JP2021126276A - Ultraviolet cut filter - Google Patents

Abstract

To provide an ultraviolet cut filter capable of irradiating and killing bacteria and virus in the air with ultraviolet (UV-C), installed in an air purifier for exhausting purified air outside the air purifier, capable of passing the air so as to suck outside air into the air purifier and exhaust the air purified outside the air purifier, capable of intercepting harmful ultraviolet (UV-C) to prevent the harmful ultraviolet from leaking outside the air purifier, compact, simple in structure and inexpensive.SOLUTION: A plurality of spherical or polyhedral balls formed of soda glass, etc., laminated into a plurality of layers and charged in the inside of a filter box having meshes 4 attached to both side end openings facing each other are placed in a passage sucking outside air into an air purifier and a passage exhausting purified air to the outside of the air purifier. Although air passes through the passages, the blocking of harmful ultraviolet (UV-C) can avoid the leakage of the harmful ultraviolet to the outside of the air purifier.SELECTED DRAWING: Figure 1

Description

The invention of the present application is provided in an air purifier that kills bacteria and viruses in the air sucked into the vessel by irradiating ultraviolet rays (UV-C) called sterilization rays with a wavelength of around 253 nanometers. It relates to an ultraviolet cut filter that allows air to pass through while preventing the leakage of ultraviolet rays (UV-C) to the outside.

Harmful bacteria and viruses that cause illnesses such as colds and influenza are floating in the air.
People may get sick by inhaling these bacteria and viruses as they breathe. In particular, if you are with a carrier in a closed space such as indoors or in a car, the risk of getting sick increases.
As one of the methods to kill bacteria and viruses in the indoor air, the indoor air is sucked into the air purifier, and the air taken into the vessel is sterilized with a high sterilizing effect and a wavelength of around 253 nanometers. Irradiates ultraviolet rays (hereinafter referred to as ultraviolet rays (UV-C)) classified into UV-C including ultraviolet rays called rays to kill bacteria and viruses and discharge purified air to the outside of the vessel. There is a way to purify the air in the room.
However, with this method, if ultraviolet rays (UV-C) leak out of the device and hit the skin or look directly at the leaked ultraviolet rays, there is a risk of skin irritation or eye damage. be.

Japanese Unexamined Patent Publication No. 2016-32620 (Patent Document 1) describes an air purifier that prevents the leakage of ultraviolet rays (UV-C) to the outside of the device and eliminates the above-mentioned danger.
In this air purifier, air is sucked from one end of the box into a box equipped with an ultraviolet lamp inside, and ultraviolet rays (UV-C) are irradiated in the box to be contained in the air. It kills bacteria and viruses and expels clean air from the other end of the box.
Then, in order to prevent the ultraviolet rays (UV-C) from leaking to the outside of the device, the wake side of the air intake port (intake port) of the air purifier and the upstream side of the air discharge port (exhaust port, outlet). In addition, a plurality of light-shielding plates (intake plates) are provided at intervals, thereby blocking ultraviolet rays (UV-C) and preventing the light-shielding plate and the light-shielding plate from leaking to the outside of the device. Air can pass through the space between and.

However, in the air purifier described in this document, a plurality of light-shielding plates are required in order to secure a passage through which air passes while preventing leakage of ultraviolet rays, and a space between the light-shielding plate and the light-shielding plate is required. The light-shielding plates must be arranged so that the notches (the parts that allow air to pass through) are staggered, and the light-shielding plates must be arranged in at least two rows and three rows with caution. Therefore, a space for that is required, and the size of the device becomes large.
In addition, a means such as painting is required to prevent ultraviolet rays (UV-C) from being reflected on the surface of the light-shielding plate, which increases the cost.

Further, as a method of blocking ultraviolet rays or avoiding irradiation to the human body, various ultraviolet cut filters have been conventionally proposed.
For example, as described in JP2013-253361A (Patent Document 2), an ultraviolet cut coat is vapor-deposited on the surface of a glass plate by a vapor deposition method, or JP-A-2008-34350 (Patent Document 3). ), A typical method of producing an ultraviolet cut filter is to apply an ultraviolet cut material composed of indium-doped zinc oxide fine particles to the surface of the glass to form an ultraviolet cut film. Although it is a method, the ultraviolet cut filter manufactured in this way is completely different from the invention of the present application in that not only the manufacturing cost is high but also that it cannot pass air by itself, and this is air-cleaned. It is not suitable for installation in a vessel.

Japanese Unexamined Patent Publication No. 2016-32620 Japanese Unexamined Patent Publication No. 2013-253361 Japanese Unexamined Patent Publication No. 2008-34350

The invention of the present application solves the above-mentioned problems of the conventional air purifier and the ultraviolet cut filter, and can be installed in the air purifier to suck the outside air into the device or to use the device. Compact and simple in structure that allows air to pass through so that it can be discharged to the outside and can block harmful ultraviolet rays (UV-C) to prevent it from leaking out of the vessel. Therefore, it is an object to provide an inexpensive ultraviolet ray cut filter.

The above-mentioned problems are solved by the following inventions described in each claim of the claims of the present application.
That is, the invention according to claim 1 sucks outside air into the vessel and kills the bacteria and viruses in the sucked air by irradiating ultraviolet rays (UV-C) in the vessel. , An ultraviolet cut filter installed in an air purifier that discharges purified air to the outside of the device, and meshes are attached to the opposite side end openings of a polygonal box-shaped or circular tubular filter box, respectively. The inside of the filter box is filled with a plurality of spherical or polyhedral balls, and the filter box is installed in a passage for sucking outside air into the vessel or a passage for discharging purified air to the outside of the vessel. The ultraviolet cut filter is characterized in that air can pass through the passage while preventing harmful ultraviolet rays (UV-C) from leaking to the outside of the vessel. be.

The invention according to claim 2 is characterized in that the plurality of balls are laminated and filled in a plurality of layers, with different phases between adjacent layers. The ultraviolet cut filter according to claim 1.

The invention according to claim 3 is the ultraviolet cut filter according to claim 1, wherein the plurality of balls are glass balls made of soda glass.

The invention according to claim 4 is the ultraviolet cut filter according to claim 3, wherein the glass ball has fine irregularities like ground glass on its surface.

The invention according to claim 5 is the ultraviolet cut filter according to claim 1, wherein the plurality of balls are ceramic balls or metal balls made of ceramics or metal.

The invention according to claim 6 is the ultraviolet cut filter according to claim 5, wherein the ceramic ball or the metal ball has a surface having fine irregularities like frosted glass. ..

Further, in the invention according to claim 7, meshes are attached to opposite side end openings of a polygonal box-shaped or circular tubular filter box, and a spherical or polyhedral shape is inside the filter box. An ultraviolet cut filter characterized in that a plurality of balls are filled to allow air to pass through while preventing harmful ultraviolet rays (UV-C) from being transmitted.

Further, the invention according to claim 8 is characterized in that the plurality of balls are laminated and filled in a plurality of layers, with different phases between adjacent layers. The ultraviolet cut filter according to claim 7.

Since the invention of the present application is configured as described above, the following effects can be obtained.
In the ultraviolet cut filter of the present invention, a plurality of spherical or polyhedral balls are filled inside a polygonal box-shaped or circular tubular filter box in which meshes are attached to opposite side end openings. It is a structure, and since it is installed in the passage that sucks in the outside air inside the air purifier and the passage that discharges the cleaned air outside the air purifier, it is in the air sucked into the air purifier. Ultraviolet rays (UV-C) containing ultraviolet rays called germicidal lines with a wavelength of around 253 nanometers, which are irradiated to kill bacteria and viruses, are filled inside the filter box of the ultraviolet cut filter. By being absorbed by the ball, reflected, and further absorbed, it is blocked and cannot pass through the UV cut filter. This makes it possible to prevent harmful ultraviolet rays (UV-C) from leaking out of the device through the ultraviolet cut filter.
On the other hand, since the air can pass through the ultraviolet cut filter through the gap between the balls of the plurality of balls, the outside air can be sucked into the vessel through the ultraviolet cut filter, or the ultraviolet rays ( Air that has been sterilized and purified by UV-C) can be discharged to the outside of the vessel.

In addition, since this ultraviolet cut filter has a simple structure as described above, it can be manufactured compactly and inexpensively.
Furthermore, since a plurality of balls are laminated and filled in a plurality of layers, with different phases between adjacent layers, the structure of the ultraviolet cut filter is further simplified, and the structure of the ultraviolet cut filter is further simplified. The blocking effect is also improved.

Further, as described above, this ultraviolet cut filter prevents harmful ultraviolet rays (UV-C) from leaking to the outside of the vessel, while air passes through the filter and is discharged to the outside of the vessel or into the vessel. Since it can be inhaled, it has traditionally been used for the same purpose when installed in a passage for inhaling outside air inside the air purifier or in a passage for discharging purified air outside the air purifier. The means such as the light-shielding plate (stand plate) that was used is no longer required, and the air purifier becomes compact, the structure becomes simple, it can be manufactured at low cost, and the air resistance is reduced. Since the fan can also be miniaturized, the noise can also be reduced.

In general, the window glass is made of soda glass. For example, in a window glass having a thickness of 4 mm, the transmittance of ultraviolet rays (UV-C) is zero, and ultraviolet rays (UV-C) are soda. It is absorbed by the glass and cannot pass through it.
Therefore, when the plurality of balls are composed of glass balls made of soda glass, ultraviolet rays (UV-C) are better absorbed by the plurality of glass balls, which is more effective. By blocking the ultraviolet rays (UV-C), it is possible to more effectively prevent the ultraviolet rays (UV-C) from passing through the ultraviolet cut filter.
Since visible light is transmitted through the glass ball, when the ultraviolet lamp is lit, the pale visible light emitted together with the ultraviolet light can be seen through the ultraviolet cut filter, so check that the ultraviolet lamp is lit or the lamp is out. You can also do it.

When the plurality of balls are composed of ceramic balls or metal balls made of ceramics or metal, the material itself blocks ultraviolet rays (UV-C) and ultraviolet rays (UV-C). However, in addition to preventing the UV cut filter from passing through, it can also be used in an environment where vibration or shock is applied.

Further, if the surface of each of the glass ball, ceramic ball, and metal ball has fine irregularities like frosted glass, ultraviolet rays (UV-C) are scattered on the surface to reduce reflection on the surface. It is possible to more effectively absorb and block ultraviolet rays (UV-C) and more effectively prevent ultraviolet rays (UV-C) from passing through the ultraviolet cut filter.

In addition, as described above, this ultraviolet cut filter has the effect of blocking harmful ultraviolet rays (UV-C) but allowing air to pass through, so taking advantage of this feature, various applications that require similar effects. It can be applied to. For example, it can be installed at the heat exhaust port of the box in which the ultraviolet lamp is installed.

It is a perspective view of the ultraviolet ray cut filter of the Example of this invention. It is a vertical cross-sectional view of the ultraviolet cut filter. It is a perspective view of the lower case of the ultraviolet cut filter. It is a perspective view of the state in which a plurality of glass balls are filled in the lower case of the ultraviolet cut filter. It is a perspective view of the upper case of the same ultraviolet ray cut filter. It is a figure which shows the laminated structure of the plurality of glass balls, and is the figure which shows the place where the air passes between the glass balls. It is a perspective view of the air purifier which installed the ultraviolet ray cut filter. It is a perspective view of the duct box which is a component of the air purifier. It is a perspective view of the state which the top plate part was removed from the ultraviolet lamp box which is a component of the air purifier. It is a perspective view of the state in which the top plate portion of the air purifier and the front plate portion on the front side are removed. It is a perspective view seen from the AA cross section shown in FIG. 7 of the air purifier.

(Example 1)
Next, an embodiment (Example 1) of the ultraviolet cut filter of the present invention will be described in detail with reference to the drawings.
The ultraviolet cut filter of the first embodiment is mainly used by being installed in an air purifier.
This air purifier sucks the outside air into the container and kills the bacteria and viruses in the inhaled air by irradiating it with ultraviolet rays (UV-C), and is cleaned in this way. The air is discharged to the outside of the vessel.
In the following, first, the ultraviolet cut filter will be described, and then the air purifier in which the filter is installed will be described.

(UV cut filter, its basic structure)
FIG. 1 is a perspective view of the ultraviolet cut filter of the first embodiment, and FIG. 2 is a vertical sectional view thereof.
As shown in FIGS. 1 and 2, the ultraviolet cut filter 1 is formed from the top of the square dish-shaped lower case 3 (see FIG. 3 for details) to the square dish-shaped upper case 2 (specifically, see FIG. 3). , Fig. 5) is fitted like a can lid, and as a whole, it is shaped like a slightly flat square box, and a plurality of glass balls 6 are inside the box. It is filled and configured.
The shapes of the upper case 2 and the lower case 3 are not limited to the square dish shape, but may be a polygonal dish shape, or may be a circular dish shape. Therefore, the shape of the box (filter box) is not limited to the square box shape, but may be a polygonal box shape or a circular tubular shape.

(Upper case, lower case)
Next, the upper case 2 and the lower case 3 will be described in more detail.
The upper case 2 and the lower case 3 have relatively shallow bottoms, as shown in FIGS. 5 and 3, and their bottom walls are largely punched to form large openings therein. Metal mesh 4s are tightly stretched and attached to the openings. The bottom of the upper case 2 is considerably shallower than the bottom of the lower case 3 because the upper case 2 may serve as the lid of the lower case 3.
Therefore, when the filter box of the ultraviolet cut filter 1 is completed by assembling the upper case 2 and the lower case 3 as described above, the mesh 4 of the upper case 2 and the mesh 4 of the lower case 3 are the filter boxes. It is attached to each of the openings at the opposite side ends (right side end and left side end in FIG. 2).

As shown in these figures, the mesh 4 is made of a punching metal shape, but the mesh 4 is not limited to this, and a large number of metal wires are woven into the same shape or intersect at right angles. It may be assembled or assumed to be.
In either case, the size of the mesh is adjusted so that the glass balls 6 do not fall into the mesh of the mesh 4 and thereby obstruct the air flow (see FIG. 6) described later. The density (number per unit area) must be selected appropriately.

The upper case 2 is also provided with attachment feet 5 for attaching the ultraviolet cut filter 1 to the air purifier 9 (see FIG. 7). As shown in FIG. 1, the mounting foot 5 surrounds the opening formed by punching in the bottom wall of the upper case 2 as described above, and forms a rectangular frame-like body (hereinafter, hereinafter, the rest of the bottom wall). It is referred to as a "rectangular frame-like body surrounding the opening". The same applies to the lower case 3.) It is attached to each of the two lower corners of 2a in FIG.
The mode in which the ultraviolet cut filter 1 is attached to the air purifier 9 will be described later.

(Filling of balls inside the filter box, laminated structure)
As shown in FIG. 2, a plurality of spherical glass balls 6 are laminated and filled in a plurality of layers (three layers in FIG. 2) in the left-right direction inside the filter box of the ultraviolet cut filter 1. There is.
In this case, the layers of the plurality of glass balls 6 are filled in different phases so that the phases do not overlap between the adjacent layers. Then, the mesh 4 is attached to the openings at both side ends of the filter box so as to be supported from both sides.
Further, these plurality of glass balls 6 are said to be made of soda glass.
The shape of the glass ball 6 is not limited to a spherical shape, and may be a polyhedral shape.

FIG. 4 is a perspective view showing a state in which a plurality of glass balls 6 are filled in the lower case 3, and the filter box of the ultraviolet cut filter 1 is slanted in a state where the upper case 2 of FIG. 2 is removed. Looking from above.
Although not shown in FIGS. 4 and 3, the inner surface of the lower case 3 is provided with a glass ball holder, if necessary, in order to prevent these glass balls 6 from moving. Here, the inner side surface of the lower case 3 is the inner side surface of the four peripheral walls around the lower case 3 and the inner side surface of the rectangular frame-shaped body 3a (see FIG. 3) surrounding the opening (the place where the mesh 4 is attached). And so on.

(Action of UV cut filter)
FIG. 6 is a diagram showing a place where air passes between the glass balls 6 and the glass balls 6 in the laminated structure of the plurality of glass balls 6.
The air 7 flowing from the lower side of FIG. 6 passes through the space between the glass balls 6 and the glass balls 6 adjacent to each other among the plurality of filled glass balls 6 and passes to the upper part of the figure. I will go.
On the other hand, the ultraviolet rays (UV-C) 8 traveling straight are absorbed by the glass of the filled glass balls 6 having a plurality of layers, and a part of the ultraviolet rays reflected on the surface of the glass beads 6. (UV-C) 8 is blocked by being absorbed by the glass of the adjacent glass ball 6, and is not irradiated (not transmitted) to the upper part of the figure.
In particular, since the glass ball 6 is made of soda glass and has excellent absorption performance of ultraviolet rays (UV-C) 8, it can effectively block ultraviolet rays (UV-C) 8.

(Air purifier, its basic structure)
FIG. 7 is a perspective view of the air purifier 9 in which the ultraviolet cut filter 1 of the first embodiment is installed, and FIG. 10 shows a state in which the top plate portion and the plate portion on the front side are removed. It is a similar figure.
As shown in FIGS. 7 and 10, the air purifier 9 has an elongated square box shape as a whole, and its structure is summarized as an ultraviolet lamp box 13 (see FIG. 9 for details). Is placed on top of the duct box 14 (see FIG. 8 for details), and the ultraviolet lamp box 13 is attached to the duct box 14.

Here, in the ultraviolet lamp box 13, the opposite side ends (lower left end and upper right end in FIGS. 7, 9, and 10) serve as vents for taking in the air 7 outside the vessel into the vessel. The above-mentioned ultraviolet cut filter 1 is fitted and attached to each of the vents.
Therefore, the ultraviolet cut filter 1 also functions as an air intake port (intake port) here.

The air 7 sucked into the vessel through the ultraviolet cut filter 1 is irradiated with ultraviolet rays (UV-C) 8 there, and the bacteria and viruses floating in the air 7 are killed and the air 7 is purified. Is discharged to the outside of the device through an internal space formed between the ultraviolet lamp box 13 and the duct box 14 from an outlet 12 that opens to the upper rear side of the air purifier 9.
On the other hand, the irradiated ultraviolet rays (UV-C) 8 cannot pass through the ultraviolet cut filter 1 as described above, and harmful ultraviolet rays (UV-C) 8 pass through the ultraviolet cut filter 1 and are outside the device. It is prevented from leaking to.
It should be noted that the irradiated ultraviolet rays (UV-C) 8 leak out from the outlet 12 through the internal space formed between the ultraviolet lamp box 13 and the duct box 14, and the distribution route thereof is , Because it is long and has twists and turns, there are few.

(UV lamp box)
Next, the ultraviolet lamp box 13 will be described in more detail.
FIG. 9 is a perspective view of the ultraviolet lamp box 13 in a state where the top plate portion (top plate wall) of the ultraviolet lamp box 13 is removed.
As shown in FIGS. 7, 9 and 10, the ultraviolet lamp box 13 has the shape of an elongated box having a rectangular cross section, and inside the ultraviolet lamp box 13, an ultraviolet lamp 10 is placed on the bottom wall of the ultraviolet lamp box 13. It is installed along the elongated direction of the lamp box 13.
A fan 11 is integrally attached to the lower part of the bottom wall, and a flow port 20 for air 7 leading to the fan 11 is provided at a substantially central portion of the bottom wall (see FIG. 10).

It has already been described that the ultraviolet cut filters 1 are fitted and attached to the vents on both opposite ends of the ultraviolet lamp box 13.
In this case, in order to attach the ultraviolet cut filter 1 to the air purifier 9, the above-mentioned attachment legs 5 provided in the upper case 2 of the ultraviolet cut filter 1 are also fixed to the bottom wall of the ultraviolet lamp box 13. As a result, the UV cut filter 1 is attached to the UV lamp box 13 and the UV cut filter 1 is attached to the air purifier 9 more firmly (see FIG. 10).

(Duct box)
Next, the duct box 14 will be described in more detail.
FIG. 8 is a perspective view of the duct box 14.
As shown in FIG. 8, the duct box 14 has a deformed box shape, does not have a top plate wall, and only the rear wall (back wall) 17 has a normal box shape. And has dimensions.
The front wall (front wall) 18 is composed of only a narrow and elongated strip, and each of the two side walls 19 is located at the rear with a slightly elongated horizontal strip portion 19a of the same width. It is made only from a slightly elongated vertical strip portion 19b that is orthogonal to this and has a narrower width and the same width as the thickness (depth) of the spacer 15. The vertical strip portion 19b extends to the height of the rear wall (back wall) 17.
Therefore, when the side walls 19 are viewed from the side, they have the shape of an L-shaped plate. Looking at the entire duct box 14 from this, the duct box 14 has an L-shaped deformed box body having a relatively shallow bottom portion and a shallower depth portion.

At the bottom of the duct box 14, a partition plate 16 having the same width (height) as the width of the strip plate of the front wall (front wall) 18 is erected close to the spacer 15.
The spacer 15 is formed by bending the left and right side edges at right angles in FIG. 8 of a rectangular flat plate, and the bent portion is directed toward the inner side surface of the rear wall (back wall) 17 of the duct box 14. It is attached there. Its role will be described later.

(Assembly of air purifier)
The ultraviolet lamp box 13 is placed on the strips of the front wall 18 of the duct box 14 and the horizontal strip portions 19a of the two side walls 19, and the vertical strips of the two side walls 19. It is placed so as to be in contact with the side of the portion 19b, stacked on the duct box 14, and attached and fixed there. Then, in this way, the air purifier 9 is assembled and completed.
When the air purifier 9 is assembled and completed in this way, at the same time, between the ultraviolet lamp box 13 and the duct box 14, there is a gap space through which the cleaned air 7 passes and an outlet thereof. The outlet 12 is formed. The spacer 15 is useful for forming such a gap space.

The vertical, horizontal, and height dimensions of the ultraviolet lamp box 13 are such that when the ultraviolet lamp box 13 is stacked on the duct box 14 as described above, the ultraviolet lamp box 13 has the L-shape of the duct box 14. The air purifier 9 has the shape of an elongated square box as a whole because it is sized to fit in the space of the L-shaped recessed portion of the shape of the irregular box.
The fan 11 integrally attached to the lower part of the bottom wall of the ultraviolet lamp box 13 is placed in the space on one side (the space on the side where the spacer 15 is arranged) partitioned by the partition plate 16 at the shallow bottom of the duct box 14. It is contained (see FIG. 10). A control panel is housed in the space on the other side.

(Action of air purifier)
Next, the operation of the air purifier 9 will be described.
The air 7 outside the device (indoor) is first sucked by the fan 11 and passes through the UV cut filters 1 attached to the vents on both sides of the UV lamp box 13 facing each other, and the UV lamp box 13 inside the device. It enters the inside and receives ultraviolet rays (UV-C) 8 emitted from the ultraviolet lamp 10 there, and bacteria and viruses floating in the ultraviolet rays (UV-C) 8 are killed and cleaned.
The purified air 7 is then further sucked by the fan 11, passes through the air flow port 20 provided on the bottom wall of the ultraviolet lamp box 13, and is the surrounding space surrounding the fan 11 at the bottom of the duct box 14. Is discharged to.

In this way, the purified air 7 discharged into the space at the bottom of the duct box 14 was then formed between the rear wall (back wall) 17 of the duct box 14 and the ultraviolet lamp box 13. The air is discharged to the outside of the air purifier 9 through the gap space, which is an outlet of the air purifier 9, and is opened to the rear side of the upper part of the air purifier 9.
Here, the outlet 12 is an exhaust port (exhaust port) for the cleaned air 7.

On the other hand, when the irradiated ultraviolet rays (UV-C) 8 go straight or are reflected by the inner wall surface of the air purifier 9 and reach the ultraviolet cut filter 1, a plurality of irradiated ultraviolet rays (UV-C) 8 are filled inside the filter box. A part of ultraviolet rays (UV-C) 8 that is absorbed by the glass of the glass beads 6 having a plurality of layers and reflected on the surface of the glass beads 6 is absorbed by the glass of the adjacent glass beads 6, so that the ultraviolet rays (UV-C) 8 are absorbed by the glass of the adjacent glass beads 6. It is blocked and cannot pass through the ultraviolet cut filter 1. This prevents harmful ultraviolet rays (UV-C) 8 from leaking out of the device through the ultraviolet cut filter 1.
The irradiated ultraviolet rays (UV-C) 8 pass through the air flow port 20, the bottom space of the duct box 14, and the air outlet 12 through the gap space, which is a long and curved flow path of the air 7. There is almost no leakage to the outside of the device.

FIG. 11 is a perspective view seen from the AA cross section of the air purifier 9 shown in FIG. 7, and according to this figure, the flow of the air 7 on the upstream side and the wake side of the fan 11 and the spacer 15 Aspects such as installation, formation of a gap space, and formation of an outlet 12 are shown in a more understandable manner.

(Effect of Example 1)
Since the ultraviolet cut filter 1 of the first embodiment and the air purifier 9 on which the ultraviolet cut filter 1 is installed are configured as described above, the following effects can be obtained.
The ultraviolet cut filter 1 of the first embodiment has a structure in which a plurality of spherical glass balls 6 are filled inside a square box-shaped filter box in which meshes 4 are attached to opposite side end openings. There is, because this is installed in the passage (specifically, the vents provided at the opposite side ends of the ultraviolet lamp box 13) for sucking and taking in the air 7 outside the device into the air purifier 9. Ultraviolet rays (UV-C) 8 containing ultraviolet rays called sterilization lines with a wavelength of around 253 nanometers, which are irradiated to kill bacteria and viruses in the air sucked into the air purifier 9, are inside the filter box. It is absorbed by a plurality of glass balls 9 filled in the above, reflected, and further absorbed, so that it is blocked and cannot pass through the ultraviolet cut filter 1. This makes it possible to prevent harmful ultraviolet rays (UV-C) 8 from leaking to the outside of the device through the ultraviolet cut filter 1.
It should be noted that the harmful ultraviolet rays (UV-C) 8 are formed in an internal space between the ultraviolet lamp box 13 and the duct box 14 (in this internal space, the cleaned air 7 is discharged to the outside of the vessel. It is rare that the air is discharged from the outlet 12 to the outside of the vessel through the air outlet 12 because the air passage is long and has a bend.
On the other hand, since the air 7 can pass through the ultraviolet cut filter 1 through the gap between the balls of the plurality of glass balls 6, the air 7 outside the vessel is introduced into the vessel through the ultraviolet cut filter 1. Can be inhaled.

Further, since the ultraviolet cut filter 1 has a simple structure as described above, it can be manufactured compactly and inexpensively.
Further, in the ultraviolet cut filter 1, a plurality of glass balls 6 are laminated inside the filter box with different phases so that the phases do not overlap between the plurality of layers and the adjacent layers. Therefore, the blocking effect of ultraviolet rays (UV-C) 8 is improved.

In general, the window glass is made of soda glass. For example, in a window glass having a thickness of 4 mm, the transmittance of ultraviolet rays (UV-C) is zero, and ultraviolet rays (UV-C) are soda. It is absorbed by the glass and cannot pass through it.
Therefore, in the plurality of glass balls 6, the ultraviolet rays (UV-C) 8 are well absorbed by the plurality of glass balls 6, so that the ultraviolet rays (UV-C) 8 are more effectively blocked. It is possible to more effectively prevent ultraviolet rays (UV-C) 8 from passing through the ultraviolet cut filter 1.
Since the glass ball 6 transmits visible light, when the ultraviolet lamp 10 is lit, the pale visible light emitted together with the ultraviolet light can be seen through the ultraviolet cut filter 1, so that the ultraviolet lamp 10 is lit. And you can check that the lamp is out.

Further, in the ultraviolet cut filter 1 of the first embodiment, the mesh 4 is tightly stretched and attached to the openings at the opposite end ends of the filter box, and a plurality of meshes 4 are filled inside the filter box. Since the plurality of layers of the glass balls 6 are supported by these meshes 4 from both sides, the layers do not collapse, and the ultraviolet cut filter 1 allows air to pass through. The action of blocking harmful ultraviolet rays (UV-C) 8 can be stably continued.
Further, since a glass ball holder is provided on the inner surface of the lower case 3 constituting the filter box to prevent the plurality of glass balls 6 from moving, as described above, also from this surface. Effect is enhanced.

Further, the spacer 15 attached to the inner surface of the rear wall (back wall) 17 of the duct box 14 assembles the air purifier 9 by stacking the ultraviolet lamp box 13 on the duct box 14 and attaching and fixing the spacer 15 there. At the same time, it functions as an auxiliary tool for assembling the box, and at the same time, it also helps to form a gap space through which the cleaned air 7 passes and an outlet 12 between the two boxes. The structure of 9 is simplified and its assembly is extremely easy.

Further, as described above, the ultraviolet cut filter 1 prevents harmful ultraviolet rays (UV-C) 8 from leaking to the outside of the device, while the air 7 can pass through the device and be sucked into the device. Since this is installed in the air purifier 9 in the passage for sucking the outside air 7, the means such as the light-shielding plate (drag plate) conventionally used for the same purpose is not required. By that amount, the air purifier 9 becomes compact, the structure becomes simpler, it can be manufactured at low cost, and the air resistance becomes smaller, so that the fan 11 can also be made smaller, so that the noise is also reduced. Can be done.
Even when the ultraviolet cut filter 1 is installed outside the air purifier 9 in a passage for discharging the purified air 7, means such as a light-shielding plate (tight plate) conventionally used here for the same purpose. Is no longer necessary, and the same effect can be achieved.

The ultraviolet cut filter of the present invention is not limited to the above examples, and various modifications and applications are possible within a range that does not deviate from the gist thereof. Some of them are illustrated below.
(Example 2)
In the first embodiment, the ultraviolet cut filter 1 is installed on the air intake side of the air purifier 9, but instead, it is installed on the air exhaust port side of the air purifier 9 or on the air intake side. It can also be installed on both the air outlet side and the air outlet side.
To install the ultraviolet cut filter 1 on the air outlet side of the air purifier 9, for example, in FIG. 10 of the first embodiment, the fan 11 is turned upside down so that the air suction port faces the air flow port 20. , This can be attached to the upper surface of the bottom wall of the ultraviolet lamp box 13. In this case, the outlet 12 serves as an air intake port, and the ultraviolet cut filter 1 also functions as an air outlet.

Further, in order to install the ultraviolet cut filter 1 on both the air intake side and the air outlet side of the air purifier 9, one of the installation locations of the ultraviolet cut filter 1 is on the bottom wall of the ultraviolet lamp box 13. The provided air flow port 20 can be preferably used.
The air flow port 20 is located on the air discharge port side when the ultraviolet cut filter 1 is installed on the air intake port side of the air purifier 9 as in the first embodiment. Therefore, the ultraviolet cut filter 1 can be installed here. Moreover, in this case, the ultraviolet cut filter 1 is located in a position close to the ultraviolet lamp 10 and is located at a place where ultraviolet rays (UV-C) 8 are likely to leak, so that it is effective in blocking the ultraviolet rays (UV-C) 8. Is the target.
In this way, when the ultraviolet cut filter 1 is installed on both the air intake side and the air outlet side of the air purifier 9, harmful ultraviolet rays (UV-C) 8 pass through the ultraviolet cut filter 1. It is possible to completely prevent leakage to the outside of the device.

(Example 3)
Further, in the first embodiment, a glass ball is used as the ball 6 to be filled in the filter box of the ultraviolet cut filter 1, but a ceramic ball or a metal ball may be used instead.
In this case, the material itself can block the ultraviolet (UV-C) 8 to prevent the ultraviolet (UV-C) 8 from passing through the ultraviolet cut filter 1, and also vibrate or shock. It can also be used in an environment where UV rays are added.

Further, the surface of each of the glass balls, ceramic balls, and metal balls 6 may be made to have fine irregularities like frosted glass, and in such a case, ultraviolet rays (UV-C) are formed on the surface. ) 8 is scattered to reduce the reflection on the surface, so that the ultraviolet rays (UV-C) 8 are more effectively absorbed and blocked, and the ultraviolet rays (UV-C) 8 pass through the ultraviolet cut filter 1. It can be prevented more effectively.

(Application example)
As an application example, for example, taking advantage of the feature that ultraviolet rays (UV-C) 8 of the ultraviolet cut filter 1 of this embodiment are blocked but air 7 is allowed to pass through, it is used as a heat exhaust port of a box in which an ultraviolet lamp is installed. , This can be applied.
More specifically, since ultraviolet (UV-C) 8 is harmful to the human body, the ultraviolet lamp 10 is usually installed in a box that shields ultraviolet (UV-C) 8, but the ultraviolet lamp 10 is also a lamp. When the box is sealed, the temperature inside the box rises because it generates heat when it is lit. Therefore, it is necessary to provide vents at the top and bottom of the box to ventilate the air inside the box and exhaust heat. In this case, the ultraviolet rays of the present embodiment are also provided at the vents (heat exhaust ports). The cut filter 1 can be used effectively.

1 ... UV cut filter, 2 ... Upper case, 2a ... Rectangular frame, 3 ... Lower case, 3a ... Rectangular frame, 4 ... Mesh, 5 ... Mounting legs, 6 ... Glass balls, 7 ... Air, 8 ... Ultraviolet (UV-C), 9 ... Air purifier, 10 ... Ultraviolet lamp, 11 ... Fan, 12 ... Outlet, 13 ... Ultraviolet lamp box, 14 ... Duct box, 15 ... Spacer, 16 ... Partition plate, 17 ... Rear wall (back wall), 18 ... Front wall (front wall), 19 ... Side wall, 19a ... Horizontal strip part, 19b ... Vertical strip part, 20 ... Air flow port.

The invention of the present application is provided in an air purifier that kills bacteria and viruses in the air sucked into the vessel by irradiating ultraviolet rays (UV-C) called sterilization rays with a wavelength of around 253 nanometers. It relates to an ultraviolet cut filter that allows air to pass through while preventing the leakage of ultraviolet rays (UV-C) to the outside.

Harmful bacteria and viruses that cause illnesses such as colds and influenza are floating in the air.
People may get sick by inhaling these bacteria and viruses as they breathe. In particular, if you are with a carrier in a closed space such as indoors or in a car, the risk of getting sick increases.
As one of the methods to kill bacteria and viruses in the indoor air, the indoor air is sucked into the air purifier, and the air taken into the vessel is sterilized with a high sterilizing effect and a wavelength of around 253 nanometers. Irradiates ultraviolet rays (hereinafter referred to as ultraviolet rays (UV-C)) classified into UV-C including ultraviolet rays called rays to kill bacteria and viruses and discharge purified air to the outside of the vessel. There is a way to purify the air in the room.
However, with this method, if ultraviolet rays (UV-C) leak out of the device and hit the skin or look directly at the leaked ultraviolet rays, there is a risk of skin irritation or eye damage. be.

Japanese Unexamined Patent Publication No. 2016-32620 (Patent Document 1) describes an air purifier that prevents the leakage of ultraviolet rays (UV-C) to the outside of the device and eliminates the above-mentioned danger.
In this air purifier, air is sucked from one end of the box into a box equipped with an ultraviolet lamp inside, and ultraviolet rays (UV-C) are irradiated in the box to be contained in the air. It kills bacteria and viruses and expels clean air from the other end of the box.
Then, in order to prevent the ultraviolet rays (UV-C) from leaking to the outside of the device, the wake side of the air intake port (intake port) of the air purifier and the upstream side of the air discharge port (exhaust port, outlet). In addition, a plurality of light-shielding plates (intake plates) are provided at intervals, thereby blocking ultraviolet rays (UV-C) and preventing the light-shielding plate and the light-shielding plate from leaking to the outside of the device. Air can pass through the space between and.

However, in the air purifier described in this document, a plurality of light-shielding plates are required in order to secure a passage through which air passes while preventing leakage of ultraviolet rays, and a space between the light-shielding plate and the light-shielding plate is required. The light-shielding plates must be arranged so that the notches (the parts that allow air to pass through) are staggered, and the light-shielding plates must be arranged in at least two rows and three rows with caution. Therefore, a space for that is required, and the size of the device becomes large.
In addition, a means such as painting is required to prevent ultraviolet rays (UV-C) from being reflected on the surface of the light-shielding plate, which increases the cost.

Further, as a method of blocking ultraviolet rays or avoiding irradiation to the human body, various ultraviolet cut filters have been conventionally proposed.
For example, as described in JP2013-253361A (Patent Document 2), an ultraviolet cut coat is vapor-deposited on the surface of a glass plate by a vapor deposition method, or JP-A-2008-34350 (Patent Document 3). ), A typical method of producing an ultraviolet cut filter is to apply an ultraviolet cut material composed of indium-doped zinc oxide fine particles to the surface of the glass to form an ultraviolet cut film. Although it is a method, the ultraviolet cut filter manufactured in this way is completely different from the invention of the present application in that not only the manufacturing cost is high but also that it cannot pass air by itself, and this is air-cleaned. It is not suitable for installation in a vessel.

Japanese Unexamined Patent Publication No. 2016-32620 Japanese Unexamined Patent Publication No. 2013-253361 Japanese Unexamined Patent Publication No. 2008-34350

The invention of the present application solves the above-mentioned problems of the conventional air purifier and the ultraviolet cut filter, and can be installed in the air purifier to suck the outside air into the device or to use the device. Compact and simple in structure that allows air to pass through so that it can be discharged to the outside and can block harmful ultraviolet rays (UV-C) to prevent it from leaking out of the vessel. Therefore, it is an object to provide an inexpensive ultraviolet ray cut filter.

The above-mentioned problems are solved by the following inventions described in each claim of the claims of the present application.
That is, the invention according to claim 1 sucks outside air into the vessel and kills the bacteria and viruses in the sucked air by irradiating ultraviolet rays (UV-C) in the vessel. , An ultraviolet cut filter installed in an air purifier that discharges purified air to the outside of the device, and meshes are attached to the opposite end openings of the polygonal box-shaped or circular tubular filter box. A plurality of spherical or polyhedral balls made of any one material selected from soda glass, ceramics, and metal are laminated and filled in the filter box in a plurality of layers. It is installed in a passage for sucking outside air inside or a passage for discharging purified air to the outside of the device, and harmful ultraviolet rays (UV-C) leak to the outside of the device through the passage. It is an ultraviolet cut filter characterized in that air can pass through while preventing the above.

Further, in the invention described in claim 2, meshes are attached to opposite side end openings of a polygonal box-shaped or circular tubular filter box, and soda glass, ceramics, and soda glass, ceramics, and the like are inside the filter box. Multiple spherical or polyhedral balls made of any one of the metals are stacked and filled in multiple layers to prevent harmful ultraviolet (UV-C) transmission. However, air is an ultraviolet cut filter characterized by being allowed to pass through.

Since the invention of the present application is configured as described above, the following effects can be obtained.
The ultraviolet cut filter of the present invention is selected from soda glass, ceramics, and metal inside a polygonal box-shaped or circular tubular filter box in which meshes are attached to opposite side end openings. It has a structure in which a plurality of spherical or polyhedron-shaped balls made of one material are laminated and filled in a plurality of layers, and this is a passage for sucking outside air into the air purifier and air purification. Since it is installed in the passage that discharges the purified air to the outside of the device, it is irradiated to kill the bacteria and viruses in the air sucked into the air purifier, and the sterilization line with a wavelength of around 253 nanometers Ultraviolet rays (UV-C) containing ultraviolet rays, which are called ultraviolet rays, are absorbed by a plurality of balls filled inside the filter box of the ultraviolet cut filter, reflected, and further absorbed to block the ultraviolet cut filter. Cannot be transparent. This makes it possible to prevent harmful ultraviolet rays (UV-C) from leaking out of the device through the ultraviolet cut filter.
On the other hand, since the air can pass through the ultraviolet cut filter through the gap between the balls of the plurality of balls, the outside air can be sucked into the vessel through the ultraviolet cut filter, or the ultraviolet rays ( Air that has been sterilized and purified by UV-C) can be discharged to the outside of the vessel.

In addition, since this ultraviolet cut filter has a simple structure as described above, it can be manufactured compactly and inexpensively.
Further, a plurality of balls, a plurality of layers, since they are filled with product layer, ultraviolet cut filter, the structure becomes easier, thereby improving shielding effect of the ultraviolet rays.

Further, as described above, this ultraviolet cut filter prevents harmful ultraviolet rays (UV-C) from leaking to the outside of the vessel, while air passes through the filter and is discharged to the outside of the vessel or into the vessel. Since it can be inhaled, it has traditionally been used for the same purpose when installed in a passage for inhaling outside air inside the air purifier or in a passage for discharging purified air outside the air purifier. The means such as the light-shielding plate (stand plate) that was used is no longer required, and the air purifier becomes compact, the structure becomes simple, it can be manufactured at low cost, and the air resistance is reduced. Since the fan can also be miniaturized, the noise can also be reduced.

In general, the window glass is made of soda glass. For example, in a window glass having a thickness of 4 mm, the transmittance of ultraviolet rays (UV-C) is zero, and ultraviolet rays (UV-C) are soda. It is absorbed by the glass and cannot pass through it.
Therefore, when the plurality of balls are composed of glass balls made of soda glass, ultraviolet rays (UV-C) are better absorbed by the plurality of glass balls, which is more effective. By blocking the ultraviolet rays (UV-C), it is possible to more effectively prevent the ultraviolet rays (UV-C) from passing through the ultraviolet cut filter.
Since visible light is transmitted through the glass ball, when the ultraviolet lamp is lit, the pale visible light emitted together with the ultraviolet light can be seen through the ultraviolet cut filter, so check that the ultraviolet lamp is lit or the lamp is out. You can also do it.

When the plurality of balls are composed of ceramic balls or metal balls made of ceramics or metal, the material itself blocks ultraviolet rays (UV-C) and ultraviolet rays (UV-C). However, in addition to preventing the UV cut filter from passing through, it can also be used in an environment where vibration or shock is applied.

Further, if the surface of each of the glass ball, ceramic ball, and metal ball has fine irregularities like frosted glass, ultraviolet rays (UV-C) are scattered on the surface to reduce reflection on the surface. It is possible to more effectively absorb and block ultraviolet rays (UV-C) and more effectively prevent ultraviolet rays (UV-C) from passing through the ultraviolet cut filter.

In addition, as described above, this ultraviolet cut filter has the effect of blocking harmful ultraviolet rays (UV-C) but allowing air to pass through, so taking advantage of this feature, various applications that require similar effects. It can be applied to. For example, it can be installed at the heat exhaust port of the box in which the ultraviolet lamp is installed.

It is a perspective view of the ultraviolet ray cut filter of the Example of this invention. It is a vertical cross-sectional view of the ultraviolet cut filter. It is a perspective view of the lower case of the ultraviolet cut filter. It is a perspective view of the state in which a plurality of glass balls are filled in the lower case of the ultraviolet cut filter. It is a perspective view of the upper case of the same ultraviolet ray cut filter. It is a figure which shows the laminated structure of the plurality of glass balls, and is the figure which shows the place where the air passes between the glass balls. It is a perspective view of the air purifier which installed the ultraviolet ray cut filter. It is a perspective view of the duct box which is a component of the air purifier. It is a perspective view of the state which the top plate part was removed from the ultraviolet lamp box which is a component of the air purifier. It is a perspective view of the state in which the top plate portion of the air purifier and the front plate portion on the front side are removed. It is a perspective view seen from the AA cross section shown in FIG. 7 of the air purifier.

(Example 1)
Next, an embodiment (Example 1) of the ultraviolet cut filter of the present invention will be described in detail with reference to the drawings.
The ultraviolet cut filter of the first embodiment is mainly used by being installed in an air purifier.
This air purifier sucks the outside air into the container and kills the bacteria and viruses in the inhaled air by irradiating it with ultraviolet rays (UV-C), and is cleaned in this way. The air is discharged to the outside of the vessel.
In the following, first, the ultraviolet cut filter will be described, and then the air purifier in which the filter is installed will be described.

(UV cut filter, its basic structure)
FIG. 1 is a perspective view of the ultraviolet cut filter of the first embodiment, and FIG. 2 is a vertical sectional view thereof.
As shown in FIGS. 1 and 2, the ultraviolet cut filter 1 is formed from the top of the square dish-shaped lower case 3 (see FIG. 3 for details) to the square dish-shaped upper case 2 (specifically, see FIG. 3). , Fig. 5) is fitted like a can lid, and as a whole, it is shaped like a slightly flat square box, and a plurality of glass balls 6 are inside the box. It is filled and configured.
The shapes of the upper case 2 and the lower case 3 are not limited to the square dish shape, but may be a polygonal dish shape, or may be a circular dish shape. Therefore, the shape of the box (filter box) is not limited to the square box shape, but may be a polygonal box shape or a circular tubular shape.

(Upper case, lower case)
Next, the upper case 2 and the lower case 3 will be described in more detail.
The upper case 2 and the lower case 3 have relatively shallow bottoms, as shown in FIGS. 5 and 3, and their bottom walls are largely punched to form large openings therein. Metal mesh 4s are tightly stretched and attached to the openings. The bottom of the upper case 2 is considerably shallower than the bottom of the lower case 3 because the upper case 2 may serve as the lid of the lower case 3.
Therefore, when the filter box of the ultraviolet cut filter 1 is completed by assembling the upper case 2 and the lower case 3 as described above, the mesh 4 of the upper case 2 and the mesh 4 of the lower case 3 are the filter boxes. It is attached to each of the openings at the opposite side ends (right side end and left side end in FIG. 2).

As shown in these figures, the mesh 4 is made of a punching metal shape, but the mesh 4 is not limited to this, and a large number of metal wires are woven into the same shape or intersect at right angles. It may be assembled or assumed to be.
In either case, the size of the mesh is adjusted so that the glass balls 6 do not fall into the mesh of the mesh 4 and thereby obstruct the air flow (see FIG. 6) described later. The density (number per unit area) must be selected appropriately.

The upper case 2 is also provided with attachment feet 5 for attaching the ultraviolet cut filter 1 to the air purifier 9 (see FIG. 7). As shown in FIG. 1, the mounting foot 5 surrounds the opening formed by punching in the bottom wall of the upper case 2 as described above, and forms a rectangular frame-like body (hereinafter, hereinafter, the rest of the bottom wall). It is referred to as a "rectangular frame-like body surrounding the opening". The same applies to the lower case 3.) It is attached to each of the two lower corners of 2a in FIG.
The mode in which the ultraviolet cut filter 1 is attached to the air purifier 9 will be described later.

(Filling of balls inside the filter box, laminated structure)
As shown in FIG. 2, a plurality of spherical glass balls 6 are laminated and filled in a plurality of layers (three layers in FIG. 2) in the left-right direction inside the filter box of the ultraviolet cut filter 1. There is.
In this case, the layers of the plurality of glass balls 6 are filled in different phases so that the phases do not overlap between the adjacent layers. Then, the mesh 4 is attached to the openings at both side ends of the filter box so as to be supported from both sides.
Further, these plurality of glass balls 6 are said to be made of soda glass.
The shape of the glass ball 6 is not limited to a spherical shape, and may be a polyhedral shape.

FIG. 4 is a perspective view showing a state in which a plurality of glass balls 6 are filled in the lower case 3, and the filter box of the ultraviolet cut filter 1 is slanted in a state where the upper case 2 of FIG. 2 is removed. Looking from above.
Although not shown in FIGS. 4 and 3, the inner surface of the lower case 3 is provided with a glass ball holder, if necessary, in order to prevent these glass balls 6 from moving. Here, the inner side surface of the lower case 3 is the inner side surface of the four peripheral walls around the lower case 3 and the inner side surface of the rectangular frame-shaped body 3a (see FIG. 3) surrounding the opening (the place where the mesh 4 is attached). And so on.

(Action of UV cut filter)
FIG. 6 is a diagram showing a place where air passes between the glass balls 6 and the glass balls 6 in the laminated structure of the plurality of glass balls 6.
The air 7 flowing from the lower side of FIG. 6 passes through the space between the glass balls 6 and the glass balls 6 adjacent to each other among the plurality of filled glass balls 6 and passes to the upper part of the figure. I will go.
On the other hand, the ultraviolet rays (UV-C) 8 traveling straight are absorbed by the glass of the filled glass balls 6 having a plurality of layers, and a part of the ultraviolet rays reflected on the surface of the glass beads 6. (UV-C) 8 is blocked by being absorbed by the glass of the adjacent glass ball 6, and is not irradiated (not transmitted) to the upper part of the figure.
In particular, since the glass ball 6 is made of soda glass and has excellent absorption performance of ultraviolet rays (UV-C) 8, it can effectively block ultraviolet rays (UV-C) 8.

(Air purifier, its basic structure)
FIG. 7 is a perspective view of the air purifier 9 in which the ultraviolet cut filter 1 of the first embodiment is installed, and FIG. 10 shows a state in which the top plate portion and the plate portion on the front side are removed. It is a similar figure.
As shown in FIGS. 7 and 10, the air purifier 9 has an elongated square box shape as a whole, and its structure is summarized as an ultraviolet lamp box 13 (see FIG. 9 for details). Is placed on top of the duct box 14 (see FIG. 8 for details), and the ultraviolet lamp box 13 is attached to the duct box 14.

Here, in the ultraviolet lamp box 13, the opposite side ends (lower left end and upper right end in FIGS. 7, 9, and 10) serve as vents for taking in the air 7 outside the vessel into the vessel. The above-mentioned ultraviolet cut filter 1 is fitted and attached to each of the vents.
Therefore, the ultraviolet cut filter 1 also functions as an air intake port (intake port) here.

The air 7 sucked into the vessel through the ultraviolet cut filter 1 is irradiated with ultraviolet rays (UV-C) 8 there, and the bacteria and viruses floating in the air 7 are killed and the air 7 is purified. Is discharged to the outside of the device through an internal space formed between the ultraviolet lamp box 13 and the duct box 14 from an outlet 12 that opens to the upper rear side of the air purifier 9.
On the other hand, the irradiated ultraviolet rays (UV-C) 8 cannot pass through the ultraviolet cut filter 1 as described above, and harmful ultraviolet rays (UV-C) 8 pass through the ultraviolet cut filter 1 and are outside the device. It is prevented from leaking to.
It should be noted that the irradiated ultraviolet rays (UV-C) 8 leak out from the outlet 12 through the internal space formed between the ultraviolet lamp box 13 and the duct box 14, and the distribution route thereof is , Because it is long and has twists and turns, there are few.

(UV lamp box)
Next, the ultraviolet lamp box 13 will be described in more detail.
FIG. 9 is a perspective view of the ultraviolet lamp box 13 in a state where the top plate portion (top plate wall) of the ultraviolet lamp box 13 is removed.
As shown in FIGS. 7, 9 and 10, the ultraviolet lamp box 13 has the shape of an elongated box having a rectangular cross section, and inside the ultraviolet lamp box 13, an ultraviolet lamp 10 is placed on the bottom wall of the ultraviolet lamp box 13. It is installed along the elongated direction of the lamp box 13.
A fan 11 is integrally attached to the lower part of the bottom wall, and a flow port 20 for air 7 leading to the fan 11 is provided at a substantially central portion of the bottom wall (see FIG. 10).

It has already been described that the ultraviolet cut filters 1 are fitted and attached to the vents on both opposite ends of the ultraviolet lamp box 13.
In this case, in order to attach the ultraviolet cut filter 1 to the air purifier 9, the above-mentioned attachment legs 5 provided in the upper case 2 of the ultraviolet cut filter 1 are also fixed to the bottom wall of the ultraviolet lamp box 13. As a result, the UV cut filter 1 is attached to the UV lamp box 13 and the UV cut filter 1 is attached to the air purifier 9 more firmly (see FIG. 10).

(Duct box)
Next, the duct box 14 will be described in more detail.
FIG. 8 is a perspective view of the duct box 14.
As shown in FIG. 8, the duct box 14 has a deformed box shape, does not have a top plate wall, and only the rear wall (back wall) 17 has a normal box shape. And has dimensions.
The front wall (front wall) 18 is composed of only a narrow and elongated strip, and each of the two side walls 19 is located at the rear with a slightly elongated horizontal strip portion 19a of the same width. It is made only from a slightly elongated vertical strip portion 19b that is orthogonal to this and has a narrower width and the same width as the thickness (depth) of the spacer 15. The vertical strip portion 19b extends to the height of the rear wall (back wall) 17.
Therefore, when the side walls 19 are viewed from the side, they have the shape of an L-shaped plate. Looking at the entire duct box 14 from this, the duct box 14 has an L-shaped deformed box body having a relatively shallow bottom portion and a shallower depth portion.

At the bottom of the duct box 14, a partition plate 16 having the same width (height) as the width of the strip plate of the front wall (front wall) 18 is erected close to the spacer 15.
The spacer 15 is formed by bending the left and right side edges at right angles in FIG. 8 of a rectangular flat plate, and the bent portion is directed toward the inner side surface of the rear wall (back wall) 17 of the duct box 14. It is attached there. Its role will be described later.

(Assembly of air purifier)
The ultraviolet lamp box 13 is placed on the strips of the front wall 18 of the duct box 14 and the horizontal strip portions 19a of the two side walls 19, and the vertical strips of the two side walls 19. It is placed so as to be in contact with the side of the portion 19b, stacked on the duct box 14, and attached and fixed there. Then, in this way, the air purifier 9 is assembled and completed.
When the air purifier 9 is assembled and completed in this way, at the same time, between the ultraviolet lamp box 13 and the duct box 14, there is a gap space through which the cleaned air 7 passes and an outlet thereof. The outlet 12 is formed. The spacer 15 is useful for forming such a gap space.

The vertical, horizontal, and height dimensions of the ultraviolet lamp box 13 are such that when the ultraviolet lamp box 13 is stacked on the duct box 14 as described above, the ultraviolet lamp box 13 has the L-shape of the duct box 14. The air purifier 9 has the shape of an elongated square box as a whole because it is sized to fit in the space of the L-shaped recessed portion of the shape of the irregular box.
The fan 11 integrally attached to the lower part of the bottom wall of the ultraviolet lamp box 13 is placed in the space on one side (the space on the side where the spacer 15 is arranged) partitioned by the partition plate 16 at the shallow bottom of the duct box 14. It is contained (see FIG. 10). A control panel is housed in the space on the other side.

(Action of air purifier)
Next, the operation of the air purifier 9 will be described.
The air 7 outside the device (indoor) is first sucked by the fan 11 and passes through the UV cut filters 1 attached to the vents on both sides of the UV lamp box 13 facing each other, and the UV lamp box 13 inside the device. It enters the inside and receives ultraviolet rays (UV-C) 8 emitted from the ultraviolet lamp 10 there, and bacteria and viruses floating in the ultraviolet rays (UV-C) 8 are killed and cleaned.
The purified air 7 is then further sucked by the fan 11, passes through the air flow port 20 provided on the bottom wall of the ultraviolet lamp box 13, and is the surrounding space surrounding the fan 11 at the bottom of the duct box 14. Is discharged to.

In this way, the purified air 7 discharged into the space at the bottom of the duct box 14 was then formed between the rear wall (back wall) 17 of the duct box 14 and the ultraviolet lamp box 13. The air is discharged to the outside of the air purifier 9 through the gap space, which is an outlet of the air purifier 9, and is opened to the rear side of the upper part of the air purifier 9.
Here, the outlet 12 is an exhaust port (exhaust port) for the cleaned air 7.

On the other hand, when the irradiated ultraviolet rays (UV-C) 8 go straight or are reflected by the inner wall surface of the air purifier 9 and reach the ultraviolet cut filter 1, a plurality of irradiated ultraviolet rays (UV-C) 8 are filled inside the filter box. A part of ultraviolet rays (UV-C) 8 that is absorbed by the glass of the glass beads 6 having a plurality of layers and reflected on the surface of the glass beads 6 is absorbed by the glass of the adjacent glass beads 6, so that the ultraviolet rays (UV-C) 8 are absorbed by the glass of the adjacent glass beads 6. It is blocked and cannot pass through the ultraviolet cut filter 1. This prevents harmful ultraviolet rays (UV-C) 8 from leaking out of the device through the ultraviolet cut filter 1.
The irradiated ultraviolet rays (UV-C) 8 pass through the air flow port 20, the bottom space of the duct box 14, and the air outlet 12 through the gap space, which is a long and curved flow path of the air 7. There is almost no leakage to the outside of the device.

FIG. 11 is a perspective view seen from the AA cross section of the air purifier 9 shown in FIG. 7, and according to this figure, the flow of the air 7 on the upstream side and the wake side of the fan 11 and the spacer 15 Aspects such as installation, formation of a gap space, and formation of an outlet 12 are shown in a more understandable manner.

(Effect of Example 1)
Since the ultraviolet cut filter 1 of the first embodiment and the air purifier 9 on which the ultraviolet cut filter 1 is installed are configured as described above, the following effects can be obtained.
In the ultraviolet cut filter 1 of the first embodiment, a plurality of spherical glass balls 6 are laminated in a plurality of layers inside a square box-shaped filter box in which meshes 4 are attached to opposite side end openings. a structure that is filled with, this passage incorporated in the air cleaner 9 which sucks the air 7 Utsuwagai (specifically, the vent port provided at side ends opposite of the ultraviolet lamp box 13) Ultraviolet rays (UV-C) containing ultraviolet rays called sterilization lines with a wavelength of around 253 nanometers, which are irradiated to kill bacteria and viruses in the air sucked into the air purifier 9 because they are installed in 8 is absorbed by a plurality of glass balls 9 filled in the filter box, reflected, and further absorbed, so that it is blocked and cannot pass through the ultraviolet cut filter 1. This makes it possible to prevent harmful ultraviolet rays (UV-C) 8 from leaking to the outside of the device through the ultraviolet cut filter 1.
It should be noted that the harmful ultraviolet rays (UV-C) 8 are formed in an internal space between the ultraviolet lamp box 13 and the duct box 14 (in this internal space, the cleaned air 7 is discharged to the outside of the vessel. It is rare that the air is discharged from the outlet 12 to the outside of the vessel through the air outlet 12 because the air passage is long and has a bend.
On the other hand, since the air 7 can pass through the ultraviolet cut filter 1 through the gap between the balls of the plurality of glass balls 6, the air 7 outside the vessel is introduced into the vessel through the ultraviolet cut filter 1. Can be inhaled.

Further, since the ultraviolet cut filter 1 has a simple structure as described above, it can be manufactured compactly and inexpensively.
Further, in the ultraviolet cut filter 1, a plurality of glass balls 6 are laminated inside the filter box with different phases so that the phases do not overlap between the plurality of layers and the adjacent layers. Therefore, the blocking effect of ultraviolet rays (UV-C) 8 is improved.

In general, the window glass is made of soda glass. For example, in a window glass having a thickness of 4 mm, the transmittance of ultraviolet rays (UV-C) is zero, and ultraviolet rays (UV-C) are soda. It is absorbed by the glass and cannot pass through it.
Therefore, in the plurality of glass balls 6, the ultraviolet rays (UV-C) 8 are well absorbed by the plurality of glass balls 6, so that the ultraviolet rays (UV-C) 8 are more effectively blocked. It is possible to more effectively prevent ultraviolet rays (UV-C) 8 from passing through the ultraviolet cut filter 1.
Since the glass ball 6 transmits visible light, when the ultraviolet lamp 10 is lit, the pale visible light emitted together with the ultraviolet light can be seen through the ultraviolet cut filter 1, so that the ultraviolet lamp 10 is lit. And you can check that the lamp is out.

Further, in the ultraviolet cut filter 1 of the first embodiment, the mesh 4 is tightly stretched and attached to the openings at the opposite end ends of the filter box, and a plurality of meshes 4 are filled inside the filter box. Since the plurality of layers of the glass balls 6 are supported by these meshes 4 from both sides, the layers do not collapse, and the ultraviolet cut filter 1 allows air to pass through. The action of blocking harmful ultraviolet rays (UV-C) 8 can be stably continued.
Further, since a glass ball holder is provided on the inner surface of the lower case 3 constituting the filter box to prevent the plurality of glass balls 6 from moving, as described above, also from this surface. Effect is enhanced.

Further, the spacer 15 attached to the inner surface of the rear wall (back wall) 17 of the duct box 14 assembles the air purifier 9 by stacking the ultraviolet lamp box 13 on the duct box 14 and attaching and fixing the spacer 15 there. At the same time, it functions as an auxiliary tool for assembling the box, and at the same time, it also helps to form a gap space through which the cleaned air 7 passes and an outlet 12 between the two boxes. The structure of 9 is simplified and its assembly is extremely easy.

Further, as described above, the ultraviolet cut filter 1 prevents harmful ultraviolet rays (UV-C) 8 from leaking to the outside of the device, while the air 7 can pass through the device and be sucked into the device. Since this is installed in the air purifier 9 in the passage for sucking the outside air 7, the means such as the light-shielding plate (drag plate) conventionally used for the same purpose is not required. By that amount, the air purifier 9 becomes compact, the structure becomes simpler, it can be manufactured at low cost, and the air resistance becomes smaller, so that the fan 11 can also be made smaller, so that the noise is also reduced. Can be done.
Even when the ultraviolet cut filter 1 is installed outside the air purifier 9 in a passage for discharging the purified air 7, means such as a light-shielding plate (tight plate) conventionally used here for the same purpose. Is no longer necessary, and the same effect can be achieved.

The ultraviolet cut filter of the present invention is not limited to the above examples, and various modifications and applications are possible within a range that does not deviate from the gist thereof. Some of them are illustrated below.
(Example 2)
In the first embodiment, the ultraviolet cut filter 1 is installed on the air intake side of the air purifier 9, but instead, it is installed on the air exhaust port side of the air purifier 9 or on the air intake side. It can also be installed on both the air outlet side and the air outlet side.
To install the ultraviolet cut filter 1 on the air outlet side of the air purifier 9, for example, in FIG. 10 of the first embodiment, the fan 11 is turned upside down so that the air suction port faces the air flow port 20. to which was to be attached to the upper surface of the bottom wall of the UV lamp box 13 can be. In this case, the outlet 12 serves as an air intake port, and the ultraviolet cut filter 1 also functions as an air outlet.

Further, in order to install the ultraviolet cut filter 1 on both the air intake side and the air outlet side of the air purifier 9, one of the installation locations of the ultraviolet cut filter 1 is on the bottom wall of the ultraviolet lamp box 13. The provided air flow port 20 can be preferably used.
The air flow port 20 is located on the air discharge port side when the ultraviolet cut filter 1 is installed on the air intake port side of the air purifier 9 as in the first embodiment. Therefore, the ultraviolet cut filter 1 can be installed here. Moreover, in this case, the ultraviolet cut filter 1 is located in a position close to the ultraviolet lamp 10 and is located at a place where ultraviolet rays (UV-C) 8 are likely to leak, so that it is effective in blocking the ultraviolet rays (UV-C) 8. Is the target.
In this way, when the ultraviolet cut filter 1 is installed on both the air intake side and the air outlet side of the air purifier 9, harmful ultraviolet rays (UV-C) 8 pass through the ultraviolet cut filter 1. It is possible to completely prevent leakage to the outside of the device.

(Example 3)
Further, in the first embodiment, a glass ball is used as the ball 6 to be filled in the filter box of the ultraviolet cut filter 1, but a ceramic ball or a metal ball may be used instead.
In this case, the material itself can block the ultraviolet (UV-C) 8 to prevent the ultraviolet (UV-C) 8 from passing through the ultraviolet cut filter 1, and also vibrate or shock. It can also be used in an environment where UV rays are added.

Further, the surface of each of the glass balls, ceramic balls, and metal balls 6 may be made to have fine irregularities like frosted glass, and in such a case, ultraviolet rays (UV-C) are formed on the surface. ) 8 is scattered to reduce the reflection on the surface, so that the ultraviolet rays (UV-C) 8 are more effectively absorbed and blocked, and the ultraviolet rays (UV-C) 8 pass through the ultraviolet cut filter 1. It can be prevented more effectively.

(Application example)
As an application example, for example, taking advantage of the feature that ultraviolet rays (UV-C) 8 of the ultraviolet cut filter 1 of this embodiment are blocked but air 7 is allowed to pass through, it is used as a heat exhaust port of a box in which an ultraviolet lamp is installed. , This can be applied.
More specifically, since ultraviolet (UV-C) 8 is harmful to the human body, the ultraviolet lamp 10 is usually installed in a box that shields ultraviolet (UV-C) 8, but the ultraviolet lamp 10 is also a lamp. When the box is sealed, the temperature inside the box rises because it generates heat when it is lit. Therefore, it is necessary to provide vents at the top and bottom of the box to ventilate the air inside the box and exhaust heat. In this case, the ultraviolet rays of the present embodiment are also provided at the vents (heat exhaust ports). The cut filter 1 can be used effectively.

1 ... UV cut filter, 2 ... Upper case, 2a ... Rectangular frame, 3 ... Lower case, 3a ... Rectangular frame, 4 ... Mesh, 5 ... Mounting legs, 6 ... Glass balls, 7 ... Air, 8 ... Ultraviolet (UV-C), 9 ... Air purifier, 10 ... Ultraviolet lamp, 11 ... Fan, 12 ... Outlet, 13 ... Ultraviolet lamp box, 14 ... Duct box, 15 ... Spacer, 16 ... Partition plate, 17 ... Rear wall (back wall), 18 ... Front wall (front wall), 19 ... Side wall, 19a ... Horizontal strip part, 19b ... Vertical strip part, 20 ... Air flow port.

Claims (8)

Inhale the outside air into the vessel, kill the bacteria and viruses in the inhaled air by irradiating with ultraviolet rays (UV-C), and discharge the purified air to the outside of the vessel. An ultraviolet cut filter installed in an air purifier,
Meshes are attached to the opposite side end openings of the polygonal box-shaped or circular tubular filter box, respectively.
The inside of the filter box is filled with a plurality of spherical or polyhedral balls.
It is installed in a passage for sucking outside air into the vessel and a passage for discharging purified air to the outside of the vessel, and harmful ultraviolet rays (UV-C) leak to the outside of the vessel through the passage. A UV-blocking filter that is characterized by allowing air to pass through while preventing it from spilling over. The ultraviolet cut filter according to claim 1, wherein the plurality of balls are laminated and filled in a plurality of layers, with different phases between adjacent layers. The ultraviolet cut filter according to claim 1, wherein the plurality of balls are glass balls made of soda glass. The ultraviolet cut filter according to claim 3, wherein the glass ball has fine irregularities like ground glass on its surface. The ultraviolet cut filter according to claim 1, wherein the plurality of balls are ceramic balls or metal balls made of ceramics or metal. The ultraviolet cut filter according to claim 5, wherein the ceramic ball or the metal ball has a surface having fine irregularities like frosted glass. Meshes are attached to the opposite side end openings of the polygonal box-shaped or circular tubular filter box, respectively.
The inside of the filter box is filled with a plurality of spherical or polyhedral balls.
An ultraviolet cut filter characterized in that air is allowed to pass through while preventing the transmission of harmful ultraviolet rays (UV-C). The ultraviolet cut filter according to claim 7, wherein the plurality of balls are laminated and filled with a plurality of layers and adjacent layers having different phases.

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