JP2018020948A - Chlorine dioxide gas generator and sterilization device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a chlorine dioxide gas generator capable of controlling the concentration of a chlorine dioxide gas, and a sterilization device using the same.SOLUTION: There is provided a sterilization device comprising a chlorine dioxide gas generator CG, in which the chlorine dioxide gas generator CG includes: a gas generation part 11 generating a chlorine dioxide gas and feeding the generated chlorine dioxide gas to a prescribed space; and a control part 12 where, based on the volume of the prescribed space, in such a manner that the concentration of the chlorine dioxide gas in the prescribed space reaches a prescribed target concentration range, in the gas generation part, on time of generating the chlorine dioxide gas and off time of stopping the generation of the chlorine dioxide gas are controlled.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a chlorine dioxide gas generator that generates chlorine dioxide gas and a sterilizer using the same.

  Conventionally, a chlorine dioxide gas generating device that generates chlorine dioxide gas having functions such as virus removal, sterilization, and deodorization is known. As such a device, for example, Kureberin LED manufactured by Daiko Pharmaceutical Co., Ltd. is used. is there. This Kreberin LED generates chlorine dioxide gas when irradiated with ultraviolet rays (see Non-Patent Document 1).

“Kreberin LED”, [online], [May 12, 2016 search], Internet (URL: http://www.seilogan.co.jp/cleverin_led/)

  By the way, in order to effectively and safely sterilize with chlorine dioxide gas, it is desirable to set the concentration of chlorine dioxide gas in a predetermined space to a predetermined value. For example, the Occupational Safety and Health Administration (OSHA) in the United States has set an exposure limit of 0.1 ppm for 8 hours a day (TWA; time weighted average). NPL 1 does not disclose or suggest a technique for controlling the concentration of chlorine dioxide gas.

  This invention is an invention made | formed in view of the above-mentioned situation, The objective is to provide the chlorine dioxide gas generator which can control the density | concentration of chlorine dioxide gas, and the disinfection apparatus using the same.

  As a result of various studies, the present inventor has found that the above object is achieved by the present invention described below. That is, the chlorine dioxide gas generator according to one aspect of the present invention is based on a gas generator that generates chlorine dioxide gas and supplies the generated chlorine dioxide gas to a predetermined space, and a volume of the predetermined space. In the gas generation unit, the on-time for generating the chlorine dioxide gas and the off for stopping the generation of the chlorine dioxide gas so that the concentration of the chlorine dioxide gas in the predetermined space falls within a predetermined target concentration range. And a control unit for controlling time.

  Such a chlorine dioxide gas generator includes the control unit, and can control the concentration of chlorine dioxide gas in the predetermined space by controlling the on time and the off time of the gas generation unit.

  In another aspect, in the above-described chlorine dioxide gas generator, a temperature at which the temperature of the gas generator is adjusted so that the concentration of chlorine dioxide gas in the predetermined space falls within the predetermined target concentration range. An adjustment unit is further provided.

  Since such a chlorine dioxide gas generator further adjusts the temperature of the gas generator, the concentration of chlorine dioxide gas in the predetermined space can be controlled more effectively. In particular, by adjusting the temperature of the gas generating unit to a temperature at which chlorine dioxide gas is efficiently generated, the concentration of chlorine dioxide gas is an initial value (including 0) (the gas by the control unit). It is possible to shorten the time required from the start of the control of the generator to the target state where the concentration of chlorine dioxide gas reaches a predetermined value.

  According to another aspect, in the above-described chlorine dioxide gas generator, the gas generator generates a chlorine dioxide gas by receiving a light emitting unit that emits ultraviolet light and an ultraviolet ray emitted from the light emitting unit. A distance between the light emitting unit and the gas source is adjusted such that the concentration of chlorine dioxide gas in the predetermined space is within the predetermined target concentration range. To do.

  Since such a chlorine dioxide gas generator further adjusts the distance between the light emitting unit and the gas source, the concentration of chlorine dioxide gas in the predetermined space can be controlled more effectively. In particular, the time required from the initial state to the target state can be shortened by setting the distance between the light emitting unit and the gas source to a distance where chlorine dioxide gas is efficiently generated.

  Further, a sterilization apparatus according to another aspect of the present invention includes a space forming body that forms a predetermined space, and chlorine dioxide gas generation that supplies chlorine dioxide gas to the predetermined space formed by the space forming body. And the chlorine dioxide gas generator is any one of the above-mentioned chlorine dioxide gas generators.

  Since such a sterilization apparatus includes any of the above-described chlorine dioxide gas generators, the concentration of chlorine dioxide gas in the predetermined space can be controlled.

  Moreover, in another one aspect | mode, in the above-mentioned sterilization apparatus, the said space formation body is the container which accommodates the articles | goods in a locker, the air shower room which implements the air shower in an air shower apparatus, and the room of a building It is either of these.

  According to this, when the space forming body is the container, a locker capable of sterilizing articles (for example, clothes such as dust-free clothes) during storage can be provided, and the space forming body is an air shower room. In this case, an air shower device capable of sterilizing not only dust but also sterilizing the air shower room can be provided during the air shower, and if the space forming body is a room, A sterilization space can be built inside.

  Moreover, in another one aspect | mode, in these above-mentioned disinfection apparatuses, the filter which cleans the air arrange | positioned between the ventilation part which produces a wind in the said predetermined space, and the said ventilation part and the said predetermined space And a section. Preferably, in the above-described sterilization apparatus, the filter unit is a HEPA (High Efficiency Particulate Air) filter.

  Such a sterilization apparatus can sterilize the bacteria collected in the filter unit, and can suppress a decrease in the bacteria collection ability in the filter unit.

  The chlorine dioxide gas generator and the sterilizer according to the present invention can control the concentration of chlorine dioxide gas in a predetermined space.

It is a figure which shows the structure of the microbe elimination apparatus in 1st Embodiment. It is a figure which shows the structure of the chlorine dioxide gas generator used for the bacteria elimination apparatus shown in FIG. It is a figure which shows the electrical structure of the chlorine dioxide gas generator shown in FIG. It is a figure which shows the relationship between the temperature of a gas generation part, and the density | concentration of chlorine dioxide gas. It is a figure which shows the relationship between the distance between a light emission part and a gas source, and the density | concentration of chlorine dioxide gas. It is a figure for demonstrating the relationship between the distance between a light emission part and a gas source, and the overlapping area of illumination light and a gas source. It is a figure for demonstrating the calculation model used when calculating the density | concentration of the chlorine dioxide gas in a predetermined space. It is a figure which shows the time change of the density | concentration of chlorine dioxide gas calculated | required from the calculation formula based on the calculation model shown in FIG. 7 when generation | occurrence | production of chlorine dioxide gas is started in the initial state of the initial value of 0 [ppb]. It is a figure which shows the time change of the density | concentration of the chlorine dioxide gas calculated | required from the calculation formula based on the calculation model shown in FIG. 7, when generation | occurrence | production of chlorine dioxide gas is stopped in the initial state of the initial value of 40 [ppb]. It is a figure which shows the time change of the density | concentration of the chlorine dioxide gas calculated | required from the calculation formula based on the calculation model shown in FIG. 7 when generation | occurrence | production of chlorine dioxide gas is started in the initial state of the initial value 30 [ppb]. The air shower room when the chlorine dioxide gas generator of the sterilization apparatus shown in FIG. 1 is controlled with the on time and the off time set based on the time variation of the chlorine dioxide gas concentration shown in FIGS. It is a figure which shows the actual measurement result of the density | concentration of the chlorine dioxide gas in the inside. It is a figure which shows the structure of the bacteria elimination apparatus in 2nd Embodiment. It is a figure which shows the structure of the microbe elimination apparatus in 3rd Embodiment. It is a figure which shows other electrical structures of the chlorine dioxide gas generator used for the microbe elimination apparatus shown in FIG.

  Hereinafter, an embodiment according to the present invention will be described with reference to the drawings. In addition, the structure which attached | subjected the same code | symbol in each figure shows that it is the same structure, The description is abbreviate | omitted suitably. In this specification, when referring generically, it shows with the reference symbol which abbreviate | omitted the suffix, and when referring to an individual structure, it shows with the reference symbol which attached the suffix.

The disinfecting apparatus in the embodiment is an apparatus for disinfecting a predetermined space with chlorine dioxide gas (ClO ₂ gas), the space forming body forming the predetermined space, and the space forming body forming the space forming body. A chlorine dioxide gas generator for supplying chlorine dioxide gas to a predetermined space. The chlorine dioxide gas generating device generates chlorine dioxide gas, supplies the generated chlorine dioxide gas to the predetermined space, and based on the volume of the predetermined space, the chlorine dioxide gas in the predetermined space. A control unit that controls an on time for generating the chlorine dioxide gas and an off time for stopping the generation of the chlorine dioxide gas in the gas generation unit so that the concentration of the chlorine gas falls within a predetermined target concentration range. With. Such a chlorine dioxide gas generation device and a sterilization device include the control unit, and by controlling the on time and the off time of the gas generation unit, the concentration of chlorine dioxide gas in the predetermined space (hereinafter, Abbreviated as “gas concentration” as appropriate). Hereinafter, such a chlorine dioxide gas generator and a sterilizer will be described more specifically with reference to the first to third embodiments.

(First embodiment)
First, the configuration of the sterilization apparatus AS in the first embodiment will be described. FIG. 1 is a diagram illustrating a configuration of a sterilization apparatus according to the first embodiment. FIG. 2 is a diagram showing a configuration of a chlorine dioxide gas generator used in the sterilization apparatus shown in FIG. 2A is a top view, FIG. 2B is a cross-sectional view taken along the line II in FIG. 2A, and FIG. 2C is a top view when the top plate and the pair of front and rear side plates are removed (inside FIG. 2D is a right side view. FIG. 3 is a diagram showing an electrical configuration of the chlorine dioxide gas generator shown in FIG.

  In FIG. 1, the sterilization apparatus AS according to the first embodiment supplies chlorine dioxide gas to a first space forming body 21 that forms a predetermined space and the predetermined space formed by the first space forming body 21. In this embodiment, the first space forming body 21 is an air shower room (compartment room) for performing an air shower, for example, in the present embodiment. As the sterilization apparatus AS, for example, an air shower apparatus disclosed in Japanese Patent Application Laid-Open No. 2014-66467 can be used. More specifically, for example, as shown in FIG. 1, the sterilization apparatus AS includes a first space forming body 21 and a pair of left and right first and second pressurized air delivery units 22-1 and 22-2. The gas blower 23, the chlorine dioxide gas generator CG, and the first housing 24 are provided.

  The first space forming body 21 includes a pair of left and right first and second walls 211-1 and 211-2, a ceiling 212, a floor 213, and a pair of front and rear entrance doors and outlet doors not shown. The predetermined space is formed inside the first and second walls 211-1, 211-2, the ceiling 212, the floor 213, the entrance door, and the exit door.

  The first and second walls 211-1 and 211-2 are each a rectangular plate-like body formed of an appropriate predetermined metal (including an alloy) such as steel plate baking coating or stainless steel, for example. They are erected so as to face each other at a predetermined interval. The predetermined interval is an appropriate distance that allows a person to pass from the entrance door to the exit door with sufficient margins and allows dust or the like attached to the person to be blown away by pressurized air (air shower). The first and second walls 211-1 and 211-2 have a plurality of openings (a plurality of first and second openings) for attaching a plurality of first and second ejection nozzles 224-1 and 224-2, which will be described later, respectively. A second nozzle mounting opening) is formed. Furthermore, in the lower portions of the first and second walls 211-1 and 211-2, the gas in the predetermined space is respectively sent to the first and second pressurized air delivery units 22-1 and 22-2. A plurality of openings (a plurality of first and second suction openings) 2111-1 and 111-2 for suctioning (introducing) into the interior are formed. The entrance door is attached to each one side end of the first and second walls 211-1 and 211-2 so as to be openable and closable, and to each other side end of the first and second walls 211-1 and 211-2. The outlet door is attached to be openable and closable. The ceiling 212 is a rectangular plate-like body formed of an appropriate predetermined metal (including an alloy), and is fixed to the upper ends of the first and second walls 211-1 and 211-2 at both side ends thereof. It is attached. The ceiling 212 is formed with an opening for mounting the gas blowing unit 23 (blowing unit mounting opening). The floor 213 is a grating plate (lattice plate) formed from an appropriate predetermined metal (including an alloy), and is fixed to the lower ends of the first and second walls 211-1 and 211-2 at both ends. Attached.

  The first and second pressurized air delivery units 22-1 and 22-2 each generate pressurized air, and the generated pressurized air is used as the predetermined space formed by the first space forming body 21. It squirts from the left and right. The first pressurized air delivery unit 22-1 is disposed outside the first wall 211-1 in the first space forming body 21, and the second pressurized air delivery unit 22-2 is disposed in the first space forming body 21. Is disposed outside the second wall 211-1. Since the first and second pressurized air delivery units 22-1 and 22-2 have the same configuration except that they are bilaterally symmetric, the first pressurized air delivery unit 22-1 will be described below. The description of the 2 pressurized air delivery unit 22-2 is omitted by indicating the configuration in parentheses. The first pressurized air delivery unit 22-1 (22-2) includes a first flow path forming body 221-1 (221-2), a first pressurized air blower 222-1 (222-2), A first filter unit 223-1 (223-2) and a plurality of first ejection nozzles 224-1 (224-2) are provided.

  The first flow path forming body 221-1 (221-2) has a plurality of first suction openings 21111-1 (211-2) formed in the first wall 211-1 (211-2). It is a member that forms a first flow path (second flow path) through which gas flows, reaching one ejection nozzle 224-1 (224-2). The first flow path forming body 221-1 (221-2) is, for example, a rectangular parallelepiped box, and one surface thereof is configured by a first wall 211-1 (211-2) (the one surface is The first wall 211-1 (211-2) is also used). The first pressurized air blower 222-1 (222-2) generates a flow of gas so as to generate pressurized air by the first jet nozzle 224-1 (224-2). For example, It is configured with a turbo fan and an axial fan. The first filter unit 223-1 (223-2), for example, collects dust and bacteria and cleans the air, and includes, for example, a HEPA (High Efficiency Particulate Air) filter. The first jet nozzle 224-1 (224-2) is a member that generates pressurized air and jets it into the predetermined space, and the first jet nozzle 224-1 (221-2) is formed on the first wall 211-1 (211-2). It is attached to the nozzle attachment opening (the second nozzle attachment opening). The first pressurized air blower 222-1 (222-2), the first filter part 223-1 (223-2), and the first ejection nozzle 224-1 (224-2) are first suctioned in this order. The first flow path forming body 221-1 (221-2) is disposed (on the first flow path) sequentially from the opening 2111-1 (2111-2) side. In order to mount the first pressurized air blower 222-1 (222-2) and the first filter portion 223-1 (223-2) in the first flow path forming body 221-1 (221-2). A first partition plate (second partition plate) for forming the first flow path (second flow path) is provided.

  In the 1st pressurized air sending part 22-1 (22-2) of such a structure, by the action | operation of the blower 222-1 (22-2) for 1st pressurized air, it is 1st suction opening from the said predetermined space. Gas is sucked in via 2111-1 (2111-2), and from the first ejection nozzle 224-1 (224-2) to the predetermined space via the first filter part 223-1 (223-2). For example, it is ejected with pressurized air at a speed of 20 m / sec to 30 m / sec.

  The gas blowing unit 23 generates wind in the predetermined space, and supplies the chlorine dioxide gas generated by the chlorine dioxide gas generator CG on the wind to the predetermined space. The gas blowing unit 23 includes, for example, a first circulation fan 231, a third filter unit 232, and an airflow rectifying unit 233, and is attached to the blowing unit mounting opening formed in the ceiling 212.

  The first circulation fan 231 includes, for example, an axial fan or a sirocco fan. The third filter unit 232 is the same as the first and second filter units 223-1 and 223-2, for example, collects dust and bacteria and cleans the air, and includes, for example, a HEPA filter. Is done. In addition, the 1st circulation fan 231 and the 3rd filter part 232 may be provided with a fan filter unit (FFU), for example. The air flow rectification unit 233 rectifies the flowing gas, and includes, for example, a plurality of perforated plates arranged at predetermined intervals in the flow direction of the air flow. The first circulation fan 231, the third filter unit 232, and the airflow rectification unit 233 are sequentially arranged toward the ceiling 212 in this order. Therefore, the third filter unit 232 is disposed between the predetermined space via the first circulation fan 231 and the airflow rectification unit 233.

  The first casing 24 forms a third flow path through which gas flows from the bottom of the floor 213 to the gas blowing section 23 through the outside of the first pressurized air delivery section 22-1 and The first space forming body 21, the first and second pressurized air delivery units 22-1 and 22-2, the gas blowing unit 23, and the chlorine dioxide gas generator CG so that the entrance door and the exit door face the outside. Is a rectangular parallelepiped box. A chlorine dioxide gas generator CG is disposed in the vicinity (periphery) of the gas blower 23 on the third flow path.

  In the gas blower 23 having such a configuration, gas is taken in from the predetermined space through the grating plate floor 213 by the operation of the chlorine dioxide gas generator CG and the first circulation fan 231, and the first pressurization is performed. Around the outside of the air delivery unit 22-1, air containing chlorine dioxide gas is delivered from the gas blowing unit 23 to the predetermined space via the chlorine dioxide gas generator CG and supplied to the predetermined space. Is done.

  And the chlorine dioxide gas generator CG of this embodiment used for the sterilization apparatus AS that also functions as such an air shower device is, for example, as shown in FIG. 2 and FIG. 112-1, 112-2) and the control unit 12, and in the example shown in FIGS. 2 and 3, the fan 13 and the temperature adjustment unit 14 (141, 142-1, 142-2) , Operating time integrating unit 15 (151-1, 151-2, 152, 152a, 153, 153a), first and second dust removing filters 16, 17, power supply unit 18 (181-187), and gas generation A box-shaped rectangular parallelepiped second housing (not shown) that houses the unit 11, the control unit 12, the fan 13, the temperature adjustment unit 14, the operating time integration unit 15, the first and second dust removal filters 16 and 17, and the power supply unit 18. Hauge And a grayed) HS.

  The gas generating unit 11 generates chlorine dioxide gas and supplies the generated chlorine dioxide gas to the predetermined space formed by the first space forming body 21. In the present embodiment, the chlorine dioxide gas generated by the gas generator 11 is placed on the wind generated by the gas blower 23 and supplied to the predetermined space. The gas generation unit 11 includes, for example, a light emitting unit 112 (112-1, 112-2) that emits ultraviolet rays, and a gas source 111 that generates chlorine dioxide gas by receiving the ultraviolet rays emitted from the light emitting unit 112. Prepare. The gas source 111 is prepared by mixing a powder or granular chlorite and an inorganic substance carrier in a columnar container made of a material having air permeability and ultraviolet light transmission, or an aqueous solution of chlorite. A chlorite mixed with an inorganic substance carrier, dried and solidified is enclosed. Chlorite is an alkali metal chlorite or alkaline earth metal chlorite, such as sodium chlorite or calcium chlorite. In the present embodiment, the above-described Kreberin LED manufactured by Daiko Pharmaceutical Co., Ltd. was used as the gas source 111. The light emitting unit 112 may irradiate one surface of a gas source (in this embodiment, a clevelin LED, the same applies hereinafter) 111 with ultraviolet rays, but in this embodiment, in order to generate chlorine dioxide gas more efficiently, In order to irradiate both surfaces of the source 111 with ultraviolet rays, the first and second light emitting units 112-1 and 112-2 are provided. As shown in FIGS. 2 and 6, the first light emitting unit 112-1 is separated from the one surface of the gas source 111 by a distance X, and the central position of the light emitting surface in the first light emitting unit 112-1 and the gas source 111. In the second housing HS, the central position of the one surface is located on substantially the same straight line, and the light emitting surface of the first light emitting unit 112-1 and the one surface of the gas source 111 are parallel to each other. Arranged. Similarly, as shown in FIGS. 2 and 6, the second light emitting unit 112-2 is separated from the other surface of the gas source 111 by a distance X, and the center position of the light emitting surface in the second light emitting unit 112-2 and the gas The second casing so that the center position of the other surface of the source 111 is located on substantially the same straight line, and the light emitting surface of the second light emitting unit 112-2 and the other surface of the gas source 111 are parallel to each other. Arranged in the HS. The distance X is adjusted so that the chlorine dioxide gas concentration (gas concentration) in the predetermined space is within a predetermined target concentration range, and the design thereof will be described later. Each of the first and second light emitting units 112-1 and 112-2 may be a black light using a fluorescent tube, but in the present embodiment, for example, ultraviolet light having a wavelength of 350 nm is emitted for power saving. It is an ultraviolet LED. The wavelength of the ultraviolet light may be another wavelength. As shown in FIG. 2, such a gas generation unit 11 is disposed in the second housing HS so as to be close to one side of the second housing HS (in the example shown in FIG. 2, the front surface side).

  Based on the volume of the predetermined space formed by the first space forming body 21, the control unit 12 adjusts the chlorine dioxide gas concentration (gas concentration) in the predetermined space to be within a predetermined target concentration range. The gas generator 11 controls an on time for generating chlorine dioxide gas and an off time for stopping the generation of chlorine dioxide gas. In the present embodiment, when the first and second light emitting units 112-1 and 112-2 irradiate the gas source 111 with ultraviolet rays, chlorine dioxide gas is generated from the gas source 111, and the first and second light emitting units 112-1 are emitted. , 112-2 stops the irradiation of the ultraviolet ray gas source 11, the generation of chlorine dioxide gas from the gas source 111 is stopped. For this reason, the control part 12 makes the lighting time which light-emits the 1st and 2nd light emission parts 112-1, 112-2 the said ON time, and light-emits the 1st and 2nd light emission parts 112-1, 112-2. With the extinguishing time to stop as the off time, the lighting time and the extinguishing time in the first and second light emitting units 112-1 and 112-2 are controlled. There may be a time lag between the start of ultraviolet irradiation and the start of chlorine dioxide gas generation, and there may be a time lag between the stop of ultraviolet irradiation and the stop of chlorine dioxide gas generation. In this case, the on time and the off time are controlled in consideration of the time lag. The design of the on-time (the lighting time) and the off-time (the light-off time) will be described later. The control unit 12 includes, for example, a program timer 12 that can change the set time.

  The fan 13 is attached to a fan mounting opening formed at one corner of the top plate of the second housing HS, and sucks and exhausts gas inside and outside the second housing HS. The fan 13 includes an axial fan, for example. A first dust filter 16 is attached to the outer surface of the fan 13 to prevent, for example, dust from entering the second housing HS. In addition, a second dust filter 17 is attached to the filter mounting opening formed at the other corner of the top plate of the second housing HS, for example, to prevent dust from entering the second housing HS. . In such a configuration, when the fan 13 is operated so as to suck in air, the gas is sucked into the second housing HS from the outside of the second housing HS through the first dust filter 16 and the fan 13, and the air is sucked in. The gas flows through the second housing HS and is exhausted from the second dust filter 17 to the outside of the second housing HS. On the other hand, when the fan 13 is operated so as to exhaust, the disposition position of the fan 13 and the first dust filter 16 and the disposition position of the second dust filter 17 are alternated. When the fan 13 is operated so as to exhaust in such an arrangement, gas is sucked into the second housing HS from the outside of the second housing HS via the second dust removing filter 17, and the sucked gas is The air flows through the two housings HS and is exhausted out of the second housing HS through the fan 13 and the first dust filter 16. In these cases, when the gas generating unit 11 is operating (that is, when the first and first light emitting units 112-1 and 112-2 radiate ultraviolet rays), the exhausted gas includes: Contains chlorine dioxide gas.

  The temperature adjusting unit 14 adjusts the temperature of the gas generating unit 11 so that the concentration (gas concentration) of chlorine dioxide gas in the predetermined space formed by the first space forming body 21 is within the predetermined target concentration range. To be adjusted. The design of the temperature will be described later. In the present embodiment, a heater 141 that radiates heat and a temperature control unit 142 that controls the temperature of the heater 141 are provided. In the present embodiment, the heater 141 is a ceramic heater, for example, and is disposed in the vicinity of the fan 13, more specifically in the lower part of the fan 13. For this reason, the gas sucked from the outside of the second housing HS by the fan 13 is efficiently adjusted to a predetermined temperature by the heater 141, and the adjusted gas flows through the gas source 111 of the gas generation unit 11. As a result, the temperature of the gas generator 11 is adjusted. In the present embodiment, since the heater 141 includes a ceramic heater, the temperature control unit 142 includes a temperature adjustment switch 142-1 that turns on and off the current flowing through the heater 141, and a temperature sensor (not shown) that measures the temperature. And a temperature controller 142-2 that controls on / off of the temperature adjustment switch 142-1 based on the sensor output. In addition to the heater 141, the temperature adjustment unit 14 may further include a Peltier element that absorbs heat.

  The operating time integrating unit 15 determines the service life of the gas source 111 of the gas generating unit 11, in particular the first and second light emitting units 112-1 and 112-that irradiate the gas source 111. The operation time of 2 is integrated and measured. The operating time integration unit 15 includes a notification unit 151 (151-1, 151-2), a relay 152, and an hour meter 153. The alerting | reporting part 151 alert | reports the lifetime of the gas source 111, for example, is provided with the indicator lamp 151-1 and the external output terminal 151-2. The indicator lamp 151-1 includes, for example, a small light bulb (bean bulb), a red or orange LED, or the like. The external output terminal 151-2 is arranged so that it can be recognized from the outside when the chlorine dioxide gas generator CG is arranged at a position where the indicator lamp 151-1 cannot be seen from the outside, for example, a buzzer or a second It is a pair of terminals for connecting an indicator lamp. The hour meter 153 measures the accumulated time by measuring the time. The start signal is input from the A contact 152a of the relay 152 that is energized only when the machine is in operation, and the accumulation of time is started. Is turned on, the indicator lamp 151-1 is turned on, and the external output terminal 151-2 is turned on (energized). This lighting notifies the life of the gas source 111. On the other hand, the accumulated time of the hour meter 153 is reset by the reset switch, the contact 153a is also turned off, the indicator lamp 151-1 is turned off, and the external output terminal 151-2 is turned off (not energized). In the present embodiment, the clevelin LED of the gas source 111 is irradiated with ultraviolet rays, so that the release of chlorine dioxide gas is completed in about 300 hours (because the lifetime is exhausted), so the hour meter 153 has a set time of 300 hours. Was set.

  The power supply unit 18 is a circuit that receives supply of commercial AC power and supplies necessary power to each unit that requires power in the sterilization apparatus AS. More specifically, the power supply unit 18 includes a metal connector 181 for connecting to the wiring of commercial AC power, a bimetal 182 that cuts off current when an abnormally high temperature of the heater 141 is detected, and a fuse that cuts off current due to overcurrent. 183, a power switch (main power switch of this apparatus) 184 for turning on and off the energization of commercial AC power, a resistance element 185, a pilot lamp 186, and a power supply 187 that generates DC power of voltage 24V from commercial AC power Is provided. Because of its function, the bimetal 182 is disposed in the vicinity (periphery) of the heater 141 as shown in FIG.

  The metal connector 181 includes three E terminals, a U terminal, and a V terminal. The E terminal of the metal connector 181 is used as a ground (ground) wire. The U terminal of the metal connector 181 is connected to the input side of the control unit (program timer in this embodiment) 12 via a fuse 183 and a power switch 184 connected in series. The V terminal of the metal connector 181 is connected to the input side of the control unit 12 via the bimetal 182. Further, a resistance element 185 and a pilot lamp 186 connected in series, and a power supply 187 are connected to the input side of the control unit 12. As a result, when the power switch 184 is turned on, the power supply 187 operates and the pilot lamp 186 is turned on. When the power switch 184 is turned off, the operation of the power supply 187 is stopped and the pilot lamp 186 is turned off. .

  On the output side of the power supply 187, the hour meter 153 and the indicator lamp 151-1 connected in series and the contact 153a of the hour meter 153 are connected in parallel to each other. The external output terminal 151-2 is connected in parallel to the indicator lamp 151-1. On the output side of the control unit (program timer in the present embodiment) 12, a fan 13, a first light emitting unit 112-1, a second light emitting unit 112-2, a temperature adjustment switch 142-1 connected in series, and a heater 141, temperature controller 142-2, and relay 152 are connected in parallel to each other.

(Operation design)
Next, the design of on time and off time (lighting time and light extinguishing time in this embodiment) in the control of the chlorine dioxide gas generator CG used in the sterilization apparatus AS of the first embodiment will be described. FIG. 4 is a diagram showing the relationship between the temperature of the gas generation unit and the concentration of chlorine dioxide gas. FIG. 5 is a diagram showing the relationship between the distance between the light emitting unit and the gas source and the concentration of chlorine dioxide gas. Each horizontal axis in FIGS. 4 and 5 represents time (elapsed time) expressed in [minute] units, and each vertical axis thereof represents the concentration of chlorine dioxide gas expressed in [ppb] units. FIG. 6 is a diagram for explaining the relationship between the distance between the light emitting unit and the gas source and the overlapping area of the illumination light and the gas source. 6A to 6C show a case where the distance X between the ultraviolet LED and the clevelin LED is 20 [mm], and FIGS. 6D to 6F show that the distance X between the ultraviolet LED and the clevelin LED is 25 [ mm], and FIGS. 6G to 6I show the case where the distance X between the ultraviolet LED and the Kreberin LED is 30 [mm]. 6A, 6D, and 6G are front views of the ultraviolet LED, and FIGS. 6B, 6E, and 6H are top views showing the arrangement state of the ultraviolet LED and the clevelin LED, and FIGS. FIG. 6F and FIG. 6I are diagrams for explaining the overlapping area of the illumination light (ultraviolet light) of the ultraviolet LED and the clevelin LED. FIG. 7 is a diagram for explaining a calculation model used when calculating the concentration of chlorine dioxide gas in a predetermined space. FIG. 8 is a graph showing the change over time in the concentration of chlorine dioxide gas obtained from the calculation formula based on the calculation model shown in FIG. 7 when generation of chlorine dioxide gas is started in an initial state of an initial value of 0 [ppb]. It is. FIG. 9 is a graph showing the change over time in the concentration of chlorine dioxide gas obtained from the calculation formula based on the calculation model shown in FIG. 7 when the generation of chlorine dioxide gas is stopped in the initial state of the initial value 40 [ppb]. It is. FIG. 10 is a graph showing the change over time in the concentration of chlorine dioxide gas obtained from a calculation formula based on the calculation model shown in FIG. 7 when generation of chlorine dioxide gas is started in an initial state of an initial value of 30 [ppb]. It is. Each horizontal axis in FIGS. 8 to 10 represents time (elapsed time) expressed in [minute] units, and each vertical axis represents chlorine dioxide gas concentration expressed in [ppb] units.

Before designing the on-time and the off-time, first, the temperature dependence of the gas concentration in the predetermined space formed by the first space forming body (air shower room in the present embodiment) 21 was measured. In this measurement, the first and second light emitting units 112-1 and 112-2 are ultraviolet LEDs each having a diameter of 46 [mm] × H57 [mm] and a power consumption of 0.7 [W], and the gas source 111 is H59.5 [mm] × W57 [mm] × D24 [mm] Kreberin LED. The cross-section (light-receiving surface) of the Kreberin LED is an angle formed by two parallel lines having the same length and two semicircles arranged at both ends of the two parallel lines and connected to the two ends, respectively. It is a round rectangle (track shape of track and field, oval). The fan 13 is a production number MU825S with a power consumption of 8 [W] and an air volume of 0.5 m ³ / min. A uniform flow of 0.4 m / sec circulating through the third flow path was passed through the predetermined space by the gas blower 23. The distance X between each light emitting surface of the first and second light emitting units 112-1 and 112-2 and each surface of the gas source 111 is set to 30 [mm] here. First, the fan 13 in the chlorine dioxide gas generator CG is operated by a pushing method for sucking gas from the outside to the inside of the second housing HS, and the temperature controller 142-2 is 20 ° C., 25 ° C. and Each was set at 30 ° C. Second, the fan 13 in the chlorine dioxide gas generator CG is operated by an exhaust system that exhausts gas from the inside of the second housing HS to the outside, and the temperature controller 142-2 is 20 ° C, 25 ° C, and 30 ° C. Set for each. In each of these cases, the gas concentration in the predetermined space was measured over time. The result is shown in FIG. As can be seen from FIG. 4, the gas concentration monotonously increases with the passage of time in each case (α1 to α8), but each case (α1) of the push-in method is more than each case (α5 to α8) of the exhaust method. .About..alpha.4) has a higher concentration (ie, more chlorine dioxide gas is generated per unit time). Among the indentation cases (α1 to α4), the highest gas concentration is obtained in the case (α1) at the set temperature of 25 ° C. (that is, the amount of chlorine dioxide gas generated per unit time is the largest).

  Next, the dependence of the distance X on the gas concentration in the predetermined space formed by the first space forming body (air shower room in this embodiment) 21 was measured. The gas source 111, the first and second light emitting units 112-1, 112-2, and the fan 13 similar to those described above were used, and a uniform flow of 0.4 m / second was passed through the predetermined space. In order to generate chlorine dioxide gas efficiently, the fan 13 is operated in a pushing manner and the set temperature is 25 ° C. from the above. The distance X was set to 20 [mm], 25 [mm], 30 [mm], 35 [mm] and 40 [mm], respectively. In each of these cases, the gas concentration in the predetermined space was measured over time. The result is shown in FIG. As can be seen from FIG. 5, the gas concentration monotonously increases with time in each case (β1 to β5), but the highest gas concentration is obtained in the case (β1) where the distance X is 25 [mm]. Has been obtained. Hereinafter, in order of increasing gas concentration, the case (β2) of 30 [mm], the case (β3) of 35 [mm], the case (β4) of 40 [mm], and the case (β5) of 20 [mm] are obtained. ing. As shown in FIG. 6, the light emitting surface of the ultraviolet LED 112 of the first and second light emitting units 112-1 and 112-2 is circular, while the surface receiving the ultraviolet light (light receiving surface) of the Kleberin LED of the gas source 111. ) Is an oval shape, and from the above dimensions, in the case [β5] of 20 mm, the light emitting surface is too close to the light receiving surface, and as shown in FIG. I won't win. Then, in the case [β1] of 25 [mm], as shown in FIG. 6F, the entire ultraviolet irradiation surface formed by the light emission of the ultraviolet LED hits substantially the entire light receiving surface. On the other hand, in each case (β2 to β4) of 30 [mm] to 40 [mm], the light emitting surface is too far away from the light receiving surface, and the light receiving surface is included in the irradiation surface as shown in FIG. 6I, for example. Cannot receive all ultraviolet rays. Further, as the distance X increases, the intensity of ultraviolet rays per unit area also decreases. For these reasons, it is considered that the measurement results shown in FIG. 5 were obtained.

Based on the above results, in the present embodiment, the predetermined space formed by the first space forming body 21 is modeled as shown in FIG. In the model shown in FIG. 7, a fan for generating a gas flow and a chlorine dioxide gas generator for placing chlorine dioxide gas on the gas flow generated by the fan are arranged in the predetermined space. The outside air introduction amount Qo [m ³ / hour] flows into the predetermined space from the outside, and the externally derived amount Qe [m ³ / hour] flows out of the predetermined space to the outside. The introduced outside air amount Qo and the exhaust amount Qe are, for example, the predetermined space formed by the space forming body 21 and the outside due to the injection of pressurized air or the opening / closing of the entrance door and the exit door Represents the amount of gas generated and discharged between the two, and these are balanced (equilibrium) (Qo = Qe). For such a model, a calculation formula (1) for deriving the gas concentration C [ppb] of the predetermined space has been devised with reference to the formula used for designing the ventilation of carbon dioxide in a room in a building. .

Here, Qs [m ³ / hour] is the amount of circulating air in the predetermined space (air shower room in the present embodiment) formed by the space forming body 21. Qr [m ³ / hour] is the amount of return air in the predetermined space. γ is a device processing rate. d is the decay rate of the chlorine dioxide gas concentration by the fan. Ci [ppb] is an initial value of the concentration of chlorine dioxide gas. Co [ppb] is the chlorine dioxide gas concentration of the introduced outside air quantity Qo. m is generally called a mixing coefficient, and m = 1 in the case of instantaneous uniform diffusion. ρ [g / l] is the density of chlorine dioxide gas, and ρ = 3.04 [g / l]. V [m ³ ] is a volume (volume) of the predetermined space. t [hour] is time. M [mg / hour] is a chlorine dioxide gas generation amount. The generation concentration coefficient k is determined from the experimental results shown in FIGS. 4 and 5 when the Kreberine LED 111 is used, the fan 13 is operated in a pushing manner, the distance is set to 25 [mm], and the temperature is set. If it is set to 25 [° C.], it will be 0.65 [mg / hour], and the amount of chlorine dioxide gas generated per unit time will be the largest, so this case is set to “1.0”. Was set to Therefore, the chlorine dioxide gas generation amount M [mg / hour] is obtained by multiplying the generation concentration coefficient k by 0.65 [mg / hour]. In Table 1, To [° C.] is the set temperature of the heater 141 in the present embodiment. X [mm] is the distance between the light emitting unit 112 and the gas source 111.

By using the calculation formula 1, the on-time (lighting time) and the off-time (light-out time) can be designed. For example, if the size of the first space forming body 21 is 1.5 [m] in width, 1.0 [m] in depth and 2.5 [m] in height, the volume V of the predetermined space is 3. 75 [m ³ ]. When the production number UM-610 (3AC) is used for the fan of this model, Qs = 726 [m ³ / hour], Qr = 721 [m ³ / hour], γ = 0.993, and d = 0.9. . The mixing coefficient m is set to 0.2, Qo = 5 [m ³ / hour], and Co = 0 [ppb]. In such a case, the target concentration range is set to, for example, 30 [ppb] to 40 [ppb], and the target concentration range from the initial state (Ci = 0) in which the gas concentration in the predetermined space is 0 [ppb]. When the time required to reach the upper limit value of t is set to t = 0.5 [hours] (30 [minutes]), for example, the generated concentration coefficient k = 0.9 can be adopted from Table 1 above. The chlorine gas generation amount M [mg / hour] is obtained as 0.9 × 0.65 = 0.585. When the generated concentration coefficient k = 0.9, there are two ways in Table 1. When the set temperature To = 30 [° C.], the distance X is set to 25 [mm], and the set temperature To = 25 [ In the case of [° C.], the distance X is set to 30 [mm], and any one of these may be adopted. When these values are substituted into the calculation formula 1, the gas concentration in the predetermined space formed by the first space forming body 21 changes as shown in FIG.

  Since the upper limit value of the target concentration range has been reached, the chlorine dioxide gas generator is turned off, so that the gas concentration in the predetermined space formed by the first space forming body 21 becomes the lower limit of the target concentration range. Reduced to value. As for the off time (light-out time), the time t may be obtained by the calculation formula 1 with Ci = 40 [ppb]. In this case, from the calculation formula 1, the gas concentration in the predetermined space formed by the first space forming body 21 changes from the state of Ci = 40 [ppb] as shown in FIG. Accordingly, the off time is obtained as t = 10 [minutes]. Since the lower limit value of the target concentration range has been reached, the gas concentration in the predetermined space formed by the first space forming body 21 is then set to the upper limit of the target concentration range by turning on the chlorine dioxide gas generator. Raised to value. The on-time (lighting time) may be obtained by the calculation formula 1 with Ci = 30 [ppb]. In this case, from the calculation formula 1, the gas concentration in the predetermined space formed by the first space forming body 21 changes from the state of Ci = 30 [ppb] as shown in FIG. As a result, the on-time is obtained as t = 14 [minutes]. Hereinafter, the gas concentration in the predetermined space formed by the first space forming body 21 is 30 [ppb] to 40 [ppb] by repeating the off time 10 [min] and the on time 14 [min]. Fluctuates between and within the target concentration range.

  In the above description, the on time and the off time are set so as to vary between the upper limit value and the lower limit value in the target density range, but the first predetermined value and the lower limit value that are equal to or lower than the upper limit value in the target density range. The on time and the off time may be set so as to fluctuate between the following second predetermined values. In the above description, the required time from Ci = 0 [ppb] to the upper limit value 40 [ppb] of the target density range is set to 30 [minutes] (0.5 [hours]). For example, when the generated concentration coefficient k is larger than 0.9, for example, 1.0, the set temperature To and the distance X can be obtained from Table 1, and the calculation formula 1 can be used. An on time and an off time are required. Alternatively, the gas generation unit 11 may be added (for example, two sets (two sets) or three sets (three sets) of the gas source 111 and the light emitting units 112 (112-1, 112-2). When the time is longer than this, the case where the generated concentration coefficient k is smaller than 0.9, for example, 0.8, 0.7, 0.6, etc. may be adopted. The set temperature To and the distance X are obtained, and the on time and the off time are obtained from the calculation formula 1.

(Operation and measurement results)
Next, the operation of the sterilization apparatus AS and the chlorine dioxide gas generation apparatus CG of the first embodiment and the actual measurement results will be described. FIG. 11 shows a case in which the chlorine dioxide gas generator of the sterilization apparatus shown in FIG. 1 is controlled with the on time and the off time set based on the time variation of the chlorine dioxide gas concentration shown in FIGS. It is a figure which shows the actual measurement result of the density | concentration of the chlorine dioxide gas in an air shower room. The horizontal axis in FIG. 11 is time (elapsed time) expressed in [minute] units, and the vertical axis is chlorine dioxide gas concentration expressed in [ppb] units.

  First, based on the above-described design, for example, the temperature controller 142-2 is set to 25 [° C.] to control the temperature of the heater 141 to 25 [° C.], and the first and second light emitting units (here, UV LEDs ) The distance X between each light emitting surface of 112-1 and 112-2 and each surface of the gas source (here, Kreberin LED) 111 was set to 30 [mm]. The fan 13 was set to operate in a push-in manner. The target density range is 30 [ppb] to 40 [ppb] as described above. For this reason, the control unit (here, the program timer) 12 is set to 30 [minutes] as the rising on time, and the next 10 [min] off time and 14 [min] on time were repeated.

  After this setting, the power switch 184 of the chlorine dioxide gas generator CG is turned on, and the power switch (not shown) in the sterilizer AS is turned on. When the power switch 184 of the chlorine dioxide gas generator CG is turned on, the control unit 12 operates the fan 13 and the first and second light emitting units 112-1 and 112-2, and ultraviolet rays are emitted from the gas source. 111 is irradiated and chlorine dioxide gas is generated. When a power supply switch (not shown) in the sterilization apparatus AS is turned on, the gas blowing section 23 is activated, and the grating from the predetermined space formed by the first space forming body 21 is activated by the operation of the first circulation fan 231. The gas is taken in through the floor 213 of the plate, travels outside the first pressurized air delivery unit 22-1, and passes from the gas blowing unit 23 through the chlorine dioxide gas generator CG to the predetermined space. Air containing chlorine gas is sent out and supplied to the predetermined space. When 30 minutes of start-up time has elapsed, the control unit 12 stops the fan 13 and the first and second light emitting units 112-1 and 112-2, thereby stopping the generation of chlorine dioxide gas. When 10 minutes of the off time have elapsed, the fan 12 is operated by the control unit 12 and the first and second light emitting units 112-1 and 112-2 are operated to generate chlorine dioxide gas. When the on-time of 14 minutes elapses, the control unit 12 stops the fan 13 and the first and second light emitting units 112-1 and 112-2, thereby stopping the generation of chlorine dioxide gas. When the off-time of 10 minutes elapses, the control unit 12 operates the fan 13 and the first and second light emitting units 112-1 and 112-2 to generate chlorine dioxide gas. Hereinafter, similarly, the on-time operation and the off-time operation are repeated. In this case, the actual measurement result of the gas concentration in the predetermined space formed by the first space forming body 21 is shown in FIG. As can be seen from FIG. 11, the gas concentration in the predetermined space formed by the first space forming body 21 is 30 [ppb] to 40 [ppb] by repeating the on time and the off time as described above. And within the target concentration range.

  Moreover, it measured about the microbe elimination effect of the microbe elimination apparatus AS in 1st Embodiment. In the actual measurement, the chlorine dioxide gas generator CG and the gas blower 23 are operated, and the chlorine dioxide gas generator CG is controlled so that the gas concentrations become 30 [ppb], 50 [ppb], and 150 [ppb], respectively. Then, about each time around 12 hours, the suspended bacteria in the predetermined space formed by the first space forming body 21 and the cleanliness thereof were measured. The result is shown in the upper part of Table 2. And it measured similarly about the case where the 1st thru | or 3rd filter part 223-1, 223-2, 232 was remove | excluded from the microbe elimination apparatus AS in 1st Embodiment. The result is shown in the lower part of Table 2. In Table 2, the “prior atmosphere” row shows the measurement results in the state before the chlorine dioxide gas generator CG and the gas blower 23 are operated, and the row “in the AS after one night” shows chlorine dioxide. The actual measurement results in a state after 12 hours have elapsed after operating the gas generator CG and the gas blowing unit 23 are shown. As can be seen from Table 2, in all cases, the floating bacteria decreased after 12 hours, and the sterilization apparatus AS in the first embodiment could not detect the bacteria. Therefore, the sterilization effect is recognized in the chlorine dioxide gas of each gas concentration in the circulation uniform flow. Further, as can be seen from Table 2, even when the first to third filter parts 223-1, 223-2, and 232 are not provided, a sufficient sterilizing effect is recognized.

  On the other hand, when the chlorine dioxide gas generator CG is operating as described above, when the inlet door is opened and closed, the first and second pressurized air delivery units 22-1 and 22-2 are operated, The compressed air is jetted into the predetermined space for a predetermined time (for example, 15 seconds or 30 seconds). In this case, since the pressurized air contains chlorine dioxide gas, not only dust removal but also sterilization can be performed during the air shower, and further, the first and second filter parts 223-1 and 223-2 collect the sterilized air. The sterilized bacteria can be sterilized with this chlorine dioxide gas, and the decrease in the ability to collect bacteria in the first and second filter sections 223-1 and 223-2 can be suppressed. Similarly, the third filter part 232 can be sterilized with chlorine dioxide gas, and the reduction of the bacteria recovery ability in the third filter part 232 can be suppressed.

  As described above, the sterilization apparatus AS and the chlorine dioxide gas generation apparatus CG in the present embodiment include the control unit 12 and controls the on time (lighting time) and the off time (light-off time) of the gas generation unit 11. By doing so, the concentration of chlorine dioxide gas in the predetermined space formed by the first space forming body 21 can be controlled.

  Moreover, since the said disinfection apparatus AS and the chlorine dioxide gas generator CG further adjust the temperature of the gas generation part 11, it can control the density | concentration of the chlorine dioxide gas in the said predetermined space more effectively. In particular, by adjusting the temperature of the gas generation unit 11 to a temperature at which chlorine dioxide gas is efficiently generated, the initial state (the gas generation by the control unit 12) in which the concentration of chlorine dioxide gas is an initial value (including 0). The time required from the start of the control of the unit 11 to the target state where the concentration of chlorine dioxide gas becomes a predetermined value can be shortened.

  Further, the sterilization apparatus AS and the chlorine dioxide gas generator CG further adjust the distance X between the light emitting unit 112 and the gas source 111, so that the concentration of chlorine dioxide gas in the predetermined space can be controlled more effectively. it can. In particular, the time required from the initial state to the target state can be shortened by setting the distance X between the light emitting unit 112 and the gas source 111 to the distance at which chlorine dioxide gas is efficiently generated.

Next, another embodiment will be described.
(Second Embodiment)
The first space forming body 21 in the sterilization apparatus AS of the first embodiment is an air shower room (compartment room) for performing an air shower in the air shower apparatus, but is not limited to this, It may be a device. In 2nd Embodiment, the space formation body which forms the said predetermined space is a storage container which accommodates the articles | goods in a locker.

  FIG. 12 is a diagram illustrating a configuration of a sterilization apparatus according to the second embodiment. More specifically, in FIG. 12, the sterilizer CR in the second embodiment includes a second space forming body 31, a chlorine dioxide gas generator CG, a second circulation fan 32, and a fourth filter section 33. The airflow rectification unit 34, the second space forming body 31, the chlorine dioxide gas generator CG, the second circulation fan 32, the fourth filter unit 33, and the fourth case 35 that accommodates the airflow rectification unit 34 are provided. The chlorine dioxide gas generator CG, the second circulation fan 32, the fourth filter unit 33, and the airflow rectifying unit 34 in the sterilization apparatus CR of the second embodiment are respectively chlorine dioxide gas in the sterilization apparatus AS of the first embodiment. Since it is the same as generator CG, the 1st circulation fan 231, the 3rd filter part 232, and air current straightening part 233, the explanation is omitted. Note that the airflow rectification unit 34 may be omitted.

  The 2nd space formation body 31 is a member which forms predetermined | prescribed space similarly to the 1st space formation body 21, and is a storage container which accommodates the articles | goods in a locker in this embodiment. More specifically, the second space forming body 31 is a rectangular parallelepiped box having a door that can be opened and closed. In the second space forming body 31, a rod-like rod 312 is hung between one side wall and the other side wall so that clothes such as dust-free clothes hung on a hanger or the like can be hung. ing. An opening for attaching the airflow rectification unit 34 (airflow rectification unit attachment opening) is formed in the ceiling of the second space forming body 31, and the gas in the predetermined space is provided in a lower part of the one side wall as described later. A plurality of openings (a plurality of third suction openings) 311 for suctioning (leading out) to the four flow paths are formed.

  The fourth housing 35 forms a fourth flow path through which the gas flows from the plurality of third suction openings 311 to the airflow rectifying unit 34 through the outside of the one side wall of the second space forming body 31. In addition, the second space forming body 31, the chlorine dioxide gas generator CG, the second circulation fan 32, the fourth filter portion 33, and the airflow rectifying portion 34 are accommodated so that the door (not shown) faces the outside. In the present embodiment, the other side wall facing the one side wall of the second space forming body 31, its back wall and its floor are also used as the other side wall, the back wall and the floor of the fourth housing 35, respectively. . The airflow rectification unit 34 is attached and fixed to the airflow rectification unit mounting opening. The chlorine dioxide gas generator CG, the second circulation fan 32, and the fourth filter unit 33 are sequentially arranged from the third suction opening 311 toward the airflow rectification unit 34 in this order. Therefore, the fourth filter unit 33 is disposed between the predetermined space via the circulation fan 32 and the airflow rectifying unit 34.

  In the sterilization apparatus CR having such a configuration, gas is taken in from the predetermined space through the plurality of third suction openings 311 by the operations of the chlorine dioxide gas generator CG and the second circulation fan 32, and the second Chlorine dioxide gas travels outside the one side wall of the space forming body 31 from the air flow rectifying unit 34 to the predetermined space via the chlorine dioxide gas generating device CG, the second circulation fan 32 and the fourth filter unit 33. Is supplied to the predetermined space. For this reason, articles stored in the second space forming body 31, for example, dust-free clothes hung on the rod 312 or articles placed on the floor are sterilized by chlorine dioxide gas. And the microbe collect | recovered by the 4th filter part 33 can be disinfected with this chlorine dioxide gas, and the fall of the microbe collection capability in the 4th filter part 33 can be suppressed. Furthermore, since the chlorine dioxide gas generator CG is designed as described above, the same effect as that of the first embodiment is achieved, and chlorine dioxide gas in the predetermined space formed by the second space forming body 31 is produced. Concentration can be controlled.

Next, another embodiment will be described.
(Third embodiment)
FIG. 13 is a diagram illustrating a configuration of a sterilization apparatus according to the third embodiment. In the third embodiment, the space forming body forming the predetermined space is a room of a building. More specifically, in FIG. 13, the sterilization apparatus HR in the third embodiment includes a third space forming body 41, a chlorine dioxide gas generation apparatus CG, a third circulation fan 42, and a fifth filter unit 43. Is provided. The chlorine dioxide gas generating device CG, the third circulation fan 42, and the fifth filter unit 43 in the sterilizing device HR of the third embodiment are respectively the chlorine dioxide gas generating device CG in the sterilizing device AS of the first embodiment, Since it is the same as the 1 circulation fan 231 and the 3rd filter part 232, the description is abbreviate | omitted.

  The 3rd space formation body 41 is a member which forms predetermined | prescribed space similarly to the 1st space formation body 21, and is a room (room) of a building in this embodiment. The third circulation fan 42, the chlorine dioxide gas generator CG, and the fifth filter unit 43 are stacked in this order, and are disposed in the third space forming body 41. Therefore, the 5th filter part 43 is arrange | positioned between the said predetermined space via the 3rd circulation fan 42 and the chlorine dioxide gas generator CG.

  In the sterilization apparatus HR having such a configuration, the chlorine dioxide gas generator CG and the third circulation fan 42 are actuated to generate wind in the predetermined space formed by the third space forming body 41, and chlorine dioxide. Chlorine dioxide gas generated by the gas generator CG is put on the wind and supplied to the predetermined space via the fifth filter unit 43. For this reason, people, articles, etc. in the third space formation body 41 are sterilized by chlorine dioxide gas, and a sterilization space can be constructed in the building. And the microbe collect | recovered by the 5th filter part 43 can be disinfected with this chlorine dioxide gas, and the fall of the microbe collection capability in the 5th filter part 43 can be suppressed. Furthermore, since the chlorine dioxide gas generator CG is designed as described above, the same effect as that of the first embodiment is achieved, and chlorine dioxide gas in the predetermined space formed by the third space forming body 41 is produced. Concentration can be controlled.

  In the first to third embodiments, the first to third filter units 223-1, 223-2, 233, the fourth filter unit 33, and the fifth filter unit 43 may be omitted.

  Further, the ultraviolet LED in the chlorine dioxide gas generator CG used in the first to third embodiments is a device having a built-in rectifier circuit that rectifies alternating current into direct current so that alternating current power can be supplied. An ultraviolet LED that does not incorporate such a rectifier circuit may be used.

  FIG. 14 is a diagram showing another electrical configuration of the chlorine dioxide gas generator used in the sterilization apparatus shown in FIG. More specifically, for example, as shown in FIG. 14, the chlorine dioxide gas generator CGa using the ultraviolet LED that does not include the rectifier circuit includes a gas generator 11a (111, 112D-1, 112D-2). The control unit 12, the fan 13, the temperature adjustment unit 14 (141, 142-1, 142-2), and the operation time integration unit 15 (151-1, 151-2, 152, 152a, 153, 153a). The first and second dust removing filters 16 and 17, the power supply unit 18 (181 to 187), the first and second AC-DC converters 19-1 and 19-2, the gas generating unit 11a, and the control unit 12 , Fan 13, temperature adjusting unit 14, operating time integrating unit 15, first and second dust filter 16, 17, power supply unit 18, and first and second AC-DC converters 19-1, 19-2. And a second housing (housing) HS box-shaped rectangular parallelepiped shape volume. In addition, since FIG. 14 shows an electrical structure, the gas source 111, the 1st dust removal filter 16, and the 2nd dust removal filter 17 are abbreviate | omitting illustration. In the chlorine dioxide gas generator CGa shown in FIG. 14, the control unit 12, the fan 13, the temperature adjustment unit 14 (141, 142-1, 142-2), and the operating time integration unit 15 (151-1, 151-2, 152). 152a, 153, 153a), the first and second dust removing filters 16, 17, and the power supply unit 18 (181 to 187), including their electrical connection modes, respectively, are shown in FIG. 2 and FIG. Control unit 12, fan 13, temperature adjustment unit 14 (141, 142-1, 142-2), operation time integration unit 15 (151-1, 151-2, 152, 152a, 153, 153a) in the chlorine gas generator CG ), The same as the first and second dust removing filters 16 and 17 and the power supply unit 18 (181 to 187), the description thereof is omitted.

  The first and second AC-DC converters 19-1 and 19-2 are constant current power supplies that convert AC power into DC power, respectively. The gas generation unit 11a is replaced with the first and second ultraviolet LEDs 112-1 and 112-2 as the first and second light emitting units 112-1 and 112-2 in the gas generation unit 11, and the first and second ultraviolet LEDs 112D. -1 and 112D-2 are the same as the gas generation unit 11 except that the description is omitted. The first and second ultraviolet LEDs 112D-1 and 112D-2 are the same as the first and second ultraviolet LEDs 112-1 and 112-2, respectively, except that they do not have a built-in rectifier circuit. Omitted.

  The first AC-DC converter 19-1 is connected to the control unit 12 (the program timer 12 in this embodiment) at its input terminal, and AC power is supplied to the first AC-DC converter 19-1 via the control unit 12. Supplied. The first AC-DC converter 19-1 is connected to the first ultraviolet LED 112D-1 at its output terminal, and converts the supplied AC power into a constant current DC power having a predetermined current value. The converted constant current DC power is supplied from the output terminal to the first ultraviolet LED 112D-1. The first ultraviolet LED 112D-1 emits ultraviolet light having a wavelength of 350 nm, for example, when supplied with constant current direct current power from the first AC-DC converter 19-1. Similarly, the second AC-DC converter 19-2 is connected to the control unit 12 (the program timer 12 in this embodiment) at its input terminal, and the second AC-DC converter 19-2 is connected to the control unit 12 via the control unit 12. AC power is supplied. The second AC-DC converter 19-2 is connected to the second ultraviolet LED 112D-2 at its output terminal, and converts the supplied AC power into a constant current DC power having a predetermined current value. The converted constant current DC power is supplied from the output terminal to the second ultraviolet LED 112D-2. The second ultraviolet LED 112D-2 emits ultraviolet light having a wavelength of 350 nm, for example, when supplied with a constant current DC power from the second AC-DC converter 19-2. The first ultraviolet LED 112D-1 irradiates the emitted ultraviolet light on one surface of the gas source 111, and the second ultraviolet LED 112D-2 irradiates the emitted ultraviolet light on the other surface of the gas source 111. The gas source 111 generates chlorine dioxide gas by being irradiated with these ultraviolet rays.

  In the example shown in FIG. 14, the first and second UV LEDs 112D-1 and 112D-2 are individually provided with the first and second AC-DC converters 19-1 and 19-2, respectively. One AC-DC converter 19 having a constant current capacity twice that of the first AC-DC converter 19-1 (or the second AC-DC converter 19-2) is shared. The DC converter 19 may supply power to the first and second ultraviolet LEDs 112D-1 and 112D-2, respectively.

  In order to express the present invention, the present invention has been properly and fully described through the embodiments with reference to the drawings. However, those skilled in the art can easily change and / or improve the above-described embodiments. It should be recognized that this is possible. Therefore, unless the modifications or improvements implemented by those skilled in the art are at a level that departs from the scope of the claims recited in the claims, the modifications or improvements are not covered by the claims. To be construed as inclusive.

AS, CR, HR; disinfection device, CG, CGa; chlorine dioxide gas generator, 11, 11a; gas generator, 12; controller, 21; first space forming body, 31; second space forming body, 32 2nd circulation fan, 33; 4th filter part, 41; 3rd space formation body, 42; 3rd circulation fan, 43; 5th filter part, 111; Gas source, 112 (112-1, 112-2; 112D-1, 112D-2); light emitting unit, 141; heater, 142-2; temperature controller, 223-1; first filter unit, 223-2; second filter unit, 231; first circulation fan, 233; Third filter section

Claims (6)

A gas generation unit that generates chlorine dioxide gas and supplies the generated chlorine dioxide gas to a predetermined space;
Based on the volume of the predetermined space, an on-time for generating the chlorine dioxide gas in the gas generation unit so that the concentration of the chlorine dioxide gas in the predetermined space is within a predetermined target concentration range, and A chlorine dioxide gas generator, comprising: a control unit that controls an off time during which generation of chlorine dioxide gas is stopped. 2. The carbon dioxide according to claim 1, further comprising a temperature adjusting unit that adjusts a temperature of the gas generating unit such that a concentration of chlorine dioxide gas in the predetermined space falls within the predetermined target concentration range. Chlorine gas generator. The gas generating unit includes a light emitting unit that emits ultraviolet rays, and a gas source that generates chlorine dioxide gas by receiving the ultraviolet rays emitted from the light emitting unit,
The distance between the light emitting unit and the gas source is adjusted so that the concentration of chlorine dioxide gas in the predetermined space is within the predetermined target concentration range. 2. The chlorine dioxide gas generator according to 2. A space forming body that forms a predetermined space; and a chlorine dioxide gas generator that supplies chlorine dioxide gas to the predetermined space formed by the space forming body,
The said chlorine dioxide gas generator is the chlorine dioxide gas generator of any one of Claim 1 thru | or 3, The sterilizer characterized by these. 5. The space forming body is any one of a storage for storing articles in a locker, an air shower room for performing air shower in an air shower device, and a room in a building. Sterilization equipment. The air blowing part which produces a wind in the said predetermined space, The filter part arrange | positioned between the said air blowing part and the said predetermined space is further provided. The Claim 4 or Claim characterized by the above-mentioned. 5. The sterilization apparatus according to 5.