DE102022131207A1 - Air disinfection device and means of transport - Google Patents

Abstract

Disclosed is an air disinfection device (1) which has a housing (2) which has an inlet opening (4) for the inflow of air to be sterilized and an outlet opening (6) for the outflow of sterilized air, and a UV-C light source which is arranged in the housing (2). The air disinfection device (1) further has louvre panels (14, 16) which are each arranged in the housing (2) in front of the inlet opening (4) and in front of the outlet opening (6) in order to prevent UV-C radiation from escaping from the housing (2).

Description

The present invention relates to an air disinfection device and a means of transport comprising the air disinfection device, such as a bus, train, aircraft or ship.

The corona pandemic has clearly shown how vulnerable the globalized world is to airborne pathogens. An effective method of preventing the further spread of viruses and bacteria is to disinfect the air using UV-C light. Air disinfection is particularly necessary where many people are together in enclosed spaces, such as on public transport.

EN 20 2020 105 193 U1 discloses a device for sterilizing air, which has a housing with an inlet opening for the air to be sterilized and an outlet opening for the sterilized air, as well as a UV light source arranged in the housing. The UV light source is formed by UV-C LEDs. A meandering channel is formed in the housing by means of partition walls and several UV-C LEDs are arranged in the individual meanders of the channel. The disadvantage here is a reduction in the flow speed due to the meandering channel.

It is therefore an object of the present invention to provide an improved air disinfection device and a means of transport. This object is achieved by the air disinfection device and the means of transport according to the independent claims. Advantageous embodiments are the subject of the dependent claims.

An air disinfection device according to the invention comprises: a housing with an inlet opening for the inflow of air to be sterilized and an outlet opening for the outflow of sterilized air; and a UV-C light source which is arranged in the housing. A louvre panel or louvre field is arranged in the housing in front of the inlet opening and in front of the outlet opening. As a result, UV-C light, which can be harmful to the human body, is prevented from escaping from the air disinfection device. The housing can thus be formed without partition walls. As a result, the flow rate of the air in the housing is not reduced and the housing can be cleaned more easily.

The inlet opening and the outlet opening are particularly preferably arranged on opposite sides of the housing so that a straight flow direction is obtained from the inlet opening to the outlet opening. The louvre panels have one or more louvres. The louvres are shaped and arranged in such a way that air can pass through the louvre panels but UV-C light cannot pass through. For this purpose, the louvres can be inclined at an angle of between 90 degrees and 270 degrees to the flow direction. The louvres can be offset from one another in the flow direction and arranged one behind the other in such a way that they overlap or reach over one another. The louvres can have an angled structure with one or more angles. The louvres can also have a wave shape.

Preferably, the slats of the slatted panels and a frame section by which the slats are held can be provided with a light-absorbing coating, such as a black or matte black color, and/or with a light-absorbing structure, such as a microstructure. The frame section can be formed by a specially provided frame or by an inner wall section of the housing. As a result, leakage of UV-C light from the housing can be prevented even more reliably.

Advantageously, the inlet opening and the outlet opening can each be formed by a perforated section in the housing. The perforation can be round, oval, rectangular, teardrop-shaped or shaped in another way.

Consequently, the escape of UV-C light can be prevented even better in conjunction with the louvre panels.

Advantageously, a fan can be arranged at the inlet opening and/or the outlet opening. Several fans can also be arranged at the inlet opening and/or the outlet opening. In this way, the air flow through the housing can be controlled and increased. Since no partition walls are required between the inlet opening and the outlet opening, a low-cost fan with low power is sufficient to increase the air flow in an energy-efficient manner.

Preferably, a housing interior formed by the housing between the slatted panels can be provided with a reflective coating. The housing interior can be lined with aluminum foil, for example. The housing interior is thus evenly illuminated with UV-C light in order to achieve reliable air disinfection.

The UV-C light source can advantageously be a UV-C tube. In this way, the interior of the housing is evenly illuminated and reliable air disinfection is achieved.

The UV-C tube can advantageously be made of quartz glass. As a result, the UV-C tube is extremely stable. This is an advantage when using the air disinfection device in a means of transport, as high safety requirements must be met here.

Particularly preferably, the UV-C tube can be held in place by clamps. As a result, the UV-C tube can be replaced quickly and efficiently in the event of a defect.

Advantageously, the UV-C light source, in particular the UV-C tube, can have an operating voltage between 9 V and 48 V. Particularly preferably, the light source can have an operating voltage of 9 V, 12 V or 48 V. These are typical on-board voltages of means of transport and the air disinfection device can be connected directly to the power supply of the means of transport without control electronics, so that an existing means of transport can be easily retrofitted with the air disinfection device.

The air disinfection device can preferably have an indicator light at a location visible from the outside of the housing for checking the functionality of the UV-C light source. The indicator light is visible from the outside as soon as its light passes through the inlet opening or outlet opening formed by means of perforations. The indicator light can therefore be used to easily check whether the UV-C light source is functioning properly without opening the housing. The indicator light can be connected to a circuit of the UV-C light source so that it lights up when the UV-C light source is functioning properly. Alternatively, a current can be detected by the UV-C light source and the indicator light is switched on if no current or too little current is detected.

The housing can advantageously be formed by a base body and a cover. This simplifies the replacement of the UV-C light source housed in the housing.

Particularly advantageously, a light source for illuminating an outside of the housing can be integrated in the cover. The light source illuminates, for example, a room or a means of transport in which the air disinfection device is arranged. Consequently, the air disinfection device can be integrated into a ceiling or a wall without being particularly prominent. In means of transport, the air disinfection device can be retrofitted in places where light sources were previously installed and the existing energy supply of the light sources can be used to supply the air disinfection device in order to enable easy retrofitting.

The light source can advantageously be an LED light source, in particular an LED spotlight. This allows energy-efficient lighting to be achieved. In addition, LED spotlights can be integrated almost flush into the cover.

Particularly preferably, the cover can lie flat on the louvre panels and the cover can form a receiving space for receiving control electronics for the light source towards the housing interior between the louvre panels. Consequently, an air disinfection device with a flat housing without protruding sections can be obtained, so that the air disinfection device can be attached to a ceiling or a wall without being particularly conspicuous.

The air disinfection device can advantageously have a contact switch between the lid and the base body in order to interrupt the power supply to the UV-C light source when the lid is opened. As a result, UV-C light is reliably prevented from escaping from the housing even if the lid is opened carelessly or in the event of vandalism.

The air disinfection device may preferably have a lighting sensor for detecting an illuminance outside the housing in order to automatically switch off the light source when the illuminance is sufficient. Accordingly, the light source is automatically switched off in the case where ambient lighting is sufficient, so that unnecessary energy consumption is avoided.

Alternatively or in addition to the lighting sensor, the air disinfection device can have a switch for controlling the operation of the light source. Accordingly, the light source can also be operated in continuous mode, e.g. as a reading light, if desired.

A means of transport according to the invention has the air disinfection device. Consequently, a reliable disinfection of the air in the means of transport can be achieved, while at the same time Irradiation of passengers with harmful UV-C light is reliably prevented.

The air disinfection device is particularly preferably arranged in the means of transport in such a way that a flow direction from the inlet opening to the outlet opening is arranged in the direction of travel of the means of transport. In means of transport, openings in the body or operation of an air conditioning system create an air draft that runs counter to the direction of travel. Consequently, by aligning the flow direction from the inlet opening to the outlet opening in the direction of travel, the inflow of air to be disinfected into the housing is improved in a simple and efficient manner.

• 1 eine schematische Querschnittsansicht einer Luftdesinfektionsvorrichtung gemäß einer ersten Ausführungsform;
• 2 eine schematische Querschnittsansicht einer Luftdesinfektionsvorrichtung gemäß einer zweiten Ausführungsform;
• 3 eine schematische Querschnittsansicht einer Luftdesinfektionsvorrichtung gemäß einer dritten Ausführungsform; und
• 4 eine schematische Querschnittsansicht einer Luftdesinfektionsvorrichtung gemäß einer vierten Ausführungsform.

Embodiments of the present invention will now be described in detail with reference to the accompanying drawings, in which:

• 1 a schematic cross-sectional view of an air disinfection device according to a first embodiment;
• 2 a schematic cross-sectional view of an air disinfection device according to a second embodiment;
• 3 a schematic cross-sectional view of an air disinfection device according to a third embodiment; and
• 4 a schematic cross-sectional view of an air disinfection device according to a fourth embodiment.

The air disinfection device according to the present invention will be described below with reference to use in a means of transport such as a bus, train, airplane and ship, but of course the air disinfection device can also be used elsewhere. It should be noted that the directions below are related to the figures. However, the air disinfection device can be mounted on a ceiling or on a wall, so the directions may be different in actual use.

1 shows an air disinfection device 1 according to a first embodiment of the present invention. The air disinfection device 1 comprises a housing 2 in which an inlet opening 4 into which air to be disinfected can flow and an outlet opening 6 from which disinfected air can flow out are formed on opposite sides of the housing 2. A direction in which the air, as indicated by the arrows in 1 shown, from the inlet opening 4 to the outlet opening 6 through the housing 2, is also referred to as a flow direction hereinafter. According to the present embodiment, the inlet opening 4 and the outlet opening 6 are formed by a perforated portion or a perforation in the housing. As shown in 1 As shown, the housing 2 is shaped as a parallelepiped, but the housing 2 may also be formed in any other shape, e.g. as an elliptical cylinder.

In order to disinfect the incoming air, a UV-C light source for emitting UV-C light, which in particular has a wavelength of 200 nm to 280 nm, preferably 222 nm or 254 nm, is arranged in a housing interior formed in the housing 2. According to the present embodiment, the UV-C light source is formed by a UV-C tube 8 made of quartz glass. The UV-C tube 8 has in particular an operating voltage of 9 V, 12 V, 24 V or 48 V, so that it can be connected directly to an on-board network or a direct voltage power supply of a means of transport. The use of the UV-C tube 8 also ensures uniform illumination of the housing interior. In addition, the housing interior, in particular in an area between the louvre panels 14, 16, can be lined with a reflective coating (not shown in the figures), such as an aluminum cladding, in order to further improve the illumination of the housing interior, so that a reliable disinfection of the air flowing through is achieved.

The UV-C tube 8 is arranged on a web 10 in which cables and, if necessary, the necessary control electronics, e.g. a voltage converter, for connecting the air disinfection device 1 to a power supply are housed. Clamps 12 for fastening the UV-C tube 8 are arranged on the web 10. The clamps 12 are designed in particular as open circles and the UV-C tube 8 can be inserted into the clamps 12 by applying light pressure from above. As a result, the UV-C tube 8 can be easily replaced in the event of a defect.

Since UV-C light can cause damage to the human body, such as inflammation of the cornea, conjunctiva and skin, it is imperative that UV-C light is prevented from escaping from the housing 2. For this reason, louvre panels 14, 16 are arranged in front of the inlet opening 4 and the outlet opening 6 in the housing 2. In the present embodiment, the louvres 18 and 20 are arranged obliquely to the flow direction. Preferably, the louvres 18, 20 of the louvre panels 14, 16 and a frame section by which the louvres 18, 29 are held are provided with a light-absorbing coating. The frame section can be provided with a frame or be formed by inner wall sections of the housing 2. The light-absorbing coating can in particular be formed by black or matt black paint. Additionally or alternatively, the slats 18, 20 of the slatted panels 14, 16 can be provided with a light-absorbing structure, e.g. a microstructure. In this way, UV-C light can be reliably prevented from escaping from the housing 2. This effect is enhanced by the inlet opening 4 and the outlet opening 6 being formed by means of perforation in the housing 2.

In order to control or increase the air flow through the housing 2, fans 22, 24 can be arranged in the housing 2 in front of the inlet opening 4 and/or in front of the outlet opening 6. Since there are no partition walls in the housing interior that reduce the flow speed, it is sufficient to provide inexpensive fans 22, 24 with low power, such as those used for cooling computers, for example. Control electronics for the fans 22, 24 can also be arranged in the web 10.

As in 1 As shown, the housing 2 is formed by a cover 26 and a cup-like base body 28. The cover 26 preferably forms an entire top of the housing 2 and can also form side walls of the housing 2 or part of the side walls. A light source for illuminating an outside of the housing 2 is introduced into the cover 26. According to the present embodiment, the light source is formed by an LED light source in the form of LED spots 30. In order to accommodate the LED spots 30 and the control electronics required for them, the cover 30 forms a receiving space 32 between the slatted panels 14, 16 towards the housing interior. The remaining part of the cover 26 outside the receiving space 32 lies flat on the slatted panels 14, 16. In this way, a flat design of the housing 2 can be achieved, so that the air disinfection device 1 can be inconspicuously attached to a wall or ceiling of a means of transport. By integrating the LED spots 30, it is also possible to remove existing light sources in the means of transport and replace them with the air disinfection device 1. An existing energy supply of the previously existing light sources can then be used to operate the air disinfection device 1.

Since the air disinfection device 1 is primarily intended for retrofitting in existing means of transport, a lighting sensor (not shown in the figures) for detecting an illuminance outside the housing 2 can also be provided. In the event that the detected illuminance is less than a predetermined threshold value, the LED spots 30 can be switched on automatically, so that no additional wiring to the air disinfection device 1 is required. Additionally or alternatively, a switch (not shown in the figures) can be provided for controlling the operation of the LED spots 30. The switch can be formed by a manually operable switch on an outside of the housing 2. Furthermore, a switch that can be remotely operated by a driver of the means of transport via radio can also be provided. Consequently, the light of the LED spots 30 can also be switched on in continuous operation if required, e.g. as a reading light.

In addition, the air disinfection device 1 can have an indicator light (not shown in the figures) that can be seen from the outside of the housing 2. This is necessary because no UV-C light can escape from the housing 2 and opening the housing 2 to check that the UV-C light source is functioning correctly should be avoided as far as possible. The indicator light can be arranged, for example, in the housing 2 near the inlet opening 4 or outlet opening 6 formed by means of a perforation, so that light emitted by the indicator light exits through the perforation. For example, the indicator light can be connected to a circuit of the UV-C tube 8, so that the indicator light goes out when a supply to the UV-C tube 8 is interrupted, e.g. due to a defect in the UV-C tube 8. Alternatively, a current through the UV-C tube 8 can also be detected and the indicator light is switched on when no current or too little current flows through the UV-C tube 8. This ensures proper operation and thus proper disinfection of the air flowing through the housing 2.

In order to reliably prevent UV-C light from escaping even in the event of careless opening of the lid 26 or in the event of vandalism, the air disinfection device 1 can have a contact switch between the lid 26 and the base body 28, which interrupts the power supply to the UV-C tube 8 when the lid 26 is opened.

Second to fourth embodiments of the present invention are shown in the 2 to 4 These embodiments differ from the embodiment described above in the design of the slats. The remaining configuration is the same as the configuration of the first embodiment described above.

According to the 2 In the second embodiment shown, the slats 34, 36 of the slats panels 14, 16 are angled. According to the 3 In the third embodiment shown, the slats 38, 40 are formed with multiple angles in a Z-shape. Alternatively, the slats can also be curved, e.g. in a wave shape. According to the 4 In the fourth embodiment shown, the lamellae 42, 44 are aligned perpendicular to the flow direction and are arranged offset in the flow direction such that they overlap or overlap one another. In the second to fourth embodiments shown in the 2 to 4 As shown, the escape of UV-C light from the housing 2 is also reliably prevented.

As already mentioned, the air disinfection device 1 is intended for use in a means of transport, such as a bus, train, airplane or ship. However, the air disinfection device 1 is not limited to this and can also be used in other places where the risk of infection is increased by the presence of several people. Examples of this are hotels, conference rooms, cinemas, concert halls, theaters or classrooms.

List of reference symbols

1

Air disinfection device

2

Housing

4

Inlet opening

6

Outlet opening

8th

UV-C tube

10

web

12

bracket

14

Slatted panel

16

Slatted panel

18

Slats

20

Slats

22

fan

24

fan

26

Lid

28

Base body

30

Light source

32

Recording room

34

Slats

36

Slats

38

Slats

40

Slats

42

Slats

44

Slats

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA accepts no liability for any errors or omissions.

Cited patent literature

• DE 202020105193 U1 [0003]

Claims (17)

Air disinfection device (1), comprising: a housing (2) with an inlet opening (4) for the inflow of air to be sterilized and an outlet opening (6) for the outflow of sterilized air, a UV-C light source arranged in the housing (2), characterized by louvre panels (14, 16) each arranged in the housing (2) in front of the inlet opening (4) and in front of the outlet opening (6). Air disinfection device (1) according to Claim 1 , wherein slats (18, 20, 34, 36, 38, 40, 42, 44) of the slatted panels (14, 16) and a frame section by which the slats (18, 20, 34, 36, 38, 40, 42, 44) are held are provided with a light-absorbing coating and/or with a light-absorbing structure. Air disinfection device (1) according to one of the Claims 1 or 2 , wherein the inlet opening (4) and the outlet opening (6) are each formed by a perforated section in the housing (2). Air disinfection device (1) according to one of the Claims 1 until 3 , wherein a fan (22, 24) is arranged at the inlet opening (4) and/or the outlet opening (6). Air disinfection device (1) according to one of the Claims 1 until 4 , wherein a housing interior formed by the housing (2) between the louvre panels (14, 16) is provided with a reflective coating. Air disinfection device (1) according to one of the Claims 1 until 5 , wherein the UV-C light source is formed by a UV-C tube (8), which consists in particular of quartz glass. Air disinfection device (1) according to Claim 6 , wherein the UV-C tube (8) is held by clamps (12). Air disinfection device (1) according to one of the Claims 1 until 7 , wherein the UV-C light source has an operating voltage between 9 V and 48 V, in particular 9 V, 12 V or 48 V. Air disinfection device (1) according to one of the Claims 1 until 8th which has a control line visible from the outside of the housing (2) for checking the functioning of the UV-C light source. Air disinfection device (1) according to one of the Claims 1 until 9 , wherein the housing (2) is formed by a cover (26) and a base body (28). Air disinfection device (1) according to Claim 10 which has a light source integrated in the cover (26) for illuminating an outside of the housing (2). Air disinfection device (1) according to Claim 11 , wherein the light source is an LED light source, in particular an LED spot (30). Air disinfection device (1) according to one of the Claims 11 or 12 , wherein the cover (26) rests flat on the louvre panels (14, 16) and forms a receiving space (32) for receiving the light source and control electronics for the light source towards the housing interior between the louvre panels (14, 16). Air disinfection device (1) according to one of the Claims 10 until 13 which has a contact switch between the lid (26) and the base body (30) in order to interrupt the energy supply of the UV-C light source when the lid (26) is opened. Air disinfection device (1) according to a Claims 11 until 14 which has a lighting sensor for detecting an illuminance outside the housing (2) in order to switch on the light source when the illuminance falls below a predetermined level, and/or a switch for controlling the operation of the light source. Means of transport comprising: the air disinfection device (1) according to one of the Claims 1 until 15 . Means of transport according to Claim 16 , wherein the air disinfection device (1) is arranged in the means of transport such that a flow direction from the inlet opening (4) to the outlet opening (6) is arranged in the direction of travel of the means of transport.

Images