JP2005013723A - Optical fibre sterilizing disinfecting device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical fiber sterilizing disinfecting device capable of safely, easily, and inexpensively sterilizing and disinfecting a place difficult for sterilization and disinfection. <P>SOLUTION: This device includes an ultraviolet ray generating part connected to a power source part, and generating ultraviolet rays by electric power supplied from a power source, and an optical fiber connected to the ultraviolet ray generating part, and propagating the ultraviolet rays generated by the ultraviolet ray generating part. The optical fiber 100 includes a core 160 for passing the ultraviolet rays, and a clad 150 formed on a coating film around the core 160. Exposure parts 130 and 140 for exposing a part of the core 160, and radiating the ultraviolet rays outside, are formed on the clad 150, and sterilization and disinfection are performed by the ultraviolet rays radiated from the exposure parts 130 and 140. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an optical fiber sterilization device that irradiates ultraviolet rays using an optical fiber.

  Household appliances and furniture, houses, kitchens and cooking utensils, medical equipment, shoes, clothes, human bodies, trains, airplanes, and other vehicles have dust, dirt, and bacteria. There are many cases where harmful microorganisms such as fungi and small animals such as flies and cockroaches are bred.

  The use of disinfectants such as insecticides and hydrogen peroxide is not always possible considering the effects on the human body, and is difficult to use because of high humidity and environmental pollution.

In view of this, there has been proposed an apparatus that effectively sterilizes and disinfects the human body by using ultraviolet rays effectively without harm.
Japanese Patent Laid-Open No. 10-149711 JP-A-8-66462 JP-A-8-266595

  For example, home appliances with a lot of moisture, such as washing machines, are trying to sterilize and disinfect by attaching an “ultraviolet lamp” to the upper lid, but there is a problem that ultraviolet rays do not reach the back of the washing tub. For this reason, black mold propagates on the back side of the washing tub or inside the main body and adheres to the laundry, which may cause illness due to the laundry.

  In view of this, a device has been devised that uses the optical fiber to guide ultraviolet rays to the back of the washing tub, utilizing the property of optical fiber that "deliver light without being attenuated far away". However, the ultraviolet rays emitted from the tip of the “optical fiber” with this apparatus can be pinpointed where desired, but the irradiation range is narrow and the irradiation amount cannot be secured sufficiently.

  In addition, the use of a film with a very special structure to selectively irradiate a wide range of light from several wavelengths from the entire “optical fiber” is costly and requires adjustment of the irradiation range. difficult.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide an optical fiber sterilizing / disinfecting apparatus capable of sterilizing and disinfecting a place where sterilization and disinfection are difficult, safely and simply at low cost.

(1) The present invention
An ultraviolet ray generating unit that is connected to the power supply unit and generates ultraviolet rays by electric power supplied from the power source;
An optical fiber that is connected to the ultraviolet ray generation unit and propagates ultraviolet rays generated by the ultraviolet ray generation unit;
The optical fiber is
Including a core through which ultraviolet rays pass and a clad formed on the film around the core;
The clad is formed with an exposed portion for exposing a part of the core and radiating ultraviolet rays to the outside, and sterilizing and disinfecting with ultraviolet rays emitted from the exposed portion.

  The ultraviolet ray generator can be constituted by, for example, an ultraviolet lamp.

  Here, there are three types of ultraviolet rays: near ultraviolet rays (320 nm to 400 nm) → UV-A, ultraviolet rays (280 nm to 320 nm) → UV-B, far ultraviolet rays (10 nm to 280 nm) → UV-C.

  For example, the ultraviolet ray generator may be configured to generate any one of these types of ultraviolet rays, or may be generated by combining or switching a plurality of types of ultraviolet rays. For example, a plurality of ultraviolet light emission sources having different wavelengths may be provided, and ultraviolet light may be generated by combining or switching them.

  Of these, UV-C has the strongest bactericidal activity and is normally absorbed by the ozone layer in the sky and does not reach the ground. Since UV-C is effective, UV-C may be generated by the ultraviolet ray generator. In this way, it is effective for controlling insects such as cockroaches and mites that live by avoiding ultraviolet rays of this wavelength.

  In addition, if the wavelength of the ultraviolet rays sent into the optical fiber is 185 nm, the ultraviolet rays of this wavelength generate “ozone” in the air, so that the “pheromones” secreted by the cockroaches to communicate with each other will be decomposed. Cockroaches are no longer approaching. Therefore, ultraviolet rays having a wavelength of 185 nm may be generated by the ultraviolet ray generator.

  An optical fiber is composed of a core and a clad having different refractive indexes of light. Here, the core is a light guide portion of an optical fiber designated by a high refractive index region, and the clad is formed in a film shape around the core and has a lower refractive index than the core.

  The optical fiber may be a clad optical fiber (for example, a step index optical fiber) in which the refractive index changes discontinuously in the radial direction of the fiber and transmits light by total reflection. For example, a graded index optical fiber).

  The material of the optical fiber may be glass, plastic, or other materials.

  Here, the optical fiber is formed in a straight stick shape, and an exposed portion is provided in a portion closer to the light source than a tip portion that is the portion farthest from the light source of the optical fiber.

  There may be one or more exposed portions. For example, it may be formed continuously in a groove shape or may be formed discontinuously.

  The exposed portion can be formed by, for example, making a cut, scratching, cutting, making a hole, making a groove, or making a cut in the outer periphery of the optical fiber.

  In this case, only the clad part may be cut, scratched, cut out, perforated or grooved, or a part of the clad and core may be cut, scratched or cut off. It is also possible to make a hole or make a groove.

  The power supply unit may be a DC power supply or an AC power supply. Moreover, a “portable type” such as a battery or a rechargeable battery may be used, or a “installation type” in which a cord is inserted from the outside may be used.

  According to the present invention, the exposed portion can be radiated from the exposed portion and used for sterilization and disinfection with a simple configuration in which the exposed portion is provided in the clad, and thus can be realized at low cost.

  Further, it is possible to easily irradiate ultraviolet rays over a wide range by providing the exposed portions continuously or by providing a plurality of exposed portions.

  Further, according to the present invention, the position of the exposed portion can be appropriately set according to the purpose of irradiation with ultraviolet rays. Therefore, ultraviolet irradiation suitable for the purpose can be performed, and sterilization and disinfection of a place that has been impossible in the past can be performed.

  Ultraviolet light itself also generates active oxygen, but when it hits titanium oxide or platinum alloys, it generates more active oxygen, increasing the ability to destroy the substance and killing power. A structure in which titanium oxide or a platinum compound is applied, or “rod-like”, “plate-like”, “string”, “ring-like”, “film-like”, or “net-like” containing titanium oxide may be added. In this way, the performance can be further improved.

  Further, according to the present invention, ultraviolet rays can be irradiated without generating heat.

(2) The optical fiber sterilizer of the present invention is
The exposed portion is
It is formed as one or a plurality of holes provided in the clad of the optical fiber.

  There may be one hole or a plurality of holes.

  Here, the one or more holes are provided in a portion closer to the light source than the tip portion which is the portion farthest from the light source of the optical fiber.

  In addition, the position of the hole, the size of the hole, the direction of the hole, the shape of the hole, the number of holes, and the interval between the holes are appropriately set according to the purpose of sterilization (the target of sterilization and the place where the holes are arranged, etc.) can do.

(3) The optical fiber sterilizer of the present invention is
The exposed portion is
The optical fiber clad is formed as a lateral groove having a predetermined width and a predetermined length along the outer periphery to expose the core.

  For example, the clad may be cut off once (360 degrees) along the outer periphery with a predetermined width. If it does in this way, an ultraviolet-ray can be irradiated to the direction of 360 degree | times along the outer periphery of an optical fiber.

  Further, a predetermined length (for example, an outer peripheral portion corresponding to a predetermined angle θ) may be cut off along the outer periphery.

  There may be one longitudinal groove or a plurality of longitudinal grooves.

  Here, the one or more vertical grooves are provided in a portion closer to the light source than the tip portion that is the portion farthest from the light source of the optical fiber.

  In addition, the position of the vertical groove, the size of the vertical groove (width and length of the vertical groove), the shape of the vertical groove, the number of vertical grooves, the interval between the vertical grooves, the purpose of sterilization It can be set as appropriate according to the place of placement.

(4) The optical fiber sterilizer of the present invention is
The exposed portion is
The clad of the optical fiber is formed as a lateral groove having a predetermined width and a predetermined length along the axial direction to expose the core.

  For example, the clad may be cut from end to end along the axial direction with a predetermined width. If it does in this way, an ultraviolet-ray can be irradiated to a predetermined direction along the axial direction of an optical fiber.

  Moreover, you may cut out only predetermined length along an axial direction.

  One transverse groove may be provided, or a plurality of transverse grooves may be provided.

  Here, the one or more lateral grooves are provided in a portion closer to the light source than the tip portion which is the portion farthest from the light source of the optical fiber.

  Also, the position of the horizontal groove, the size of the horizontal groove (width and length of the horizontal groove), the shape of the horizontal groove, the number of horizontal grooves, and the interval between the horizontal grooves are for the purpose of sterilization (disinfection and disinfection target, location, etc.) It can be set accordingly.

(5) The optical fiber sterilizer of the present invention is
The exposed portion is
The clad of the optical fiber is formed as a spiral groove when the core is exposed by spirally taking a predetermined length with a predetermined width along the outer periphery.

  In this way, it is possible to irradiate ultraviolet rays in a 360 degree direction around the optical fiber.

  The spiral groove may be provided from end to end of the optical fiber, or may be provided in a part of the optical fiber.

  One spiral groove or a plurality of spiral grooves may be provided.

  Here, the one or more spiral grooves are provided in a portion closer to the light source than the tip portion that is the portion farthest from the light source of the optical fiber.

  Also, the position of the spiral groove, the size of the spiral groove (the width and length of the spiral groove), the shape of the spiral groove, the number of spiral grooves, the spacing between the spiral grooves Can be set as appropriate according to the purpose of sterilization (object of sterilization and place of disposition).

(6) The optical fiber sterilizer of the present invention is
A plurality of the optical fibers are included.

  By combining a plurality of optical fibers, it becomes possible to irradiate necessary and sufficient ultraviolet rays over a wider range.

  Here, the ultraviolet rays generated by one ultraviolet ray generator may be distributed to a plurality of optical fibers, or a corresponding ultraviolet ray generator may be provided for each optical fiber.

(7) The present invention
An ultraviolet ray generating unit that is connected to the power supply unit and generates ultraviolet rays by electric power supplied from the power source;
An optical fiber that is connected to the ultraviolet ray generation unit and propagates ultraviolet rays generated by the ultraviolet ray generation unit;
The optical fiber is
It includes a core through which ultraviolet light passes and a clad formed on the film around the core, and is set in a bent state at at least one or more locations, and is sterilized by ultraviolet rays emitted from the bent portion. Features.

  The ultraviolet ray generator can be constituted by, for example, an ultraviolet lamp.

  An optical fiber is composed of a core and a clad having different refractive indexes of light. Here, the core is a light guide portion of an optical fiber designated by a high refractive index region, and the clad is formed in a film shape around the core and has a lower refractive index than the core.

  The optical fiber may be a clad optical fiber (for example, a step index optical fiber) in which the refractive index changes discontinuously in the radial direction of the fiber and transmits light by total reflection. For example, a graded index optical fiber).

  The material of the optical fiber may be glass, plastic, or other materials.

  Here, by bending the optical fiber formed in a straight or stick shape, ultraviolet rays are emitted from the bent portion.

  One place or a plurality of places may be bent.

  The power supply unit may be a DC power supply or an AC power supply. Moreover, a “portable type” such as a battery or a rechargeable battery may be used, or a “installation type” in which a cord is inserted from the outside may be used.

  According to the present invention, since it is possible to radiate ultraviolet rays from a bent portion and use it for sterilization and disinfection with a simple configuration of bending an optical fiber formed in a straight or stick shape, it can be realized at low cost.

  Further, according to the present invention, ultraviolet rays can be irradiated without generating heat.

(8) The optical fiber sterilizer of the present invention is
The connection part between the optical fiber and the ultraviolet ray generator includes means for changing the direction of the axis of the optical fiber.

  According to the present invention, since the direction of the axis of the optical fiber can be changed, the direction of the axis can be changed according to the application.

(9) The optical fiber sterilizer of the present invention is
The plurality of optical fibers are arranged radially.

(10) The optical fiber sterilizer of the present invention is
The plurality of optical fibers are arranged in parallel in one row.

(11) The optical fiber sterilizer of the present invention is
The plurality of optical fibers are arranged on a panel.

(12) The optical fiber sterilizer of the present invention is
The ultraviolet ray generator is
It includes a plurality of light sources that generate ultraviolet rays having different wavelengths.

  Ultraviolet rays having different wavelengths may be used in combination, or may be switched for use.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

  In addition, this Embodiment demonstrated below does not limit the content of this invention described in the claim at all.

1. Optical Fiber Sterilization / Disinfection Device FIGS. 1A and 1B are diagrams for explaining the configuration of the optical fiber sterilization device of the present embodiment.

  As shown in FIG. 1A, an optical fiber sterilization apparatus 10 according to the present embodiment is connected to a power supply unit 40 and generates an ultraviolet ray by electric power supplied from the power supply, and the ultraviolet ray generation unit. And an optical fiber 20 that propagates ultraviolet rays generated by the ultraviolet ray generator.

Here, the optical fiber 20 includes a core (inner layer) that transmits ultraviolet rays, and a clad (outer layer) that has a refractive index different from that of the core and is formed on the film around the core.
The clad has an exposed portion for exposing a part of the core and leaking ultraviolet rays to the outside, and can be sterilized and disinfected by the ultraviolet rays leaking from the exposed portion.

  The power supply unit 40 may be a DC power supply or an AC power supply. Moreover, a “portable type” such as a battery or a rechargeable battery may be used, or a “installation type” in which a cord is inserted from the outside may be used.

  In addition, if a timer is provided in the power supply unit 40, “setting of irradiation start and end times” and “setting of appropriate irradiation time” suitable for the purpose of sterilization can be performed.

  In a configuration using ultraviolet light sources having different wavelengths, a timer may be set to switch the ultraviolet light sources having different wavelengths.

  Furthermore, if a voltage / current variableer supplied by the power supply unit 40 is provided, the “ultraviolet ray irradiation intensity” can be adjusted, and more appropriate ultraviolet ray irradiation can be performed.

  The material of the optical fiber 20 may be glass or plastic. The optical fiber 20 has the property that light traveling through the core (inner layer) part is totally reflected inside the cladding (outer layer), and therefore reaches far. For this reason, there is a possibility that the clad may be damaged, or if the fiber itself bends greatly, light leaks or attenuates, and the light cannot be transmitted well. Therefore, it is preferable to use the optical fiber without bending (in a straight line state).

  In this embodiment, by exposing a part of the core (inner layer) from the clad (outer layer) of the optical fiber with holes or grooves, it becomes possible to easily irradiate ultraviolet rays over a wide range. By adjusting the “hole size, number, spacing, position”, “number of grooves, angle, width”, etc., it becomes possible to irradiate ultraviolet rays according to the purpose.

On the other hand, many types of optical fibers have been produced, ranging from thin fibers having a diameter of 1 mm or less to many times thicker. Furthermore, the combination of the diameters of optical fibers enables sterilization and disinfection according to the application.

  Further, as shown in FIG. 1B, a plurality of optical fibers may be included. At this time, the light generated by one ultraviolet ray generator may be distributed to a plurality of optical fibers, or a plurality of ultraviolet ray generators may be provided to generate one ultraviolet ray corresponding to each optical fiber. You may make it have a part.

  2A and 2B are diagrams for explaining a case where an exposed portion is formed by making a hole in a clad of an optical fiber.

  As shown in FIG. 2A, holes 110-1 to 110-12 are made in the clad of the optical fiber 100. Then, as shown in FIG. 2B, a part of the core (inner layer of optical fiber) 160 is exposed from a hole (for example, 130 or 140) formed in the clad (outer layer of optical fiber) 150, and ultraviolet rays are emitted from the exposed portion. It can be used for sterilization and disinfection.

  Further, by devising the shape of the hole in the clad (outer layer) 150 of the optical fiber 100, the range 120 in which the ultraviolet ray can be irradiated can be adjusted, and the ultraviolet ray can be irradiated in the aimed direction. For example, as shown in FIG. 2B, the shape of the hole may be a cylindrical shape 140 or a conical shape 130. When the cone 130 is used, the ultraviolet irradiation range 120-1 is increased by increasing the angle θ around the apex of the cross section of the cone, and the ultraviolet irradiation range 120-1 is decreased by decreasing the angle θ. be able to.

  Although ultraviolet rays themselves generate active oxygen, when they are applied to titanium oxide or an alloy of platinum, active oxygen is further generated, increasing the ability to destroy the substance and killing power. Therefore, as shown in FIG. 15, it is possible to apply titanium oxide or a platinum compound to the flange 170 or the bottom 172 of the hole 110 of the optical fiber to further improve the performance.

  FIGS. 3A and 3B are diagrams for explaining the case where the exposed portion is formed as a lateral groove in which the core is exposed by removing the clad of the optical fiber along the outer periphery with a predetermined width and a predetermined length. is there.

  As shown in FIG. 3A, lateral grooves 210-1 to 210-11 are provided in the clad of the optical fiber 200 so as to be perpendicular to the axial direction 202 of the optical fiber 200.

  Then, as shown in FIG. 3B, a part of the core (inner layer) 260 is exposed from the lateral groove (for example, 230) provided in the clad (outer layer) 250 of the optical fiber 200, and ultraviolet rays are emitted from the exposed portion. Can be used for sterilization.

  Here, the degree of emission of ultraviolet rays can be adjusted according to the spacing between the lateral grooves. Therefore, an optimal lateral groove may be provided according to the application of sterilization irradiation.

  Also, the degree of UV emission can be adjusted according to the length of the lateral grooves and the location of the lateral grooves.

  For example, as shown in FIG. 3B, a lateral groove 230 may be provided so as to go around the clad (outer layer) of the optical fiber. In this way, ultraviolet rays can be emitted in the direction of 360 degrees around the outer periphery of the optical fiber.

  Further, the ultraviolet irradiation range around the groove can be adjusted by the angle θ when a part of the clad is cut out as the horizontal groove.

  FIG. 4 is a diagram for explaining the width and length (angle) of the lateral groove and the irradiation range of ultraviolet rays.

  For example, as shown in FIG. 4, a lateral groove 240 may be formed in a part of the clad (outer layer) 250 of the optical fiber. If it does in this way, an ultraviolet-ray can be emitted to the predetermined range 220 around an optical fiber.

  Here, the irradiation range of the ultraviolet rays can be adjusted by appropriately setting the width l1 and the length l2 of the lateral grooves.

  Although ultraviolet rays themselves generate active oxygen, when they are applied to titanium oxide or an alloy of platinum, active oxygen is further generated, increasing the ability to destroy the substance and killing power. Accordingly, as shown in FIGS. 16A and 16B, titanium oxide or a platinum compound is applied to the flange 270, the bottom 272, and the inner wall 274 of the clad 230 of the optical fiber to further improve the performance. Good.

  FIGS. 5A to 5D illustrate the case where the exposed portion is formed as a lateral groove in which the core is exposed by removing the clad of the optical fiber by a predetermined width and a predetermined length along the axial direction. FIG.

  As shown in FIG. 5A, a longitudinal groove 310 having a predetermined width l3 and a predetermined length l4 is formed in the clad of the optical fiber 300 along the axial direction 302 of the optical fiber 302.

  Then, as shown in FIG. 5B, a part of the core (inner layer) 360 is exposed from a longitudinal groove (for example, 330) formed in the clad (outer layer) 350 of the optical fiber 300, and ultraviolet rays are emitted from the exposed portion. (See 320), so it can be used for sterilization.

  Here, when the optical fiber is arranged in the optical fiber sterilization device or when the optical fiber sterilization device is set, the direction in which the ultraviolet rays are irradiated can be adjusted by adjusting the direction in which the transverse groove is directed.

  Here, the ultraviolet emission position can be adjusted by the position where the lateral groove is provided (for example, the position in the axial direction). Therefore, a longitudinal groove may be provided at an optimum position according to the application of sterilization irradiation.

  For example, if a vertical groove 332 is provided as shown in FIG. 5C, the vicinity of 322 is an ultraviolet emission position, and if a vertical groove 334 is provided as shown in FIG. 5D, the vicinity of 324 is an ultraviolet emission. Position.

  Although ultraviolet rays themselves generate active oxygen, when they are applied to titanium oxide or an alloy of platinum, active oxygen is further generated, increasing the ability to destroy the substance and killing power. Therefore, as shown in FIG. 17, titanium oxide or a platinum compound may be applied to the flange 370 or the bottom 372 of the longitudinal groove 230 of the optical fiber to further improve the performance.

  Further, as shown at 380, titanium oxide or a platinum compound may be spirally applied along the outer periphery of the optical fiber.

  FIG. 13 is a view for explaining a case where the exposed portion is formed as a spiral groove when the clad of the optical fiber is spirally taken with a predetermined width and a predetermined length along the outer periphery to expose the core. FIG.

  As shown in the figure, a groove 910 having a predetermined width l5 and a predetermined length is formed in the clad of the optical fiber 900 along the outer periphery of the optical fiber.

  In this way, a part of the core (inner layer) 960 is exposed from the groove 930 on the spiral formed in the clad (outer layer) 950 of the optical fiber 900, and ultraviolet rays are emitted from the exposed portion, so that it is used for sterilization. be able to. Moreover, since it is possible to irradiate ultraviolet rays around the optical fiber in the direction of 360 °, 360 ° around the optical fiber can be sterilized and disinfected with one optical fiber.

  FIGS. 6A and 6B are examples of an optical fiber sterilization apparatus in which a plurality of optical fibers are combined and arranged on a panel.

  For example, as shown in FIG. 6A, a panel-type optical fiber sterilizing / disinfecting apparatus 400 is configured by arranging an ultraviolet ray generator 410 and a plurality of optical fibers 420-1, 420-2, 420-3,. You may make it do.

  Here, as shown in 420-1, 420-2, 420-3, for example, optical fibers having different positions in which the longitudinal grooves are provided (shining fibers having different ultraviolet irradiation positions) may be combined. The irradiation range of ultraviolet rays can be adjusted by the combination pattern.

  When a plurality of optical fibers are combined, the plurality of optical fibers may be arranged in parallel in a row on the panel.

  Further, the ultraviolet ray generator may use a fluorescent lamp type light source 410 as shown in FIG. 6A, or may use a fluorescent lamp type light source 412 as shown in FIG. 6A.

  Further, titanium oxide or a platinum compound may be applied to the panel 430 to further improve the performance.

  FIG. 7 is a diagram for explaining the ultraviolet ray generator.

  The ultraviolet ray generator 30 includes an ultraviolet light source 32, a reflecting plate, and a reflecting mirror 34. Here, the reflecting plate and the reflecting mirror 34 are installed so that the reflected ultraviolet rays are collected on the cross section of the optical fiber, and the ultraviolet rays emitted from the ultraviolet light source 32 are guided toward the optical fiber 20 by the reflecting plate and the reflecting mirror 34.

  The ultraviolet light source can be composed of, for example, an ultraviolet lamp.

  Here, there are three types of ultraviolet rays: near ultraviolet rays (320 nm to 400 nm) → UV-A, ultraviolet rays (280 nm to 320 nm) → UV-B, far ultraviolet rays (10 nm to 280 nm) → UV-C.

  The ultraviolet ray generator may be configured to generate any one of these types of ultraviolet rays, or may be generated by combining or switching a plurality of types of ultraviolet rays.

  FIG. 18 is a view showing an ultraviolet ray generator having a plurality of ultraviolet light sources. The ultraviolet light source 1 (32-1) and the ultraviolet light source 2 (32-2) are ultraviolet light sources that generate ultraviolet rays having different wavelengths, and may be combined or switched to generate ultraviolet rays. The number of light sources is not limited to two, and a plurality of light sources may be provided depending on the difference in wavelength.

  Of these, UV-C has the strongest bactericidal activity and is normally absorbed by the ozone layer in the sky and does not reach the ground. Since UV-C is effective, UV-C may be generated by the ultraviolet ray generator. In this way, it is effective for controlling insects such as cockroaches and mites that live by avoiding ultraviolet rays of this wavelength.

  In addition, if the wavelength of the ultraviolet rays sent into the optical fiber is 185 nm, the ultraviolet rays of this wavelength generate “ozone” in the air, so that the “pheromones” secreted by the cockroaches to communicate with each other will be decomposed. Cockroaches are no longer approaching. Therefore, ultraviolet rays having a wavelength of 185 nm may be generated by the ultraviolet ray generator.

  FIG. 8 is a diagram for explaining the connection portion.

  You may make it provide the flexible joints 52-1 to 52-3 in the connection part 50 of the one or several optical fibers 20-1 to 20-3 and the ultraviolet-ray generation part 30. FIG. By doing in this way, the angle adjustment of the optical fibers 20-1 to 20-3 becomes free.

  FIG. 9 is a diagram for explaining another example of the connecting portion.

  The connecting part 50 between one or a plurality of optical fibers 20-1 to 20-5 and the ultraviolet ray generating part 30 may be curved. For example, it may be a hemispherical surface as shown in FIG. 9 or a full spherical surface (not shown).

  If the connection part 50 is formed as a curved surface in this way, it is easy to connect optical fibers in multiple directions at the same time.

  FIG. 10 is a diagram for explaining another configuration example of the optical fiber of the optical fiber sterilization apparatus according to the present embodiment. As shown in FIG. 10, the optical fiber 600 may be bent and set in the optical fiber sterilization apparatus. If it does in this way, since the ultraviolet-ray leaks outside from the bent part 610-1 to 610-11, it can be used for sterilization.

  It should be noted that titanium oxide or a platinum compound may be applied around the light piper 600, or a surface on which titanium oxide or a platinum compound is applied may be further improved.

  FIGS. 11A to 11D are diagrams showing an application example of the optical fiber sterilization apparatus of the present embodiment to a washing machine.

  FIG. 11A shows an optical fiber sterilization device 710 of this embodiment including one optical fiber 720, FIG. 11B is a cross-sectional view of the exposed portion of the optical fiber, and FIG. FIG. 11D is a plan view of a washing machine 730 incorporating the optical fiber sterilizing / disinfecting apparatus 720 of the present embodiment, and FIG. 11D is a side view of the washing machine 730 incorporating the optical fiber sterilizing / disinfecting apparatus 720 of the present embodiment. is there.

  As shown in FIG. 11 (B), when a lateral groove (a lateral groove cut out of the outer circumference corresponding to α = 90 degrees) having a length of ¼ of the outer circumference of the optical fiber is inserted in the clad (outer layer) of the optical fiber, The surrounding 90 degree range can be irradiated with ultraviolet rays.

  And as shown in FIG.11 (D), as shown in FIG.11 (D), the washing tub 740 is shown by arrange | positioning the optical fiber sterilization apparatus 710-1 to 710-4 of this Embodiment in the four corners of a washing machine. Can be irradiated with ultraviolet rays.

  For example, by arranging the sheet-like optical fiber sterilizing / disinfecting apparatus shown in FIG. 6 on the bottom part inside the washing machine, the bottom part of the washing tub 740 can be uniformly irradiated with ultraviolet rays.

  Here, as far ultraviolet rays (10 nm to 280 nm) → UV-C is effective as the ultraviolet rays, UV-C may be generated in the ultraviolet ray generating section. In this way, it is effective for controlling insects such as cockroaches and mites that live by avoiding ultraviolet rays of this wavelength.

  In addition, if the wavelength of the ultraviolet rays sent into the optical fiber is 185 nm, the ultraviolet rays of this wavelength generate “ozone” in the air, so that the “pheromones” secreted by the cockroaches to communicate with each other will be decomposed. Cockroaches are no longer approaching. Therefore, ultraviolet rays having a wavelength of 185 nm may be generated by the ultraviolet ray generator.

  The incorporation of the optical fiber sterilizing / disinfecting apparatus of the present embodiment is not limited to an electric washing machine, and may be a home appliance such as a dishwasher, a refrigerator, a range, a mixer, and an air conditioner, or may be incorporated other than an electric product.

  FIG. 12 is a diagram showing an application example of the optical fiber sterilization device of the present embodiment to a house.

  For example, by disposing the optical fiber sterilization device of this embodiment around the attic 832, the ceiling 838, the under floor 834, and the unit bath 836 of the building or house 830, the optical fiber sterilization device of this embodiment can be sterilized. it can.

  Here, as far ultraviolet rays (10 nm to 280 nm) → UV-C is effective as the ultraviolet rays, UV-C may be generated in the ultraviolet ray generating section. In this way, it is effective for controlling insects such as cockroaches and mites that live by avoiding ultraviolet rays of this wavelength.

  In addition, if the wavelength of the ultraviolet rays sent to the optical fiber is 185 nm, the ultraviolet rays of this wavelength generate “ozone” in the air, so that the “pheromones” secreted by cockroaches to communicate with each other will be decomposed. Cockroaches are no longer approaching. Therefore, ultraviolet rays having a wavelength of 185 nm may be generated by the ultraviolet ray generator.

  FIG. 19 is a diagram illustrating an example in which the optical fiber sterilization apparatus of the present embodiment is installed in a narrow portion near a wall, such as furniture or kitchen furniture.

  By placing the center 850 of the optical fiber sterilizer at the corner of the wall and the three optical fibers 860-1, 860-2 and 860-3 along the three axes orthogonal to each other at the corner of the wall, Sterilization and disinfection of the attic, under the floor, and the back of furniture and furniture can be performed.

  Here, as far ultraviolet rays (10 nm to 280 nm) → UV-C is effective as the ultraviolet rays, UV-C may be generated in the ultraviolet ray generating section. In this way, it is effective for controlling insects such as cockroaches and mites that live by avoiding ultraviolet rays of this wavelength.

  In addition, if the wavelength of the ultraviolet rays sent to the optical fiber is 185 nm, the ultraviolet rays of this wavelength generate “ozone” 870 in the air, so that the “pheromone” secreted by cockroaches to keep in touch with each other will be decomposed. , Cockroaches will not get close. Therefore, ultraviolet rays having a wavelength of 185 nm may be generated by the ultraviolet ray generator.

2. Portable Pest Control Device Next, a portable pest control device realized using the optical fiber sterilization device of the present embodiment will be described.

  While there are creatures with “negative phototacticity” that avoid ultraviolet rays, there are many creatures with “positive phototacticity” that gather in ultraviolet rays. In particular, many insects have positive phototactic properties, and insect traps and insecticides using this property have been developed.

  The mechanism is that a metal wire with a high voltage of 1000 V to 1500 V is stretched around the ultraviolet lamp, and insects that come into contact with this wire are electrocuted.

  However, this apparatus has a drawback in that an ultraviolet lamp must use a household power source of 100V or a vehicle power source of 12V. It is therefore impossible to carry it anywhere and anytime.

  On the other hand, fully portable “catchers” and “insecticides” that apply a voltage of 1000 V or more using dry batteries have been developed. For example, a tennis racket type seems to be suitable for catching flying insects at first glance by swinging, but in order to process many insects by keeping them in the form of chasing after flying or running away insects It takes a lot of effort and is not necessarily an efficient method.

  FIG. 14 is a diagram for explaining the portable pest control apparatus of the present embodiment.

  A simple pest control apparatus 500 according to the present embodiment is connected to a portable power source unit 510, and generates an ultraviolet ray by power supplied from the power source. The ultraviolet ray generator is not shown, and is connected to the ultraviolet ray generator. An optical fiber 520 for propagating ultraviolet rays generated in the above, a portable power supply unit 510, a high voltage generation unit (not shown) that generates a high voltage by power supplied from the power supply, and a high voltage connected to the high voltage generation unit. Including a high-voltage conductive portion composed of conductive wires 530-1, 530-2, and 530-3.

  The grip portion 560 is a portion that the user has (holds) during use, and a power source portion 310, a city ultraviolet ray generator and a high voltage generator (not shown) may be incorporated therein.

The optical fiber 520 includes a core through which ultraviolet rays pass and a clad formed on the coating around the core. The clad has an exposed portion for exposing a part of the core and emitting ultraviolet rays to the outside. The high-voltage conductive part is disposed so that the conductive wires 530-1, 530-2, and 530-3 pass around or in the vicinity of the optical fiber 520 or the exposed part, and collects ultraviolet rays emitted from the exposed part. The optical fiber 520 may be configured as an assembly of a plurality of optical fibers so that the insects can easily come into contact with a conductive wire with a high voltage.

  By combining a plurality of optical fibers, it becomes possible to irradiate necessary and sufficient ultraviolet rays over a wider range.

  Here, the ultraviolet rays generated by one ultraviolet ray generator may be distributed to a plurality of optical fibers, or a corresponding ultraviolet ray generator may be provided for each optical fiber.

  The ultraviolet ray generator can be constituted by, for example, an ultraviolet lamp.

  The optical fiber 520 includes a core and a clad having different light refractive indexes. Here, the core is a light guide portion of an optical fiber designated by a high refractive index region, and the clad is formed in a film shape around the core and has a lower refractive index than the core.

  The optical fiber 520 may be a clad optical fiber (for example, a step index optical fiber) that discontinuously changes its refractive index in the radial direction of the fiber and transmits light by total reflection. It may be a converging optical fiber that transmits light, for example, a graded index optical fiber).

  The material of the optical fiber may be glass, plastic, or other materials.

  Here, the optical fiber is formed in a straight stick shape, and an exposed portion is provided.

  There may be one or more exposed portions. For example, it may be formed continuously in a groove shape or may be formed discontinuously.

  The exposed portion can be formed by, for example, making a cut, scratching, cutting, making a hole, making a groove, or making a cut in the outer periphery of the optical fiber.

  In this case, only the clad part may be cut, scratched, cut out, perforated or grooved, or a part of the clad and core may be cut, scratched or cut off. It is also possible to make a hole or make a groove.

  The power source unit 510 can use a portable power source such as a dry battery or a rechargeable battery.

  The high voltage generator can be realized by a transformer or the like.

  The conductive wire constituting the high voltage conductive portion can be realized by, for example, a metal wire or a carbon wire.

  According to the present invention, with a simple configuration in which an exposed portion is provided in the clad, ultraviolet rays are emitted from the exposed portion, the light emitted from the optical fiber collects the insects, and the gathered insects are in contact with the conductive wire subjected to high voltage And electrocuted.

  Using an optical fiber requires very little power, so a dry cell power supply can be used. In addition, because of its light weight, it can be used anywhere from outdoor to indoor.

  Further, a protector 540 is provided around the conducting wire of the high voltage conducting unit.

  If it does in this way, safety can be ensured so that a person may not touch the conduction wires 530-1, 530-2, and 530-3 of a high voltage conduction part accidentally.

  Note that the switch 512 may be energized only when it is pressed, a switch that is turned on or off, or a combination of both.

  20A and 20B are diagrams for describing another example of the portable pest control apparatus of the present embodiment.

  20A and 20B, a portable pest control device 500′-1 includes a main body frame 560 that forms an outer frame of a predetermined virtual surface (here, a rectangular surface), and a gripping unit connected to the main body frame. 550.

The gripping unit 550 includes a power source unit, an ultraviolet ray generation unit, a high voltage generation unit, and the like (not shown).
See
A plurality of optical fibers 520-1, 520-2,... Are arranged at predetermined intervals on a predetermined virtual surface inside the main body frame 560. The plurality of optical fibers 520-1, 520-2,... May be arranged inside the main body frame 560 in parallel at a predetermined interval, for example, may be arranged in a lattice shape, or a fan shape It may be arranged radially so as to form.

  The main body frame may be rectangular (including a rectangle or square), a fan shape, or a circle (an ellipse or a shape like a tennis racket).

  The conductive wires 530-1, 530-2,... Arranged so as to pass around or in the vicinity of the optical fibers 520-1, 520-2,. As shown in FIG. 20, the optical fibers 520-1, 520-2,... May be arranged in parallel, for example, as shown in FIG. And may be arranged orthogonally.

  In this way, pests can be collected more efficiently.

  Although the preferred embodiments to which the present invention is applied have been described above, the application of the present invention is not limited to the above-described embodiments.

  The optical fiber sterilization apparatus of the present embodiment can be used for sterilization of various places and objects. The shape and size of the optical fiber sterilization / disinfection apparatus according to this embodiment can be appropriately determined according to the sterilization / disinfection target.

  For example, the optical fiber sterilizing / disinfecting apparatus according to the present embodiment may be an object for sterilizing furniture, machines, equipment, devices, etc., and in this case, a shape suitable for being arranged in these “gap” and “space”. It is better to design it to a size.

  Further, for example, the optical fiber sterilizing / disinfecting apparatus of the present embodiment may be a device for sterilizing the inside and inside of clothing, the inside of shoes, and the inside of tools used for sports and housework. For example, the optical fiber sterilizing / disinfecting apparatus of this embodiment may be attached to a hanger for hanging clothes.

  Further, for example, the optical fiber sterilizing / disinfecting apparatus according to the present embodiment may be an apparatus for sterilizing / disinfecting the interior or interior space of animals and plants (may be humans).

  Further, for example, the optical fiber sterilization device of the present embodiment may be a device for performing sterilization inside a tube or piping.

  Further, for example, the optical fiber sterilization device of the present embodiment may be a device for sterilizing tableware including pots, teapots, baby bottles and the like.

  Further, for example, the optical fiber sterilization device of the present embodiment may be a device for sterilizing a kitchen, a kitchen, or a cooking utensil.

  Further, for example, the optical fiber sterilization device of the present embodiment may be a device for sterilizing medical instruments and sanitary tools.

  Further, for example, the optical fiber sterilization apparatus of the present embodiment can be used for sterilizing water by placing it in water, and ozone water can also be produced.

FIGS. 1A and 1B are diagrams for explaining the configuration of the optical fiber sterilization apparatus of the present embodiment. 2A and 2B are diagrams for explaining a case where an exposed portion is formed by making a hole in a clad of an optical fiber. FIGS. 3A and 3B are diagrams for explaining the case where the exposed portion is formed as a lateral groove in which the core is exposed by removing the clad of the optical fiber along the outer periphery with a predetermined width and a predetermined length. is there. FIG. 4 is a diagram for explaining the width and length (angle) of the lateral groove and the irradiation range of ultraviolet rays. FIGS. 5A to 5D illustrate the case where the exposed portion is formed as a lateral groove in which the core is exposed by removing the clad of the optical fiber by a predetermined width and a predetermined length along the axial direction. FIG. FIGS. 6A and 6B are examples of an optical fiber sterilization apparatus in which a plurality of optical fibers are combined and arranged on a panel. FIG. 7 is a diagram for explaining the ultraviolet ray generator. FIG. 8 is a diagram for explaining the connection portion. FIG. 9 is a diagram for explaining another example of the connecting portion. FIG. 10 is a diagram for explaining another configuration example of the optical fiber of the optical fiber sterilization apparatus according to the present embodiment. FIGS. 11A to 11D are diagrams showing an application example of the optical fiber sterilization apparatus of the present embodiment to a washing machine. FIG. 12 is a diagram showing an application example of the optical fiber sterilization device of the present embodiment to a house. FIG. 13 is a view for explaining a case where the exposed portion is formed as a spiral groove when the clad of the optical fiber is spirally taken with a predetermined width and a predetermined length along the outer periphery to expose the core. FIG. FIG. 14 is a diagram for explaining the portable pest control apparatus of the present embodiment. FIG. 15 is a view showing a configuration for further improving the performance by applying titanium oxide or a platinum compound to the ridge or bottom of the hole of the optical fiber. FIG. 16 is a diagram showing a configuration for further improving the performance by applying titanium oxide or a platinum compound to the ridges and bottoms of the lateral grooves of the optical fiber. FIG. 17 is a diagram showing a configuration in which titanium oxide or a platinum compound is applied to the ridges or bottoms of the longitudinal grooves of the optical fiber to further improve the performance. FIG. 18 is a view showing an ultraviolet ray generator having a plurality of ultraviolet light sources. FIG. 19 is a diagram illustrating an example in which the optical fiber sterilization apparatus of the present embodiment is installed in a narrow portion near a wall, such as furniture or kitchen furniture. 20A and 20B are diagrams for describing another example of the portable pest control apparatus of the present embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Optical fiber sterilizer 20 Optical fiber 30 Ultraviolet light generation part 32 Ultraviolet light source 34 Reflector, reflector 40 Power supply part 50 Connection part 52-1 to 52-3 Flexible joint 100 Optical fiber 110 Hole 150 Cladding 160 Core 200 Optical fiber 210 Horizontal groove 250 Cladding 260 Core 300 Optical fiber 310 Vertical groove 350 Cladding 360 Core 400 Optical fiber sterilization device 410 Ultraviolet generation unit 412 Ultraviolet generation unit 420-1 to 420-3 Optical fiber 430 Panel 500 Portable pest control device 510 Power supply unit 512 Switch 520 Optical fiber 530-1, 530-2, 530-3 Conductor wire 540 Protector 600 Optical fiber 610-1 to 610-11 Bent part of optical fiber

Claims (12)

An ultraviolet ray generating unit that is connected to the power supply unit and generates ultraviolet rays by electric power supplied from the power source;
An optical fiber that is connected to the ultraviolet ray generation unit and propagates ultraviolet rays generated by the ultraviolet ray generation unit;
The optical fiber is
Including a core through which ultraviolet rays pass and a clad formed on the film around the core;
An optical fiber sterilizing / disinfecting apparatus according to claim 1, wherein the clad is formed with an exposed portion for exposing a part of the core and radiating ultraviolet rays to the outside, and sterilizing and disinfecting by the ultraviolet rays emitted from the exposed portion. In claim 1,
The exposed portion is
An optical fiber sterilization apparatus, wherein the optical fiber sterilization apparatus is formed as one or a plurality of holes provided in the clad of the optical fiber. In any one of Claims 1 thru | or 2.
The exposed portion is
An optical fiber sterilizing / disinfecting apparatus, wherein the optical fiber clad is formed as a lateral groove having a predetermined width and a predetermined length along the outer periphery to expose the core. In any one of Claims 1 thru | or 3,
The exposed portion is
An optical fiber sterilizing / disinfecting apparatus, wherein the optical fiber clad is formed as a lateral groove having a predetermined width and a predetermined length along the axial direction to expose the core. In any one of Claims 1 thru | or 4,
The exposed portion is
An optical fiber sterilizing / disinfecting apparatus, wherein the optical fiber clad is formed as a spiral groove when the core is exposed by spirally taking a predetermined length and a predetermined width along the outer periphery. An ultraviolet ray generating unit that is connected to the power supply unit and generates ultraviolet rays by electric power supplied from the power source;
An optical fiber that is connected to the ultraviolet ray generation unit and propagates ultraviolet rays generated by the ultraviolet ray generation unit;
The optical fiber is
It includes a core through which ultraviolet light passes and a clad formed on the film around the core, and is set in a bent state at at least one or more locations, and is sterilized by ultraviolet rays emitted from the bent portion. An optical fiber sterilization device. In any one of Claims 1 thru | or 6.
An optical fiber sterilization apparatus comprising a plurality of the optical fibers. In any one of Claims 1 thru | or 7,
An optical fiber sterilizing / disinfecting apparatus characterized in that means for changing the direction of the axis of the optical fiber is included in the connecting portion between the optical fiber and the ultraviolet ray generator. In any one of Claims 1 thru | or 8.
An optical fiber sterilizing / disinfecting apparatus, wherein the plurality of optical fibers are arranged radially. In any one of Claims 1 thru | or 9,
An optical fiber sterilizing / disinfecting apparatus, wherein the plurality of optical fibers are arranged in parallel in one row. In any one of Claims 1 thru | or 10.
An optical fiber sterilization apparatus, wherein the plurality of optical fibers are arranged on a panel. In any one of Claims 1 thru | or 11,
The ultraviolet ray generator is
An optical fiber sterilization device comprising a plurality of light sources for generating ultraviolet rays of different wavelengths.

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