JPH07313583A - Air sterilizer - Google Patents

Abstract

PURPOSE:To attain air sterilizing processing with high efficiency by forming an air discharge port so as not to be opposed to an air introducing port, and arranging an ultraviolet lamp in a position opposed to the air introducing port so as to extend in the same direction as the air introducing port. CONSTITUTION:A first ultraviolet lamp 30 is arranged in a position opposed to an air introducing port 23 in a sterilizing processing chamber S, and since air upward introduced in the sterilizing processing chamber S from the air introducing port 23 collides with a lower half surface part of the ultraviolet lamp 30, ultraviolet rays are irradiated to this air from the ultraviolet lamp 30, and sterilizing processing is performed. Since the air collides with an outside surface of the ultraviolet lamp 30, art air flow in the sterilizing processing chamber S is largely disturbed, and an air discharge port 25 is formed so as not to be opposed to the air introducing port 23, and the flow direction of the whole air is changed. Thereby, since introduced air comes to stay for comparatively long time in the sterilizing processing chamber S, sterilizing processing of the introduced air can be attained with high efficiency.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air sterilizer for sterilizing air using ultraviolet rays.

[0002]

2. Description of the Related Art Generally, since many bacteria are present in the atmosphere, it is required to appropriately sterilize air from the viewpoint of environmental hygiene or to realize a comfortable environment. For this reason, the air sterilizer is used.

5 and 6 are explanatory views showing the outline of the configuration of an example of a conventional air sterilizer, FIG. 5 is a schematic front view, and FIG. 6 is a schematic side view. 5 and 6, reference numeral 80 denotes a box-shaped casing, an air inlet 81 is formed at one end side (right side in FIG. 5) of the front surface of the casing 80, and an air inlet port 81 is formed at the other end side of the front surface of the casing 80. An outlet 82 is formed. The fan 8 is provided at the air inlet 81 and the air outlet 82, respectively.
3, 84 are provided.

Inside the casing 80, a rectangular cylindrical chamber 85 having both ends closed is provided so as to extend in the horizontal direction.
A rod-shaped ultraviolet lamp 90 that emits ultraviolet light containing a 3.7 nm light beam is arranged along the extending direction of the chamber 85.

Further, an air inlet 86 is formed at one end side (right side in FIG. 5) of the lower surface of the chamber 85, and the air inlet 86 is provided with an air through an inlet duct 88 having a bent portion. It is connected to the inflow port 81. The air outlet 8 is provided on the other end side of the lower surface of the chamber 85.
7 is formed, and this air exhaust port 87 is connected to the air outflow port 82 via an exhaust duct 89 having a bent portion.

In the air sterilizer having the above structure, the fans 83 and 84 are driven so that the outside air at the place where the air sterilizer is arranged is taken into the device through the air inlet 81. Further, it is introduced into the chamber 85 through the introduction duct 88 and the air introduction port 86, flows in the chamber 85 toward the air discharge port 87 along the direction in which the ultraviolet lamp 90 extends, and then, the air discharge port 87 and The air is discharged from the air outlet 82 through the discharge duct 89. Then, in the chamber 85, the air is sterilized by the ultraviolet rays emitted from the ultraviolet lamp 90.

An air sterilizer using such an ultraviolet lamp is described in, for example, Japanese Patent Application Laid-Open No. 61-279248.

[0008]

However, in the air sterilization apparatus having the above-described structure, the air flowing in the chamber 85 flows in a laminar flow state rectified along the ultraviolet lamp 90, and therefore in the vicinity of the ultraviolet lamp 90. The air flowing along the inner wall surface of the chamber 85 cannot be sufficiently sterilized by the ultraviolet light from the ultraviolet lamp 90 regardless of the air flowing through the chamber 85. As a result, high efficiency in the air sterilization treatment is obtained. There was a problem that I could not get it.

The present invention has been made in view of the above circumstances, and an object thereof is to provide an air sterilizer which can achieve air sterilization treatment with high efficiency.

[0010]

SUMMARY OF THE INVENTION An air sterilizer of the present invention comprises a casing having an air inlet and an air outlet, a sterilizing unit provided in the casing for sterilizing air, and the air inlet. An air sterilizing apparatus comprising a ventilation fan that allows the external air from flowing through the sterilizing unit, wherein the sterilizing unit comprises:
A sterilization chamber formed by a flat box-shaped air passage member, and a rod-shaped ultraviolet lamp provided in the sterilization chamber, one end of one surface of the air passage member that partitions the sterilization chamber On the side, a slit-shaped air introduction port that communicates with the air inlet is formed, and on the other end side of the other surface of the air passage member that partitions the sterilization chamber, the air is provided so as not to face the air introduction port. An air outlet leading to the outlet is formed,
The ultraviolet lamp is arranged at a position facing the air inlet so as to extend in the same direction as the air inlet.

Further, in the air sterilizer of the present invention,
The air outlet is formed in a slit shape, and an additional rod-shaped ultraviolet lamp arranged so as to extend in the same direction as the air outlet is provided at a position facing the air outlet in the sterilization chamber. Preferably.

Further, in the air sterilizer of the present invention,
The sterilization unit has a plurality of sterilization treatment chambers that are formed to line up in a stacked state from the air inlet to the air outlet, and in the sterilization treatment chambers adjacent to each other, the upstream sterilization treatment is performed. The air outlet of the chamber is connected to the air inlet of the sterilization chamber on the downstream side.

Further, in the air sterilizer of the present invention,
The sterilization unit has a processing chamber forming space that extends from the air inlet toward the air outlet, and a plurality of sterilizers are provided by dividing the processing chamber forming space by a partition plate that is detachably attached. The processing chambers are formed so as to be lined up in a stacked state from the air inlet to the air outlet.

[0014]

According to the air sterilization apparatus of the present invention, since the ultraviolet lamp is arranged in the sterilization chamber at a position facing the air inlet, the air introduced into the sterilization chamber from the air inlet is When the flow collides with the outer surface of the ultraviolet lamp and the flow is greatly disturbed, the ultraviolet ray from the ultraviolet lamp is sufficiently reliably irradiated, and the sterilization treatment is performed with high efficiency. Further, since the introduced air collides with the outer surface of the ultraviolet lamp, the air is agitated, and the air discharge port is formed so as not to face the air introduction port. Is changed so that the air stays in the sterilization chamber for a relatively long time, and as a result, the sterilization process of air is achieved with high efficiency.

According to the air sterilizer of claim 2,
In the sterilization chamber, since an additional ultraviolet lamp is arranged at a position facing the air outlet, the air introduced into the sterilization chamber also collides with the outer surface of the additional ultraviolet lamp. In this state, the ultraviolet rays from the additional ultraviolet lamp are irradiated, thereby obtaining higher efficiency in the sterilization treatment of air.

According to the air sterilizer of claim 3,
Since a plurality of sterilization chambers in which the air outlet of the upstream sterilization chamber communicates with the downstream air inlet is formed, the plurality of sterilization chambers successively perform multiple sterilization treatments. Therefore, it is possible to provide an air sterilizer having a large throughput and high efficiency.

According to the air sterilizer of claim 4,
By dividing the processing chamber forming space by the partition plate that is detachably attached, a plurality of sterilization processing chambers are formed, so that the sterilization unit can be downsized and
By removing the partition plate, replacement of the ultraviolet lamp becomes easy.

[0018]

Embodiments of the air sterilizer of the present invention will be described below with reference to the drawings. 1 and 2 are sectional views for explaining the outline of an air sterilizer according to a first embodiment of the present invention, FIG. 1 is a longitudinal side view, and FIG. 2 is a transverse front view.

In this air sterilizer, a box-shaped casing 10 is provided, an air inlet 11 is formed on the lower surface of the casing 10, and an air outlet is formed on the upper portion of the front surface (the right surface in FIG. 1) of the casing 10. 12 are formed.

Air outlet 12 in casing 10
A ventilation fan 15 made of, for example, a sirocco fan is arranged at a position opposite to, and a sterilization unit 20 for sterilizing the air taken into the casing 10 is arranged below the ventilation fan 15. .

The sterilization unit 20 is provided with a horizontally flat box-shaped air passage member 21 made of, for example, aluminum whose inner surface is mirror-finished. The interior space of the air passage member 21 serves as a sterilization chamber S. Are formed.
Further, a slit-shaped air introduction port 23 is formed to extend in the left-right direction in FIG. 2 on one end side (right side in FIG. 1) of the air passage member 21, and the other end of the upper surface 24 of the air passage member 21. A slit-shaped air outlet 25 is formed on the side so as to extend in the same direction as the air inlet 23.

In the sterilization processing room S, the wavelength is 253.7 nm.
A rod-shaped first ultraviolet lamp 30 that emits ultraviolet rays including the light rays is arranged at a position facing the air inlet 23, that is, a position directly above the air inlet 23 so as to extend in the same direction as the air inlet 23. In addition, a similar second ultraviolet lamp 35 is provided at a position facing the air discharge port 25, that is, a position immediately below the air discharge port 25.
It is arranged so as to extend in the same direction as 5. Both ends of the first ultraviolet lamp 30 and the second ultraviolet lamp 35 are detachably held by sockets 31 fixed to the left and right inner side surfaces 26, 27 of the air passage member 21.

In the illustrated example, the air inlet 11 of the casing 10 is detachably provided with a prefilter 13 for removing large dust, and the upper portion of the prefilter 13 removes small dust. The charging filter 14 is detachably provided to clean the air by removing dust and prevent the outer surfaces of the first ultraviolet lamp 30 and the second ultraviolet lamp 35 from being contaminated. To be done.

In the above air sterilizer, the ventilation fan 15 is driven so that the outside air at the place where the air sterilizer is arranged causes the air inflow port 11 to move.
Is taken into the casing 10 through the pre-filter 13 and the charging filter 14, and then this air passes through the sterilization processing chamber S of the sterilization unit 20 and is then discharged to the outside from the air outlet 12. Then, in the sterilization processing chamber S, air is introduced into the interior at a considerable flow rate because the air introduction port 23 has a slit shape, and immediately thereafter, it collides with or approaches the outer surface of the first ultraviolet lamp 30. , Then, after flowing toward the other end and colliding with or approaching the outer surface of the second ultraviolet lamp 35,
The air is discharged from the slit-shaped air discharge port 25. Therefore, in the sterilization processing chamber S, the air is the first ultraviolet lamp 3
Sterilization is performed by the ultraviolet rays emitted from the 0 and second ultraviolet lamps 35.

According to the air sterilizing apparatus of the first embodiment, since the first ultraviolet lamp 30 is arranged in the sterilization processing chamber S at a position facing the air introducing port 23, the air introducing port is Since the air introduced upward from 23 into the sterilization processing chamber S collides with the lower half of the outer surface of the first ultraviolet lamp 30, this air is irradiated with ultraviolet rays from the first ultraviolet lamp 30. It is sterilized. In addition, the air collides with the outer surface of the first ultraviolet lamp 30 to greatly disturb the flow of air in the sterilization processing chamber S, and the air outlet 25 is formed so as not to face the air inlet 23. However, the direction of the flow of the entire air is changed, whereby the air stays in the sterilization processing chamber S for a relatively long time, so that the sterilization processing of air is performed in the sterilization processing chamber S. Can be achieved with high efficiency.

Further, in the sterilization processing chamber S, the air outlet 2
Since the second ultraviolet lamp 35 is arranged at a position opposite to 5, the air introduced into the sterilization processing chamber S collides with or approaches the outer surface of the second ultraviolet lamp 35 and then flows. Direction changed and air outlet 25
Is discharged from the first ultraviolet lamp 30 by being irradiated with the ultraviolet light from the second ultraviolet lamp 35.
Since air is sterilized in the same manner as in the above, high sterilization efficiency can be obtained.

Further, the air passage member 2 forming the sterilization processing chamber S.
1 has an inner surface made of mirror-finished aluminum, so that in the sterilization chamber S, the light emitted from the first ultraviolet lamp 30 and the second ultraviolet lamp 35 is the inner surface of the air duct member 21. The ultraviolet light is reflected on the air that is reflected by and flows through the sterilization processing chamber S, so that high light utilization efficiency is obtained.

In the above, the width w ₁ of the air introduction port 23 is preferably 1 to 2.5 times the size of the outer diameter r of the first ultraviolet lamp 30. The size of the distance d ₁ to the outer surface of the first ultraviolet lamp 30 is preferably 0.5 to 1 times the size of the outer diameter r of the first ultraviolet lamp 30. By satisfying such a condition, the air can surely collide with or approach the first ultraviolet lamp 30.

The size of the width w ₂ of the air discharge port 25 is 1 to the size of the outer diameter r of the second ultraviolet lamp 35.
The distance d ₂ from the air outlet 25 to the outer surface of the second ultraviolet lamp 35 is preferably 2.5 times the outer diameter r of the second ultraviolet lamp 35. 5
It is preferably 1 to 1. By satisfying such a condition, the air can surely collide with or approach the second ultraviolet lamp 35.

FIGS. 3 and 4 are explanatory sectional views showing the structure of the air sterilizer according to the second embodiment of the present invention.
3 is a vertical side view, and FIG. 4 is a transverse front view. This air sterilizer is, for example, of a type that is used by being hung on a wall surface in a room, and has a box-shaped casing 40, an air inlet 41 is formed on a lower surface of the casing 40, and a front surface of the casing 40. An air outlet 42 is formed in the upper part (right side in FIG. 1).

A ventilation fan 45 made of, for example, a sirocco fan is arranged at a position facing the air outlet 42 in the casing 40. Below the ventilation fan 45, the air taken in the casing 40 is arranged. A sterilizing unit 50 for performing sterilization is arranged, for example, on the inner wall surface of the casing 40 in a detachable state. A pre-filter 43 is removably provided at the air inlet 41 of the casing 40, and a charging filter 44 is removably provided at the upper part of the pre-filter 43.
Reference numeral 80 is a control unit that controls the operation of the air sterilizer.

In the sterilization unit 50, an air passage forming member 51 extending vertically along the inner surface of the casing 40.
Is provided. Specifically, this air passage forming member 51
Are arranged along the front surface and the rear surface of the casing 40, respectively, and the front surface plate 52a and the rear surface plate 52b that are provided to face each other, and are arranged along both side surfaces of the casing 40. Both side plates 53a, 53b provided to face each other so as to connect the edges.
It is composed of and.

An internal space surrounded by the air passage forming member 51 is a processing chamber forming space. In this processing chamber forming space, for example, a plurality of (for example, five in the illustrated example) aluminum whose surface is mirror-finished is used. ) Rectangular partition plates 54, 55, 5
6, 57 and 58 are horizontally arranged in order from the bottom so as to be detachable at regular intervals. Specifically, the partition plates 54 to 58 are sized to fit the horizontal contour of the processing chamber forming space, and the pair of holding members 61 extending in the horizontal direction are provided on the inner surfaces of the side surface plates 53a and 53b. , 62
, Are provided at regular intervals in the vertical direction,
The partition plates 54 to 58 are arranged such that both edge portions thereof are slidably received by corresponding holding members 61 and 62, respectively. Then, the inside of the processing chamber forming space is divided by the partition plates 54 to 58, so that a plurality of (four in the illustrated example) sterilization processing chambers S1, S2, S3, S4 each having a flat air passage member are placed below. It is formed so as to be stacked in order from.

The partition plates 54, 55, 56, 57,
Each of the openings 58 has slit-shaped openings 54a, 55a, 56a, 57a, 58a extending in the left-right direction in FIG.
Are formed so as not to face each other. Specifically, in the odd-numbered partition plates from the bottom, in the illustrated example, the first, third, and fifth partition plates 54, 56, 58 have openings 54a, 5 on one end side (left side in FIG. 3), respectively.
6a, 58a are formed, and in the even-numbered from the bottom, the second and fourth partition plates 55, 57 in the illustrated example, the openings 5 are formed on the other end side (right side in FIG. 3), respectively.
5a and 57a are formed. And the sterilization processing room S
In each of S1, S2, S3 and S4, the openings 54a, 55a, 56 of the lower partition plates 54, 55, 56, 57 are formed.
a and 57a are air inlets, and the upper partition plate 55,
Openings 55a, 56a, 57a, 58 of 56, 57, 58
a is an air outlet. Therefore, the partition plates 55-55
The openings 55a to 57a of 57 also serve as an air outlet for the lower sterilization chamber and an air inlet for the upper sterilization chamber.

Each of the sterilization processing chambers S1 to S4 has a wavelength of 2
First rod-shaped emitting ultraviolet ray including 53.7 nm light ray
The ultraviolet lamp 70 is disposed at a position facing the air inlet of each sterilization chamber so as to extend in the same direction as the air inlet, and the similar second ultraviolet lamp 75 is
It is arranged so as to extend in the same direction as the air outlets at a position facing the air outlets associated with each sterilization chamber. First
Both ends of the ultraviolet lamp 70 and the second ultraviolet lamp 75 are detachably held by sockets 71 fixed to the inner surfaces of the side plates 53a and 53b.

Further, in each of the sterilization processing chambers S1 to S4, two mountain-shaped reflecting mirrors 63 and 64 are respectively projected inward on the inner surfaces of the front plate 52a and the rear plate 52b.
Are fixedly arranged so as to be located laterally of the first ultraviolet lamp 70 and the second ultraviolet lamp 75, respectively. The angle at the top of the reflection mirrors 63 and 64 is 90 degrees, for example.

Further, in this example, a detection mechanism for detecting a defective ultraviolet lamp is provided in the control unit 80, and the detection mechanism is provided in each of the sterilization processing chambers S1 to S4.
If any one of the ultraviolet lamp 70 and the second ultraviolet lamp 75 fails, it is displayed on the operation panel (not shown).

In the above air sterilizer, the ventilation fan 45 is driven so that the outside air at the place where the air sterilizer is arranged causes the air inflow port 41.
Is taken into the casing 40 through the pre-filter 43 and the charging filter 44, and then this air passes through the sterilization unit 50 and is then discharged to the outside from the air outlet 42. In the sterilization unit 50, the air is introduced into the sterilization processing chamber S1 at a considerable flow rate because the opening 54a of the partition plate 54 has a slit shape, and immediately thereafter, the air collides with the outer surface of the first ultraviolet lamp 70. Alternatively, they approach each other, then flow toward the other end, and this time the second
After colliding with or approaching the outer surface of the ultraviolet lamp 75, it is discharged from the sterilization processing chamber S1 through the slit-shaped opening 55a of the partition plate 55 and is introduced into the sterilization processing chamber S2. At this time, the air in the sterilization processing chamber S1 is sterilized by the ultraviolet rays emitted from the first ultraviolet lamp 70 and the second ultraviolet lamp 75. Then, the air is sterilization processing chambers S2 to S4 in the same manner as above.
Pass through.

In the above, the flow rate of the air sent by the ventilation fan 45 is set in the sterilization processing chambers S1 to S4.
For example, it can be 3 m ³ / min. In this case, the time for which the air passes through the sterilization unit 50 is, for example, 2.0 seconds, and in each of the sterilization processing chambers S1 to S4, it is ¼, that is, 0.5 seconds.

Further, the openings 54a of the partition plates 54 to 58 are
58a width, openings 54a-57a of partition plates 54-57
To the outer surface of the first ultraviolet lamp 70, and the distance from the openings 55a to 58a of the partition plates 55 to 58 to the outer surface of the second ultraviolet lamp 75. It is preferable to satisfy the same conditions as in the example.

According to the air sterilizing apparatus of the second embodiment, in each of the sterilization processing chambers S1 to S4, the air introduced is the first ultraviolet lamp 7 as in the case of the first embodiment.
Since the outer surface of No. 0 and the outer surface of the second ultraviolet lamp 75 collide with or approach, the air is irradiated with the ultraviolet rays from the first ultraviolet lamp 70 and the second ultraviolet lamp 75 to be sterilized. . In addition, the air collides with the outer surface of the first ultraviolet lamp 70, so that the flow of air is greatly disturbed in the sterilization processing chambers S1 to S4, and the openings 54a to 58a of the partition plates 54 to 58 are formed.
However, they are formed so as not to face each other, the direction of the flow of the entire air is changed, and as a result, the air stays in the sterilization processing chambers S1 to S4 for a relatively long time, thereby sterilizing the air. Can be achieved with high efficiency. The partition plates 54 to 58 forming the sterilization processing chambers S1 to S4 are made of mirror-finished aluminum, and the sterilization processing chambers S1 to S4 have the first ultraviolet lamp 70 and the second ultraviolet lamp 75 side. Since the reflection mirrors 63 and 64 are arranged so as to be located in one direction, the light emitted from the first ultraviolet lamp 70 and the second ultraviolet lamp 75 in the sterilization processing chambers S1 to S4 is divided by the partition plates 54 to 58. Further, since the air that is reflected by the reflection mirrors 63 and 64 and flows through the sterilization processing chambers S1 to S4 is irradiated with ultraviolet rays, high light utilization efficiency can be obtained.

Since the plurality of sterilization processing chambers S1 to S4 are connected in series, the air passing through the sterilization unit 50 is sequentially sterilized in each of the sterilization processing chambers S1 to S4. Therefore, it is possible to sufficiently sterilize a large amount of air in a short time.

Further, the partition plate 54 is detachably attached.
Since the plurality of sterilization processing chambers S1 to S4 are formed by dividing the processing chamber forming space by the air passage forming member 51 by ˜58, the sterilization unit 50 can be easily manufactured, and the sterilization unit is small. Can be realized. Also, by removing the partition plates 54 to 58,
First ultraviolet lamp 70 and second ultraviolet lamp 75
It is possible to secure a sufficient space necessary for the replacement of. Further, it is possible to change the number of sterilization processing chambers according to the size of the place where the air sterilization device is arranged.

<Experimental Example> An air sterilizer according to the second embodiment was produced under the following conditions. Power consumption of the motor of the ventilation fan 45: 90 W First ultraviolet lamp 70 and second ultraviolet lamp 75
Outer diameter: 25 mm First ultraviolet lamp 70 and second ultraviolet lamp 75
Power consumption: 15W Dimensions of sterilization chambers S1 to S4: 400mm x 140mm
× 50 mm Dimension of openings 54a to 58a of the partition plates 54 to 58: 55
mm × 400 mm Distance between the centers of the first ultraviolet lamp 70 and the second ultraviolet lamp 75: 55.2 mm From the outer surface of the first ultraviolet lamp 70, openings 54a to 57 are formed.
Distance to a: 15 mm From the outer surface of the second ultraviolet lamp 75 to the openings 55a to 58
Distance to a: 15 mm

Using this air sterilizer, an air sterilization treatment test was conducted by the following method in a container having an internal volume of about 24 m ³ . [Test method] An air sterilizer is installed on the wall surface in the container, and before starting the operation of the air sterilizer, and 10 minutes, 20 minutes, 40 minutes and 6 minutes after the start of the operation.
After 0 minutes, the air sampler was used to collect bacteria floating in the container for 2 minutes. The collected bacteria were cultured on an agar medium at 35 to 37 ° C. for 24 hours, and the number of colonies generated on the agar medium was measured. The results are shown in Table 1.

[0046]

[Table 1]

As is clear from Table 1, it was confirmed that the air in the container was sufficiently sterilized after the operation of the air sterilizer was started.

[0048]

According to the air sterilization apparatus of the present invention, the ultraviolet lamp is disposed in the sterilization chamber at a position facing the air introduction port, so that the sterilization chamber is introduced into the sterilization chamber. Since the air collides with the outer surface of the ultraviolet lamp, the air is irradiated with the ultraviolet rays from the ultraviolet lamp in this state to be sterilized. Further, the air collides with the outer surface of the ultraviolet lamp, which greatly disturbs the flow of air in the sterilization chamber, and the air discharge port is formed so as not to face the air introduction port. The direction is changed so that the air stays in the sterilization chamber for a long time, so that high efficiency is obtained in the sterilization process of air.

According to the air sterilizer of claim 2,
In the sterilization chamber, the additional ultraviolet lamp is arranged at a position facing the air outlet, so that the air introduced into the sterilization chamber also collides with or approaches the outer surface of the additional ultraviolet lamp. After that, the flow direction is changed and the air is discharged from the air discharge port, so that the ultraviolet light from the additional ultraviolet lamp is irradiated, and thereby higher efficiency is obtained in the air sterilization process.

According to the air sterilizer of claim 3,
The sterilization unit has a plurality of sterilization chambers in which the air outlet of the upstream sterilization chamber communicates with the air inlet of the downstream side. Since a plurality of sterilization treatments are sequentially performed by the above method, it is possible to provide an air sterilization apparatus having a large treatment amount and high efficiency.

According to the air sterilizer of claim 4,
Since the sterilization chamber is formed by dividing the space for forming the treatment chamber by the partition plate that is detachably attached, the sterilization unit can be easily manufactured, and the sterilization unit can be downsized. it can. Further, by removing the partition plate, it is possible to sufficiently secure the space required for exchanging the ultraviolet lamp.

[Brief description of drawings]

FIG. 1 is an explanatory vertical sectional side view showing an outline of an air sterilizer according to a first embodiment of the present invention.

FIG. 2 is an explanatory cross-sectional front view showing the outline of the air sterilizer according to the first embodiment of the present invention.

FIG. 3 is an explanatory vertical sectional side view showing a configuration of an air sterilizer according to a second embodiment of the present invention.

FIG. 4 is an explanatory transverse front view showing the configuration of an air sterilizer according to a second embodiment of the present invention.

FIG. 5 is a schematic front view showing a schematic configuration of an example of a conventional air sterilizer.

FIG. 6 is a schematic side view of the air sterilizer of FIG.

[Explanation of symbols]

10,40 Casing 11,41 Air inlet 12,42 Air outlet 13,43 Pre-filter 14,44 Charging filter 15,45 Ventilation fan 20,50 Sterilization unit 21 Air passage member 22 Lower surface 23 Air inlet 24 Upper surface 25 Air Discharge port 26, 27 Inner side surface 30, 70 First ultraviolet lamp 35, 75 Second ultraviolet lamp 51 Air passage forming member 52a Front plate 52b Rear plate 53b, 53b Both side plates 54, 55, 56, 57, 58 Partition plate 54a, 55a, 56a, 57a, 58a Opening 61, 62 Holding member 63, 64 Reflecting mirror 31, 71 Socket S, S1, S2, S3, S4 Sterilization chamber 80 Casing 81 Air inlet 82 Air outlet 83, 84 Fan 85 Chamber 86 Air Inlet 87 Air Outlet 88 Introducer Door 89 exhaust duct 90 ultraviolet lamp

Claims (4)

[Claims] 1. A casing having an air inlet and an air outlet, a sterilizing unit provided in the casing for sterilizing air, and external air from the air inlet via the sterilizing unit. An air sterilizer comprising a ventilation fan for flowing through, wherein the sterilization unit is a sterilization chamber formed by a flat box-shaped air passage member, and a rod-shaped ultraviolet ray provided in the sterilization chamber. A slit-shaped air inlet opening to the air inlet is formed on one end side of one surface of an air passage member that partitions the sterilization chamber, and a wind that partitions the sterilization chamber. On the other end side of the other surface of the road member, an air outlet communicating with the air outlet is formed so as not to face the air inlet, and the ultraviolet lamp is located at a position facing the air inlet. An air sterilizer which is arranged so as to extend in the same direction as the air inlet. 2. An additional rod-shaped ultraviolet lamp having an air discharge port formed in a slit shape and arranged in the sterilization chamber at a position facing the air discharge port so as to extend in the same direction as the air discharge port. The air sterilizer according to claim 1, wherein the air sterilizer is provided. 3. The sterilization unit has a plurality of sterilization processing chambers formed so as to be stacked in a stacked state from the air inlet to the air outlet, and in the sterilization processing chambers adjacent to each other, the upstream side is provided. The air sterilization apparatus according to claim 1 or 2, wherein an air outlet of the side sterilization chamber is connected to an air inlet of the downstream side sterilization chamber. 4. The sterilization unit has a processing chamber forming space extending from the air inlet toward the air outlet, and the processing chamber forming space is divided by a partition plate that is detachably attached. The air sterilizer according to claim 3, wherein the plurality of sterilization processing chambers are formed so as to be lined up in a stacked state from the air inflow port toward the air outflow port.