KR102578966B1 - Systems, methods and kits for preventing invasion of insects into a given area - Google Patents

Abstract

A system, method, and kit for preventing the invasion of insects into a predetermined area using a combination of a low-larva or insect repellent light source and a larva light source, without attracting as much as possible insects that do not originally need to be attracted by the larva light source. , provides systems, methods, and kits to more effectively prevent insect invasion into the area.

Description

Systems, methods and kits for preventing invasion of insects into a given area

The present invention relates to systems, methods, and kits for preventing invasion of insects into an area. More specifically, a system for preventing the invasion of insects into a predetermined area by combining low-larva or insect-repelling light from which the wavelength region in which insects show phototaxis is removed and larval light in the wavelength region in which insects show phototaxis. , methods, and kits.

It is generally known that insects have the characteristic of moving toward the stimulus of light, that is, phototaxis, and many methods and devices for attracting and exterminating insects using this characteristic have been proposed, and have been proposed in various places such as sports facilities, stadiums, stores, factories, etc. It is used in various places.

However, recently, the idea that artificially exterminating insects is not desirable from the viewpoint of preserving the natural ecosystem has emerged.

In contrast, an LED lamp emitting low insect light that does not include the wavelength of the ultraviolet region or insect repellent light that does not include the wavelength of the ultraviolet region and the visible light region to which insects are sensitive (for example, patent document 1), and insects Using films, sheets, covers, yellow-based colorants, etc. that block light in the sensitive wavelength range, low-light or insect-blocking light is extracted from light emitted from fluorescent lamps, metal halide lamps, LED lamps, etc., and this is used as a light source. Methods and devices (for example, Patent Documents 2 to 6) have been proposed and are being used.

Methods and devices using these low-larva or insect-repelling light sources are desirable means from the viewpoint of preserving the natural ecosystem because they prevent insects from being actively attracted and reduce the invasion of insects into a given location.

However, in the method and device using these low-larva or insect-repellent light sources, when there is no other light source around the place where the low-larva or insect-repellent light source is installed, the insects react to the slightest light stimulus, and the low-larva or insect-repellent light source is used. There is a problem that the number of insects flying into the vicinity of the place where the insect-repelling light source is installed increases.

In contrast, in the lighting system for a ball game practice field, a low larval discharge lamp is used as a light source for illumination of the area used by the user, and a blue light metal halide lamp is used as a light source for illumination of the area where the user's batted ball flies. A lighting system has been proposed (Patent Documents 7 and 8). This system uses an ultraviolet radiation light source with a high larval effect to actively attract and attract insects outside the vicinity of the low larva light source, and is one of the solutions to the above problem of a method and device for installing only a low larva or insect repellent light source. Provides a solution.

However, the blue light metal halide lamp used as the lighting light source in this system emits ultraviolet rays in all directions of 360° (without a reflector) or in a range of 180° (with a reflector), and even if it is a lamp with a reflector, it can be used outside the ball game practice field. It is installed to emit ultraviolet rays toward. For this reason, there is a problem that insects that are unrelated to the purpose of reinforcing the larva deterrent effect by the larva or insect repellent light source are also attracted. In other words, not only insects flying around the low larva or insect repellent light source are attracted, but also insects outside the ball game range are attracted, so the number of insects flying into the ball game range increases, and metal halide lamps and low larva discharge lamps are used. When approaching or when there are many insects in the ball game practice field, insects may fly into the area where the user is located. In addition, because the number of insects flying into the ball game practice field increases, it causes discomfort to users.

Japanese Patent No. 4804335 Japanese Patent Publication No. 2001-143657 Japanese Patent Publication No. 2005-216572 Japanese Patent Publication No. 2000-169767 Japanese Patent Publication No. 2006-129712 Japanese Patent No. 2682818 Japanese Patent Publication No. 2003-9744 Japanese Patent Publication No. 2009-27940

In view of the above problems, the present invention provides a system, method, and kit for preventing insect invasion into a predetermined area using a combination of a low-larva or insect repellent light source and a larva light source, and provides a system, method, and kit for preventing insect invasion into the area. The purpose is to provide systems, methods, and kits that more effectively prevent.

As a result of studies to solve the above problems, the present inventors have used a directional larva light source to increase the larva light source to a specific range so as not to attract insects unrelated to the purpose of reinforcing the larval deterrent effect by a low larva or insect repellent light source. It was found that the above problem could be solved by radiating toward , and the present invention was completed.

That is, the present invention, in one embodiment, is a system for preventing insects from entering a predetermined area, including a low larva or insect repellent light source and a larva light source, wherein the low larva or insect repellent light source is the predetermined area. A range requiring illumination of at least a portion of the area is illuminated with low larva or insect repellent light, and the larva light source has directivity, is installed at a position spaced apart from the predetermined area, and irradiates the larva light toward the predetermined area. , provides a system.

The present invention, in another embodiment, is a method of preventing invasion of insects into a predetermined area, comprising: illuminating an area requiring illumination of at least a portion of the predetermined area with a low-larva or insect-repellent light source; and directional lighting. A method is provided, including the step of installing a larval light source at a position spaced apart from the predetermined area and emitting larval light from the larval light source toward the predetermined area.

The present invention also, in another embodiment, is a kit for preventing insect invasion into a predetermined area, including a low larva or insect repellent light source and a larva light source, wherein the low larva or insect repellent light source is located in the predetermined area. Provides a kit wherein at least a portion of the illumination illuminates a required range, the larva light source has directivity, is installed at a location spaced apart from the predetermined area, and larva light is emitted toward the predetermined area.

The present invention, in another embodiment, is a kit for preventing insects from entering a predetermined area in combination with a low-larva or insect repellent light source, including a larva light source, wherein the low-larva or insect repellent light source includes the predetermined light source. A kit is provided wherein at least a portion of the area illuminates a required range, the larva light source has directivity, is installed at a location spaced apart from the predetermined area, and larva light is emitted toward the predetermined area. .

The present invention, in another embodiment, is a kit for preventing insects from entering a predetermined area in combination with a larva light source, including a low larva or insect repellent light source, wherein the low larva or insect repellent light source includes the predetermined light source. A kit is provided wherein at least a portion of the area illuminates a required range, the larva light source has directivity, is installed at a location spaced apart from the predetermined area, and larva light is emitted toward the predetermined area. .

The present invention, in a preferred embodiment, is a system for preventing insect intrusion into a building, comprising a low-larva or insect repellent light source and a larval light source, comprising:

The low-larva or insect-repellent light source is installed within the building, at the boundary between the building and other environments, or around the building, and illuminates the area requiring lighting with low-larva or insect-repellent light,

The larva light source has directivity, is installed at a location spaced apart from the building and its surroundings, and provides a system that radiates larva light toward the building.

The present invention, in another preferred embodiment, is a system for preventing the intrusion of insects into a specific compartment or room formed within a building, comprising a low-larva or insect repellent light source and a larva light source,

The low-larva or insect repellent light source is installed in the specific compartment or room and illuminates the specific compartment or room with low-larva or insect repellent light,

The larva light source has directivity, is installed at a location spaced apart from the specific compartment or room, and radiates larval light toward the entrance of the specific compartment or room.

In another preferred embodiment of the present invention, the larva light source has a directivity angle of 120° or less. Moreover, in another preferred embodiment of the present invention, the larval light source includes an LED lamp that emits larval light whose maximum peak wavelength is 340 to 400 nm. Moreover, in another preferred embodiment of the present invention, the larva light source is installed at a distance of 10 m or more from the predetermined area, more preferably at a distance of 10 m to 15 m from the predetermined area. Moreover, in another embodiment of the present invention, the larva light source emits larva light toward a part of the predetermined area.

In another preferred embodiment, the present invention is also a method of preventing insects from flying into the vicinity of the low larva or insect repellent light source by combining a low larva or insect repellent light source with a larva light source, comprising:

The larva light source includes an ultraviolet radiation LED with a directivity angle of 45° to 120° and a maximum peak wavelength of 340 to 400 nm, and is installed at a distance of 10 m or more from the larva or insect repellent light source. Alternatively, a method of irradiating larva light toward an insect repellent light source is provided. In this embodiment, the larva light source is preferably installed at a distance of 10 m to 15 m from the low larva or insect repellent light source.

In the system, method, and kit (hereinafter sometimes referred to as the system, etc.) according to the present invention, the low-larva or insect repellent light source is used in a range that requires illumination of at least a portion of a predetermined area to prevent insect invasion. , which brings in light without actively attracting insects to the area. On the other hand, a larva light source having directivity is installed at a position away from the predetermined area, and the larva light is emitted toward the predetermined area, thereby actively directing insects that have flown into the area or are likely to fly to the area out of the area. While attracting insects, we try to avoid attracting other insects as much as possible. As a result, the invasion of insects into the area can be prevented more effectively.

1 shows an outline of a system according to one embodiment of the present invention. This embodiment provides a system for preventing insect invasion into the factory and its surroundings (truck yard). A plurality of low-larva or insect-repellent light sources are arranged at equal intervals on a wall having an entrance or exit for loading, and the surroundings of the factory, including the truck yard, are illuminated with low-larva light or insect-repellent light. On the other hand, a directional larva light source is installed away from the factory and truck yard, and larva light is emitted toward the factory and truck yard.
Figure 2 shows a system according to another embodiment of the present invention. In this embodiment, a system is provided to prevent insect intrusion into specific areas within a building. The space within the building is open to the outside, but a low-larva or insect-repelling light source and a larval light source are arranged to prevent insects from entering the clean booth formed within the building. Low-larva or insect-repellent light sources are arranged at predetermined intervals in the clean booth, and illuminate the inside of the clean booth with low-larva light or insect-repellent light. There are cases where an entrance is formed in a clean booth and internal light leaks through it, but even in such cases, low-flying or insect-proof light leaks out. The larva light source is installed away from the clean booth, and larva light is emitted toward the area of the entrance and exit of the clean booth.
Figure 3 shows an example of arrangement of a low-larva or insect repellent light source. (a) shows an example in which a low-larvae or insect-repellent light source is placed in a building, (b) shows an example in which a low-larvae or insect-repellent light source is placed in a partial compartment (room) in the building, and (c) represents an example in which a low-larva or insect-repellent light source is placed at the boundary between a building and another area, (d) shows an example in which a low-larva or insect-repellent light source is placed around the building, and (e) shows an example, This shows an example in which a low insect or insect repellent light source is placed in a specific range of space that is open to the outside.
Figure 4 shows an example of a low-larva or insect repellent light source. (a) shows an example of a main white LED light source that emits light of a wavelength other than the ultraviolet region, or a yellow-green LED light source that emits light of a wavelength other than the ultraviolet region and the visible light region with a larval effect, and these LED light sources has directivity. (b) shows an example in which light emitted from a fluorescent lamp, metal halide lamp, LED light source, etc. is passed through a filter or sheet that cuts the ultraviolet ray region or the visible light region where the larva effect is more effective, thereby producing low larval or insect-repelling light. (c) shows an example in which a fluorescent lamp, metal halide lamp, LED light source, etc. is covered with a dye that cuts the ultraviolet region or the visible light region, which has a more larval effect, and emits anti-larva or insect repellent light. (d) shows an example in which a fluorescent lamp, metal halide lamp, LED light source, etc. is covered with a film that cuts the ultraviolet region or the visible light region, which has a more effective insect repellent effect, and emits low insect repellent or insect repellent light.
Figure 5 shows an example of arrangement of a larval light source. In this example, a plurality of larval light sources are arranged at a distance of 10 m from the area where insect invasion is intended to be prevented. This larva light source has a directing angle of 45°, and with one light source, larval light is irradiated to the area in a range of 8.2 m in width. With this irradiation range in mind, a plurality of larva light sources are arranged at 4.1 m intervals, and there is an area where larva light is irradiated overlapping within a range of 4.1 m in a straight line between adjacent larva light sources.
Figure 6 shows another example of the arrangement of the larval light source. In this example, the larval light source is placed 15 m away from the area where insect invasion is intended to be prevented. This larva light source also has a directing angle of 45°, and with one light source, larval light is irradiated to the area in a range of 12.4 m in width. With this irradiation range in mind, a plurality of larva light sources are arranged at intervals of 6.2 m, and there is an area where larva light is irradiated overlapping within a range of 6.2 m in a straight line between adjacent larva light sources.
Figure 7 shows the relationship between the distance from the area where insect invasion is intended to be prevented and the irradiated area of the larva light when a larva light source with a directing angle of 45° is used. One larva light source placed 10 m away from the area irradiates the area with larva light in a range of 8.2 m in width, and one larva light source placed 15 m away from the area irradiates the area with larval light in a range of 12.4 m in width. The larval light is irradiated to the building, and one larval light source placed 20 m away from the area irradiates the larval light to the area in a range of 16.6 m in width.
Figure 8 shows another example of arrangement of the larval light source. In this example, a plurality of larva light sources with a directing angle of 120° are used, and the larva light sources are arranged 10 m away from the area where insect invasion is intended to be prevented. In this case, larval light is irradiated to the area from a single light source in a range of 34.6 m in width. With this irradiation range in mind, a plurality of larva light sources are arranged at intervals of 17.3 m, and there is an area where larva light is irradiated overlapping within a range of 17.3 m in a straight line between adjacent larva light sources.
Figure 9 shows another example of arrangement of the larval light source. In this example as well, a larva light source with a directing angle of 120° is used, but the larva light source is placed 15 m away from the area where insect invasion is intended to be prevented. In this case, larval light is irradiated to the area from a single light source in a range of 52.0 m in width. With this irradiation range in mind, a plurality of larva light sources are arranged at intervals of 26.0 m, and there is an area where larva light is irradiated overlapping within a range of 26.0 m in a straight line between adjacent larva light sources.
Figure 10 shows the relationship between the distance from the area where insect invasion is intended to be prevented and the irradiated area of the larva light when a larva light source with a directing angle of 120° is used. One larva light source placed 10 m away from the area irradiates the area with larva light in a range of 34.6 m in width, and one larva light source placed 15 m away from the area irradiates the area with larva light in a range of 52.0 m in width. The larval light is irradiated to the area, and one larval light source arranged 20 m away from the area irradiates the larval light to the area in a range of 69.3 m in width.
Figure 11 shows another example of arrangement of the larval light source. In this example, a larva light source with a directing angle of 120° and a larval light source with a directing angle of 90° are arranged in combination. In this example, a larval light source with a directing angle of 90° is installed at both ends, and a larval light source with a directing angle of 120° is installed between them.
Figure 12 shows another example of arrangement of the larval light source. In this example, a larva light source with a directing angle of 120° and a larval light source with a directing angle of 45° are arranged in combination. In this example, the larva light source with a directing angle of 120° is radiated toward the entire area where insect invasion is intended to be prevented, and the larval light source with a directing angle of 45° is radiated toward a part of the area. .
Figure 13 shows another example of arrangement of the larval light source. In this example, a larva light source with a directing angle of 120° and a larval light source with a directing angle of 60° are arranged in combination. Additionally, in this example, the radial directions are different for the larva light source with a directivity angle of 120° and the larval light source with a directive angle of 60°.
Figure 14 shows the wavelength spectrum of each UV lamp (direction angles 45°, 120°, and 180°) used as a larval light source in the [Example] (measuring device used: PG-200N, manufactured by UPRTEK). For UV lamps with orientation angles of 45° and 120°, the wavelength spectrum is shown by measuring the light intensity at positions 10 m and 15 m away from the installation position of the light source.
Figure 15 shows the wavelength spectrum obtained by combining each UV lamp (direction angle 45°, 120°, and 180°) used as a larva light source in the [Example] and a main white LED lamp (Measuring device used: PG manufactured by UPRTEK) -200N). The light intensity was measured at a location 10 m away from the installation location of the light source.
Figure 16 shows the wavelength spectra of a UV-cut main white LED lamp and a yellow insect-repellent LED lamp used as a low-larva or insect-repellent light source in the [Example] (measuring device used: PG-200N, manufactured by UPRTEK). The light intensity was measured at a location 10 m away from the installation location of the light source.
Fig. 17 shows an outline of the lighting device used in the [Example].
Figure 18 shows the arrangement of each lighting device in the insect trapping test conducted in 2019. The left side shows the arrangement when lit for the first time, and the right side shows the arrangement when lit for the second time.
Figure 19 shows the arrangement of each lighting device and the arrangement and size of the blackout curtain in the insect trapping test conducted in 2020. (a) shows the configuration of a control in which a lighting device equipped with a low-larva or insect-repellent light source is placed right in front of a blackout curtain with a width of 8.2 m, without replacing the lighting device equipped with a larva light source. (b), a lighting device equipped with a low-larva or insect-repellent light source is placed right in front of a blackout curtain with a width of 8.2 m, the lighting device equipped with a low-larva light source is replaced with a lighting device equipped with a low-larvae or insect-repellent light source, and the blackout curtain The configuration of Example 8 is shown, arranged 10 m away from. The larva light source has a directing angle of 45°, and the larval light is irradiated to the blackout curtain with the same width as the 8.2 m wide blackout curtain. (c), a lighting device equipped with a low-larva or insect-repellent light source is placed right in front of a blackout curtain with a width of 4.1 m, the lighting device equipped with a low-larva light source is replaced with a lighting device equipped with a low-larvae or insect-repellent light source, and the blackout curtain It shows the configuration of Example 9 arranged 10 m away from. The larval light source has a directing angle of 45°, and the larval light is irradiated not only throughout the 4.1 m wide blackout but also beyond the range of the blackout. (d) is the configuration of Example 10 in which a lighting device equipped with a low larva or insect repellent light source and a lighting device equipped with a larva light source are placed 10 m apart without forming a blackout behind the low larva or insect repellent light source. indicates. The larval light source has a directing angle of 45°. (e), a lighting device equipped with a low-larva or insect-repellent light source is placed right in front of a blackout curtain with a width of 8.2 m, and the lighting device equipped with a low-larva light source is not replaced with a lighting device equipped with a low-larva or insect-repellent light source. The configuration of Comparative Example 4 is shown, which is arranged 10 m away from the blackout curtain in the direction opposite to the larva or insect repellent light source. The larval light source has a directing angle of 45°.
Figure 20 shows the arrangement of each lighting device and the arrangement and size of the blackout curtain in the insect trapping test conducted in 2020. (a) shows the configuration of a control in which a lighting device equipped with a low-larvae or insect-repelling light source is placed without replacing the lighting device equipped with a larvae light source. (b), a lighting device equipped with a low-larva or insect-repellent light source is placed right in front of a blackout curtain with a width of 4.1 m, the lighting device equipped with a low-larva light source is replaced with a lighting device equipped with a low-larvae or insect-repellent light source, and the blackout curtain It shows the configuration of Example 11 arranged 5 m away from. The larva light source has a directing angle of 45°, and the larval light is irradiated to the blackout curtain with the same width as the 4.1 m wide blackout curtain. (c) is the configuration of Example 12 in which a lighting device equipped with a low larva or insect repellent light source and a lighting device equipped with a larva light source are placed 5 m apart without forming a blackout behind the low larva or insect repellent light source. indicates. The larval light source has a directing angle of 45°. (d), a lighting device equipped with a low-larva or insect-repellent light source is placed right in front of a blackout with a width of 8.2 m, the lighting device equipped with a low-larvae light source is replaced with a lighting device equipped with a low-larva or insect-repellent light source, and the blackout It shows the configuration of Example 13 arranged 5 m away from. The larva light source has a directing angle of 80°, and the larval light is irradiated to the blackout curtain with a width approximately the same as that of the 8.2 m wide blackout curtain. (e) is the configuration of Example 14 in which a lighting device equipped with a low-larvae or insect-repelling light source and a lighting device equipped with a larvae light source are opposed to each other at a distance of 5 m without forming a blackout behind the low-larvae or insect-repelling light source. indicates. The larval light source has a directing angle of 80°.
Figure 21 is a graph (quoted from ED Bickford, LE Snat-conft. Paper, 1964) showing an example of the relationship between the light intensity and wavelength of an insect.

Below, embodiments of the present invention will be described with reference to the drawings. However, it should be noted that the present invention is not limited to the embodiments described below, and the technical idea of the present invention can be applied to other embodiments.

As described above, the present invention relates to a system for preventing insect invasion into a predetermined area by combining a low-larva or insect repellent light source and a larva light source, etc.

“Predetermined area” in the present specification refers to an area where insect invasion is intended to be prevented by the system of the present invention, etc. (hereinafter sometimes referred to as an “insect prevention area”), such as a factory or store. In addition to the physical structures, it also includes spaces surrounding such structures (backyards, parking lots, etc.), playing areas or spectator seating areas of sports facilities, and paving. Accordingly, the “predetermined area” may include various facilities and spaces. For example, stores such as supermarkets, convenience stores, and restaurants, or parts thereof (e.g., entrances) or surrounding areas; facilities or parts of various factories such as food factories or semiconductor manufacturing plants (e.g., entrances and exits); or Its surroundings (e.g., truck yard), a house or part thereof (e.g., entrance) or its surroundings, a place where users of a golf driving range or batting range may be present, and an audience seating area of a sports facility such as a baseball field or soccer stadium. , pavement, near airport runways, bus stops and their surroundings, station platforms, etc., all facilities, places and spaces where it is desired to prevent insect intrusion are included.

When physical structures such as factories and stores and the surrounding areas of such structures are designated as insect-proof areas, suppressing the intrusion of insects into the surroundings of the factories or stores, etc., more reliably prevents insects from entering the factories or stores themselves. I am in a relationship. In this case, preventing insects from entering the factory or store itself is required at a higher level, which is different from the level required for the surrounding area. Accordingly, in the “predetermined area”, areas with different levels required to prevent invasion of insects may coexist.

In the specification of this application, “low insect light” means light containing little or no ultraviolet light with a wavelength of 340 nm to 400 nm, and “insect light” means light that includes the ultraviolet light with a wavelength of 340 nm to 480 nm and the visible light region. means light containing little or no light. For example, as shown in Figure 16, "low larval light" does not contain a peak of 5 μW/m2 or more in the ultraviolet region with a wavelength of 340 nm to 400 nm, and preferably includes a peak of 2 μW/m2 or more. I never do that. In addition, “insect-proof light” does not contain a peak of 5 μW/m 2 or more in the ultraviolet region and visible light region with a wavelength of 340 nm to 480 nm, and preferably does not contain a peak of 2 μW/m 2 or more.

As a low-larva or insect-repellent light source, for example,

A daylight LED light source emitting light containing little or no wavelengths in the ultraviolet region, as shown in FIG. 4(a), or light containing little or no wavelengths in the ultraviolet region and visible light region with the larval effect. A yellow-green LED light source emitting (they are directional),

Light emitted from a fluorescent lamp, metal halide lamp, LED light source, etc., as shown in Figure 4(b), is passed through a filter or sheet that cuts the ultraviolet region or the visible light region where the insect-repelling effect is more effective, producing low-larvae or insect-repellent light. radiating light source system,

As shown in Figure 4(c), a fluorescent lamp, metal halide lamp, LED light source, etc. is covered with a dye (for example, a yellow dye) that cuts the ultraviolet region or the visible light region, which has a more larval effect, to reduce larvae or A light source system that emits insect-repelling light, and

Examples include a light source system that covers a fluorescent lamp, metal halide lamp, LED light source, etc., as shown in FIG. 4(d), with a film that cuts the ultraviolet region or the visible light region where the insect-repelling effect is more effective, and emits low-infection or insect-repellent light. You can.

Such low-larvae or insect-repellent light sources are commercially available. Examples of low-larvae light sources include ultraviolet radiation cut-out shatterproof fluorescent lamp FLR40SEX-N/M.P/NU (manufactured by NEC Lighting), Opt Energy Real Color ( (manufactured by Daesung Fine Chemical Co., Ltd.), and straight white LED lamp (model number: LDF10ss·D/6/6-U1, manufactured by Ohm Electric Co., Ltd.). In addition, the insect repellent light source includes yellow, yellow-green or green lamps, and commercially available products include, for example, pure yellow fluorescent lamp low-larva FLR40SY-F/M (manufactured by NEC Lighting) and Magic Optron LED ( (manufactured by Daesung Fine Chemical Co., Ltd.).

A light source is also known that causes blue to near-ultraviolet light with a peak wavelength of 370 nm to 480 nm to be absorbed by a phosphor that emits yellow light with a peak wavelength of 560 nm to 580 nm as excitation light, thereby increasing the intensity of low-abundance light emitted from the phosphor ( Patent Document 1), it may be used as a low-larva light source of the present invention.

A low insect or insect repellent light source brings light to the range where illumination of the insect repellent area is required without actively attracting insects to the insect repellent area. Therefore, “the surroundings of insect repellent light sources” are included in the insect repellent area.

The low-larva or insect-repellent light source can be installed in various places, for example, within a building such as a factory or store (see (a) in Figure 3), or in a part of a section or room within the building ((b) in Figure 3 ), the boundary between the building and other spaces (see (c) in Figure 3), the surroundings of the building (see (d) in Figure 3), or areas used by players at golf driving ranges or batting ranges, parking lots, and outdoors. It can be installed in a specific range of spaces (see (e) in Figure 3) that are open to the outside of sports facilities.

In the example of FIG. 3(a) , the insect-proof area is a building such as a factory or a store, and in the example of FIG. 3(b) , the insect-proof area is a partial partition or room of the building. In addition, in the examples of FIG. 3(c) and FIG. 3(d), the insect prevention area is the building and its surroundings. In this example, it is assumed that the surroundings of the building and/or the building are illuminated, but if the surroundings of the building are illuminated with low larva or insect-repelling lights, the active attraction of insects to the surroundings of the building is suppressed, and as a result, the attraction of insects to the building's surroundings is suppressed. Invasion is suppressed. In this example, installation of a low-larva or insect-resistant light source in the building is not essential, and there are cases where the low-larva or insect-resistant light source is not installed in the building. Therefore, these correspond to examples of installing a low insect or insect repellent light source in a part of the insect repellent area. Moreover, in the example (e) of FIG. 3 , the insect prevention area is usually a place used by users.

In a system or the like according to one embodiment of the present invention, a larva light source is installed to be spaced apart from an insect repellent area, and larva light is emitted toward the insect repellent area. Additionally, in a system according to another embodiment, the larva light source is installed to be spaced apart from the larva or insect repellent light source, and the larva light is emitted toward the larva or insect repellent light source.

In the specification of this application, “larval light” means light in the ultraviolet region with a wavelength of 340 to 400 nm, and preferably means light with a maximum peak wavelength in the range of 340 to 400 nm. The larval light source may be a light source that emits only the ultraviolet ray region, or may be a light source that emits ultraviolet rays and visible light. The larval light source may also be a light source that combines a light source that emits ultraviolet rays and a light source that emits visible light.

Among insects, some insects have high sensitivity to visible light, and by blending visible light with ultraviolet light, there are cases where various types of insects can be more effectively attracted toward the larval light source.

The installation of the larval light source is preferably carried out in a location away from the area or the low larva or insect repellent light source to the extent that insects attracted to the larval light source do not fly into the insect repellent area. From this point of view, the distance between the larva light source and the insect repellent area or the low larva or insect repellent light source is preferably 5 m or more, and more preferably 10 m or more.

On the other hand, if you are too far away from the insect repellent area or the low larva light source, the intensity of the larva light will be lowered and the attracting effect will not be sufficiently exerted. Therefore, it is necessary to set a distance that can attract insects around the insect repellent area or the low larva light source. You need to install it. In addition, as the distance from the insect repellent area increases, the irradiation range becomes wider even if a larva light source with the same directivity angle is used, so it is necessary to select an appropriate distance depending on the range of the target insect repellent area and the directivity angle of the larva light source used ( This point is explained in detail next).

From this point of view, the distance between the larva light source and the insect repellent area or the low larva or insect repellent light source is preferably 30 m or less, more preferably 20 m or less, and especially preferably 15 m or less. Additionally, depending on the installation environment, it may be 10 m or less.

When larva light is radiated toward a structure such as a building, the distance between the larva light source and the insect repellent area or low larva or insect repellent light source is preferably determined by considering the reflectance of the wall on which the larva light is irradiated or the intensity of the reflected light. Specifically, when the intensity of reflected light is high, there is a risk of causing a larval effect due to the reflected larval light, so structures such as buildings with a reflectivity of 10% or less are preferably selected as the subject of application of the present invention. Also, from the same point of view, when irradiating ray light to a structure such as a building, the peak wavelength intensity in the ultraviolet region of the reflected light is 10 μW/m2 or less at a position of 10 cm from the wall, preferably 5 μW/m2 or less. It is desirable to install a larval light source on the street.

Here, in the present specification, the distance between the larva light source and the insect repellent area can be determined based on the position closest to the larva light source in the insect repellent area. However, when setting a structure such as a store or factory and its surroundings as an insect prevention area, the decision may be made based on the location closest to the larva light source of the structure. The level of need to prevent insect intrusion is different between structures such as stores and factories and their surroundings, and the distance to prevent insect intrusion into the structure may be set based on the location of the structure with the highest need. Because.

In the system of the present invention, etc., larva light is radiated toward the entire insect repellent area or a part of it, and therefore a light source having directivity is used as the larva light source. Above all, it is sufficient to have enough directivity to control the irradiation range, and larval light sources with various directivity angles can be used. In general, a larval light source with a directing angle of less than 180° is selected, it is preferable to select a larval light source with a directing angle of 120° or less, more preferably a larval light source with a directing angle of 60° or less, and a larval light source with a directing angle of 45° or less is selected. The choice of light source is particularly desirable. However, considering the use of commercially available products, a larval light source of 45° to 120° is preferable, and a larval light source of 45° to 60° is more preferable.

For example, many LEDs that have a directivity angle of 45° to 120° and emit ultraviolet rays with a peak wavelength of 340 to 400 nm are commercially available, and it is convenient to use them. Such ultraviolet radiation LEDs include, for example, NVSU233B/NVSU233B-D4 (peak wavelength 365 nm or 385 nm, directivity angle 60° or 120°, manufactured by Nichia Chemical Industries, Ltd.), NCSU276C (peak wavelength 365 nm, directive angle 120°, manufactured by Nichia Chemical Industries, Ltd.), CUN66B1B (peak wavelength 365 nm, directing angle 45°, manufactured by Seoul Viosys), CUN66A1B (peak wavelength 365 nm, directing angle 120°, manufactured by Seoul Viosys), and these ultraviolet rays One or more radiating LEDs can be combined. Additionally, when combining multiple LEDs, multiple types of LEDs with different characteristics such as peak wavelength and directivity angle may be combined.

Additionally, examples of commercially available larval light sources that emit ultraviolet rays and visible light include Mushi Hybrid (manufactured by Iida Lighting Co., Ltd.). Additionally, as a commercially available light source that emits visible light that can be combined with a light source that emits ultraviolet rays to form a larval light source, the Nu series (manufactured by Hotalux) can be cited, for example.

The larva light is emitted toward the entire insect repellent area or a part of it, but as shown in Figures 7 and 10, the irradiation range of the larva light emitted from one larva light source is a function of the distance of the larva light source from the insect repellent area and the larva light source. It is determined according to the orientation angle of . Therefore, depending on the target irradiation range, it is desirable to appropriately select the orientation angle and installation position (distance from the area that prevents insect invasion) of the larva light source so that the larva light is irradiated in the planned range. Additionally, there may be only one larva light source, but by combining multiple larva light sources, the larval light can be irradiated to a wider area. For example, as shown in FIGS. 5, 6, 8, and 9, a plurality of larva light sources can be arranged at predetermined intervals to irradiate larva light throughout the target range. At this time, for example, if a larval light source with a large orientation angle such as 120° is used, as in the embodiment shown in FIGS. 8 and 9, there is an advantage in that a wide area can be irradiated with a single light source, but irradiation There are cases where the light intensity per area of the range becomes small or it becomes difficult to set an appropriate irradiation range. On the other hand, for example, if a larval light source having a small directivity angle such as 45° is used, as in the embodiment shown in FIGS. 5 and 6, it is easy to set various irradiation ranges including narrow ranges. At the same time, there is an advantage that the light intensity per area of the irradiation range increases, but since a single light source cannot cover a wide irradiation range, a relatively large number of larval light sources may be required.

When using a plurality of larval light sources, each light source can be placed in various positions depending on the orientation angle, target irradiation range, installation environment, etc. For example, when using a plurality of larva light sources having the same directing angle, typically, as shown in FIGS. 5, 6, 8, and 9, the target irradiation range, the directing angle of the larva light source, and the insect resistance Depending on the distance from the area, arrange the larva light sources so that the larval light is irradiated in the same direction at equal intervals so that the larval light is irradiated as uniformly as possible throughout the target range (avoiding unirradiated areas). can do. In the embodiment shown in Fig. 5, at a position where the distance from the insect control area is 10 m, a plurality of larva light sources with a directivity angle of 45° are spaced at equal intervals of 4.1 m (a distance of 1/2 the irradiation range of one larva light source). It is installed as . As a result, there is no area around the insect repellent area where larva light is not irradiated, and the overlap of larva light irradiated from adjacent larva light sources occurs continuously and uniformly. Similarly, in the embodiment shown in FIG. 6, a plurality of larva light sources with a directing angle of 45° are installed at equal intervals of 6.2 m at a position where the distance from the insect prevention area is 15 m, thereby forming the same irradiation situation. I'm doing it. In the embodiment shown in Figs. 8 and 9, a plurality of larva light sources with a directing angle of 120° are installed at positions of 10 m and 15 m, respectively, from the insect control area. In this case, since the irradiation ranges of one larva light source are 34.6 m and 52.0 m, respectively, the larva light sources are arranged at intervals of 17.3 m and 26.0 m, respectively. In this embodiment, the overlap of larva lights from adjacent larva light sources is one, and is located in the center of the irradiation range. Since the light intensity is high in this part, facilities where it is desired to specifically prevent insects from flying in, for example, an entrance or exit, may be located in this part.

On the other hand, the larval light sources do not necessarily need to be arranged at equal intervals, and may be arranged at different intervals depending on the situation of the target irradiation range. In addition, it is not necessarily necessary to combine larva light sources with the same directing angle, and larval light sources with different directing angles may be combined. Therefore, for example, as shown in FIG. 11, the larva light sources at both ends can be selected with a smaller directing angle than the other larva light sources and arranged at smaller intervals. In addition, as shown in Figure 12, the entire target range is irradiated with a larva light source with a large directivity angle, and a larval light source with a small directive angle is used in a spot in an area where it is desired to prevent insects from flying in. You can also conduct overlapping investigations.

In addition, the larval light source does not necessarily have to face the same direction when irradiated in the target range. For example, as shown in FIG. 13, the larva light sources at both ends may be installed inward from the other larva light sources.

In one embodiment of the present invention, the larval light may be radiated toward the entire insect repellent area or toward a part of it. However, even in the case of radiating toward a portion, it is preferable to radiate toward as wide an area as possible. In addition, when a structure such as a store or factory is included in the insect prevention area, it is not necessary to direct the larva light into the structure such as a store or factory, but even in this case, it is radiated “toward” the insect prevention area. Moreover, in another embodiment of the present invention, the larva light is emitted toward a low larva or insect repellent light source. Even if the larva light from one larva light source is irradiated to one larva or insect repellent light source, or if it is irradiated to multiple larva or insect repellent light sources, it is emitted “toward” the larva or insect repellent light source. do.

On the other hand, in the system of the present invention, etc., it is important to prevent the larval light from being emitted toward spaces other than the insect prevention area. If such space increases, insects unrelated to the purpose of reinforcing the larva blocking effect of the larvae or insect repellent will be attracted, increasing the possibility of insects flying into the area intended to prevent invasion.

Here, representative embodiments of the present invention will be described.

Fig. 1 shows an embodiment in which a factory and truck yard area is set as an area to prevent invasion of insects. In the embodiment shown in FIG. 1, a plurality of low-larvae or insect-repellent light sources are arranged at regular intervals on the wall having the entrance and exit of the factory, and the surroundings of the factory, including the truck yard area, are illuminated with low-larvae or insect-repellent light. . As a result, we are trying to avoid actively attracting insects around the factory. On the other hand, a plurality of larval light sources are installed at a distance of about 10 to 15 m (7 to 12 m from the truck yard) from the wall having the entrance and exit of the factory. The installed larvae light sources all have the same orientation angle (for example, 45°), are installed at equal intervals, and emit larvae light toward a certain range of the factory and its surroundings. As a result, insects flying around the factory, including the truck yard area, react to the larval light and are attracted to the larval light source, creating a more insect-free environment around the factory, thereby preventing insects from invading the factory. It can definitely be prevented.

Figure 2 shows an embodiment in which a clean booth formed within a building is set as an area to prevent invasion of insects. In this embodiment, the inside of the building is a space open to the outside of the building, but a low-larvae or insect-repelling light source and a larvae light source are arranged to prevent insects from entering the clean booth formed within the building. Low-larva or insect-repellent light sources are arranged at predetermined intervals in the clean booth and illuminate the inside of the clean booth. A doorway is formed in the clean booth, and internal light may leak through it. However, since the exposed light is low-larva or insect-repelling light, insects are not actively attracted by the exposed light. The larva light source is installed at a distance of 5 to 10 m from the clean booth, and larva light is emitted toward the area of the entrance and exit of the clean booth. In this way, insects flying near the entrance or exit of the clean booth react to the larval light and are attracted to the larva light source, making it possible to more reliably prevent insects from entering the clean booth.

Hereinafter, the present invention will be explained based on examples. However, it should be noted that the present invention is not limited to the following examples.

Example

In order to evaluate the effectiveness of the system according to the present invention in preventing insects from entering a predetermined location, an insect trapping test was conducted.

1. 2019 Insect Capture Test

This test is conducted by combining a low-larva or insect-repellent light source and a larval light source consisting of a UV lamp with various directing angles or a combination of it and a day white LED, and the larvae are measured from the number of insects caught by each light source. The mortality rate and larval rate were determined. The combination of light sources in each Example and Comparative Example is shown in the table below.

In the table, “UV lamp with a directivity angle of 45°” and “UV lamp with a directive angle of 120°” refer to ultraviolet radiation LED lamps (straight-tube UV-LED, manufactured by Iida Lighting Co., Ltd.) with a maximum peak wavelength of 365 nm, respectively. These are lamps adjusted to angles of 45° and 120°, and the “UV lamp with a directing angle of 180°” is an ultraviolet-emitting fluorescent lamp (black light, manufactured by NEC) with a maximum peak wavelength of 365 nm, adjusted to a directing angle of 180°. It is one lamp. The wavelength spectrum of each UV lamp is shown in Figure 14.

In the table, “main white LED” refers to a main white LED lamp (model number: LDF10ss·D/6/6-U1, manufactured by Ohm Electric Co., Ltd.) that emits light in the visible light range. In Examples 3 and 4 and Comparative Example 2, a “UV lamp” and a “day white LED” were combined to constitute a “larval light source.” Each larval light source is adjusted so that the light intensity at each wavelength measured at a position of 10 m from the light source is approximately the same. The wavelength spectrum of each larval light source is shown in Figure 15.

In the table, “UV cut daylight white LED” is a daylight white LED lamp (model number: LDF10ss·D/6/6-U1, manufactured by Ohm Electric Co., Ltd.) that does not emit ultraviolet rays in the range of 340 to 400 nm, and is used as a low-cluster light source. there is. In addition, “yellow-green insect repellent LED” is a yellow-green insect repellent LED lamp (Magic Optron LED, manufactured by Daesung Fine Chemical Co., Ltd.) that hardly emits light in the 340-480 nm ultraviolet ray and visible light range, and is used as an insect repellent light source. The wavelength spectra of the main white LED lamp and the insect-repellent LED lamp are shown in Figure 16.

The insect capture test was conducted using the lighting device 12 shown in FIG. 17. This device is equipped with each of the light sources 14 described above, and traps insects with adhesive sheets 13 laid on both sides. In the test, the lighting device 12 was placed on a cardboard box 17 and used.

As shown in Fig. 18, the above-described anti-larva or insect repellent light source (not shown) was first attached to this lighting device, and two units were placed at intervals of 10 m during packaging. A blackout curtain 18 was placed at a midpoint 5 m apart from each lighting device 15 to prevent light from each lighting device 15 from leaking toward the other lighting devices 15. Next, it was placed opposite to one of the two lighting devices 15, and the lighting device 16 equipped with each larval light source was placed at a distance of 10 m or 15 m. The other one was not replaced with a lighting device (16) equipped with a larval light source. All installed light sources were turned on for about 10 minutes, and insects were captured using adhesive sheets attached to each lighting device. After that, the lighting device 16 having the larva light source was moved and replaced with another lighting device equipped with a low larva light source or an insect repellent light source (the arrangement of each lighting device during the first lighting is shown on the left in FIG. 18 and the arrangement of each lighting device during the second lighting is shown on the right side of FIG. 18). All of the installed light sources were turned on for about 10 minutes, and the number of insects captured in each lighting device was counted for a total of 20 minutes of the two turns on. The test was conducted twice in July and September 2019, and the number of birds caught was calculated as the average value. The larvae retention rate and larvae rate were obtained using the equations shown below.

[Equation 1]

Larval arrest rate (%) = [1 - (A/B)] × 100

[Equation 2]

Larval rate (%) = (C/B) × 100

In the formula, A represents the number of insects caught by a lighting device having a low-larva or insect-repellent light source replaced with a lighting device having a larva light source. B represents the number of insects caught by a lighting device with a low-larva or insect-repelling light source that is not replaced with a lighting device with a larva light source. C represents the number of insects caught by a lighting device equipped with a larval light source.

The test results of each Example and Comparative Example are summarized in the table below.

As shown in the test results above, it was confirmed that the larval rate increased as the directing angle of the UV lamp increased. This is understood to be due to the broadening of the irradiated range of the larval light, thereby attracting more insects. In addition, even when a UV lamp with a beam angle of 45° was used (Examples 1 and 7), the larger the distance from the larval or insect repellent light source, the higher the larval rate, but this also increased the irradiated range due to the increased distance. Because it became wider, it is understood that it attracted more insects. On the other hand, looking at the larva blocking rate, compared to the case of using a UV lamp with a beam angle of 180°, the larva blocking rate is greater when UV lamps with a beam angle of 45° and 120° are used, and the larva blockage rate is higher when using UV lamps with a beam angle of 180°. This indicates that it can attract more insects.

2. 2020 Insect Capture Test

In this test, the case where a structure is included in the insect prevention area was assumed, and the larva stopping rate and larva rate were investigated for the installation conditions of the blackout and larva light source formed assuming the structure. The test conditions in each Example and Comparative Example are as follows.

In the table, “UV lamp with a directivity angle of 45°” and “UV lamp with a directive angle of 80°” refer to an ultraviolet radiation LED lamp (straight tube UV-LED, manufactured by Iida Lighting Co., Ltd.) with a maximum peak wavelength of 365 nm, respectively. The lamp is adjusted to 45° and 80°. Additionally, as a low-larvae or insect-repellent light source, an insect-repellent LED lamp (Magic Optron LED, manufactured by Daesung Fine Chemical Co., Ltd.) was used.

In addition, the test procedure for each Example and Comparative Example was basically the same as the test in 2019. When using the lighting device shown in Figure 17, first, two lighting devices equipped with the above-mentioned low-larva or insect-repellent light source are placed at intervals of 10 m during packaging, and a blackout curtain is installed assuming a structure, Immediately behind each low-larva or insect-repellent light source, a 4.1 m or 8.2 m blackout curtain was installed so that each low-larva or insect-repellent light source was located at the midpoint of the width of the blackout curtain. Next, a blackout curtain was placed at a midpoint 5 m away from each lighting device on a straight line between the two lighting devices to prevent light from each lighting device from leaking toward the other lighting device. Next, in Examples 8 to 14, the lighting device equipped with each larva light source was placed opposite to one of the two lighting devices, leaving a distance of 10 m or 5 m. On the other hand, in Comparative Example 4, the lighting device equipped with the larva light source was installed facing the opposite direction to the low larva or insect repellent light source rather than opposing the low larva or insect repellent light source. All installed light sources were turned on for about 10 minutes, and insects were captured using adhesive sheets attached to each lighting device. After that, the lighting device with the larva light source was moved and replaced with another lighting device equipped with a low-larva or insect repellent light source (the arrangement of each lighting device during the first lighting and the second lighting) The arrangement of each lighting device is the same as that shown in Figure 18). All equally installed light sources were turned on for about 10 minutes, and the number of insects captured in each lighting device was counted for a total of 20 minutes of the two turns on. The test was conducted twice in August 2020, and the number of birds caught was calculated as the average value. In addition, the larvae retention rate and larvae rate were obtained using the above equation in the same manner as in the 2019 test.

The test results of each example and comparative example are shown below.

From the above test results, the configuration of Example 8, which irradiates larval light within the range of the blackout formed assuming a structure, is different from the configuration of Example 9, which irradiates larval light outside the range of the blackout, or the blackout assuming a structure. It is understood that compared to the configuration of Example 10 without formation, the larvae retention rate is slightly higher and the larvae rate is significantly reduced. In addition, in the configuration of Comparative Example 4, in which the larva light source is not replaced with the low larva or insect repellent light source and is oriented in the opposite direction to the low larva or insect repellent light source, the larval deterrence rate becomes a low value similar to the control, and the larva rate decreases significantly. has risen.

In addition, the configuration of Example 13, which irradiates larval light within the approximate range of a blackout curtain with a width of 8.2 m using a larva light source with a directing angle of 80°, is a larval light source with a directing angle of 45° and a 4.1 m wide light source. Compared to the configuration of Example 11 in which larva light was irradiated within the approximate range of the dark curtain, the larva stopping rate slightly decreased and the larval rate slightly increased. This is thought to be due to the fact that the irradiation space of the larva light expanded as the direction angle of the larva light source increased. On the other hand, the configuration of Example 13 had the same larval deterrence rate as that of Example 14, which had the same configuration as Example 13, except that a blackout film assuming a structure was not formed, but the larval rate decreased. It was confirmed that even when the direction angle of the larva light source was increased, the insect repellent effect could be increased by irradiating the larva light toward the structure.

These test results show that, according to the system of the present invention, it is possible to more effectively prevent insects from entering a predetermined area without attracting as much as possible insects that do not need to be attracted.

1: Low insect or insect repellent light source (lamp)
2: Building (factory)
3: Carry-out entrance
4: Caterpillar light
5: Larva light source (lamp)
6: window
7: In the factory (in the building)
8: Clean booth
9: Entrance
10: Insect prevention area
11: Use space
12: lighting device
13: Adhesive sheet
14: Light source (low caterpillar or insect repellent lamp, caterpillar lamp)
15: Lighting device with low-larva or insect-repellent lamp
16: Lighting device with larva lamp
17: Cardboard box
18: Blackout
19 : Truck
20: Facility (open outdoor space)
21: Partial compartment or room within a building

Claims (32)

A system for preventing insect intrusion into a building, comprising a low-larva or insect-repelling light source and a larval light source,
The low-larva or insect-repellent light source is installed within the building, at the boundary between the building and other environments, or around the building, and illuminates the area requiring lighting with low-larva or insect-repellent light,
The larva light source has a directing angle of 80° or less, is installed at a location more than 10 m away from the building, and the irradiation range by the directing angle is within the range of the building, and directs larval light toward the building. Radiating system. A system that provides illumination while preventing insects from flying, comprising a low-larva or insect-repellent light source and a larval light source,
The low-larva or insect-repellent light source is installed to illuminate the area requiring lighting with low-larva or insect-repellent light,
The larva light source includes an ultraviolet radiation LED with a directivity angle of 80° or less and a maximum peak wavelength of 340 to 400 nm, and is directed at a distance of 10 m or more from the low larva or insect repellent light source and toward the low larva or insect repellent light source. A lighting system installed to emit larva light and prevent insects from flying to the vicinity of a low larva or insect repellent light source. According to claim 1,
The system wherein the larva light source has a directing angle of 60° or less. According to claim 2,
The system wherein the larva light source has a directing angle of 60° or less. According to claim 1 or 3,
The system wherein the larval light source comprises an LED lamp that emits ultraviolet rays with a maximum peak wavelength between 340 and 400 nm. delete According to claim 1 or 3,
A system in which the larva light source is installed at a distance of 10 m to 30 m from the building. According to claim 1 or 3,
A system in which the larva light source is installed at a distance of 10 m to 15 m from the building. According to claim 1 or 3,
A system wherein the irradiation area by the orientation angle is a part of the building. According to claim 1 or 3,
A system wherein the larva light source is installed at a distance such that when the larva light is irradiated to the building, the reflected light is 10% or less of the radiated light at a position of 10 cm from the wall. A method of preventing the invasion of insects into a building by combining a low-larva or insect-repellent light source and a larva light source,
The low-larva or insect-repellent light source is installed within the building, at the boundary between the building and other environments, or around the building, and illuminates the area requiring illumination with low-larva or insect-repellent light,
The larva light source has a directing angle of 80° or less, and is installed at a location 10 m or more away from the building so that the irradiation range by the directing angle is within the range of the building, and directs larvae toward the building. A method of emitting light. A method of illuminating a low larva or insect repellent light source by combining a larva light source and preventing insects from flying into the vicinity of the low larva or insect repellent light source,
The larva light source includes an ultraviolet radiation LED with a directing angle of 80° or less and a maximum peak wavelength of 340 to 400 nm, and is directed at a distance of 10 m or more from the larva or insect repellent light source. A method installed to emit larval light. According to claim 11,
The method wherein the larva light source has a directing angle of 60° or less. According to claim 12,
The method wherein the larva light source has a directing angle of 60° or less. The method of claim 11 or 13,
The method wherein the larval light source includes an LED lamp that emits ultraviolet rays whose maximum peak wavelength is in the range of 340 to 400 nm. delete The method of claim 11 or 13,
A method of installing the larva light source at a distance of 10 m to 30 m from the building. The method of claim 11 or 13,
A method of installing the larva light source at a distance of 10 m to 15 m from the building. The method of claim 11 or 13,
A method wherein the irradiation area by the orientation angle is a part of the building. The method of claim 11 or 13,
A method of installing the larva light source at a distance such that when the larva light is irradiated to the building, the reflected light is 10% or less of the radiated light at a position of 10 cm from the wall. As a kit to prevent insects from entering a building,
The kit includes a low-larva or insect repellent light source and a larva light source,
The low-larva or insect-repellent light source is installed within the building, at the boundary between the building and other environments, or around the building, and illuminates the area requiring lighting with low-larva or insect-repellent light,
The larva light source has a directing angle of 80° or less, is installed at a location more than 10 m away from the building, and the irradiation range by the directing angle is within the range of the building, and directs larval light toward the building. Radiating, kit. As a kit to prevent insects from entering a building,
The kit includes a larval light source and is combined with a low larval or insect repellent light source,
The low-larva or insect-repellent light source is installed within the building, at the boundary between the building and other environments, or around the building, and illuminates the area requiring lighting with low-larva or insect-repellent light,
The larva light source has a directing angle of 80° or less, is installed at a location more than 10 m away from the building, and the irradiation range by the directing angle is within the range of the building, and directs larval light toward the building. Radiating, kit. As a kit to prevent insects from entering a building,
The kit includes a low-larva or insect-repellent light source and is combined with a larva light source,
The low-larva or insect-repellent light source is installed within the building, at the boundary between the building and other environments, or around the building, and illuminates the area requiring lighting with low-larva or insect-repellent light,
The larva light source has a directing angle of 80° or less, is installed at a location more than 10 m away from the building, and the irradiation range by the directing angle is within the range of the building, and directs larval light toward the building. Radiating, kit. A kit for lighting while preventing insects from flying,
The kit includes a low-larva or insect repellent light source and a larva light source,
The low-larva or insect-repellent light source is installed to illuminate the area requiring lighting with low-larva or insect-repellent light,
The larva light source includes an ultraviolet radiation LED with a directivity angle of 80° or less and a maximum peak wavelength of 340 to 400 nm, and is directed at a distance of 10 m or more from the low larva or insect repellent light source and toward the low larva or insect repellent light source. A kit installed to emit larva light and prevent insects from flying to the vicinity of the larval or insect repellent light source. A kit for lighting while preventing insects from flying,
The kit includes a larval light source and is combined with a low larval or insect repellent light source,
The larva light source includes an ultraviolet radiation LED with a directivity angle of 80° or less and a maximum peak wavelength of 340 to 400 nm, and is directed at a distance of 10 m or more from the low larva or insect repellent light source and toward the low larva or insect repellent light source. A kit installed to emit larva light and prevent insects from flying to the vicinity of the larval or insect repellent light source. A kit for lighting while preventing insects from flying,
The kit includes a low-larva or insect-repellent light source and is combined with a larva light source,
The larva light source includes an ultraviolet radiation LED with a directivity angle of 80° or less and a maximum peak wavelength of 340 to 400 nm, and is directed at a distance of 10 m or more from the low larva or insect repellent light source and toward the low larva or insect repellent light source. A kit installed to emit larva light and prevent insects from flying to the vicinity of the larval or insect repellent light source. The method according to any one of claims 21 to 23,
The kit wherein the larva light source has a directing angle of 60° or less. The method according to any one of claims 24 to 26,
The kit wherein the larva light source has a directing angle of 60° or less. The method according to any one of claims 21 to 23,
A kit in which the larva light source is installed at a distance of 10 m to 30 m from the building. The method according to any one of claims 21 to 23,
A kit in which the larva light source is installed at a distance of 10 m to 15 m from the building. The method according to any one of claims 21 to 23,
A kit wherein the irradiation range by the orientation angle is a part of the building. The method according to any one of claims 21 to 23,
A kit that installs the larva light source at a distance such that when the larva light is irradiated to the building, the reflected light is 10% or less of the radiated light at a position of 10 cm from the wall.

Images