JP7312230B2 - Arrangement structure of chamber box and ultraviolet light attenuation part - Google Patents

Description

TECHNICAL FIELD The present invention relates to an arrangement structure of a chamber box and an ultraviolet light attenuation unit connected to an air conditioning duct or the like.

Germicidal lamp housings with peepholes are known. A peephole is formed in the central portion of the cover portion, and the lighting state of the germicidal lamp can be confirmed through the peephole.

Utility Model Registration No. 3231577

Germicidal lamps mainly emit ultraviolet rays. When the ultraviolet rays leak out of the device and are irradiated, there is a possibility that the surrounding devices may be deteriorated or the human body may be affected.

The present invention has been made in view of the above points. The object is to provide a chamber box that allows confirmation of the internal state without degrading peripheral devices.

The characteristics of the chamber box according to the invention are:
at least one ultraviolet light emitting unit that emits light including ultraviolet light;
at least one wall having at least one window for viewing the interior from the outside;
at least one ultraviolet light attenuation unit located between the ultraviolet light emitting unit and the window and attenuating the intensity of light with wavelengths in the ultraviolet region ;
The at least one ultraviolet light emitting unit includes a first ultraviolet light source and a second ultraviolet light source that emit light containing ultraviolet light with different peak wavelengths,
The at least one ultraviolet light attenuation unit,
a first attenuator that attenuates light having a wavelength in a first ultraviolet region among light emitted from the first ultraviolet light source;
a second attenuator that attenuates light of a wavelength in a second ultraviolet region different from the first ultraviolet region, out of the light from the second ultraviolet light source;
The first damping body and the second damping body are arranged in the window so as to overlap each other .

The internal state can be checked without degrading the peripheral devices.

BRIEF DESCRIPTION OF THE DRAWINGS It is a perspective view which shows the outline of a structure of the air cleaning system 10 by this Embodiment. 2 is a cross-sectional view showing a cross section taken along arrow AA in FIG. 1, and is a cross-sectional view showing the configuration of the first optical system. FIG. FIG. 2 is a cross-sectional view showing a cross section taken along arrow BB in FIG. 1, and is a cross-sectional view showing the configuration of the first optical system. 3 is a perspective view showing the appearance of the air cleaning unit 300. FIG. 3 is a perspective view showing the configuration of the air cleaning unit 300. FIG. 6 is a perspective view showing a state when a photocatalyst filter cassette, which will be described later, is removed from the state shown in FIG. 5. FIG. 3 is a cross-sectional view showing the arrangement of a photocatalyst filter 344, a light source for catalytic activation 350, and a light source for deactivation 360. FIG. FIG. 4 is a cross-sectional view showing a window portion 400 provided in the front wall 126; FIG. 3 is a cross-sectional view showing a state in which a first ultraviolet light blocker 510 and a second ultraviolet light blocker 520 are attached to a window portion 400; FIG. 4 is a cross-sectional view showing a light blocking body 430 that can be attached to the window portion 400;

Embodiments will be described below with reference to the drawings. FIG. 1 is a perspective view showing a schematic configuration of an air cleaning system 10 according to this embodiment. 1, the air cleaning unit 300 is indicated by hidden lines. FIG. 2 is a cross-sectional view showing a cross section taken along arrow AA in FIG. FIG. 3 is a cross-sectional view showing a cross-section taken along arrow BB in FIG. 1, 2 and 3, the air purification unit 300 is shown with hidden lines for clarity and convenience. 2 and 3, hooks 132 and 134 and wires 136 and 138 are omitted for clarity.

<<Direction>>
<Upstream direction>
The upstream direction is the direction toward a source of fluid, such as air. For example, the upstream direction is the direction toward an air conditioner (air conditioner) or the like.

<Downstream direction>
The downstream direction is the direction opposite to the upstream direction and is the direction toward the supply destination of fluid such as air. The downstream direction is, for example, the direction toward a building room or the like to which air is supplied.

<Upstream and downstream direction>
Upstream and downstream directions are directions along the upstream and downstream directions. It does not matter what direction it is, as long as it extends along the upstream and downstream directions. Note that the upstream/downstream direction may be a horizontal direction, a vertical direction, or any other direction.

<upward direction, upper side, upward direction, etc.>
The upward direction is the direction opposite to the downward direction, which will be described later, and is the direction opposite to the direction of gravity.

<Downward, downward, downward, etc.>
The downward direction is the direction of gravity. That is, the downward direction is the direction indicated by the thread that suspends the object.

<Vertical direction>
The vertical direction is a direction along the upward and downward directions. It does not matter which direction it is, as long as it is along the upward and downward directions.

<Forward direction, front side, front side, etc.>
The forward direction is directed primarily toward the location of maintenance and repair personnel. It is also called the front side or the front direction. The forward direction is the direction toward the side that is easier for the operator to operate.

<Backward direction, rear side, back side, depth side, etc.>
The rearward direction is the direction opposite to the forward direction and away from the operator's position. It is also referred to as the far side, the far side direction, and the depth direction. The rearward direction is the direction toward the side that is difficult for the operator to operate.

<Fore-and-aft direction>
The front-rear direction is a direction along the forward and rearward directions. It does not matter which direction it is, as long as it is along the forward and backward directions.

<<<<Configuration of Air Cleaning System 10>>>>
As shown in FIG. 1, the air cleaning system 10 includes a chamber box 100, an air conditioning duct 200, and an air cleaning unit 300.

<<<air conditioning duct 200>>>
Air-conditioning duct 200 is a member that constitutes an air-conditioning system provided in a building or the like. Air-conditioning systems include, for example, centralized air-conditioning control systems for detached houses, condominiums, and commercial facilities, as well as air-conditioning systems for vehicles such as aircraft.

Air-conditioning duct 200 generally has an elongated hollow structure. An air conditioner (air conditioner) (not shown) is connected to the air conditioning duct 200 . An air conditioner is a device that discharges air that has undergone conditions such as cooling, heating, humidification, and dehumidification. The air discharged from the air conditioner passes through the air conditioning duct 200 and is supplied to the rooms of the building or the like. That is, an air conditioner is connected to the upstream side of the air conditioning duct 200, a room such as a building is connected to the downstream side of the air conditioning duct 200, and air from the air conditioner is guided from upstream to downstream by the air conditioning duct 200. be.

<<<chamber box 100>>>
As shown in FIGS. 1 and 2, the chamber box 100 is arranged in the middle of the air conditioning duct 200 . The chamber box 100 may be arranged together with the air conditioning duct 200 when it is installed, or may be arranged additionally to the existing air conditioning duct 200 .

The chamber box 100 has a substantially rectangular parallelepiped shape. Chamber box 100 has a hollow shape. The chamber box 100 preferably has a square tubular shape. In addition, the chamber box 100 may have a cylindrical shape.

Since the chamber box 100 is hollow, it is possible to secure a housing space CS for housing the air cleaning unit 300 . As shown in FIGS. 1 to 3, the air purification unit 300 is housed in the housing space CS formed by the air conditioning duct 200. As shown in FIG.

The chamber box 100 is made of thin metal such as aluminum or stainless steel. The chamber box 100 may be made of resin such as plastic, glass, or the like. The material of the chamber box 100 may be appropriately selected in consideration of strength, heat conduction, weight reduction, and the like.

<<Six Walls>>
Chamber box 100 has six walls. Specifically, chamber box 100 has upstream wall 112 and downstream wall 116 , top wall 122 , bottom wall 124 , front wall 126 and rear wall 128 .

<Upstream Wall 112, Downstream Wall 116>
Upstream wall 112 and downstream wall 116 are positioned opposite each other. The upstream wall 112 and the downstream wall 116 have a thin plate-like substantially square shape. Upstream wall 112 and downstream wall 116 coincide with a cross-section along a direction perpendicular to the upstream-to-downstream direction.

The upstream wall 112 is positioned upstream of the air conditioning duct 200 . The upstream wall 112 has an upstream communication port 114 . The upstream wall 112 is connected to an air conditioning duct 200 located upstream. Air from the air conditioner flows into the chamber box 100 through the upstream communication port 114 .

Downstream wall 116 is located downstream of air conditioning duct 200 . Downstream wall 116 has a downstream communication port 118 . The downstream wall 116 is connected to an air conditioning duct 200 located downstream. Air from the chamber box 100 flows out to the air conditioning duct 200 on the downstream side through the downstream communication port 118 .

<Upper Wall 122, Lower Wall 124, Front Wall 126, Rear Wall 128>
The upper wall 122, the lower wall 124, the front wall 126, and the rear wall 128 have a thin plate-like substantially square shape. An upper wall 122 and a lower wall 124 are arranged in parallel facing each other. A front wall 126 and a rear wall 128 are arranged parallel and facing each other. The upper wall 122, the lower wall 124, the front wall 126, and the rear wall 128 define a substantially rectangular cylindrical shape.

A space surrounded by the upstream wall 112, the downstream wall 116, the upper wall 122, the lower wall 124, the front wall 126 and the rear wall 128 defines a hollow housing space CS. In the accommodation space CS of the chamber box 100, air mainly flows from upstream to downstream.

<Hooks 132, 134 and Wires 136, 138>
Hooks 132 and 134 are provided at the upstream and downstream ends of the top wall 122, respectively. For example, eyebolts or the like can be used as hooks 132 and 134 . A lower end of a wire 136 is detachably connected to the hook 132 , and a lower end of a wire 138 is detachably connected to the hook 134 .

As shown in FIG. 1, the chamber box 100 and the air-conditioning duct 200 are generally arranged in a layout space LS formed in the ceiling space, the attic space, the floor space, the wall space, or the like. The upper ends of the wires 136 and 138 of the chamber box 100 can be locked to the upper surface (not shown) of the arrangement space LS. The hooks 132, 134 and wires 136, 138 allow the chamber box 100 to be suspended. The hooks 132, 134 and the wires 136, 138 are not limited to the hooks 132, 134, and any device that allows the chamber box 100 to be provided at a fixed position may be used.

As will be described later, the chamber box 100 may become heavy due to the air purification unit 300 being attached inside it. Even if the chamber box 100 becomes heavy, it can be stably held in the arrangement space LS by suspending the chamber box 100 . In addition, even if vibration occurs due to the movement of the air flowing through the chamber box 100, by suspending the chamber box 100, it is possible to stably hold it at a fixed position in the arrangement space LS.

<Rear side opening 158>
Chamber box 100 has a rear opening 158 . A rear opening 158 is formed in the rear wall 128 . An air purification unit 300 , which will be described later, can be provided in the chamber box 100 through the rear opening 158 . The air purification unit 300 is fixed to the chamber box 100 with fastening members such as bolts. In consideration of maintenance and repair workability, an opening (not shown) is provided on the front side of the front wall 126 or the like, and the air cleaning unit 300 is detachably attached to the rear wall 128 through the opening. You may

Note that the specific method of fixing the air purification unit 300 to the chamber box 100 is not limited to this. For example, the air cleaning unit 300 may be fixed to the chamber box 100 via a reinforcing member (not shown). Alternatively, the air cleaning unit 300 may be attached to the chamber box 100 using fastening members other than bolts, locking members such as hooks, or the like.

<<Other aspects of the chamber box 100>>
The shape of the chamber box 100 may be cylindrical as well as rectangular. Moreover, the shape of the chamber box 100 may be a polygonal tubular shape such as a pentagonal tubular shape or a hexagonal tubular shape.

An outer surface of the chamber box 100 may be covered with a heat insulating member (not shown). The flowing air can be guided from upstream to downstream without changing its temperature.

The inner surface of the chamber box 100 may be formed smooth by reducing unevenness. It is possible to reduce the pressure loss and allow the air to flow smoothly.

<<<air cleaning unit 300>>>
FIG. 4 is a perspective view showing the appearance of the air cleaning unit 300. As shown in FIG. FIG. 5 is a perspective view showing the configuration of the air cleaning unit 300. As shown in FIG. FIG. 6 is a perspective view showing a state when a photocatalyst filter cassette 340, which will be described later, is removed from the state shown in FIG. FIG. 7 is a cross-sectional view showing the arrangement of the photocatalytic filter 344, the light source 350 for catalytic activation, and the light source 360 for deactivation.

The air purification unit 300 includes a photocatalyst filter cassette 340 , a catalytic activation light source 350 and a deactivation light source 360 .

<Photocatalyst filter cassette 340>
The photocatalyst filter cassette 340 has a photocatalyst filter 344 carrying a photocatalyst. The photocatalyst filter cassette 340 is formed in a cassette shape so as to be detachable.

<Light source for catalyst activation 350>
The catalyst activation light source 350 emits ultraviolet light. The ultraviolet light emitted from the light source for catalytic activity 350 is applied to the photocatalytic filter 344 of the photocatalytic filter cassette 340 . The photocatalyst of the photocatalytic filter 344 is activated by irradiation with ultraviolet light. The configuration of the photocatalyst filter 344 will be described later.

<Inactivation light source 360>
The deactivation light source 360 emits ultraviolet light with a shorter wavelength than the ultraviolet light emitted from the catalyst activation light source 350 . The ultraviolet light emitted from the deactivation light source 360 is applied to the photocatalyst filter 344 of the photocatalyst filter cassette 340 . Bacteria and viruses are inactivated by irradiating the photocatalyst filter 344 with ultraviolet light having a shorter wavelength than the ultraviolet light emitted from the light source 350 for catalytic activation.

The air cleaning unit 300 also includes an outer panel 310 , a filter guide rail 320 and a light source support frame 330 .

<Outer plate 310>
The outer plate 310 has a rectangular shape. The outer plate 310 is a plate for holding the filter guide rail 320 and attaching the air cleaning unit 300 to the air conditioning duct 200 .

<Filter guide rail 320>
The filter guide rail 320 is a member for detachably supporting the photocatalyst filter cassette 340 . Filter guide rail 320 is provided to protrude into air conditioning duct 200 from the inner surface of outer plate 310 (the surface facing inside air conditioning duct 200 ).

<Light source support frame 330>
The light source supporting frame 330 has an elongated shape. Light source support frame 330 is provided to protrude into air conditioning duct 200 from the inner surface of outer plate 310 . The light source support frame 330 is provided with a catalyst activation light source 350 or a deactivation light source 360 .

<Photocatalyst filter 344>
The photocatalyst filter cassette 340 has a photocatalyst filter 344 . The photocatalyst filter 344 carries a photocatalyst that exhibits a photocatalytic function when irradiated with ultraviolet rays.

In this embodiment, the photocatalytic filter 344 has a structure in which a photocatalyst containing apatite, titanium oxide, or the like is carried on the surface of a filter base made of an inorganic material such as stainless steel or aluminum.

The filter substrate is made of, for example, a non-woven fabric made of fibrous material made of stainless steel, aluminum, or the like, or expanded metal or punched metal made of stainless steel, aluminum, or the like. By using a filter base made of an inorganic material such as stainless steel or aluminum, deterioration of the filter base can be suppressed, and maintenance and replacement frequency can be reduced.

The method of supporting the photocatalyst includes a method of coating the surface of the filter base material, and a method of supporting a particulate photocatalyst in the fibrous body when a fibrous base material is used. The method of supporting on the surface of the filter base material is preferable in that it can easily receive the ultraviolet rays emitted by the light source 350 for catalytic activity. On the other hand, the method of supporting a fibrous body, mesh, or punching metal as a base material is preferable in that the contact area with the air flowing through the air conditioning duct 200 can be increased and the contact time with the photocatalyst can be extended.

In this embodiment, the photocatalytic filter cassette 340 has a photocatalytic filter 344 and a filter frame 342 . The photocatalyst filter 344 is held by a filter frame 342 . The photocatalyst filter 344 extends in a flat shape by being held on the filter frame 342 . Although two photocatalyst filter cassettes 340 are used in this embodiment, the number of photocatalyst filter cassettes 340 is not limited to this, and may be one or three or more.

<Support of photocatalyst filter cassette 340>
The photocatalyst filter cassette 340 is detachably supported by a pair of filter guide rails 320 facing each other.

The filter guide rail 320 has an elongated shape. The filter guide rail 320 has a tip side (protruding end side (the side away from the outer plate 310)) and a base end side (the outer plate 310 side).

The filter guide rail 320 has a substantially U-shaped cross section. The filter guide rail 320 has a bottom groove and two sidewalls. The two side walls protrude from the bottom groove with the bottom groove interposed therebetween, and face each other in parallel. An opening is formed by two sidewalls spaced apart from each other.

The pair of filter guide rails 320 are arranged such that the openings face each other and the bottom grooves are separated from each other.

In this embodiment, the air cleaning unit 300 has two photocatalyst filter cassettes 340 . A pair of filter guide rails 320 facing each other is used for each of the two photocatalyst filter cassettes 340 .

The photocatalyst filter cassette 340 is sandwiched and held between a pair of filter guide rails 320 facing each other. The ends of the photocatalyst filter cassette 340 are slid into the openings of the filter guide rails 320 from the distal end side (protruding end side) of the pair of filter guide rails 320 facing each other toward the base end side (outer plate 310 side). let it insert. In this manner, the photocatalyst filter cassette 340 is attached to the outer plate 310 via the pair of filter guide rails 320 .

A filter frame 342 of the photocatalyst filter cassette 340 has locking pieces 346 . The locking piece 346 protrudes toward the side facing the filter guide rail 320 . The locking piece 346 protrudes in a direction perpendicular to the sliding direction of the photocatalyst filter cassette 340 (that is, a direction perpendicular to the normal direction of the photocatalyst filter 344). On the other hand, the filter guide rail 320 has locking holes 322 .

When the photocatalyst filter cassette 340 is attached to the filter guide rail 320 , the locking piece 346 of the photocatalyst filter cassette 340 is locked to the locking hole 322 of the filter guide rail 320 . As a result, the photocatalyst filter cassette 340 is fixed at a predetermined position on the filter guide rail 320 .

<Catalyst activation light source 350 and deactivation light source 360>
The catalyst activation light source 350 is a light source for irradiating the photocatalyst filter cassette 340 with ultraviolet light to activate the photocatalyst. The inactivating light source 360 is a light source for inactivating bacteria and viruses. By configuring the catalyst activation light source 350 and the inactivation light source 360 separately without sharing them, both the effect of deodorizing by activating the photocatalyst and the effect of inactivating bacteria and viruses can be achieved. , it becomes possible to get enough. In particular, the air conditioning duct 200 has a large amount of air to process compared to a normal indoor air purifier or the like. For this reason, in order to sufficiently obtain the effects of deodorization and inactivation of bacteria, it is desirable to configure the catalyst activation light source 350 and the inactivation light source 360 separately.

The catalyst activation light source 350 has a plurality of light emitting diodes 352 . The plurality of light emitting diodes 352 are arranged substantially linearly. The deactivation light source 360 has a plurality of light emitting diodes 362 . The plurality of light emitting diodes 362 are arranged substantially linearly. By configuring the catalyst activation light source 350 with the light emitting diode 352 and the deactivation light source 360 with the light emitting diode 362, for example, compared to the case of using an ultraviolet lamp, the catalyst activation light source 350 and the deactivation light source 350 The size of the light source 360 can be reduced. Specifically, the catalyst activation light source 350 and the deactivation light source 360 can be formed thin. By doing so, it is possible to suppress an increase in air resistance in the air conditioning duct 200 due to the light source 350 for catalyst activation and the light source 360 for deactivation. Therefore, the catalyst activation light source 350 and the deactivation light source 360 can be applied to a small (thin) air conditioning duct 200 as well.

Further, by configuring the light source 350 for catalyst activation with a light emitting diode 352 and configuring the light source 360 for deactivation with a light emitting diode 362, power consumption can be suppressed as compared with the case of using an ultraviolet lamp, for example.

In addition, the light emitting diodes 352 and 362 have a long lifespan, eg, not requiring replacement of the light emitting diodes for more than five years. For this reason, compared to ultraviolet lamps that must be replaced about once a year, it is possible to reduce the trouble of replacement and running costs, and improve maintainability. In particular, as in the present embodiment, the effect can be greatly enhanced by separately configuring the catalyst activation light source 350 with the light emitting diode 352 and the deactivation light source 360 with the light emitting diode 362 .

A light-emitting diode that emits ultraviolet light with a wavelength of 360 nm or more and 380 nm or less is used as the light-emitting diode 352 that constitutes the light source 350 for catalytic activation. In this embodiment, a light emitting diode 352 that emits ultraviolet light with a wavelength of 365 nm is used as the light source 350 for catalyst activation.

As the light emitting diode 362 constituting the deactivation light source 360, one that emits ultraviolet light having a shorter wavelength than the light emitting diode 352 constituting the catalyst activation light source is used. More specifically, a light-emitting diode that emits deep ultraviolet light with a wavelength of 250 nm or more and 280 nm or less is used as the light-emitting diode 362 that constitutes the deactivation light source 360 . In this embodiment, a light-emitting diode 362 that emits deep ultraviolet light with a wavelength of 280 nm is used as the light source 360 for deactivation.

As shown in FIG. 6, a plurality of light emitting diodes 352 are arranged in a substantially straight line on the light source support frame 330 to constitute the catalytic activation light source 350 . A plurality of light emitting diodes 362 are arranged in a substantially straight line on the light source support frame 330 to form the deactivation light source 360 . The light source supporting frame 330 on which the light emitting diode 352 is arranged and the light source supporting frame 330 on which the light emitting diode 362 is arranged are spaced apart from each other in parallel. Therefore, the plurality of light emitting diodes 352 and the plurality of light emitting diodes 362 are arranged in a matrix as a whole (on intersections of a plurality of grids).

In this embodiment, the air cleaning unit 300 has two photocatalyst filter cassettes 340 . The two photocatalyst filter cassettes 340 are arranged to face each other while being separated from each other. A catalytic activation light source 350 and a deactivation light source 360 are arranged between the photocatalytic filters 344 of the two photocatalytic filter cassettes 340 .

As shown in FIGS. 6 and 7, the air purification unit 300 has a total of four catalyst activation light sources 350 and two deactivation light sources 360. As shown in FIGS. Six light source supporting frames 330 protrude from the outer plate 310 . Six light source supporting frames 330 extend vertically from the outer plate 310 . The six light source supporting frames 330 are arranged parallel to each other while being separated from each other. Each of the four catalyst activation light sources 350 and the two deactivation light sources 360 is attached to the light source support frame 330 .

Two light sources for catalytic activation 350 and one light source for deactivation 360 are arranged in association with each of the two photocatalyst filters 344 . Two catalytic activation light sources 350 corresponding to each of the photocatalytic filters 344 are arranged in parallel with one deactivation light source 360 interposed therebetween. Ultraviolet rays emitted from two light sources for catalytic activation 350 and one light source for deactivation 360 travel toward the corresponding photocatalytic filters 344 and are irradiated.

The catalyst activation light source 350 is arranged farther from the photocatalyst filter cassette 340 than the deactivation light source 360 is. As a result, the entire photocatalyst filter 344 can be irradiated with the ultraviolet light from the light source 350 for catalytic activation, even if the photocatalyst filter 344 is relatively large in size, and a sufficient photocatalyst activation effect can be obtained. In addition, the deactivation light source 360 is arranged closer to the photocatalyst filter cassette 340 than the catalyst activation light source 350 is. This makes it possible to sufficiently obtain the effect of inactivating bacteria and viruses by the inactivating light source 360 .

As shown in FIG. 7, the catalyst activation light source 350 and the deactivation light source 360 are provided so that the emitted ultraviolet light is directed from the inside (the center side in the air conditioning duct 200) to the outside (the inner wall side of the air conditioning duct 200). It is As a result, the wires for the catalyst activation light source 350 and the deactivation light source 360 can be collected in the central portion of the air cleaning unit 300, and the wiring layout can be simplified. However, not limited to this, the catalyst activation light source 350 and the deactivation light source 360 are provided so as to emit ultraviolet light from the outside (the inner wall side of the air conditioning duct 200) toward the inside (the center side in the air conditioning duct 200). may In this case, since the inner wall of the air conditioning duct 200 is less likely to be irradiated with ultraviolet light, deterioration of the air conditioning duct 200 can be suppressed.

In this embodiment, the photocatalyst filter 344 is arranged such that the extending surface of the photocatalyst filter 344 is parallel to the air flow from upstream to downstream. is not limited to this. For example, the photocatalyst filter 344 may be arranged such that the extending surface of the photocatalyst filter 344 is perpendicular to the air flow. Moreover, the photocatalytic filter 344 may be arranged so that the surface on which the photocatalytic filter 344 extends forms a predetermined angle with respect to the air flow.

As shown in FIG. 4, a handle 312 is provided on the front side of the outer plate 310 (the surface exposed to the outside of the air conditioning duct 200). An operator can grip the handle 312 to attach or detach the air cleaning unit 300 to or from the air conditioning duct 200 .

A power jack 314 is provided on the front side of the outer plate 310 . A power plug (not shown) is inserted into the power jack 314 . The power plug is provided at the end of a power cord (not shown) extending from a power supply device (not shown).

A notification light emitting diode 316 is provided near the power jack 314 . The notification light emitting diode 316 notifies the power supply state, the driving state of the catalyst activation light source 350 and the deactivation light source 360, and the like by emitting light.

<<<<window part 400>>>>
FIG. 8 is a cross-sectional view showing the window 400 provided in the front wall 126. As shown in FIG. In addition, in FIG. 8, the window part 400 is indicated by an imaginary line in order to show the positional relationship with the air cleaning unit 300. As shown in FIG.

The front wall 126 has a window 400 . The window part 400 is an opening (through hole). A worker or the like can visually recognize the inside of the chamber box 100 through the window portion 400 . In particular, through the window 400, the lighting state of the catalytic activation light source 350 (plurality of light emitting diodes 352) and the deactivation light source 360 (plurality of light emitting diodes 362) of the air purification unit 300 can be visually recognized. That is, it can be confirmed through the window 400 whether the air cleaning unit 300 is operating normally.

The window portion 400 may be provided not only on the front wall 126 but also on the lower wall 124 , the front wall 126 and the rear wall 128 as well as the upstream wall 112 and the downstream wall 116 . The window part 400 may be provided at a portion where the work of checking the inside of the chamber box 100 is facilitated.

The window part 400 has an elongated rectangular shape. The longitudinal direction of the window portion 400 is the upstream/downstream direction. As shown in FIG. 8, the catalyst activation light source 350 and the deactivation light source 360 are arranged dispersedly in the upstream and downstream directions. Specifically, two catalyst activation light sources 350 and one deactivation light source 360 are arranged on each of the upper and lower sides. On each of the upper and lower sides, the catalyst activation light sources 350 are arranged at two locations, upstream and downstream, and the deactivation light source 360 is arranged at one central location. By arranging the longitudinal direction of the window 400 in the upstream/downstream direction, the entire state of the light source 350 for catalytic activation and the light source 360 for deactivation can be visually recognized through the window 400 .

The shape, size, position, etc. of the window 400 may be appropriately determined according to the arrangement (distribution) and size of the light source 350 for catalytic activation and the light source 360 for deactivation. Through the window part 400, the operation state of the light source 350 for catalytic activation and the light source 360 for deactivation can be accurately visually recognized by configuring the entirety of the light source 350 for catalytic activation and the light source 360 for deactivation. can.

<<Wavelength Range of Catalyst Activation Light Source 350 and Inactivation Light Source 360>>
The light-emitting diodes 352 constituting the light source 350 for catalytic activation described above mainly emit ultraviolet light (UV-A) in a wavelength range of 360 nm or more and 380 nm or less. Ultraviolet light (UV-A) has a peak wavelength of 365 nm. The light emitting diode 352 also emits light in the visible wavelength range.

The light-emitting diode 362 constituting the deactivation light source 360 described above mainly emits ultraviolet light (UV-C) in a wavelength range of 250 nm or more and 280 nm or less. Ultraviolet light (UV-C) has a peak wavelength of 280 nm. The light emitting diode 362 also emits light in the visible wavelength range.

<<<<ultraviolet light blocker 500>>>>
An ultraviolet light blocker 500 is attached to the window portion 400 . The ultraviolet light blocker 500 has a first ultraviolet light blocker 510 and a second ultraviolet light blocker 520 .

<<First ultraviolet light blocker 510>>
The first ultraviolet light blocker 510 is made of soda lime glass. The first ultraviolet light blocker 510 is made of glass. The first ultraviolet light blocker 510 has a plate-like shape with a predetermined thickness. The first ultraviolet light blocker 510 is made of glass and has higher rigidity than the second ultraviolet light blocker 520 .

The first ultraviolet light blocker 510 mainly attenuates ultraviolet light (UV-C) emitted from the deactivation light source 360 . Specifically, the first ultraviolet light blocker 510 attenuates light of 300 nm or less. In particular, the first ultraviolet light blocker 510 preferably blocks light of 300 nm or less. That is, the first ultraviolet light blocker 510 preferably does not transmit light of 300 nm or less.

The first ultraviolet light blocker 510 transmits light with wavelengths in the visible light range. That is, the first ultraviolet light blocker 510 transmits light having wavelengths in the visible light range included in the light emitted from the deactivation light source 360 .

Note that the first ultraviolet light blocker 510 is not limited to soda lime glass as long as it is an optical element that does not transmit light of 300 nm or less. The first ultraviolet light blocker 510 may be an optical element that emits only visible light, such as an optical element that converts light of 300 nm or less into visible light. Furthermore, the first ultraviolet light blocker 510 may be an optical element having durability against ultraviolet light.

<<Second ultraviolet light blocker 520>>
The second ultraviolet light blocker 520 is composed of an ultraviolet light transmission prevention film. The second ultraviolet light blocker 520 is made of resin or the like. The second ultraviolet light blocker 520 has a film-like shape with a predetermined thickness. The second ultraviolet light blocker 520 has flexibility. The second ultraviolet light blocker 520 deforms more easily than the first ultraviolet light blocker 510 .

The second ultraviolet light blocker 520 mainly attenuates ultraviolet light (UV-A) emitted from the light source 350 for catalytic activity. Specifically, the second ultraviolet light blocker 520 attenuates light of 400 nm or less. In particular, the second ultraviolet light blocker 520 preferably blocks light of 400 nm or less. That is, the second ultraviolet light blocker 520 preferably does not transmit light of 400 nm or less.

The second ultraviolet light blocker 520 transmits light with wavelengths in the visible light range. That is, the second ultraviolet light blocker 520 transmits light having a wavelength in the visible light range included in the light emitted from the light source 350 for catalytic activation.

It should be noted that the second ultraviolet light blocker 520 is not limited to an ultraviolet transmission preventing film as long as it is an optical element that does not transmit light of 400 nm or less. The second ultraviolet light blocker 520 may be an optical element that emits only visible light, such as an optical element that converts light of 400 nm or less into visible light. Furthermore, the second ultraviolet light blocker 520 may be an optical element having durability against ultraviolet light.

<Structure of Ultraviolet Light Blocking Body 500>
FIG. 9 is a cross-sectional view showing a state in which the first ultraviolet light shielding member 510 and the second ultraviolet light shielding member 520 are attached to the window portion 400. FIG.

The first ultraviolet light shielding member 510 and the second ultraviolet light shielding member 520 are arranged to cover the entire surface of the window 400 while overlapping each other. Specifically, the second ultraviolet light shielding member 520 is adhered onto the first ultraviolet light shielding member 510 to be integrated. By attaching the second ultraviolet light shielding member 520 to the first ultraviolet light shielding member 510, the second ultraviolet light shielding member 520 can be kept in a constant shape. By integrating the first ultraviolet light shielding member 510 and the second ultraviolet light shielding member 520, the attachment work to the window part 400 can be simplified.

<<<<light shielding body 430>>>>
FIG. 10 is a cross-sectional view showing a light shield 430 that can be attached to the window 400. As shown in FIG. In addition, in FIG. 10 , the first ultraviolet light shielding member 510 and the second ultraviolet light shielding member 520 are provided inside the front wall 126 . The entire surface of the window part 400 is covered with the first ultraviolet light blocker 510 and the second ultraviolet light blocker 520 .

A light shield 430 is a lid for the window 400 . The light shielding body 430 has a plate-like shape with a predetermined thickness. The light blocking body 430 has a size corresponding to the size of the window portion 400 .

The light shield 430 blocks light in a wide range of wavelengths including visible light. The light shielding body 430 is made of metal such as aluminum or stainless steel. The light blocking body 430 may be made of a resin such as plastic as long as it is a material that blocks light. The light shielding body 430 preferably has high rigidity. The first ultraviolet light blocker 510 and the second ultraviolet light blocker 520 can be properly protected.

The light blocking body 430 can be detachably attached to the window portion 400 . When it is not necessary to check the inside of the chamber box 100 , the light shield 430 is attached to the window 400 . A light shield 430 can be fitted into the window 400 . When the light shield 430 is attached to the window portion 400 , the light shield 430 covers the first ultraviolet light shield 510 and the second ultraviolet light shield 520 . The first ultraviolet light blocker 510 and the second ultraviolet light blocker 520 can be protected by the light blocker 430 .

Also, as described above, the light shield 430 can block light in a wide wavelength range. Even if the first ultraviolet light blocker 510 and the second ultraviolet light blocker 520 deteriorate over time, it is possible to prevent light from leaking to the outside.

<<<<Other configurations>>>>
<Protective glass>
A protective glass (not shown) may be provided to protect the second ultraviolet light blocker 520 from the outside. The protective glass transmits light with wavelengths in the visible range. By providing the protective glass, it is possible to prevent the second ultraviolet light blocker 520 from being damaged or damaged due to contact with a member such as a tool or other device from the outside of the chamber box 100 .

<Light guide member such as optical fiber>
Light emitted from the first ultraviolet light blocker 510 and the second ultraviolet light blocker 520 is transmitted through the first ultraviolet light blocker 510 and the second ultraviolet light blocker using various light guide members such as optical fibers. It may be guided to the blocking body 520 . The light emitted from the first ultraviolet light blocker 510 and the second ultraviolet light blocker 520 is accurately guided to the window part 400 without being obstructed by various members provided inside the chamber box 100. be able to. Visibility can be improved.

<<<<Scope of Embodiment>>>>
The embodiments have been described as described above. However, the description and drawings forming part of this disclosure should not be understood as limiting. Various embodiments and the like not described here are included.

(Embodiment of invention)
<<First Embodiment>>
According to a first embodiment,
at least one ultraviolet light emitting unit that emits light including ultraviolet light (for example, the catalyst activation light source 350 and the deactivation light source 360 described above);
At least one wall portion (for example, the front wall 126, the lower wall 124, the front wall 126, back wall 128, upstream wall 112, downstream wall 116, etc.);
At least one ultraviolet light attenuating portion (for example, the first ultraviolet light blocker 510 and the second A chamber box is provided comprising a UV light blocker 520 such as

The chamber box comprises at least one ultraviolet light emitting portion, a wall portion and at least one ultraviolet light attenuating portion.

At least one ultraviolet light emitting section emits light including ultraviolet light. Specifically, at least one ultraviolet light emitting unit emits light with a wavelength in the ultraviolet light range and light with a wavelength in the visible light range.

The wall has at least one window. The window is an area for viewing the inside from the outside of the chamber box. The window can be, for example, an opening (through hole).

Examples of the at least one wall portion include the following. When the chamber box is formed of a sphere, ellipsoid, prolate sphere, etc., at least one wall is a single (one) wall. When the chamber box is formed of a conical body or the like, at least one wall is two walls, one side and one bottom. When the chamber box is formed of a cylinder, an elliptical cylinder, or the like, at least one wall has three walls, one side and two bottoms.

At least one ultraviolet light attenuation portion is located between the ultraviolet light emitting portion and the window portion. The position of the at least one ultraviolet light attenuation portion can be any desired position between the ultraviolet light emitting portion and the window portion. The position of at least one ultraviolet light attenuating portion is preferably close to the window portion. By bringing the ultraviolet light attenuation section closer to the window section, it is possible to prevent stray light such as reflected light emitted from the ultraviolet light emission section from reaching the window section.

At least one ultraviolet light attenuator attenuates the intensity of light with wavelengths in the ultraviolet range. In particular, at least one ultraviolet light attenuating section preferably blocks light with wavelengths in the ultraviolet region. It should be noted that blocking is a type of attenuation, and is included in blocking if the intensity of light with wavelengths in the ultraviolet range can be sufficiently attenuated. Sufficient attenuation means that the strength is such that it is difficult to degrade the member or the like. For example, it is sufficient if the intensity can be attenuated to about the intensity of ultraviolet rays contained in sunlight.

At least one ultraviolet light attenuating part attenuates the intensity of light with wavelengths in the ultraviolet region, so that the ultraviolet light is prevented from leaking to the outside through the window part, and deterioration of peripheral devices and the like can be prevented.

Also, at least one ultraviolet light attenuator can be configured by a shielding plate for shielding ultraviolet rays or an attenuation plate for attenuating the intensity of ultraviolet rays.

The aperture has a size and shape corresponding to the arrangement and number of the ultraviolet light emitting portions. The openings are arranged at positions according to the arrangement and number of the ultraviolet light emitting portions. By doing so, the states of all the ultraviolet light emitting portions can be visually confirmed.

An opening is provided in any one of the wall surfaces. An opening can be provided at a position that is easily visible according to installation conditions such as the space in which the chamber box is installed.

<<Second Embodiment>>
A second embodiment is the first embodiment, wherein
The at least one ultraviolet light emitting unit includes a first ultraviolet light source (e.g., the catalytic activation light source 350 described above) and a second ultraviolet light source (e.g., including the inactivating light source 360 described above),
The at least one ultraviolet light attenuation unit,
a first attenuator (for example, the second ultraviolet light blocker 520 described above) that attenuates the light of the wavelength in the first ultraviolet region among the light of the first ultraviolet light source;
A second attenuator (for example, the first ultraviolet light blocker 510 described above) that attenuates light of a wavelength in a second ultraviolet region different from the first ultraviolet region among the light from the second ultraviolet light source etc.) and

Even when a plurality of ultraviolet light sources having different peak wavelengths are used, the ultraviolet light can be accurately blocked or attenuated by using corresponding attenuators.

<<Third Embodiment>>
A third embodiment is the second embodiment,
The first attenuator transmits light of wavelengths in the visible range contained in light from the first ultraviolet light source,
The second attenuator transmits light in the visible range included in the light from the second ultraviolet light source.

The lighting state of the first ultraviolet light source and the lighting state of the second ultraviolet light source can be visually recognized by using the light in the visible region emitted from the first ultraviolet light source and the second ultraviolet light source.

<<Fourth Embodiment>>
A fourth embodiment is the second embodiment,
The first damping body and the second damping body are arranged in the window so as to overlap each other.

By stacking the first attenuator and the second attenuator, the window can be shared, the configuration can be simplified, and the ultraviolet light can be blocked or attenuated accurately and simply.

In addition, it is preferable that the window section further includes a detachable light shield (for example, the light shield 430 described above). When not in use (when there is no need to visually recognize), the window can be properly closed.

<<Fifth Embodiment>>
A fifth embodiment is the third embodiment,
The first damping body is made of a glass material,
the second damping body is made of a non-glass material,
The second attenuator is arranged farther from the ultraviolet light emitting section than the first attenuator.

A second damping body made of a non-glass member is covered by a first damping body made of a glass member. Therefore, the second attenuator is not directly irradiated with ultraviolet light, and deterioration of the second attenuator can be prevented. That is, the first damping body can function as a protector for the second damping body.

The second attenuator may also be made of a glass material as long as it conforms to the wavelength range of ultraviolet light.

REFERENCE SIGNS LIST 10 air cleaning system 100 chamber box 200 air conditioning duct 300 air cleaning unit 400 window 500 ultraviolet light shielding member 510 first ultraviolet light shielding member 520 second ultraviolet light shielding member CS housing space LS arrangement space

Claims (5)

at least one ultraviolet light emitting unit that emits light including ultraviolet light;
at least one wall having at least one window for viewing the interior from the outside;
at least one ultraviolet light attenuation unit located between the ultraviolet light emitting unit and the window and attenuating the intensity of light with wavelengths in the ultraviolet region ;
The at least one ultraviolet light emitting unit includes a first ultraviolet light source and a second ultraviolet light source that emit light containing ultraviolet light with different peak wavelengths,
The at least one ultraviolet light attenuation unit,
a first attenuator that attenuates light having a wavelength in a first ultraviolet region among light emitted from the first ultraviolet light source;
a second attenuator that attenuates light of a wavelength in a second ultraviolet region different from the first ultraviolet region, out of the light from the second ultraviolet light source;
The chamber box , wherein the first damping body and the second damping body are arranged in the window so as to overlap each other . The first attenuator transmits light of wavelengths in the visible range contained in light from the first ultraviolet light source,
2. The chamber box according to claim 1 , wherein said second attenuator transmits light of wavelengths in the visible range included in light from said second ultraviolet light source. The first damping body is made of a glass material,
the second damping body is made of a non-glass material,
3. The chamber box according to claim 2, wherein said second attenuator is arranged farther from said ultraviolet light emitting section than said first attenuator. Air flows inside from upstream to downstream,
The first ultraviolet light source and the second ultraviolet light source are arranged apart from each other in the upstream and downstream direction of the air,
The chamber box according to claim 1, wherein the window has an elongated shape, and the longitudinal direction of the window is the up-down direction. 2. The chamber box according to claim 1, wherein the first ultraviolet light source and the second ultraviolet light source are long and extend in a direction perpendicular to the upstream and downstream directions.

Images