JP5435619B2 - Surface sterilizer - Google Patents

Description

  The present invention relates to a method and an apparatus for efficiently sterilizing a surface or a wide area such as a space where a person enters.

  In recent years, for example, methicillin-resistant Staphylococcus aureus (MRSA) and other drug-resistant bacteria tend to increase the damage caused by infectious diseases, and pathogens harmful to human bodies can be surely killed in a wide area in hospitals and nursing homes. Development of technology that can be done is desired.

  In general, as a method for preventing infection caused by pathogens, there are known methods for suppressing the growth of pathogens using drugs, and methods for destroying pathogens by irradiating ultraviolet light to destroy the pathogen's genetic information. . In the former case, the pathogen may acquire resistance to the drug by using the drug continuously or repeatedly, and the drug may eventually become ineffective. In the latter case, although the pathogen can be surely killed, the ultraviolet light has an adverse effect on the human body, so that there is a problem that it is not suitable as a means for sterilizing a wide space where people enter and exit. In addition, since ultraviolet light rapidly deteriorates the synthetic resin, there is a problem in that it is not suitable as a permanent sterilization means around us.

  In recent years, near-ultraviolet light has attracted attention as a light beam that does not cause adverse effects on the human body and can sufficiently kill pathogens. The prior art relating to a method and apparatus that can safely and efficiently sterilize an area with respect to a person has not been materialized at present.

  However, as a conventional technique related to a method or apparatus for sterilizing a very narrow area or a specific place using ultraviolet light or near ultraviolet light, or a method or apparatus for sterilizing a wide area or space using a medicine or the like, For example, the following inventions and technical contents are known.

Patent Document 1 has a name of “a method for enhancing drug sensitivity of a drug-resistant pathogenic microorganism and a method for preventing the appearance of highly drug-resistant bacteria”, and has a wavelength of 400 to 410 nm peaking at 405 nm in the presence of an antibacterial substance. A method for enhancing the susceptibility of pathogenic microorganisms having drug resistance to antibacterial substances by irradiating light from light emitting diodes (LEDs), and high drug resistance by irradiating LED light in the presence of a high concentration of antibacterial substances A method for preventing the appearance of pathogenic microorganisms such as methicillin resistant Staphylococcus aureus (MRSA) having

In the invention disclosed in Patent Document 1, the light intensity irradiated to the resistant bacteria of LED light is preferably 100 μW to 100 mW / cm ² , most preferably ² to 10 mW / cm ² . Although the irradiation method to the irradiation object differs depending on the structure of the irradiation apparatus, the shape of the object, and the existing environment, it is close (5 to 20 cm) when targeting animals such as humans and plants. Alternatively, it is disclosed that the process is performed at an interval of 200 cm from the object.

  Patent Document 2 has the name “refrigerator”, and includes a light source for lighting in the storage space and a light source for enhancing the bacteriostatic effect (for example, light having a wavelength including blue of 400 nm or more and 500 nm or less). A refrigerator that keeps the refrigerator clean and improves freshness is disclosed. In the invention described in Patent Document 2, as compared with the case of using ultraviolet rays (for example, wavelength 254 nm), there is an adverse effect caused by ultraviolet rays such as promotion of lipid oxidation of food by ultraviolet irradiation, promotion of deterioration of resin, and influence on human body. It is disclosed that it can be avoided and is effective.

  In Patent Document 3, the name “ultraviolet sterilizer and ultraviolet sterilization method” is used, and light emitted from a light emitting chip (for example, a light emitting diode (LED)) having a main emission peak in a wavelength region of 360 to 380 nm is focused by a condenser lens. An invention related to a virus ultraviolet sterilizer that inactivates a virus in a direct (light-collecting) irradiation section by radiating is disclosed. In the ultraviolet sterilization apparatus disclosed in Patent Document 3, even in a portion where the ultraviolet rays are not sufficiently irradiated (indirect irradiation portion; a portion whose light intensity is about 1/100 of that of the light collecting portion (direct irradiation portion)), It is disclosed that the sterilizing effect of colored liquid can be dramatically improved.

  Patent document 4 has the name “photodisinfection method and apparatus using flash pulses”, and flash pulses at a predetermined interval from a blue light emitting diode array (for example, a light source “blue LED” has a wavelength of 419 nm to 519 nm and a peak wavelength of 466 nm). And a sterilization by irradiating an object to be sterilized at a predetermined distance and disinfecting.

  In addition, if attention is given to sterilization in a room where people come in and out, as a sterilization method that does not use light, a method of circulating ozone by supplying ozone gas or positive and negative ions into the room (for example, Patent Document 5), or an ultrasonic humidifier A method of atomizing electrolytic anodic water and spraying and diffusing it into the space (for example, Patent Document 6) is also disclosed.

JP 2008-79510 A JP 2007-309631 A JP 2008-161095 A JP 2004-275335 A JP 2008-249324 A JP 2006-149995 A

  In the prior literature as described above, regarding the method of safely and efficiently sterilizing (or bacteriostatically) any wide area to humans and others, the technical contents are necessarily sufficiently disclosed. I can't say that.

  For example, Patent Document 1 describes that near-ultraviolet rays can be irradiated 200 cm away from the sterilization target, but this enhances the susceptibility of pathogenic microorganisms having drug resistance. The treatment is facilitated, and no mention is made of the presence or absence of a bactericidal effect.

  In addition, each of the inventions disclosed in Patent Documents 2 to 4 is a sterilization method or apparatus using light with a wavelength that is safe for humans, but from a light source for sterilization to a surface to be irradiated (a surface for which sterilization is desired). There is only a knowledge of up to several tens of centimeters in terms of the distance to, and it can safely and efficiently sterilize a wide area in a room where people go in and out (especially up to 2 meters in height). It cannot be said that the technical contents necessary as a method or apparatus are sufficiently disclosed, and there is a problem that it is not suitable for use in such applications.

  Moreover, in the invention disclosed in Patent Document 5, a technique using ozone gas or positive and negative ions is disclosed. However, in the former case, ozone gas is harmful to the human body, so it should be used in a room used by a person. Can not be performed, or after the sterilization treatment, the ozone gas concentration in the room is sufficiently lowered, or equipment for detecting the state is required, so the device becomes large and it is difficult to make a movable compact form there were. Even in the latter case, there is a problem that the apparatus becomes large, and it is necessary to prepare or replenish the supply source of positive and negative ions as needed, which places a burden on the operator. In addition, positive and negative ions may corrode metals, and there is a problem that they are not suitable as a sterilizing means that is constantly used in daily space.

  Furthermore, the invention disclosed in Patent Document 6 discloses a method of atomizing a sterilizing chemical solution and releasing the space. However, the sterilizing apparatus becomes large, and the sterilizing chemical solution is replenished or the room is ventilated after the sterilizing treatment. It was necessary to do and was complicated. In addition, there is a possibility that the electric appliance may break down due to the sterilizing chemical solution, and there is a problem that it is not suitable as a sterilizing means that is constantly used in a daily space.

  In addition to those described above, there are sterilization methods using chemical arrangements such as naphthalene and fumigation sterilization methods using ethylene oxide, etc., but this is suitable for reliably sterilizing the entire space where people enter and exit. It is a practical sterilization means that can be easily used, such as requiring a large amount of drug, causing problems (secondary contamination) due to transfer or adhesion of the drug used for sterilization, and requiring time for ventilation. That wasn't true.

  The present invention has been made in response to such a conventional situation, and an object of the present invention is to easily and reliably sterilize the surface of an arbitrary wide area, and to perform human body and covering during and after the sterilization process. An object of the present invention is to provide a surface sterilization method and apparatus that do not adversely affect an irradiation object.

In order to achieve the above object, the surface sterilization apparatus according to the first aspect of the present invention is a light source that emits light having a maximum light intensity at 400 nm to 410 nm (hereinafter, this light is referred to as near ultraviolet light). When the position adjustment unit for adjusting the distance between the irradiated object and the light source based on the control signal, a sensor for sensing knowledge intensity of near-ultraviolet light to be irradiated onto the irradiation target, the off the light emission of the light source control and calculates the illuminance of the near ultraviolet light to be irradiated onto the irradiation target based on a detection signal from the sensor, it transmits a control signal so that the illuminance value is 0.82mW / cm ² or more, the illuminance and determined Ru controller by calculation irradiation time required for near-ultraviolet light from the values, the timer for measuring the irradiation time of the near-ultraviolet light, with intensity values, to have a, and Table radical 113 that displays the irradiation time required It is a feature.
The surface sterilization apparatus according to the second aspect of the present invention includes a light source that emits light having a maximum light intensity at 400 nm to 410 nm (hereinafter, this light is referred to as near-ultraviolet light) on the irradiation target, and the irradiation target. A position adjustment unit that adjusts the distance between the target and the light source, a sensor that senses the intensity of near-ultraviolet light irradiated on the irradiated target, and the light emission and extinction of the light source are controlled, based on the detection signal from the sensor Calculates the illuminance value of near-ultraviolet light irradiated on the irradiation target and calculates the necessary time for irradiation of near-ultraviolet light from this illuminance value, a timer for measuring the irradiation time of near-ultraviolet light, and illuminance And a display unit for displaying the required irradiation time together with the value.

In the first and second aspects of the present invention, the near-ultraviolet light is irradiated for at least 2 hours so that the intensity on the irradiation target is 0.82 mW / cm ² or more. It has the effect of affecting almost 100% of the pathogens present on the object. On the other hand, when a part or all of the irradiation target is made of synthetic resin, the irradiation target is compared with the case of using ultraviolet rays (for example, a wavelength of about 254 nm) used in a conventional germicidal lamp. Since it does not deteriorate rapidly, the damage is suppressed and the human body is hardly adversely affected.

In addition, when using near-ultraviolet light used in the inventions of claims 1 and 2, there is no residue left on the surface to be irradiated, as in the conventional sterilization method by spraying the sterilizing agent, so that secondary contamination is not caused. It also has the effect of eliminating the cause of the occurrence of

In the first and second aspects of the invention, for example, when near-ultraviolet light is used to repeatedly sterilize the entire room, fading of decorative items such as indoor walls and paintings, or synthetic resin products. Since there is a slight possibility of causing deterioration, in order to avoid such a problem, the intensity of near-ultraviolet light on the surface of the irradiation target is kept within the range of 0.82 mW / cm ^{2 to 2} mW / cm ² . It is desirable to perform sterilization in the state. In the first and second aspects of the invention, the light source has an effect of irradiating near ultraviolet light as described above. The position adjustment unit supports and fixes the light source and has an effect of enabling adjustment of the distance between the irradiation target and the light source. Furthermore, the sensor has the effect of transmitting a signal relating to the intensity detection knowledge intensity of near-ultraviolet light on an irradiated object to the control unit. And while a control part controls light emission and extinction of a light source, while calculating the illuminance value of near-ultraviolet light irradiated on an irradiation object based on the signal transmitted from a sensor, from the obtained illuminance value It has the effect | action of calculating | requiring the irradiation required time of near ultraviolet light by a calculation . And a control part has the effect | action of controlling the action | operation of a position adjustment part as needed (in the case of Claim 1) . Alternatively, the control unit moves the light source (including the concept of the entire apparatus according to claim 2 including the light source) so that the illuminance value of near-ultraviolet light on the irradiation target is 0.82 mW / cm ² or more. (In the case of claim 2) or a signal for displaying on the display section that the illuminance value of near-ultraviolet light on the irradiated object is smaller than 0.82 mW / cm ² It has the effect | action of transmitting to a part. Furthermore, the timer has an effect of measuring the irradiation time of near ultraviolet light. The display unit has an effect of displaying the necessary irradiation time and the illuminance value calculated by the control unit. In this way, the provision of the display unit has an effect of prompting the user to move the light source or adjust the light emission output of the light source as necessary (in the case of claim 2) . Moreover, it has the effect | action of enabling confirmation of the irradiation time of a near ultraviolet light, or irradiation required time with respect to a user.

The surface sterilization apparatus according to claim 3 is the surface sterilization apparatus according to claim 2, wherein when the illuminance value is less than 0.82mW / cm ² , it is characterized in further comprising a warning lamp or the voice generating unit for transmitting the status to the user.

Present aspect, in addition to the same effect as the invention described in claim 2, warning light or sound generating unit, the illuminance of the near ultraviolet light to be irradiated onto the irradiation target within 0.82mW / cm ² When the condition is not satisfied, the situation is notified to the user by a blinking signal or voice.

According to the first and second aspects of the present invention, it is possible to irradiate an object in a wide area where a person can go in and out and work while standing at an arbitrary distance of 1 m or more. It is possible to sterilize easily and reliably sterilization targets such as methicillin-resistant Staphylococcus aureus (MRSA). Of course, the present invention is effective not only against methicillin-resistant Staphylococcus aureus but also against Pseudomonas aeruginosa and other bacteria regardless of the presence or absence of resistance.

In addition, the surface sterilization apparatus according to claims 1 and 2 does not require the construction of a system related to human safety because there is no concern about near-ultraviolet light adversely affecting the human body during and after sterilization. Since the intensity of near-ultraviolet light used in the inventions according to items 1 and 2 is not so strong, a person can engage in work in an area to be irradiated even during near-ultraviolet light irradiation.

That is, according to the first and second aspects of the invention, not only when the irradiation of the near ultraviolet light for sterilization is interrupted, but also during the sterilization treatment according to the first and second aspects of the invention (near ultraviolet) Even during the light irradiation), the user can use the area to be irradiated for the purpose of work or the like regardless of usual.

In addition, the near-ultraviolet light used in the inventions of claims 1 and 2 does not cause a rapid deterioration of the synthetic resin product even if the synthetic resin product is irradiated for a long time or repeatedly. Therefore, the irradiated object can be repeatedly sterilized without worrying about material deterioration, and each time, there is an effect that a high sterilization effect can be always obtained or a high sterilization effect can be maintained.

Further, unlike the case where sterilization is performed using chemicals, the sterilizing component does not remain or adhere to the object to be sterilized (occurrence of secondary contamination), so that a person does not feel uncomfortable after the sterilization operation. In addition, since there is no need for preparation or replenishment of the medicine, there is also an effect that the burden on the worker for the sterilization work can be greatly reduced. Further, according to the first and second aspects of the present invention, by including the sensor and the position adjusting unit, the intensity of near-ultraviolet light on the irradiation target 1 m or more away from the light source is always 0.82 mW / cm ² or more. So that the position of the light source can be automatically moved (in the case of claim 1) . Alternatively, since the invention according to claim 1 can be moved by a (manual) operation (in the case of claim 2) , a reliable bactericidal effect can be obtained on the irradiation target. In addition, since the inventions according to claims 1 and 2 include the sensor, the control unit, and the display unit, it is possible to easily confirm whether or not the target area can be reliably sterilized. Furthermore, it is possible to confirm the time required morphism irradiation can help ensure a sterilizing effect by near ultraviolet light irradiation.

In addition to the same effect as that of the invention described in claim 2 , the invention described in claim 3 of the present invention more reliably ensures that the illuminance value of near-ultraviolet light on the irradiated object is less than 0.82 mW / cm ^2. Can be communicated to the user.

It is a conceptual diagram of the surface sterilization method which concerns on Example 1 of this invention. It is a conceptual diagram of the surface sterilization method which concerns on Example 2 of this invention. It is a perspective view which shows the external appearance of the surface sterilizer which concerns on Example 3 of this invention. It is a perspective view which shows the external appearance of the surface sterilizer which concerns on Example 4 of this invention. It is a photograph which shows the bactericidal effect at the time of irradiating near ultraviolet light from the position 1 m away to the petri dish which apply | coated methicillin resistant Staphylococcus aureus (MRSA) for a fixed time. It is a photograph which shows the bactericidal effect at the time of irradiating near ultraviolet light for a fixed time from the position 2 m away to the petri dish which apply | coated methicillin resistant Staphylococcus aureus (MRSA).

  Hereinafter, a surface sterilization method and an apparatus thereof according to an embodiment of the present invention will be described in detail with reference to Examples 1 to 4.

  Conventionally, when it is necessary to sterilize indoor surfaces or any wide area, it is necessary to use a sterilizing lamp or chemical that emits ultraviolet light having a high sterilizing effect. In the former case, a sufficient sterilizing effect is expected. However, when the sterilization treatment is repeated, the object to be sterilized made of synthetic resin may be rapidly deteriorated, or the color for decoration of the object to be sterilized may be rapidly faded. In the latter case, secondary contamination of the object to be sterilized by the drug is likely to occur, and it cannot be said that it is a sterilizing means that can be easily and repeatedly used.

  Under such conventional circumstances, the inventor, in the process of earnestly sterilizing light, naturally uses a considerable amount of light to obtain a certain sterilizing effect with light from a light emitting diode (LED) having a 405 nm peak wavelength. While it is speculated that the intensity is necessary, unexpectedly, it was found that a sufficient bactericidal effect can be expected by irradiating even a low intensity light for a certain period of time, and it is composed of existing light emitting diodes (LEDs). By using a simple and inexpensive lighting device, it is possible to sterilize hospital-acquired bacteria, such as MRSA, not only by inhibiting growth but also by reducing the number of bacteria by light irradiation at a relatively long distance of 2 meters. The invention of the sterilization method and the sterilization apparatus which can be carried out was led.

  The surface sterilization method according to Example 1 of the present invention will be described in detail with reference to FIG. FIG. 1 is a conceptual diagram of a surface sterilization method according to Embodiment 1 of the present invention.

As shown in FIG. 1, in the surface sterilization method 1a according to the first embodiment, a light source 2 is arranged at least 1 m or more away from an object to be sterilized 3 that needs to be sterilized at an arbitrary place, The light 4 having a maximum light intensity of 400 nm to 410 nm on the sterilization target 3 (hereinafter simply referred to as “near ultraviolet light 4”), the intensity (irradiation intensity) on the sterilization target 3 is 0.82 mW / cm. Irradiation is performed for at least 2 hours while maintaining ² or more.

  In the surface sterilization method 1a according to the first embodiment, the pathogen attached on the sterilization target 3 is killed by irradiating the sterilization target 3 in an arbitrary place with the near ultraviolet light 4. As a result, the sterilizing effect on the object 3 to be sterilized is exhibited.

  Therefore, according to the surface sterilization method 1a according to the first embodiment, there is an effect that an arbitrary wide area irradiated with the near ultraviolet light 4 can be sterilized efficiently.

  Moreover, when near ultraviolet light 4 is used as a light beam that brings about a sterilizing effect on the surface of the object to be sterilized 3, even if the near ultraviolet light 4 is directly irradiated to a person, or near ultraviolet light 4 enters the human eye. There is no fear of adverse effects. Further, unlike the ultraviolet light (for example, a wavelength of about 254 nm) used in the ultraviolet germicidal lamp, the near ultraviolet light 4 does not cause the synthetic resin to rapidly deteriorate. Can be sterilized repeatedly. As a result, the to-be-sterilized target 3 in an arbitrary place can be kept hygienic.

  Further, in the case of the surface sterilization method 1a according to Example 1, as in the case of sterilization using a sterilizing component such as a drug, ventilation is necessary after the sterilization treatment, or the sterilizing component attached to the object to be sterilized 3 is sterilized. There is no risk of causing undesirable effects other than the effects. In addition, since there is no need to replenish or prepare medicines, sterilization can be performed very simply. As a result, there is an effect that troubles and labor of the sterilization work can be greatly reduced.

  That is, according to the surface sterilization method 1a according to the first embodiment, the state before and after the sterilization treatment is not limited to the presence or absence of the pathogen on the target 3 to be sterilized without any special treatment by the operator. Since there is no change, there is an effect that defects caused by the sterilization treatment can be made almost zero.

In particular, in the surface sterilization method 1a according to Example 1, the intensity of the near ultraviolet light 4 reaching the object to be sterilized 3 is set to 0.82 mW / cm ² or more so that the near ultraviolet light 4 is irradiated for 2 hours. The sterilizing effect on the surface of the object 3 to be sterilized can be almost 100%.

  In this case, since the target 3 to be sterilized can be sterilized more reliably, the risk that an infectious disease or the like is caused by a pathogen can be greatly reduced, and the safety of the target 3 to be sterilized after sterilization is further increased. It has the effect of being able to.

The surface sterilization method according to Example 2 of the present invention will be described in detail with reference to FIG. (Particularly corresponding to claim 1)
FIG. 2 is a conceptual diagram of a surface sterilization method according to Embodiment 2 of the present invention. In addition, the same code | symbol is attached | subjected about the part same as what was described in FIG. 1, and the description about the structure is abbreviate | omitted.

  As shown in FIG. 2, the surface sterilization method 1 b according to the second embodiment arranges a stationary type or a detachable type light source 2 in a space 5 in which light from the outside can be shielded, and an optical environment in the space 5. Is the near ultraviolet light 4 only, and the state is maintained for 2 hours.

  The surface sterilization method 1a according to the first embodiment can sterilize a wide area at an arbitrary place, whereas the surface sterilization method 1b according to the second embodiment can be sterilized by the inner surface of the space 5 such as a room ( (Including the inner surface of the door 6a and the indoor side of the light shielding material 8.) The area irradiated with the near-ultraviolet light 4 can be sterilized all over the object to be sterilized 3.

  The space 5 here refers to, for example, the interior of a building where people enter and exit, a partitioned space, or breeding of livestock and animals, and storage of plants (including quarantine stations and quarantine stations). For example, a partitioned space. Further, the interior of the building is a space 5 having a door 6a as a doorway 6 and a window 7 having a light shielding material 8 (for example, a curtain, a blind, etc.) as shown in FIG.

  The other actions and effects of the surface sterilization method 1b according to the second embodiment are the same as those of the surface sterilization method 1a according to the first embodiment.

  Further, in FIG. 2, the case where the light source 2 that emits near ultraviolet light 4 is provided on the wall surface of the space 5 is described as an example. However, the light source 2 is installed on the floor surface in addition to the wall surface that forms the space 5. Or a ceiling not shown. Further, the light source 2 may be configured to be removable from the space 5 and moved. Furthermore, the light source 2 may be provided at a specific location in the space 5, or a plurality of light sources 2 may be scattered on the wall surface of the space 5.

  The surface sterilization methods 1a and 1b according to the first embodiment and the second embodiment described above are both inside the space that is not provided with ventilation means or inside a space that cannot restrict human access for a long time. Particularly suitable for side sterilization.

Also in the surface sterilization method 1b according to the second embodiment, the intensity of the near-ultraviolet light 4 on the inner side surface of the room that is the object to be sterilized 3 is 0.82 mW / cm, similarly to the surface sterilization method 1a according to the first embodiment. ^By setting it to ² or more, the bactericidal effect of the pathogen on the surface of the object 3 to be sterilized can be almost 100%. In this case, the surface safety of the to-be-sterilized object 3 after the sterilization treatment is further enhanced, and it is possible to effectively prevent the occurrence of infectious diseases caused by the diseased specimen.

  A surface sterilization apparatus according to Embodiment 3 of the present invention will be described in detail with reference to FIG. In particular, the surface sterilization apparatus according to the third embodiment is an apparatus that emits near-ultraviolet light 4 used in the surface sterilization methods 1a and 1b according to the first and second embodiments. This is shown as a specific mode, and its action and effect are the same as those of the surface sterilization methods 1a and 1b according to the first and second embodiments.

  FIG. 3 is a perspective view showing the appearance of the surface sterilizer according to Embodiment 3 of the present invention. In addition, the same code | symbol is attached | subjected about the same part as what was described in FIG. 1 or FIG. 2, and the description about the structure is abbreviate | omitted.

As shown in FIG. 3, the surface sterilization apparatus 9a according to the third embodiment is configured such that the light source 2 is supported and fixed by the position adjusting unit 12a and is movable on the ground surface or in the vertical vertical direction. The control part 16 for controlling light emission, light extinction, etc. is provided. In addition, the surface sterilizer 9a according to the third embodiment receives the illuminance meter connected to the control unit 16 via the extension cord 32 (the length is 2 meters or more, or even if the length is close to 5 meters). In addition to the function of controlling the light source 2, the control unit 16 calculates the illuminance value (the light emission intensity of the light source 2) based on the signal transmitted from the illuminometer light receiving unit 31, and this A display unit 33 for displaying the illuminance value result obtained by the calculation is provided.
The position adjusting unit 12a, which is a mechanism for moving the installation position of the light source 2, includes, for example, a leg portion 14 provided with casters 15 and a support shaft 13 standing on the leg portion 14. Note that the support shaft 13 may include a telescopic mechanism 20 that slides the light source 2 in the axial direction of the support shaft 13. In this case, there is an effect that the mounting position of the light source 2 in the vertical vertical direction can be freely changed.

  Further, light emission and extinction of the light source 2 can be switched by a switch 18 provided in a control unit 16 connected to the light source 2 via a wiring cord 17. Furthermore, the control unit 16 is connected to a wiring cord 17 having a power intake unit 19 for taking in power supplied from the outside to the light source 2 and a control mechanism (not shown).

  Moreover, in Example 3, although the case where the planar light source which arrange | positioned several LED11 on the board | substrate 10 was used as an example and demonstrated as the light source 2 is demonstrated, the light which has the maximum of light intensity in 400 nm-410 nm is demonstrated. As long as it can irradiate (near-ultraviolet light 4) with high output, you may use things other than LED11.

In order to perform sterilization using the surface sterilization apparatus 9a according to Example 3 as shown in FIG. 3, the illuminometer light receiving unit 31 is disposed on the sterilization target 3 (not shown), and then the target sterilization is performed. The surface sterilizer 9a is moved to a position where the object 3 can be irradiated with near-ultraviolet light 4 by using the moving means 12a, the light source 2 is turned on by operating the switch 18 of the control unit 16, and the value of the display unit 33 May be confirmed to be a predetermined value (0.82 mW / cm ² or more). When the illuminance value of the near-ultraviolet light 4 detected by the illuminometer light receiving unit 31 is equal to or less than a predetermined value, the installation location of the surface sterilization apparatus 9a is more specifically specified so as to be equal to or higher than the predetermined value. The position of the light source 2 may be adjusted using the position adjustment unit 12a. In this case, the telescopic mechanism 20 may also be used as appropriate to adjust the light intensity of the near ultraviolet light 4 on the object to be sterilized 3 by adjusting the height position of the light source 2. The illuminometer light receiving unit 31 is a predetermined place of the surface sterilizing device 9a after the setting of the position of the surface sterilizing device 9a and the height position of the light source 2 is completed or when the illuminometer light receiving unit 31 is not used. It can be configured so that it can be stored and stored.

  According to the surface sterilization apparatus 9a according to Example 3 described above, sufficient intensity (illuminance value) of the near-ultraviolet light 4 for exhibiting the sterilizing effect can be obtained on the sterilization target 3 that needs to be sterilized. It can be confirmed whether or not. For this reason, the operator can appropriately change the installation position of the surface sterilization apparatus 9a based on the information displayed on the display unit 33 so that the near-ultraviolet light 4 having sufficient intensity is irradiated onto the object 3 to be sterilized. Therefore, it is possible to always ensure a sufficient intensity of the near ultraviolet light 4 on the object 3 to be sterilized.

  Therefore, it has the effect that the pathogen in the to-be-sterilized object 3 can be killed and sterilized.

  Although not specifically shown, the control unit 16 is provided with a light emission output adjustment unit that can adjust the light emission output of the light source 2, and the illuminance value of the near ultraviolet light 4 on the object to be sterilized 3 can be changed by the operation of the light emission output adjustment unit. You may comprise. In this case, the illumination value can be changed without moving the surface sterilizer 9a. Further, the surface sterilization apparatus 9a according to the third embodiment may include both the light emission output adjustment unit and the position adjustment unit 12a. In this case, the operability and flexibility of the surface sterilization apparatus 9a according to the third embodiment ( It can be expected to improve the usability and usage situation.

  Further, when the control unit 16 is not irradiated with the near-ultraviolet light 4 having sufficient intensity on the object to be sterilized 3, a warning light or a sound generation unit is provided so that the user can be notified of the situation by a flashing signal or voice. It may be provided.

Furthermore, by providing the illuminance meter light receiving unit 31, a portion where the illuminance value of the near ultraviolet light 4 irradiated on the surface of the object to be sterilized 3 is a predetermined value or more (for example, 0.82 mW / cm ² or more), that is, a sterilizing effect can be expected. There is an effect that the user can recognize the portion and a portion less than a predetermined value (for example, less than 0.82 mW / cm ² ), that is, a portion having a questionable sterilization effect. That is, the user can grasp and recognize up to which part a sufficient sterilizing effect can be expected in the region irradiated with the near ultraviolet light 4.

  In addition, irradiation of the near ultraviolet light 4 necessary for obtaining the illuminance value (irradiation intensity) of the near ultraviolet light 4 and the predetermined sterilization rate (bactericidal effect) on the sterilized target 3 for each bacterial species that becomes a pathogen Since the substantial sterilization effect is exhibited in the sterilization target 3 based on the illuminance value on the sterilization target 3 measured by the illuminometer light receiving unit 31 by grasping the relationship with time in advance. The necessary irradiation time can also be grasped in advance. In this case, the irradiation time necessary for sterilizing the target pathogen may be displayed on the display unit 33 of the control unit 16 as a timer.

  Although not shown, in the surface sterilization apparatus 9a according to the third embodiment, as a mechanism for moving the position of the light source 2, in addition to the caster 15 and the expansion / contraction mechanism 20 described above, the rotation angle and attachment angle of the light source 2 with respect to the support shaft 13 You may provide the angle adjustment mechanism (not shown) which can change freely.

  In this case, it is possible to irradiate the near-ultraviolet light 4 toward the light source 2 on the floor or ceiling, or on a desk or any other place. More specifically, there is an effect that the surface can be sterilized by irradiating various ultraviolet rays 4 to various things such as beds, bathtubs, breeding cages and containers such as animals.

  As described above, the surface sterilization apparatus 9a according to the third embodiment may include a light emission output adjusting unit for adjusting the light emission output of the near-ultraviolet light 4 emitted from the light source 2.

  In this case, by increasing the light emission output of the near-ultraviolet light 4 emitted from the light source 2, a sufficient sterilizing effect can be exhibited even when the near-ultraviolet light 4 is irradiated from a location far away from the object to be sterilized 3. Since it becomes possible, it has the effect that disinfection of a wider area can be enabled. The same applies to the surface sterilizer according to Example 4 shown below.

  Since the surface sterilization apparatus 9a according to the third embodiment as described above can be moved to an arbitrary place on the ground by including the position adjusting unit 12a, a permanent sterilization facility can be used as long as a power supply source can be secured. It has an effect that an arbitrary place where there is no water can be sterilized easily and reliably at any time without using a chemical solution or the like.

  Moreover, since it is not necessary to perform work such as ventilation after performing the sterilization treatment, the burden on the operator can be greatly reduced. Moreover, since the near ultraviolet light 4 does not have a bad influence with respect to a human body or a synthetic resin product, a person can also work on the spot, performing the sterilization process by the surface sterilizer 9a.

  Therefore, according to the surface sterilization apparatus 9a according to the third embodiment, the user can confirm an area that is easy to handle, high in safety, and can be expected to have a certain sterilization effect in a wide range 3 to be sterilized. It is possible to provide a sterilizing apparatus.

  In addition, in the surface sterilization apparatus 9a according to the third embodiment, the near-ultraviolet light 4 may be continuously irradiated from the light source 2 or may be irradiated with pulses. In the latter case, power consumption can be saved.

A surface sterilization apparatus according to Example 4 of the present invention will be described in detail with reference to FIG. (In particular, it corresponds to claim 2.)
FIG. 4 is a perspective view showing an appearance of a surface sterilizer according to Embodiment 4 of the present invention. The same parts as those described in FIGS. 1 to 3 are denoted by the same reference numerals, and description of the configuration is omitted.

  The surface sterilization apparatus 9a according to the third embodiment is configured to be movable on the ground, whereas the surface sterilization apparatus 9b according to the fourth embodiment is configured to be used by being suspended and fixed on the ceiling. Is.

  Furthermore, the surface sterilization apparatus 9b according to the fourth embodiment includes a CCD camera (Charge Coupled Device camera) 41 and an analysis unit 42 that converts signals from the CCD camera 41 into illuminance values as a mechanism (sensor) for detecting the intensity of light. I have. A position adjusting unit 12 b is provided as a mechanism for moving the position of the light source 2, and the position adjusting unit 12 b is composed of an expansion / contraction mechanism 20. However, instead of or in addition to the expansion / contraction mechanism 20 as the position adjustment unit 12b, in addition to the expansion / contraction mechanism 20, a rotation mechanism (not shown) of the light source 2 or an irradiation angle adjustment mechanism of the near ultraviolet light 4 by the light source 2 (not shown). ) May be provided.

  Note that the control unit 16 is the same as the control unit 16 according to the third embodiment for controlling the turning on and off of the light source 2 and the adjustment of the illuminance thereof in the surface sterilization apparatus 9b according to the fourth embodiment. Moreover, the sensor with which the surface sterilizer 9a which concerns on Example 3 is provided may be replaced with the sensor with which the surface sterilizer 9b which concerns on Example 4 is equipped, and vice versa.

  As shown in FIG. 4, the surface sterilizer 9b according to the fourth embodiment supports and fixes the light source 2 so as to hang from an attachment surface (not shown) on the back side of the light emitting surface of the light source 2, and is also illustrated. The position adjustment part 12b which enables adjustment of the distance of the to-be-sterilized target 3 and the light source 2 is provided, and the control part 16 is provided in the wiring cord 17 connected to the light source 2 or the position adjustment part 12b. Further, at the end of the position adjusting unit 12b that is not connected to the light source 2, a power intake unit 19 (for example, a power plug or the like) for taking in power from a power supply unit provided on a mounting surface (not shown) is provided. The power intake 19 is configured to function as a fixture to the mounting surface.

  The surface sterilization apparatus 9b according to Example 4 as described above has an effect that the surface can be efficiently sterilized by irradiating the near ultraviolet light 4 from the vertical upper side of the object to be sterilized 3 at an arbitrary position. .

  Moreover, in the surface sterilization apparatus 9b according to Example 4, as a method for detecting and measuring the irradiation intensity (illuminance value) of the near ultraviolet light 4 on the surface of the object to be sterilized 3 using the CCD camera 41, for example, FIG. As shown, a reference standard sheet 44 for converting sensitivity characteristics (spectral characteristics) for each light wavelength of the CCD camera into illuminance values is arranged on the surface of the area, and the CCD camera 41 is placed at a reference point 45 on the sheet 44. A measurement system that combines beams 46 from an sighting device 43 provided in the vicinity (infrared rays or the like visualized so as to be visible in red or the like with human eyes) can be used.

  In such a method, the positional relationship between the posture of the CCD camera 41 and the reference standard sheet 44 is grasped by irradiation of the beam 46 (of course, the position and posture of the light source 2 may be taken into consideration), and the CCD is used. The camera 41 is configured to capture the spectral characteristics of the upper surface of the reference standard sheet 44 irradiated with the near-ultraviolet light 4 and convert the light intensity of the near-ultraviolet light 4 into an illuminance value by the analysis unit 42.

  Regarding background light (background) when measuring the illuminance of near-ultraviolet light 4 by the CCD camera 41 (light reception), a measurement environment standard is appropriately set in advance such as light color, color rendering index state, or no light condition. The relationship between the spectral characteristic (so-called sensitivity characteristic) of the near-ultraviolet light 4 irradiated on the reference standard sheet 44 by the CCD camera 41 and the illuminance value under a predetermined background is examined in advance, and the control unit 16 It may be stored in an analysis unit (not shown) provided in FIG.

  Similarly to the surface sterilizer 9a according to the third embodiment shown in FIG. 3, the surface sterilizer 9b according to the fourth embodiment as described above uses the light source 2 for sterilization with the light intensity (illuminance value) on the surface of the object 3 to be sterilized. ) Can be moved so that the intensity is adjusted to a predetermined intensity, and the expected degree of sterilization effect of the object to be sterilized 3 to be sterilized can be confirmed and grasped in advance. It is possible to ensure the surface sterilizing effect of the object to be sterilized 3 desired by the person.

  Finally, with reference to FIG. 5 and FIG. 6, the results of tests conducted to verify the effects of the surface sterilization method and surface sterilization apparatus according to the present invention will be described.

  FIG. 5 is a photograph showing the bactericidal effect when near ultraviolet light is irradiated for a certain time from a position 1 m away from a petri dish coated with methicillin-resistant Staphylococcus aureus (MRSA). FIG. 6 is a photograph showing the bactericidal effect when near ultraviolet light is irradiated for a certain time from a position 2 m away from a petri dish coated with methicillin-resistant Staphylococcus aureus (MRSA).

  Here, the sterilization effect was verified for each of the case where the distance of the light source 2 from the object 3 to be sterilized was 1 m (Test 1) and 2 m (Test 2).

  In Test 1, a planar light source (light source) is configured using a plurality of light emitting diodes (LEDs) having a peak wavelength value of 405 nm, and MRSA (methicillin) adjusted to a predetermined concentration at a distance of 1 m from the light source. (Resistant Staphylococcus aureus) Place a circular petri dish coated with fungus solution, and each was irradiated with near-ultraviolet light 4 for 1 hour, 4 hours, 9 hours, 12 hours, 24 hours and then left at room temperature for 24 hours. This is a photo of the petri dish. In addition, a petri dish that does not irradiate near-ultraviolet light 4 at all is prepared as a comparison object, and a MRSA bacterial solution prepared in the same manner is applied. went.

  In Test 2, the same light source as in Test 1 was used, and a circular petri dish coated with MRSA bacterial solution adjusted to a predetermined concentration was placed at a distance of 2 m from this light source for 1 hour, 4 hours, and 9 hours, respectively. 12 is a photograph of a petri dish that was cultured for 24 hours after being irradiated with near-ultraviolet light 4 continuously for 24 hours. In addition, the petri dish which did not irradiate the near-ultraviolet light 4 at all as a comparison object was prepared, the MRSA bacterial solution was applied, and then a photograph was taken for those cultured for 24 hours in the same manner as other samples.

In Test 1, the light emission pulse frequency of the light source that emits near-ultraviolet light 4 is 200 Hz, and the light intensity of the object to be sterilized 1 m away from the light source (near-ultraviolet light 4 received at 1 m directly under the light source is dispersed to each wavelength. Each light intensity was integrated in terms of energy, and the calculated value was 0.82 mW / cm ² . In Test 2, the same light source as that used in Test 1 was used, and near-ultraviolet light 4 was continuously irradiated (no pulse emission). In Test 2, the light intensity of the object to be sterilized 1 m away from the light source was 0.82 mW / cm ² .

  In each of the above tests, after standing or culturing for 24 hours, the number of colonies on each plate (petri dish) was counted, and the number of colonies for the comparison target section (plate that was not irradiated with near ultraviolet light 4). The bactericidal effect was evaluated from the difference.

In this test shown in FIG. 5 and FIG.
After adjusting the MRSA bacterial solution in Broth (Lennox) liquid culture so that the optical density, that is, OD600 nm is 0.1, the diluted MRSA solution is 1/1000, and then 0.1 ml of the bacterial solution is added to 0.6 ml of physiological solution. In addition to saline, the plate (circular petri dish) was uniformly inoculated, and the surface of the plate was dried before use as a test material.

As shown in FIG. 5, in Test 1, the MRSA survival rate when irradiated with near-ultraviolet light 4 from a position 1 m away was 63% at an irradiation time of 1 hour, 2% at an irradiation time of 4 hours, and an irradiation time of 24 hours. It was 0%. In Test 2, MRSA could be sterilized almost 100% by continuous irradiation with near ultraviolet light 4 for 4 hours.

Therefore, even from a position 2 m or more away from the object to be sterilized, light having a maximum light intensity at a wavelength of 405 nm (near ultraviolet light 4) is used, and the intensity of the near ultraviolet light 4 on the surface of the object to be sterilized is 0. It can be said that MRSA can be sterilized and reduced to the number of bacteria considered not to cause nosocomial infection by irradiating for 4 hours while maintaining at .82 mW / cm ² or more.

  As described above, according to the present invention, a wide area such as a road surface where people can go in and out can be installed overhead so as not to obstruct people's traffic and work, and it is easy to use without using drugs or the like. It is a sterilization method and device that can be reliably sterilized and has little adverse effect on the human body and the object to be sterilized during or after the sterilization compared with conventional ultraviolet sterilization lamps. , Nursing homes, laboratories, breeding of livestock and animals, and storage of plants (including quarantine stations and quarantine stations), kitchens, toilets, bathrooms, large storage facilities, and other hygiene management Can be used in fields related to facilities and equipment that require

DESCRIPTION OF SYMBOLS 1a, 1b ... Surface sterilization method 2 ... Light source 3 ... Object to be sterilized (object to be irradiated) 4 ... Near-ultraviolet light (light having a maximum light intensity at 400 nm to 410 nm) 5 ... Space 6 ... Entrance / exit 6a ... Door 7 ... Window DESCRIPTION OF SYMBOLS 8 ... Light shielding material 9a, 9b ... Surface sterilizer 10 ... Board | substrate 11 ... LED 12a, 12b ... Position adjustment part 13 ... Support shaft 14 ... Leg part 15 ... Moving means (caster) 16 ... Control part 17 ... Wiring cord 18 ... Switch DESCRIPTION OF SYMBOLS 19 ... Electric power taking-in part 20 ... Telescopic mechanism 31 ... Illuminance meter light-receiving part 32 ... Telescopic cord 33 ... Display part 41 ... CCD camera 42 ... Analysis part 43 ... Aiming device 44 ... Reference standard sheet 45 ... Reference point 46 ... Beam

Claims (3)

A light source that emits light having a maximum light intensity at 400 nm to 410 nm (hereinafter, this light is referred to as near-ultraviolet light) on the irradiation target;
A position adjusting unit that adjusts the distance between the irradiation target and the light source based on a control signal ;
A sensor for sensing knowledge the intensity of the near-ultraviolet light to be irradiated the onto the irradiation target,
Controls off and light emission of the light source, on the basis of the detection signal from the sensor the irradiated onto the irradiation target by calculating the intensity of the near ultraviolet light, the illuminance value is 0.82mW / cm ² or more and determined Ru controller by the control signal sent, calculating the irradiation time required for the near-ultraviolet light from the illuminance value such that,
A timer for measuring the irradiation time of the near ultraviolet light;
Together with the illumination value, surface disinfection apparatus characterized by having a table radical 113 that displays the required time morphism before KiTeru. A light source that emits light having a maximum light intensity at 400 nm to 410 nm (hereinafter, this light is referred to as near-ultraviolet light) on the irradiation target;
A position adjusting unit for adjusting a distance between the irradiation target and the light source;
A sensor for sensing knowledge the intensity of the near-ultraviolet light to be irradiated the onto the irradiation target,
Controls off and light emission of the light source, on the basis of the detection signal from the sensor the irradiated onto the irradiation target by calculating the intensity of the near ultraviolet light, irradiation required from the illuminance value of the near-ultraviolet light and determined Ru controller by calculation time,
A timer for measuring the irradiation time of the near ultraviolet light;
Together with the illumination value, surface disinfection apparatus characterized by having a table radical 113 that displays the required time morphism before KiTeru. Claim, wherein the control unit further comprising when the illuminance value is less than 0.82mW / cm ^2, a warning lamp or the voice generating unit for transmitting the status to the user by flashing signals or speech 2. The surface sterilizer according to 2 .