the present invention. It is sectional drawing for description which shows an example of a structure of an excimer lamp.

  Hereinafter, embodiments of the present invention will be described in detail.

FIG. 1 is an explanatory sectional view showing an example of the configuration of the ultraviolet radiation device of the present invention. FIG. 2 is a cross-sectional view taken along the line AA in the ultraviolet radiation device of FIG. FIG. 3 is a bottom view of the ultraviolet radiation device of FIG.
The ultraviolet radiation device 10 of the present invention includes an ultraviolet light source unit 11 that includes an ultraviolet light source that emits ultraviolet light, for example, an excimer lamp 20, a lamp storage chamber 12 that houses the ultraviolet light source unit 11, and light from the excimer lamp 20. It has the light guide part 13 which guides light.

[Ultraviolet light source unit]
The ultraviolet light source unit 11 includes an ultraviolet light source composed of a double straight tubular excimer lamp 20 and a reflecting member 28 disposed so as to extend along the lamp central axis of the excimer lamp 20.
The reflecting member 28 has a full length longer than the full length of the excimer lamp 20 and is composed of a rectangular curved plate-shaped aluminum concave plane mirror that is curved in a semicircular shape along the circumferential direction of the excimer lamp 20. . The reflecting member 28 is disposed such that the reflecting surface (inner peripheral surface) of the reflecting member 28 faces the excimer lamp 20. Here, the reflecting member 28 may be formed of an aluminum vapor deposition film provided on the outer peripheral surface of the excimer lamp 20 (specifically, the outer peripheral surface of the outer tube 22 described later). An ultraviolet emission region is formed by a region not facing the reflecting member 28 on the outer peripheral surface of the outer tube 22 of the excimer lamp 20.

The excimer lamp 20 includes an arc tube 21 made of a dielectric material that transmits ultraviolet rays, such as synthetic quartz glass and fused silica glass. The arc tube 21 has a cylindrical outer tube 22 and a cylindrical inner tube 23 having an outer diameter smaller than the inner diameter of the outer tube 22 disposed along the tube axis in the outer tube 22. It has a double tube structure. In the luminous tube 21, the outer tube 22 and the inner tube 23 are arranged so that the tube axis of the outer tube 22 and the tube axis of the inner tube 23 coincide with each other. The tube axis of the tube is the lamp central axis. In the arc tube 21, both end portions of the outer tube 22 and the inner tube 23 are joined by sealing wall members 24 </ b> A and 24 </ b> B, and an annular inner space S <b> 1 is formed between the outer tube 22 and the inner tube 23. Is formed. The internal space S1 is filled with a discharge gas. Further, the arc tube 21 is provided with a net-like outer electrode 25 made of, for example, stainless steel in close contact with the outer peripheral surface of the outer tube 22, and the inner peripheral surface of the inner tube 23 has the inner peripheral surface thereof. A cylindrical inner electrode 26 made of, for example, aluminum is provided in close contact with the surface. The inner electrode 26 may be made of an aluminum vapor deposition film provided on the inner peripheral surface of the inner tube 23 of the excimer lamp 20. A pair of electrodes composed of the outer electrode 25 and the inner electrode 26 are arranged so as to face each other, and at the boundary between the outer electrode 25 and the inner electrode 26 and the inner space S1, each arc tube 21 tube walls (dielectric material) are interposed. In the inner space S1 of the arc tube 21, a discharge region is formed in a region where the pair of electrodes face each other with the tube wall (dielectric material) of the arc tube 21 and the internal space S1 therebetween.
In the example of this figure, the outer electrode 25 and the inner electrode 26 are each connected to a high-frequency power source (not shown) via lead wires (not shown). In order to prevent leakage, the outer electrode 25 is a ground electrode (low voltage side electrode), and the inner electrode 26 is a high voltage supply electrode.

As the excimer lamp 20, a lamp having a center wavelength in a wavelength range of 190 to 250 nm is preferably used. In the excimer lamp used as the excimer lamp 20 and having a center wavelength in the wavelength range of 190 to 250 nm, light including ozone-generated ultraviolet rays is emitted.
Specific examples of the discharge gas used in the excimer lamp 20 include, for example, argon fluoride (ArF) gas (center wavelength of the obtained radiation light 193 nm), krypton bromide (KrBr) gas (center wavelength of the obtained radiation light) 207 nm), krypton chloride (KrCl) gas (center wavelength of the obtained synchrotron radiation 222 nm), krypton fluoride (KrF) gas (center wavelength of the synchrotron radiation obtained 248 nm), xenon iodide (XeI) gas (the synchrotron radiation obtained) And a chlorine (Cl ₂ ) gas (a central wavelength of the obtained synchrotron radiation of 259 nm). Among these, argon fluoride gas, krypton bromide gas, and krypton chloride gas are preferable, krypton bromide gas and krypton chloride gas are more preferable, and krypton chloride gas is particularly preferable.
Further, as the excimer lamp 20, an ultraviolet excimer fluorescent lamp having a configuration in which an ultraviolet light emitting phosphor having a peak wavelength in a wavelength range of 200 to 250 nm is applied to the inner peripheral surface of the arc tube 21 can be used. Here, the fluorescence from the ultraviolet light emitting phosphor has a certain spectral line width, similar to the emitted light of the excimer lamp, and therefore, the peak wavelength light, the light on the longer wavelength side than the peak wavelength, and the center. It also includes light on the shorter wavelength side than the wavelength. Therefore, an ultraviolet excimer fluorescent lamp in which an ultraviolet light emitting phosphor having a peak wavelength in the wavelength range of 200 to 250 nm is applied emits light containing ozone-generated ultraviolet light. That is, when an ultraviolet excimer fluorescent lamp is lit in an air atmosphere, ozone (O ₃ ) is generated by the absorption of ozone-generated ultraviolet light contained in the emitted light of the ultraviolet excimer fluorescent lamp by oxygen. Become.

The excimer lamp 20 and the reflecting member 28 are supported and fixed by base members 32A and 32B disposed at both ends of the excimer lamp 20 and the reflecting member 28.
Specifically, the base members 32A and 32B are each formed of a substantially annular cylindrical body. The cross section of the substantially annular cylindrical body perpendicular to the tube axis has an inner diameter slightly smaller than the inner diameter of the inner tube 23 of the excimer lamp 20 and an outer diameter slightly larger than the outer diameter of the reflecting member 28. A part of the torus having a part is missing, and the outer shape is a part of a missing circle. Since the base members 32A and 32B are substantially ring-shaped, the excimer lamp 20 can be cooled with high efficiency by cooling air taken into the lamp housing chamber 12 from an air supply fan 12B described later.
From the inner surfaces (surfaces facing the excimer lamp 20) of the base members 32A and 32B, the annular cylindrical engaging portions 33A having an outer diameter slightly smaller than the inner diameter of the inner tube 23 of the excimer lamp 20, respectively. 33B is provided so as to protrude in a state where the inside of the ring communicates with the inside of the ring of the base members 32A and 32B. Further, from the outer surfaces of the base members 32A and 32B, annular cylindrical engaging portions 34A and 34B are provided so as to protrude in a state where the insides of the rings communicate with the insides of the base members 32A and 32B. ing.
In the base members 32A and 32B, the engaging portions 33A and 33B protruding inward are inserted into the inner tube 23 of the excimer lamp 20, whereby the excimer lamp 20 is held by the base members 32A and 32B. Yes.

[Lamp storage room]
The lamp housing chamber 12 in which the ultraviolet light source unit 11 is housed is for cooling the excimer lamp 20 in the lamp housing chamber 12 provided at both ends of the peripheral wall portion 12A made of a substantially rectangular cylindrical body and the peripheral wall portion 12A. The air supply fan 12B and the exhaust fan 12C circulate the cooling air.
In the lamp storage chamber 12, the ultraviolet light source unit 11 is disposed so that the tube axis of the peripheral wall portion 12A and the tube axis of the excimer lamp 20 extend coaxially. Specifically, two ultraviolet light source unit support portions 14A and 14B having the same outer peripheral shape as the inner peripheral shape in a cross section perpendicular to the axial direction of the peripheral wall portion 12A are separated from each other in the peripheral wall portion 12A of the lamp storage chamber 12. The engaging portions 34A and 34B of the base members 32A and 32B of the ultraviolet light source unit 11 are engaged with the engaging holes 14H and 14H provided in the ultraviolet light source unit support portions 14A and 14B, respectively. As a result, the ultraviolet light source unit 11 is supported and fixed in the lamp storage chamber 12.
The peripheral wall portion 12A is made of a light-shielding material, for example, black anodized aluminum. Moreover, it is preferable that a reflective layer made of, for example, aluminum is provided in a region facing the light emitting portion of the excimer lamp 20 on the inner surface of the peripheral wall portion 12A.
In the ultraviolet radiation device 10 of the present invention, a region facing the ultraviolet emission region of the excimer lamp 20 (specifically, the outer peripheral surface of the outer tube 22 of the excimer lamp 20 opposite to the reflecting member 28) on the peripheral wall portion 12A. Is formed with a quadrangular opening 12D.

It is preferable that an ozone filter is provided on the downstream side of the excimer lamp 20 in the exhaust path by the supply fan 12B and / or the exhaust fan 12C.
In the ultraviolet radiation device 10 of the example of this figure, an ozone filter 16 is provided between the ultraviolet light source unit 11 and the exhaust fan 12C.
The ozone filter 16 adsorbs and decomposes ozone.
By providing the ozone filter 16 in the exhaust path formed by the air supply fan 12B and / or the exhaust fan 12C, it is possible to reduce ozone generated in the lamp housing chamber 12 and discharged to the outside of the apparatus.

[Light guide part]
The light guide portion 13 that guides light from the excimer lamp 20 includes a tubular portion 15 having a rectangular tubular shape, and an inner peripheral shape of the proximal end portion 15A in the proximal end portion 15A of the tubular portion 15. The light guide window 18 having the same outer peripheral shape and having ultraviolet transparency is fitted and fixed. On the other hand, the distal end portion 15B of the cylindrical portion 15 is closed by an irradiation window 17 having ultraviolet transparency. Specifically, an irradiation window 17 having the same outer peripheral shape as the inner peripheral shape of the tip portion 15B is fitted and fixed in the tip portion 15B of the cylindrical portion 15.
On the inner peripheral surface of the cylindrical portion 15, a reflection layer 19 made of, for example, a high-luminance aluminum plate or an aluminum vapor deposition film that reflects light from the excimer lamp 20 is provided.
The oxygen-containing layer forming space S2 defined by the reflective layer 19, the light guide window 18, and the irradiation window 17 provided on the inner peripheral surface of the cylindrical portion 15 in the light guide portion 13 absorbs ultraviolet rays. The oxygen-containing layer is formed by being filled with a gas that generates ozone. The oxygen-containing layer forming space S2 may be an airtight closed space where there is no leakage of ozone generated in the oxygen-containing layer to the outside, but obstructing free circulation of ozone generated in the oxygen-containing layer to the outside. As long as the leakage is suppressed to a small level, high airtightness may not be ensured.
The gas that absorbs the ultraviolet rays that fill the oxygen-containing layer and generates ozone may be any gas that contains oxygen, and specifically includes air (air in the environment outside the apparatus).

  The light guide unit 13 is disposed so as to protrude from the lamp storage chamber 12. Specifically, the base end portion 15 </ b> A of the cylindrical portion 15 of the light guide portion 13 extends in a state in which the cylindrical portion 15 of the light guide portion 13 extends in a direction perpendicular to the tube axis of the excimer lamp 20. The peripheral wall portion 12A is fitted and fixed to the opening 12D.

The thickness of the oxygen-containing layer, that is, the separation distance between the light guide window 18 and the irradiation window 17 takes into consideration the configuration of the excimer lamp 20 (specifically, the type of discharge gas, etc.), the lighting conditions of the excimer lamp 20, and the like. It is determined as appropriate.
Specifically, the thickness of the oxygen-containing layer is preferably 10 to 100 mm, and more preferably 30 to 60 mm.
When the thickness of the oxygen-containing layer is too small, the ozone-containing ultraviolet absorption capacity of the oxygen-containing layer becomes small, and the amount of ozone generated in the oxygen-containing layer, that is, the amount of ozone-generated ultraviolet light absorbed in the oxygen-containing layer Becomes smaller. Therefore, there is a possibility that generation of ozone in the air atmosphere outside the apparatus cannot be sufficiently suppressed.
On the other hand, when the thickness of the oxygen-containing layer is excessive, the heat retaining action by the oxygen-containing layer is increased, so that the excimer lamp 20 is excessively heated by heat generated by lighting the excimer lamp 20 or the like. As a result, the service life of the excimer lamp 20 may be shortened.

The irradiation window 17 can be made of a material such as quartz glass.
The irradiation window 17 preferably has a filter function for cutting off ultraviolet rays in a wavelength range harmful to the skin (hereinafter referred to as “harmful ultraviolet rays A”). Specifically, a filter function can be provided by providing a filter layer that blocks harmful ultraviolet rays A and transmits light of other wavelengths on the inner surface or outer surface of the irradiation window 17.

The light guide window 18 can be made of a material such as quartz glass.
The light guide window 18 is different from the wavelength range of ultraviolet light (harmful ultraviolet light A) cut by the irradiation window 17 and cuts ultraviolet light in a wavelength region harmful to the skin (hereinafter referred to as “harmful ultraviolet light B”). It is preferable to have a filter function. Specifically, a filter function can be imparted by providing a filter layer that blocks harmful ultraviolet rays B and transmits light of other wavelengths on the inner surface or outer surface of the light guide window 18.

Ultraviolet rays having a wavelength range harmful to the skin are, for example, ultraviolet rays having a wavelength range of 230 to 300 nm. Since the wavelength range is wide, a single filter layer may sufficiently block ultraviolet rays having a wavelength range harmful to the skin. However, by dividing the wavelength range harmful to the skin into harmful ultraviolet rays A and harmful ultraviolet rays B and providing two filter layers, it is possible to reliably block ultraviolet rays in the wavelength range harmful to the skin.
The harmful ultraviolet rays A and the harmful ultraviolet rays B are ultraviolet rays having a wavelength range of 230 to 280 nm and ultraviolet rays having a wavelength range of 280 to 320 nm, respectively.

In the ultraviolet radiation device 10, excimer discharge is generated in the internal space S <b> 1 by applying a high frequency high voltage to a pair of electrodes of the excimer lamp 20 by a high frequency power source, and excimer light according to the type of discharge gas. Is emitted from the outer peripheral surface of the outer tube 22 as emitted light. The emitted light from the excimer lamp 20 includes ultraviolet light having a wavelength that is absorbed by oxygen and generates ozone. The emitted light of the excimer lamp 20 is emitted from the ultraviolet emission region on the outer peripheral surface of the outer tube 22 after a part thereof is reflected directly and the other part is reflected by the reflecting member 28. A part of the light emitted from the ultraviolet emission region of the outer tube 22 of the excimer lamp 20 is directly reflected, and the other part is reflected on the inner surface of the peripheral wall portion 12A of the lamp storage chamber 12, and then guided. The light enters the light guide window 18 of the optical unit 13.
Of the emitted light of the excimer lamp 20 incident on the light guide window 18, harmful ultraviolet light B (ultraviolet light in the wavelength range of 280 to 320 nm) is selectively blocked by the filter layer of the light guide window 18, and other wavelength ranges Light is transmitted.
The light transmitted through the light guide window 18 is incident on the oxygen-containing layer blocked by the light guide window 18 and the irradiation window 17, and the ozone-generated ultraviolet light contained in this light is selectively absorbed in the oxygen-containing layer. Then, ozone is generated, and light from which the ozone-generated ultraviolet light has been removed enters the irradiation window 17. Here, since the oxygen-containing layer forming space S2 in which the oxygen-containing layer is formed is a closed space, ozone is generated in the oxygen-containing layer by absorption of ozone-generating ultraviolet rays by oxygen in the atmosphere. The ozone is prevented from leaking outside the apparatus.
Further, among the light incident on the irradiation window 17, harmful ultraviolet rays A (ultraviolet rays in the wavelength range of 230 to 280 nm) are selectively blocked by the filter layer of the irradiation window 17 and light in other wavelength ranges is transmitted. The
As described above, ozone generation ultraviolet rays and light with reduced emission intensity of harmful ultraviolet rays A and harmful ultraviolet rays B are emitted from the irradiation window 17 of the ultraviolet radiation device 10.

In the lamp storage chamber 12, the air supply fan 12 </ b> B and the exhaust fan 12 </ b> C are operated, so that the atmosphere outside the apparatus extends from one end side where the air supply fan 12 </ b> B is arranged to the other end side where the exhaust fan 12 </ b> C is arranged. Is distributed as cooling air.
The light emitted from the ultraviolet emission region of the outer tube 22 of the excimer lamp 20 is also absorbed by the oxygen-containing layer in the lamp housing chamber 12 to generate ozone. The ozone is heated by heat from the excimer lamp 20 and is quickly decomposed (thermally decomposed) to generate oxygen, or by the ozone filter 16 provided between the excimer lamp 20 and the exhaust fan 12C. Adsorbed and removed. Therefore, ozone discharged outside the apparatus can be reduced.
Therefore, according to the ultraviolet radiation device 10, generation of ozone in the atmospheric air outside the device can be suppressed, and a desired wavelength range in the vicinity of a wavelength of 200 nm can be obtained by selecting and using the discharge gas in the excimer lamp 20. Can be emitted with high emission intensity. Moreover, even if the ultraviolet radiation device 10 generates ozone inside the device, the ozone can be prevented from leaking outside the device.

  Such an ultraviolet radiation device of the present invention can be suitably used for a use application in which ultraviolet rays having a wavelength range of 190 nm to 250 nm are required in a living space. Specifically, for example, it can be suitably used as an ultraviolet sterilizer for skin using, for example, ultraviolet rays having a wavelength of 230 nm or less.

In the ultraviolet radiation device 10 as described above, an oxygen-containing layer is formed in the light guide portion 13 (oxygen-containing layer forming space S2) closed by the irradiation window 17 having ultraviolet transparency, and ozone-generating ultraviolet rays are generated. The light from the excimer lamp 20 that emits the contained light is emitted through the oxygen-containing layer. Therefore, the ozone-generated ultraviolet light contained in the light from the excimer lamp 20 is selectively absorbed in this oxygen-containing layer. As a result, the emitted light from the ultraviolet radiation device 10 can reduce the emission intensity of the ozone-generated ultraviolet light without greatly reducing the emission intensity of ultraviolet light other than the ozone-generated ultraviolet light.
Therefore, according to the ultraviolet radiation device 10, it is possible to suppress the generation of ozone in the air atmosphere outside the device, and it is possible to radiate ultraviolet rays having a wavelength of around 200 nm with high emission intensity.
Further, ozone generated ultraviolet light contained in the light from the excimer lamp 20 is absorbed by the atmosphere in the lamp storage chamber 12 to generate ozone. However, since the ozone filter 16 is provided, the ozone is filtered into the ozone filter 16. Is adsorbed by. As a result, ozone discharged to the outside of the apparatus can be reduced.

As mentioned above, although embodiment of this invention was described, this invention is not limited to said embodiment, A various change can be added.
For example, the oxygen-containing layer forming space does not have to be a closed space, and may be an open space opened in the lamp storage chamber. Specifically, the light guide window of the light guide unit is not provided, and only the irradiation window can be provided. Even when the oxygen-containing layer forming space is an open space opened in the lamp housing chamber, the oxygen-containing layer is heated by heat from an ultraviolet light source or the like, and the temperature is increased. Ozone generated in the oxygen-containing layer is quickly decomposed (thermally decomposed), or removed by being adsorbed by an ozone filter provided between the ultraviolet light source and the exhaust fan, because the constituent atmosphere is difficult to flow. Therefore, ozone discharged to the outside of the apparatus can be reduced.
Further, for example, the ultraviolet light source may have a configuration in which an excimer lamp is disposed inside the outer tube.
Further, for example, the ultraviolet light source is not limited to an excimer lamp including a double tube type arc tube having the above-described configuration, and an excimer lamp including a single tube type arc tube such as a flat tube may be used. .
Further, for example, the shape of the cylindrical portion of the light guide is not limited to a rectangular cylindrical shape, and may be a cylindrical cylindrical portion 15X as shown in FIG. In FIG. 4, the same components as those of the ultraviolet radiation device of FIG. In FIG. 4, reference numeral 19X denotes a reflective layer.
Further, for example, ozone decomposing means may be disposed in the oxygen-containing layer forming space in the light guide. As the ozonolysis means, an apparatus for thermally decomposing ozone generated in the oxygen-containing layer, specifically, for example, a heater or the like can be used.

  Hereinafter, specific examples of the present invention will be described, but the present invention is not limited to the following examples.

[Example 1]
An ultraviolet radiation device having the configuration shown in FIG. 1 (hereinafter also referred to as “ultraviolet radiation device [1]”) was produced.
The produced ultraviolet radiation device [1] has the following specifications.

(Excimer lamp)
Outer tube: material: synthetic quartz glass, outer diameter: 40 mm, inner diameter: 36 mm
Inner tube: material: synthetic quartz glass, outer diameter: 26 mm, inner diameter: 24 mm
Discharge gas: type (filled gas type); krypton (filled pressure; mixed gas of 20 kPa (150 Torr) and chlorine 133 Pa (1 Torr) (total sealed pressure; 20.1 kPa (151 Torr))
Ultraviolet light emitted: Total length of light lamp centered at an emission wavelength of 222 nm: 100 mm
Discharge space distance: 5mm
(Lamp storage room)
Peripheral wall: Material: Aluminum, width (length in the direction perpendicular to the paper surface in FIG. 1); 50 mm, height (length in the vertical direction in FIG. 1); 50 mm, total length: 130 mm
(Light guide part)
Light guiding window: material: quartz glass, length (length in the direction perpendicular to the paper surface in FIG. 1); 50 mm, width (length in the left-right direction in FIG. 1); 50 mm, thickness: 1.3 mm
Irradiation window: material: quartz glass, length (length in the direction perpendicular to the paper surface in FIG. 1); 50 mm, width (length in the left-right direction in FIG. 1); 50 mm, thickness: 1 mm
Oxygen-containing layer: thickness (length in the vertical direction in FIG. 1); 40 mm

  For the produced ultraviolet radiation device [1], when the air supply fan and the exhaust fan are rotated and the excimer lamp is turned on, the maximum in the vicinity of the irradiation window in the air atmosphere outside the device and in the vicinity of the exhaust fan The ozone concentration was measured. The results are shown in Table 1 below. The ozone concentration was measured using an ozone concentration meter “EG-3000F” (manufactured by Sugawara Jitsugyo Co., Ltd.).

[Example 2]
In the ultraviolet radiation device [1] according to Example 1, a similar ultraviolet radiation device [2] was produced except that the light guide window was not provided.
With respect to this ultraviolet radiation device [2], the ozone concentration in the atmospheric air outside the device at the time of operation of the excimer lamp was measured by the same method as in Example 1. The results are shown in Table 1 below.

[Comparative Example 1]
In the ultraviolet radiation device [1] according to the first embodiment, the light guide portion sandwiched between the light guide window and the irradiation window is not provided, and the irradiation window is directly fitted into the opening of the lamp storage chamber. Other than that, a similar ultraviolet radiation device [3] was produced.
With respect to this ultraviolet radiation device [3], the ozone concentration in the atmospheric air outside the device during the operation of the excimer lamp was measured by the same method as in Example 1. The results are shown in Table 1 below.

  In Table 1, the ozone concentration of the ultraviolet radiation devices [1] to [3] was set to 1 based on the ozone concentration in the atmospheric air outside the device near the irradiation window outside the ultraviolet radiation device [1]. The relative value of the ozone concentration in the air atmosphere outside the device when the ultraviolet radiation devices [1] to [3] are operated is shown.

From the results of Table 1, it was confirmed that according to the ultraviolet radiation device [1] according to Example 1 of the present invention, generation of ozone in the air atmosphere outside the device can be extremely suppressed.
Moreover, in the ultraviolet radiation device [2] according to Example 2 of the present invention, it was confirmed that the generation of ozone in the vicinity of the irradiation window outside the device can be extremely suppressed. This is considered that ozone generation by light emitted from the irradiation window is suppressed by sufficiently absorbing ozone-generated ultraviolet rays in the oxygen-containing layer. It was also confirmed that the ozone concentration in the vicinity of the exhaust fan can be suppressed to some extent. This is presumably because only the ozone generated in the oxygen-containing layer forming space opened in the lamp storage chamber that was not decomposed by the heat from the excimer lamp was exhausted by the exhaust fan.
Moreover, in the ultraviolet radiation device [3] according to Comparative Example 1, it was found that the ozone concentration in the vicinity of the irradiation window was high. This is because the distance between the excimer lamp and the irradiation window is too narrow to obtain a sufficient thickness of the oxygen-containing layer, and therefore, the ozone-generated ultraviolet rays cannot be sufficiently absorbed and are emitted to the outside of the apparatus. It is done.

DESCRIPTION OF SYMBOLS 10 Ultraviolet radiation device 11 Ultraviolet light source unit 12 Lamp storage chamber 12A Perimeter wall part 12B Air supply fan 12C Exhaust fan 12D Opening 13 Light guide part 14A, 14B Ultraviolet light source unit support part 14H Engagement hole 15, 15X Cylindrical part 15A Base end part 15B Tip 16 Ozone filter 17 Irradiation window 18 Light guide window 19, 19X Reflective layer 20 Excimer lamp 21 Light emitting tube 22 Outer tube 23 Inner tube 24A, 24B Sealing wall member 25 Outer electrode 26 Inner electrode 28 Reflective member 32A, 32B Base Member 33A, 33B Engagement part 34A, 34B Engagement part 50 Excimer lamp 51 Light emission tube 52 Outer tube 53 Inner tube 54A, 54B Sealing wall member 55 Outer electrode 56 Inner electrode 59 High frequency power supply S1 Inner space S2 Oxygen-containing layer forming space

Claims (2)

An ultraviolet light source that emits light including ultraviolet light of a wavelength that is absorbed by oxygen and generates ozone;
A lamp storage chamber for storing the ultraviolet light source;
An ultraviolet radiation device having a light guide portion for guiding light from the ultraviolet light source,
The light guide portion is closed by an irradiation window having a UV transparent, have a UV-absorbing wavelength for generating is absorbed ozone to the oxygen,
The lamp storage chamber has a cylindrical body;
An ultraviolet radiation device having at least one of an exhaust fan and an air supply fan at at least one of one end and the other end of the cylindrical body . The ultraviolet radiation device according to claim 1 , wherein an ozone filter is provided in an exhaust path formed by at least one of the exhaust fan and the air supply fan .

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