JP5197550B2 - UV sterilizer - Google Patents

Description

  The present invention relates to an apparatus for sterilizing bacteria floating in the air and bacteria adhering to a ceiling, floor, wall, etc. by ultraviolet irradiation.

  Ultraviolet irradiation is known as a means for killing bacteria floating in the air. Sterilization by chemical treatment or the like has problems such as chemical residue and generation of harmful substances, but sterilization by ultraviolet irradiation does not cause these problems. Therefore, sterilization by ultraviolet irradiation is suitable for indoor sterilization of food factories, pharmaceutical factories, cosmetic factories, hospitals and the like. As a sterilization apparatus using ultraviolet irradiation, for example, a so-called sterilization lamp that is directly attached to the ceiling or suspended is known.

  However, since the ultraviolet light diffuses in the germicidal lamp, the germicidal effect can be obtained only near the ultraviolet irradiation lamp, and it cannot be said that a sufficient germicidal effect can be obtained in the whole room.

  As an apparatus for solving this problem, for example, in Patent Document 1, a cycle of sucking indoor air into the apparatus, irradiating the interior with ultraviolet rays, and releasing sterilized air into the room is repeated. Thus, an apparatus for disinfecting air in the entire room is disclosed.

JP-A-2005-090831

  However, in the apparatus disclosed in Patent Document 1, when there is a place where air flows in the room, all air in the room may not circulate through the apparatus. Even if all the air circulates through the device, the air released into the room after sterilization mixes with the unsterilized air, so it takes a long time to replace the entire indoor space with the sterilized air. It will be necessary.

  Therefore, an object of the present invention is to provide an ultraviolet sterilizer capable of sterilizing indoor air reliably and efficiently.

  The ultraviolet sterilizer according to the present invention includes a light source that condenses and emits ultraviolet rays generated by an ultraviolet lamp in a beam shape, a first hollow tube that directly or indirectly introduces ultraviolet rays emitted from the light source, A first reflecting member that is fixed in position relative to the hollow tube and that reflects ultraviolet rays that have passed through the first hollow tube at a right angle; and a first reflecting member that can be rotated about the longitudinal axis of the first hollow tube. One rotation drive mechanism, a second hollow tube through which ultraviolet light reflected by the first reflecting member passes, a position relative to the second hollow tube is fixed, and ultraviolet light that has passed through the second hollow tube is reflected at right angles Synchronizing with the rotation of the second reflecting member and the first reflecting member, the second reflecting member revolves around the longitudinal axis of the first hollow tube while rotating around the longitudinal axis of the second hollow tube. The second rotational drive mechanism to drive and the ultraviolet rays reflected by the second reflecting member are emitted. Comprising: a detection section, and by actuating the first rotating mechanism and the second rotation drive mechanism while generating ultraviolet rays UV lamp, to scan the space preset by the ultraviolet rays emitted from the emitting portion.

  According to the present invention, since the space is scanned with the ultraviolet rays reflected by the second reflecting member that rotates around the axis orthogonal to the revolution axis while revolving, the air flow can be detected in a short time regardless of the presence or absence of the air flow. The inside of the space can be sterilized. In addition, since the ultraviolet rays also scan the surfaces such as walls, ceilings, and floors that partition the space, bacteria attached to these surfaces can be sterilized.

It is a figure which shows an example of the ultraviolet sterilizer which concerns on this invention. It is a figure for demonstrating the application example of an ultraviolet sterilizer (1st Embodiment). It is a figure for demonstrating the application example of an ultraviolet sterilizer (1st Embodiment). It is a figure for demonstrating the application example of an ultraviolet sterilizer (2nd Embodiment). It is a figure for demonstrating the application example of an ultraviolet sterilizer (2nd Embodiment). It is a figure for demonstrating the application example of an ultraviolet sterilizer (3rd Embodiment). It is a figure for demonstrating the application example of an ultraviolet sterilizer (3rd Embodiment). It is a figure for demonstrating the application example of an ultraviolet sterilizer (4th Embodiment). It is a figure for demonstrating the application example of an ultraviolet sterilizer (4th Embodiment). It is a figure which shows the other example of the ultraviolet sterilizer which concerns on this invention. It is a figure for demonstrating the application example of an ultraviolet sterilizer (5th Embodiment). It is a figure for demonstrating the application example of an ultraviolet sterilizer (5th Embodiment).

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

  FIG. 1 is a diagram showing an example of an ultraviolet sterilizer according to an embodiment of the present invention.

  The ultraviolet sterilizer 100 includes a light source 1 that generates ultraviolet light, and an irradiation unit 2 that irradiates the entire space such as a room with ultraviolet light from the light source 1 as described later.

  The light source 1 includes a light source cover 7, a UV lamp 3, a curved mirror 4, a convex lens 5, and a concave lens 6 disposed in the light source cover 7.

  The light source cover 7 is a cylindrical member having one end open and a UV lamp 3 mounting portion at the other end. Hereinafter, the open side is the front end side, and the side where the UV lamp 3 is attached is the base end side.

  The UV lamp 3 is installed at an attachment portion on the base end side of the light source cover 7 so as to emit ultraviolet rays into the light source cover 7. The UV lamp 3 used here generates ultraviolet light having a wavelength of about 254 nm, which has the strongest sterilizing power among UV-C (short wave) known as ultraviolet light for sterilization.

  The curved mirror 4 is an umbrella-shaped member whose diameter increases from the proximal end side toward the distal end, and is installed so as to surround the UV lamp 3. The inner surface of the curved mirror 4 has a shape that reflects the ultraviolet rays emitted from the UV lamp 3 toward the convex lens 5. Since it is desirable that the inner surface of the curved mirror 4 has a higher ultraviolet reflectance, for example, aluminum is deposited on the inner surface of the curved mirror 4. In addition, it is not restricted to aluminum vapor deposition, For example, the curved mirror 4 itself may be formed with aluminum, and an inner surface may be grind | polished or electrolytically polished.

  A convex lens 5 is disposed on the distal end side of the curved mirror 4, and a concave lens 6 is disposed on the distal end side. The curvature of the convex lens 5 and the concave lens 6 is a so-called beam shape in which ultraviolet rays directly incident on the convex lens 5 from the UV lamp 3 and ultraviolet rays reflected and incident on the curved mirror 4 are translated with a certain irradiation width after passing through the concave lens 6. Set as follows.

  The irradiating unit 2 has passed through the changing unit 20, the introducing unit 8 that converts the traveling direction of the ultraviolet light, the changing unit 20 that converts the traveling direction of the ultraviolet light that has passed through the introducing unit 8. And a discharge unit 26 that changes the traveling direction of the ultraviolet rays and irradiates the air in the room or the like.

  The introduction portion 8 includes an introduction portion reflecting material 9 therein, and a first portion is formed so that beam-shaped ultraviolet rays emitted from the light source 1 are incident on the introduction portion reflecting material 9 at a portion facing the tip opening of the light source 1. The introduction hole 10 opens. The introduction portion 8 has a first emission hole 11 opened in a traveling direction portion of ultraviolet rays reflected by the introduction portion reflecting material 9.

  The introduction part reflecting material 9 is a plate-like member, and aluminum is vapor-deposited on the surface on the side where the ultraviolet rays are reflected, like the curved mirror 4. The introducing portion reflecting material 9 reflects the ultraviolet light that has entered the introducing portion 8 from the first introducing hole 10 toward the first emitting hole 11. In FIG. 1, the first introduction hole 10 and the first discharge hole 11 are opened on the surfaces orthogonal to each other, and the ultraviolet rays are incident from the direction orthogonal to the surface on which the first introduction hole 10 is opened. It is not limited to this. For example, ultraviolet light from the light source 1 is incident on the first introduction hole 10 from a direction having an inclination with respect to the normal line of the surface where the first introduction hole 10 opens (for example, an obliquely upward direction in FIG. 1). May be.

  The changing unit 20 is connected to the hollow first light guide tube 16 at a portion facing the first discharge hole 11 and communicates with the introduction unit 8 via the first light guide tube 16. In addition, the changing portion reflector 21 is fixed inside the changing portion 20 so as to change the traveling direction of the ultraviolet light incident on the changing portion 20 via the first light guide tube 16 in a direction substantially perpendicular to the changing portion 20. . And the 2nd light guide tube 22 is connected to the change part 20 so that the ultraviolet-ray reflected by the change part reflection material 21 may pass.

  That is, the ultraviolet rays that have passed through the first emission hole 11 are incident on the changing unit 20 through the first light guide tube 16, reflected by the changing unit reflector 21, and from the changing unit 20 through the second light guide tube 22. Released.

  In addition, the change part reflection material 21 is a plate-like member like the introduction part reflection material 9, and aluminum is vapor-deposited on the surface on the side where the ultraviolet rays are reflected.

  The first light guide tube 16 is rotatably supported in the through hole of the support member 15 via the first bearing 17 and the second bearing 18. A spur gear 14 is fixed to the outer peripheral portion of the portion of the first light guide tube 16 protruding from the support member 15 by press-fitting or the like. The spur gear 14 meshes with a pinion gear 13 fixed to the shaft of the motor 12. On the other hand, a first gear 19 is provided on the outer peripheral portion of the support member 15 on the changing portion 20 side. The first gear 19 may be formed integrally with the support member 15, or a ring-shaped gear formed separately may be fitted to the outer periphery of the support member 15.

  The discharge portion 26 is rotatably supported by the second light guide tube 22 via the third bearing 24 and the fourth bearing 25, and communicates with the changing portion 20 via the second light guide tube 22. . In addition, the emission part reflector 27 is disposed inside the emission part 26 so as to change the traveling direction of the ultraviolet light incident via the second light guide tube 22 in a direction substantially orthogonal to the emission part 26. The emission part 26 is provided with an emission hole 28 so that the ultraviolet light reflected by the emission part reflecting material 27 is emitted to the outside of the emission part 26. Therefore, the ultraviolet light that has entered the emission part 26 via the second light guide tube 22 is reflected by the emission part reflector 27 and emitted from the emission hole 28 to the outside of the emission part 26. The emitting part reflecting material 27 is also a plate-like member like the introducing part reflecting material 9 and the changing part reflecting material 21, and aluminum is vapor-deposited on the surface on the side where ultraviolet rays are reflected.

  A second gear 23 that meshes with the first gear 19 is provided on the outer periphery of the discharge portion 26. The first gear 19 and the second gear 23 are bevel gears. The second gear 23 may be formed integrally with the discharge portion 26, or a ring-shaped gear formed separately may be fitted to the outer periphery of the discharge portion 26.

  The portion of the support member 15 provided with at least the first gear 19, the portion of the discharge portion 26 provided with at least the second gear 23, and the changing portion 20 are covered with the second case 30. The portion of the discharge portion 26 that is not covered by the second case 30 is covered by the first case 29, and the discharge portion 26 communicates with the outside of the first case 29 through the discharge hole 28.

  When the motor 12 is driven in the irradiation unit 2 configured as described above, the driving force of the motor 12 is transmitted to the spar gear 14 via the pinion gear 13 and the first light guide tube 16 rotates around the axis. At this time, since the first light guide tube 16 is rotatably supported with respect to the support member 15, the support member 15 remains stopped without rotating.

  When the first light guide tube 16 rotates, the changer 20 connected to the first light guide tube 16 and the second light guide tube 22 connected to the changer 20 also rotate around the axis of the first light guide tube 16. As a result, the discharge portion 26 supported by the second light guide tube 22 also rotates around the axis of the first light guide tube 16.

  Further, the discharge portion 26 is engaged with the first gear 19 provided on the outer periphery of the support member 15 that is stopped, and the second gear 23 provided on the outer peripheral portion is rotatably supported by the second light guide tube 22. ing. For this reason, when the emitting part 26 rotates around the axis of the first light guide tube 16, it rotates around the axis of the second light guide tube 22.

  That is, when the motor 12 is driven, the discharge hole 28 revolves around the axis of the first light guide tube 16 while rotating around the axis of the second light guide tube 22.

  At this time, since the changing portion reflecting material 21 also rotates around the axis of the first light guide tube 16, the direction of the changing portion reflecting material 21 with respect to the introducing portion reflecting material 9 changes, but the introducing portion reflecting material 9 reflects the reflected ultraviolet light. Is arranged so as to be incident on the changing portion reflecting material 21, the ultraviolet light reflected by the introducing portion reflecting material 9 passes through the second light guide tube 22 and enters the changing portion reflecting material 21. Similarly, the changing portion reflecting material 21 and the emitting portion reflecting material 27 change the orientation of the emitting portion reflecting material 27 with respect to the changing portion reflecting material 21 by the rotation of the emitting portion 26, but the ultraviolet rays reflected by the changing portion reflecting material 21. Is reflected by the emitting portion reflecting material 27 and emitted from the emitting hole 28.

  Therefore, according to the irradiating unit 2, a circle having a radius of ultraviolet rays emitted from the emission hole 28 around the axial center of the second light guide tube 22 with the ultraviolet rays generated by the light source 1 is formed in the first light guide tube 16. The region formed by rotating around the axis can be scanned. Therefore, the above-described ultraviolet sterilizer 100 is installed on the ceiling or wall of a room or hallway, and the motor 12 is driven while irradiating ultraviolet rays, so that bacteria floating in the indoor space, ceiling, hallway, Bacteria attached to walls and the like can be sterilized.

  The ultraviolet sterilizer 100 may have the form shown in FIG. The difference between the configuration of FIG. 1 and the configuration of FIG. 10 is that there is no introduction portion 8 in FIG. 10, and ultraviolet rays from the light source 1 are directly incident on the changing portion reflecting material 21.

By the way, in the sterilization by ultraviolet rays, it is necessary to irradiate the bacteria and the like to be sterilized with irradiation energy necessary to kill them. The irradiation energy is expressed by the product (μW.sec / cm ² ) of the intensity of ultraviolet light (μW. / Cm ² ) and the irradiation time (sec). The irradiation energy necessary for killing various bacteria is as follows: It varies greatly depending on bacteria. Further, the ultraviolet intensity has a characteristic that it decreases as the distance from the UV lamp 3 increases.

  Therefore, when the ultraviolet sterilizer 100 described above is installed, the irradiation energy necessary for killing the bacteria to be sterilized is examined with IES Lighting Handbook and the like, and based on the size of the space to be sterilized. The ultraviolet intensity of the UV lamp 3 to be used and the irradiation time are determined. For example, when it is desired to shorten the time required for sterilization or when sterilizing a wider space, the UV lamp 3 having higher ultraviolet intensity is used.

  When the irradiation time is determined, the reduction ratio between the pinion gear 13 and the spur gear 14 and the reduction ratio between the first gear 19 and the second gear 23 are set based on the irradiation time. At this time, the width of the beam-like ultraviolet rays is also taken into consideration. For example, even if the rotation speed of the irradiating unit 2 is constant, the time required for the ultraviolet rays to pass through a predetermined position in the space becomes longer as the width of the ultraviolet rays becomes wider, and as a result, the irradiation time becomes longer.

  When the ultraviolet sterilizer 100 is operated at each set reduction ratio, the motor 12 is driven for a time necessary to irradiate the necessary irradiation energy over the entire space to be sterilized. Thereby, bacteria floating in the space to be sterilized can be killed.

  The operation / stop of the motor 12 and the UV lamp 3 is controlled by a controller (not shown).

  Next, a sterilization system using the above-described ultraviolet sterilizer 100 will be described.

  2 and 3 are diagrams for explaining a sterilization system applied to a passage and a room in a building.

  Here, the room 45 surrounded by the ceiling 46, the floor 47, the side walls 50 and 51, the wall 49 including the door 43, and the wall 48 including the door 44 is an object of sterilization. An ultraviolet sterilizer 100 is disposed on the ceiling 46 in the substantially central portion of the room 45. In addition, a sensor 41 that detects a person who enters and exits the room 45 from the door 43 and a sensor 42 that detects a person who enters and exits the room 45 from the door 44 are disposed on the ceiling 46. The sensors 41 and 42 are turned on when a person is detected, and turned off when a person is not detected. That is, when there is no person in the room 45, the sensor 41 and the sensor 42 are OFF.

  When either the sensor 41 or the sensor 42 is ON, the control unit is controlled so that the ultraviolet sterilizer 100 does not operate.

  As shown in FIG. 2, when a person enters the room 45 through the door 43, the sensor 41 detects the person and turns on. In this state, the ultraviolet sterilizer 100 does not operate. However, since the UV lamp 3 takes time until it can emit light due to its characteristics, preparation for ultraviolet irradiation is started in preparation for the person leaving the room.

  As long as a human is in the room 45, the sensor 41 remains ON. Then, when a person leaves the door 43, it is turned OFF. Further, when a person leaves the door 44 while the sensor 41 is on, the sensor 41 and the sensor 42 are turned off.

  As shown in FIG. 3, when a person leaves the door 43 or the door 44 and the sensor 41 and the sensor 42 are turned off, the control unit performs UV sterilization for an irradiation time necessary to kill bacteria in the room 45. The device 100 is activated.

  Even when the ultraviolet sterilizer 100 is in operation, when a person enters the room 45 and the sensor 41 or the sensor 42 is turned on, the control unit immediately stops the ultraviolet sterilizer 100. In this case, both the motor 12 and the UV lamp 3 may be stopped, or only the UV lamp 3 may be stopped without stopping the motor 12.

  As described above, the control unit sterilizes the interior of the room 45 by operating the ultraviolet sterilizer 100 every time a person leaves the room 45. Therefore, even if bacteria etc. are attached to the room 45 and bacteria are brought into the room by entering the room 45, the bacteria etc. brought in will be sterilized after the person leaves. Then, it is possible to prevent bacteria from breeding in the room 45 and virus infection to the subsequent occupants.

  The system described above is not limited to the room 45, and can also be applied to a case where a closed space corresponding to the room 45 is formed by providing the door 43 and the door 44 in the middle of the hallway. For example, the present invention can be applied to a hospital corridor or the like, and can be a system that performs sterilization every time a person passes.

  In the above description, only one ultraviolet sterilizer 100 is disposed in the room 45, but two or more may be disposed depending on the size and shape of the room 45.

  A second embodiment will be described.

  In the present embodiment, the configuration of the ultraviolet sterilizer 100 is the same as that of the first embodiment, but the system control method using the ultraviolet sterilizer 100 is different.

  The object of sterilization in this embodiment is a sterile facility such as a research facility or manufacturing site for pharmaceuticals and cosmetics.

  4 and 5 are diagrams for explaining a sterilization system to which the present embodiment is applied.

  The room 45 of the present embodiment has the same configuration as the room 45 of the first embodiment, except that the door 44 and the sensor 42 that detects entry / exit from the door 44 are not provided. A person entering the room 45 wears protective clothing, gloves, and goggles for preventing exposure to ultraviolet rays.

  As shown in FIG. 4, when the sensor 41 detects a human and is turned on, the control unit operates the UV lamp 3 and the motor 12. Thereby, while the person is working in the room 45, the space in the room 45 is sterilized by the ultraviolet sterilizer 100. And if a human leaving room is detected, a control unit will operate the ultraviolet sterilizer 100 continuously for the preset time, and will stop after that.

  According to the system as described above, it can be suspended in the air at facilities where pharmaceuticals cannot be used for sterilization or disinfection due to contamination problems, or in cosmetics where the bacteria can easily propagate. And bacteria attached to the wall can be killed.

  A third embodiment will be described.

  The ultraviolet sterilizer 100 of the present embodiment has the same configuration of the light source 1 and the irradiation unit 2 as the first embodiment, whereas the ultraviolet sterilizer 100 of the first embodiment is installed on the ceiling. The ultraviolet sterilizer 100 according to this embodiment is different in that it is movable and a sensor for detecting a person's entrance / exit is attached to the ultraviolet sterilizer 100.

  6 and 7 are diagrams for explaining a sterilization system to which the present embodiment is applied.

  As shown in FIG. 6, the ultraviolet sterilizer 100 includes a sensor 41 in addition to the light source 1 and the irradiation unit 2 shown in FIG. 1, and is used in a state set on a table such as a tripod 55. .

  First, as shown in FIG. 6, the ultraviolet sterilizer 100 is installed at a position about half the height from the floor 47 to the ceiling 46 in the center of the room 45. When the ultraviolet sterilizer 100 is installed, the operator turns on the start switch and leaves the room 45. The sensor 41 is activated by turning on the start switch, detects an operator, and is turned on. Even if the start switch is turned on, the control unit prohibits the operation of the UV lamp 3 and the motor 12 until the sensor 41 is turned off. When the operator leaves the room and the door 43 closes, the sensor 41 is turned off. Therefore, the control unit operates the UV lamp 3 and the motor 12 for a preset time and stops them when the set time has elapsed.

  If a human enters during the sterilization and the sensor 41 is turned on, the control unit immediately stops the UV lamp 3 and the motor 12.

  6 and 7, driving power is supplied from the power source in the room 45, but it may be supplied from a battery or the like.

  The mobile ultraviolet sterilization apparatus 100 as described above is suitable for sterilization of a room whose operation frequency is not high enough to be provided on the ceiling as in the first and second embodiments, and sterilization in a vehicle or an aircraft. Yes. For example, when sterilizing a railway vehicle, after the vehicle arrives at the terminal station and the passenger is taken down, the ultraviolet sterilizer 100 is brought in and sterilized. According to the ultraviolet sterilizer 100, the entire interior of the vehicle can be sterilized in a shorter time compared to the method of irradiating the sucked air with ultraviolet rays. Since there is no remaining or no remaining material, the interior of the vehicle can be sterilized even when the time until the restart is limited as in the case of immediately turning back. Since the window glass has an ultraviolet transmittance of 0%, even if the ultraviolet sterilizer 100 is operated while stopped at the home where it arrived, a person at the home will not be exposed to the ultraviolet rays, and is excellent in safety.

  A fourth embodiment will be described.

  In the present embodiment, the configuration of the ultraviolet sterilizer 100 is the same as that of the first embodiment, but the target using the ultraviolet sterilizer 100 is different. The object of sterilization in this embodiment is immigration facilities such as airports.

  8 and 9 are diagrams for explaining the present embodiment.

  Two rooms of room A and room B are provided as immigration facilities, and an ultraviolet sterilizer 100A and an ultraviolet sterilizer 100B are installed in the approximate center of the ceiling of each room. In each room, a plurality of immigration counters 64 are installed.

  When an aircraft or the like arrives, as shown in FIG. 8, first, the entrance 60 and the exit 61 of the A room are opened, and the entrant is guided to the A room. At this time, the ultraviolet sterilizer 100A in the room A is stopped. On the other hand, the room B closes the inlet 62 and the outlet 63 and operates the ultraviolet sterilizer 100B to sterilize the room. The operation time of the ultraviolet sterilizer 100B is set in advance according to the sterilization line output of the UV lamp 3 to be used, the size of the room, and the like. Even when the sterilization by the ultraviolet sterilizer 100B is completed, the inlet 62 and the outlet 63 of the B chamber are kept closed.

  When all examinations of immigrants guided to room A are completed and the immigration officer leaves the room, the entrance 60 and exit 61 of room A are closed.

  Then, when the next flight aircraft or the like arrives, the entrance 62 and the exit 63 of the room B are opened as shown in FIG. At this time, in the room A, the ultraviolet sterilizer 100A is operated to sterilize the room.

  Thereafter, whenever an aircraft or the like arrives, the A room and the B room are alternately used as described above, and the unused room is sterilized.

  If room A and room B are alternately used and sterilized as described above, even if there are passengers infected with a virus on one flight, it is possible to prevent infection on the passengers of other flights that arrived at the time of immigration. , Infection damage can be reduced.

  Note that three or more rooms may be prepared, and one of the rooms may be closed for sterilization without using all the rooms at the same time as described above.

  Moreover, if the system shown in FIGS. 2 and 3 is applied to the passage from the exit of an aircraft or the like to the A room and the B room, it is possible to more reliably prevent other passengers from being infected.

  A fifth embodiment will be described.

  In the present embodiment, the configuration of the ultraviolet sterilizer 100 is the same as that of the first embodiment, but the target using the ultraviolet sterilizer 100 is different. The space to be sterilized in this embodiment is an internal space such as a bioreactor or a storage tank used in a food factory or the like.

  11 and 12 are diagrams for explaining the present embodiment, and are cross-sectional views showing a system for cleaning and sterilizing the inside of the stirred tank bioreactor.

  As shown in FIGS. 11 and 12, the stirring tank type bioreactor includes a tank 70, a stirring blade 74 that is rotatably installed in the tank 70, a stirring motor 71 that rotationally drives the stirring blade 74, and a three-dimensional structure. A high pressure cleaning system including a cleaning nozzle, a jet cylinder 72, and the like, and an ultraviolet sterilizer 100 are provided. Since the stirring blades 74 and the stirring motor 71, and the three-dimensional cleaning nozzle and jet cylinder 72 are known ones, they will be briefly described.

  The stirring blade 74 includes a shaft 74a connected to the shaft of the stirring motor 71, and a plurality of blades 74b provided near the tip of the shaft 74a. The stirring blade 71 rotates around the shaft 74a by the stirring motor 71, and the tank 70 Stir the contents.

  The three-dimensional cleaning nozzle 73 has the same structure as that disclosed in, for example, Japanese Patent Laid-Open No. Hei 8-010734, and the three-dimensional cleaning nozzle 73 is connected to a jet cylinder 72 that can be moved up and down in the tank 70. It is attached to the tip of the cylinder 72a. Then, by operating the three-dimensional cleaning nozzle 73 while raising and lowering the cylinder 72a, the entire inner surface of the tank 70 can be cleaned at high pressure. The three-dimensional cleaning nozzle 73 is stored in a nozzle storage unit 75 provided at the upper part of the tank 70 when not operating.

  The ultraviolet sterilizer 100 basically has the same configuration as that shown in FIG. 1 or FIG. 10, but the first light guide tube 16 is formed longer than that shown in FIG. The first light guide tube 16 operates in the same manner as the cylinder 72a of the jet cylinder 72, and the ultraviolet sterilizer 100 is in a position protruding into the tank 70 when activated, and is stored in the ultraviolet sterilizer storage section 76 when not activated. The The first light guide tube 16 is inclined with respect to the central axis of the tank 70.

  Next, cleaning and sterilization operations in the tank 70 will be described.

  When the inside of the tank 70 is emptied, as shown in FIG. 11, first, the three-dimensional cleaning nozzle 73 is operated while raising and lowering the cylinder 72a to clean the inner surface of the tank 70 with high pressure. When the high-pressure cleaning is completed, the three-dimensional cleaning nozzle 73 is stored in the nozzle storage portion 75 as shown in FIG. 12, and the ultraviolet sterilizer 100 is moved to the protruding position in the tank 70, and then the preset operation time is reached. Operate and sterilize. When the operation time elapses, the ultraviolet sterilizer storage unit 76 is returned.

  Although sterilization cannot be performed only by performing high-pressure washing, in the case of a stirring tank that handles chemicals and foods, there is a problem that sterilization with chemicals is difficult to avoid contamination. However, since contamination cannot be generated with the ultraviolet sterilizer 100, the inner surface of the tank 70 can be cleaned and sterilized by the above-described system.

  Further, by installing the first light guide tube 16 so as to be inclined with respect to the central axis of the tank 70, the frequency at which the ultraviolet rays emitted from the ultraviolet sterilizer 100 are incident at right angles to the inner surface of the tank 70 is reduced. As shown in FIG. 12, it is possible to efficiently sterilize using reflection on the inner surface of the tank 70.

  The present invention is not limited to the above-described embodiments, and it goes without saying that various modifications can be made within the scope of the technical idea described in the claims.

DESCRIPTION OF SYMBOLS 1 Light source 2 Irradiation part 3 UV lamp 4 Curved mirror 5 Convex lens 6 Concave lens 7 Light source cover 8 Introduction part 9 Introduction part Reflective material 10 1st introduction hole 11 1st discharge | release hole 12 Motor 13 Pinion gear 14 Spur gear 15 Support member 16 1st light guide Tube 17 First bearing 18 Second bearing 19 First gear 20 Change portion 21 Change portion reflector 22 Second light guide tube 23 Second gear 24 Third bearing 25 Fourth bearing 26 Release portion 27 Release portion reflector 28 Release hole 29 first case 30 second case 41 sensor 42 sensor 43 door 44 door 45 room 46 ceiling 47 floor 48 wall 49 wall 50 side wall 51 side wall 55 tripod 70 tank 73 three-dimensional cleaning nozzle 74 stirring blade

Claims (5)

A light source that condenses and emits the ultraviolet light generated by the ultraviolet lamp in a beam,
A first hollow tube for directly or indirectly introducing ultraviolet rays emitted from the light source;
A first reflecting member that is fixed in position relative to the first hollow tube and that reflects ultraviolet rays that have passed through the first hollow tube at right angles;
A first rotation drive mechanism capable of rotating the first reflecting member around a longitudinal axis of the first hollow tube;
A second hollow tube through which ultraviolet rays reflected by the first reflecting member pass;
A second reflecting member that is fixed in position relative to the second hollow tube and that reflects the ultraviolet rays that have passed through the second hollow tube at right angles;
The second reflecting member is driven to revolve around the longitudinal axis of the first hollow tube while rotating around the longitudinal axis of the second hollow tube in synchronization with the rotation of the first reflecting member. A second rotation drive mechanism;
An emitting part for emitting ultraviolet rays reflected by the second reflecting member;
With
The first rotation drive mechanism and the second rotation drive mechanism are operated while generating ultraviolet rays with the ultraviolet lamp, thereby scanning a preset space with ultraviolet rays emitted from the emission unit. UV sterilizer.   When the ultraviolet lamp, the first rotary drive mechanism, and the second rotary drive mechanism start operating, at least the necessary irradiation energy for killing the object to be sterilized is irradiated to the entire space scanned with ultraviolet rays. 2. The ultraviolet sterilizer according to claim 1, wherein the ultraviolet sterilizer operates for a time required for the operation. The first rotational drive mechanism includes an electric motor that rotationally drives the first hollow tube, and a speed reduction mechanism that decelerates the rotational speed of the electric motor,
The second rotation drive mechanism includes a fixed support member that rotatably supports the first hollow tube, a first bevel gear provided on the outer periphery of the fixed support member, and a part of the second hollow tube. A rotating member that is rotatably supported on the outer periphery of the rotating member and includes the second reflecting member therein, and a second bevel gear that is provided on the outer periphery of the rotating member and meshes in a direction perpendicular to the first bevel gear. The ultraviolet sterilizer according to claim 1 or 2, characterized by the above. A human sensor for detecting human entry and exit into the preset space;
4. The method according to claim 1, wherein when the human sensor detects an entry, the ultraviolet lamp, the first rotation drive mechanism, and the second rotation drive mechanism are activated after detecting the backward movement. The ultraviolet sterilizer described in one. A human sensor for detecting human entry and exit into the preset space;
When the presence sensor detects the entry, the ultraviolet lamp, the first rotation drive mechanism, and the second rotation drive mechanism are activated, and when the presence sensor detects the exit, a predetermined time elapses from the exit. The ultraviolet sterilizer according to any one of claims 1 to 3, wherein the ultraviolet sterilizer is stopped.

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