BE1028571A1 - AIR DISINFECTION DEVICE AND METHOD FOR AIR DISINFECTION - Google Patents

Abstract

Air disinfection device for disinfecting air in a space accessible to persons, comprising a housing having an air inlet, an air outlet, and air disinfecting means, the air disinfecting means being adapted to disinfect air flowing through the housing from the air inlet to the air outlet, so as to to obtain disinfected air, and air displacing means for displacing air from the air inlet to the air outlet, wherein the air displacing means are arranged such that the air disinfection device operates according to the air displacement principle, wherein an air discharge velocity of the disinfected air from the air outlet is set such that the air from the air outlet is evenly distributed (ie that the air supply to the room is even) and mixing of the disinfected air with ambient air is minimized, and preferably avoided. As well as creating an upward airflow in the space.

Description

AIR DISINFECTION DEVICE AND PROCEDURE FOR DISINFECTION

FROM AIR The present invention relates to an air disinfection device for disinfecting air in a space accessible to persons. Furthermore, the present invention relates to a method for disinfecting air in a space accessible to persons. According to the prior art, the disinfection of air is generally achieved by drawing air into a space, filtering the sucked in air, and then blowing out the filtered air into the space. A drawback of air disinfection according to the prior art is that the blown out, filtered air mixes with the ambient air, i.e. the air in the room, so that pollutions in the ambient air are spread through the room. This is particularly undesirable when these contaminants are organisms such as pathogens, for example bacteria, viruses, microorganisms, fungi, yeasts, parasites, and the like. It is true that the concentration of contaminants in the ambient air will decrease as a result of the filtering. However, organisms, and particularly pathogens, can self-replicate when, for example, they are inhaled by a person. Therefore, even with a low concentration of contaminants, there is a health risk for persons in the room. It is the object of the present invention to obviate at least the above drawback of the prior art, i.e. to provide an air disinfection device and method which reduces the health risks of persons due to air pollutions, in particular organisms such as pathogens. , mitigates. To this end, according to a first aspect, the present invention provides an air disinfection device of the type mentioned in the preamble, characterized by comprising a housing with an air inlet, an air outlet, and air disinfectants, wherein the air disinfectants are designed to disinfect air that flows through the housing from the air inlet to the air outlet in order to obtain disinfected air, and air displacing means for displacing air from the air inlet to the air outlet, the air displacing means being arranged such that the air disinfection device operates according to the air displacement principle, wherein an air outlet velocity of the disinfected air from the air outlet is set in such a way that the air from the air outlet is evenly distributed (ie that the air supply to the room is even) and mixing of the disinfected air with ambient air is minimized minimized, and preferably at least substantially avoided by a uniform supply.

By using the displacement principle, which is explained in more detail below, the disinfected air is mixed as little as possible with the ambient air, ie the air in the space accessible to persons. The disinfected air displaces the ambient air, or 'polluted air', away from the air outlet direction and finally to the air inlet, where the polluted air is drawn in through the air inlet to be disinfected.

As a result, the air disinfection device according to the invention can displace the undisinfected air, i.e. the polluted air, to a part of the room where people in the room do not or hardly inhale it. Contaminants, especially small organisms such as pathogens, are displaced together with the polluted air, so that the health risks for people in the room due to these pollutions are effectively mitigated. This is particularly advantageous where pathogens can spread as aerosols, as is the case with certain viruses.

The air displacement principle, also referred to as displacement ventilation, is a method of air distribution in a room in which air (for example cool air) is supplied at a low flow rate (and preferably near a floor of the room). The supplied air then collects at the level of the supply (i.e. the air outlet), and thus preferably near the floor of the room. By means of convection and/or buoyancy forces, for example due to heat sources in the room (such as equipment and/or persons) and/or the density of the supplied air, the supplied air moves upwards (or downwards as appropriate), preferably towards the ceiling. of space. Due to the low flow rate and even supply of the supplied air, it mixes as little as possible with the air present in the room. This displacement effect is further increased by the air pressure difference caused by the high possible circulation rate as a result of the air displacing means.

Preferably, the circulation of air in the space takes place in principle without mixing air from outside the space, so that the present air filtration device consumes relatively little energy. Preferably, the air filtration device supplies filtered air to the space via the air outlet at a temperature at least substantially equal to a temperature of the polluted air in the space. In other words, the air is preferably not cooled or heated by the air filtration device.

Disinfected air is supplied to the space by the present air disinfection device via its air outlet in a manner in which mixing of supplied disinfected air and polluted air present in the space is limited to a minimum. This is done by supplying disinfected air to the room via the air outlet (preferably in a lower area in the room, and more preferably near a floor of the room), preferably evenly and at low speed, while simultaneously supplying contaminated air via the air inlet. (preferably in a higher area in the room, more preferably near a ceiling of the room, and still further preferably at a height of at least 1.80 metres) from the space to the housing of the air disinfection device design.

According to an embodiment of the air disinfection device, the air outlet is arranged below the air inlet, and preferably at a floor height of the room. As a result, the polluted air in the room is displaced upwards towards the ceiling of the room by means of the air displacement principle. Preferably, the polluted air is displaced to a minimum height of 1.80 m, so that the average person does not breathe the polluted air. More preferably, the polluted air is displaced to a height of 2 m or more, so that the majority of the persons do not breathe the polluted air. According to a further embodiment of the air disinfection device, a vertical distance between the air inlet and the air outlet is at least 1.5 m, preferably at least 1.8 m, and more preferably more than 2 m. the space provides an air column between the air inlet and the air outlet, which air column mainly consists of disinfected air. Persons residing in this air column therefore do not breathe polluted air, which may for instance comprise organisms such as pathogens. According to a further embodiment of the air disinfection device, an air outflow direction of the disinfected air from the air outlet is substantially horizontal. Horizontal should be read here as substantially parallel to a floor of a room, or substantially perpendicular to the direction of gravity. Due to the horizontal outflow of disinfected air, it is distributed as evenly as possible throughout the room, creating a layer, or column, of disinfected air throughout the room. As a result, the present embodiment ensures an air quality that is as even as possible in the entire room. That is to say that the air quality at a specific height at a first position in the room is substantially equal to the air quality at the same height at a second position in the room. Preferably, the air outlet is further provided with a distribution screen, which ensures that the air flowing from the air outlet is distributed evenly. In other words, the air flowing from the air outlet is discharged proportionally over the entire cross-sectional area of the air outlet. Preferably, the distribution screen comprises an air-permeable textile, and/or a perforated plate.

According to a further embodiment of the air disinfection device, the air outflow velocity is in the range of 0.2 m/s to 2 m/s, preferably in the range of 0.4 m/s to 2 m/s, and more preferably 0.5 m/s to 2 m/s. Tests with the air disinfection device have shown that an excellent result is achieved at these outflow velocities, and in particular at an outflow velocity between 0.5 and 2 m/s. That is, the polluted air is effectively displaced from the air outlet toward the air inlet throughout the room. According to a further embodiment of the air disinfection device, the air displacing means comprise a flow rate of 300 m 2 /hr to 4000 m 2 /hr. The flow rate, i.e. the amount of air per unit time that can be disinfected by the air disinfection device, can be set, for instance depending on the volume of the space, and/or a legal and/or desirable circulation rate. The circulation rate is the number of times that a room content of the room is refreshed per hour with disinfected air by the air disinfection device. The circulation rate of the air disinfection device is preferably at least twofold, and more preferably equal to or higher than the legally required circulation rate. The legally required circulation number may differ per jurisdiction and/or the type of space (e.g. operating room of a hospital, concert hall, catering establishment, et cetera). As an example, a flow capacity of 300 m?/hour provides for a twofold circulation in a room or zone with a floor area of approximately 50 to 60 m2, with a room height of approximately 2.5 to 3 m. As a further example, a flow capacity of 4000 m?/hour in a fourfold to sixfold circulation with a floor area of approximately 220 m? (room height of approximately 3 meters, and sixfold circulation), up to a floor area of 400 m? (room height 2.5 meters, and quadruple circulation).

According to a further embodiment of the air disinfection device, the air disinfection means comprise an ionizer and/or a UV light source. Preferably, the UV light source emits UV-C light, preferably with a wavelength of 200 nm to 300 nm, more preferably with a wavelength of 240 nm to 280 nm, and still further preferably with a wavelength of about 254 nm. For example, an ionizer is a device that uses high voltage to ionize air atoms and molecules, i.e. to give it an electrical charge. The ionizer preferably also comprises an electrostatically positively (or negatively) charged plate with which particles,

for example bacteria and viruses, among others, can be captured from the air after ionization. Additionally or alternatively, the ionizer may generate ozone. Ozone is highly reactive, and can therefore filter chemicals and odors from the air. A UV light source generates light in the UV (ultraviolet) spectrum, which includes a wavelength between about 10 nm and 400 nm. The UV light source preferably emits UV-C light, which comprises a wavelength of between 100 nm and 300 nm, and which is known to be highly disinfecting. UV-C light, for example, can destroy bacteria, viruses, and single-celled organisms (such as protozoa). The UV light source is, for example, a low-pressure mercury lamp, a high-pressure mercury lamp, an LED lamp, an excimer lamp, or a combination thereof. By using the air disinfectants, polluted air from the room is effectively disinfected, mitigating health risks for people in the room. For example, the polluted air may contain contaminants such as organisms (e.g. bacteria, single-celled organisms, viruses, parasites, etc.), which contaminants, and in particular organisms, are effectively neutralized by the air disinfectants.

According to a further embodiment of the air disinfection device, it furthermore comprises an air filter received in the housing, which filter is arranged to filter air flowing through the housing from the air inlet to the air outlet. Preferably, the air filter comprises at least one of an EPA filter, a HEPA (high-efficiency particulate air) filter, a carbon filter, a pleated filter and/or a bag filter. An EPA or HEPA filter is a highly efficient filter that captures between a minimum of 85% and a maximum of approximately 99.999995% of 0.3 µm dust particles, depending on the HEPA class of the filter (according to European Standard 1822:2009 of the EU) which runs from E10 (>85%) to U17 (>99.999995%). One or more air filters can be provided upstream of the air disinfectants, downstream of the air disinfectants, or upstream and downstream of the air disinfectants. Preferably, the air filter comprises an activated carbon filter, i.e. a carbon filter. Preferably, the filter element comprises an active carbon filter in combination with one or more other filters, all of which are in particular designed as plate filters. Preferably, the filter comprises a pleated filter or bag filter, for instance as a pre-filter. For example, the pleated filter or bag filter is an F5, F6, F7, F8, or F9 filter.

Preferably, the air filter is accommodated in the housing downstream of the air disinfectants, and in particular the UV light source. As a result, particles from the air, for example bacteria and viruses inter alia, which are captured by the air filter, are exposed for longer to the UV light emitted by the UV light source, the UV light being preferably UV-C light. Preferably, a pre-filter is also included in the housing, upstream of the UV light source, the pre-filter being for instance a coarse filter. Still further preferably, downstream of the air disinfectants and the air filter, a carbon filter is arranged in the housing, with which, for instance, particles such as ozone can be collected.

Still further preferably, the housing contains the following components, in order from downstream of the air inlet to upstream of the air outlet: a pre-filter, a UV light source, an air filter (such as a HEPA or E10 filter), and a carbon filter.

Alternatively to or additionally to the air filter, an electrostatic air filter may also be provided in the housing.

In general, an electrostatic air filter comprises an ionization section, where particles in the air move through an ionizing field and become electrostatically charged, and a collection section, with plates with a potential difference between them, through which the charged particles are attracted and collected.

Preferably, the air disinfection device forms a self-contained unit which can be connected to the mains, for instance by means of a power cable, such as a cord and plug that can be connected to a socket.

In other words, the air disinfection device is preferably a separate unit, preferably movable, which is designed to be plug-in ready.

Thus, the separate unit constitutes a “plug and play” device.

According to a second aspect of the present invention, it provides a method for disinfecting air in a space accessible to persons, comprising the steps of: - sucking air through an air inlet by means of air displacing means, - disinfecting air by means of air disinfectants the air drawn in, - blowing out the disinfected air through an air outlet by means of the air displacing means, wherein the blowing out of the disinfected air takes place according to the air displacement principle, wherein an air outflow velocity of the disinfected air from the air outlet is set such that mixing of the disinfected air air with ambient air is minimized.

The method has at least the same advantages as the advantages mentioned with regard to the air disinfection device according to the first aspect of the present invention.

According to a further embodiment of the method, air is drawn in near a ceiling of the room.

As a result, the polluted air in the room is sucked towards the ceiling, so that people present in the room do not or less breathe this polluted air.

According to a further embodiment of the method, the blowing out of disinfected air takes place near a floor of the room. As a result, the polluted air is displaced evenly upwards in the room towards the ceiling of the room by means of the air displacement principle. Preferably, the polluted air is displaced to a minimum height of 1.80 m, so that the average person does not breathe the polluted air. More preferably, the polluted air is displaced to a height of 2 m or more, so that the majority of the persons do not breathe the polluted air. According to a further embodiment of the method, the disinfection of the aspirated air is achieved by irradiating the aspirated air with UV light, preferably UV-C light, and/or by ionizing the aspirated air. By using the UV light and/or ionization, polluted air from the room is effectively disinfected, mitigating health risks for people in the room. The polluted air may, for example, contain contaminants such as organisms (e.g. bacteria, unicellular organisms, viruses, parasites, etc.), which contaminants, and in particular organisms, are effectively neutralized by the UV light and/or ionization. According to a third aspect of the present invention, it provides a space, such as a room, provided with an air disinfection device according to the first aspect of the invention, and/or one or more embodiments thereof. Preferably, the air inlet is arranged near a ceiling of the room (e.g. room), and the air outlet is arranged near a floor of the room. The present invention will be further elucidated below with reference to the attached figures, in which: Figure 1 shows an air disinfection device for disinfecting air in a space accessible to persons; and - Figure 2 shows a schematic principle representation of air flows in relation to the air disinfection device.

Figure 1 shows an air disinfection device 1 for disinfecting air in a space accessible to persons. The air disinfection device 1 comprises a housing 2 with an air inlet 3, an air outlet 4 and air disinfection means 5. Air from the space can flow into the housing 2 through the air inlet 3 . Air flowing through the housing 2 from the air inlet 3 to the air outlet 4 is disinfected by the air disinfectants 5, such as UV-C lamps. Disinfected air can flow out of the housing 2 through the air outlet 4, wherein the outflow direction of the disinfected air from the air outlet 4 is substantially horizontal.

Figure 1 further shows air displacing means 6 for displacing air from the air inlet 3 through the housing 2 to the air outlet 4. Air displacing means 6 may include fans, bellows, and other air displacing means 6 known to those skilled in the art.

The air displacing means 6 are provided downstream of the filters 7,8,9 and the disinfecting means 5 .

An additional advantage of placing the air displacing means 6 as far downstream as possible is that the air displacing means 6 become polluted less quickly, since the air has already been filtered by the air filters 7,8,9 and disinfected by the air disinfectants 5. Placing the air displacing means 6 as far downstream as possible is that the power supply (not shown) of the air displacing means 6 can also be placed at the bottom of the housing 2, so that a possible plug connection (not shown) of the air disinfection device 1 is located virtually at floor height 10 of the space, where there are also sockets in many buildings.

A first air filter 7, or pre-filter 7, for filtering air at the air inlet 3, a second air filter 8, and a third air filter 9 for filtering air at the air outlet 4 are arranged to filter air passing through the housing 2 of the air inlet 3 flows to the air outlet 4.

The first air filter 7, the second air filter 8, and the third air filter 9 may, for example, comprise a carbon filter and/or a HEPA filter and/or a bag filter.

It is also conceivable that only the first filter 7 or the second filter 8 or the third filter 9 (or a combination thereof) are provided in the air disinfection device 1.

It is also conceivable that further filters (not shown) are provided in or on the housing 2. The filters 7,8,9 can be removably received in the housing 2, so that they can be easily replaced.

The air disinfection device 1 can also be provided with indicators, such as lamps, sound signal generators, or a display, with which it can for instance be indicated when the filters 7,8,9 need to be replaced, for instance after a certain volume of air has passed through the device 1. has been disinfected or after a certain operating time of the device 1. Preferably, the pre-filter 7 is a pleated filter or a bag filter, such as an F5, F6, F7, F8, or F9 filter.

Such a filter is for instance suitable as a pre-filter 7, to filter dust (solid particles) from the air before the air is disinfected by the air disinfectants 5, and optionally filtered by the further filters 8,9. The second filter 8 is preferably an EPA or a HEPA filter, and the third filter 9 is preferably a carbon filter.

In Figure 2 air flows are shown schematically by arrows.

The means of air displacement

6 move air from the air inlet 3 through the housing 2 to the air outlet 4. The outflow direction of air disinfected by the air disinfectants 5 from the air outlet

4 is substantially horizontal. As a result, the disinfected air from the air outlet 4 displaces the ambient air from below according to the displacement principle, wherein an air outflow speed of the disinfected air from the air outlet 4 is set such that mixing of the disinfected air with ambient air present in the room is minimized. The ambient air, which is displaced from below by the disinfected air according to the displacement principle, is pushed towards the air inlet 3, which is arranged at a vertical distance from the air outlet 4. Preferably, the vertical distance is at least 1.80 metres, wherein the air outlet 4 is further preferably arranged near a floor of the room. Ambient air, which is preferably minimally mixed with disinfected air, can flow into the housing 2 through the air inlet 3 . In other words, the disinfected air is preferably blown out at floor height 10 through the air outlet 4 of the device 1, after which the air in the room is displaced towards the ceiling of the room, and then in a height zone of the room of preferably above 1. .8 meters is drawn in through the air inlet 3.

The air disinfection devices 1 shown in Figures 1 and 2 are preferably self-contained, optionally movable units. In an embodiment not shown, an air disinfection device 1 can be provided with displacing means (not shown), such as (castor) wheels, which are for instance placed under the housing 2, or on one or more sides of the housing 2 when it has to be for instance 90 degrees. be tilted for transport. The air disinfection device 1 is preferably provided with a power supply as well as a power supply cable and plug connected thereto. The plug can preferably be included in a standard socket, so as to supply the air disinfection device 1 with power. Preferably, the air displacing means 6 and the air disinfecting means 5 are supplied with power by the same power supply. It is also conceivable that several air disinfection devices 1 can be coupled to each other or be provided separately from each other in the space, in order to be able to provide a greater flow rate capacity for a specific space.

It is noted that the invention is not limited to the embodiments described above and also extends to other embodiments falling within the scope of the appended claims.

Claims (14)

Conclusions An air disinfection device for disinfecting air in a space accessible to persons, comprising: a housing with an air inlet, an air outlet, and air disinfectants, the air disinfectants being adapted to disinfect air passing through the housing from the air inlet to the air outlet flows to obtain disinfected air, the air disinfectants comprising a UV light source which emits UV-C light; and air displacing means for displacing air from the air inlet to the air outlet, wherein the air displacing means are arranged such that the air disinfection device operates according to the air displacement principle, wherein an air discharge velocity of the disinfected air from the air outlet is set such that the air from the air outlet is uniform is distributed and mixing of the disinfected air with ambient air is minimized, the air outlet being located below the air inlet, and preferably at a floor height of the room, and the air disinfection device forming a separate self-contained unit that can be connected to the mains be connected, for example by means of a power cable. Air disinfection device according to claim 1, wherein the housing is provided with moving means, such as castors, in order to be able to move the air disinfection device. Air disinfection device according to claim 1 or 2, wherein a vertical distance between the air inlet and the air outlet is at least 1.5 m, preferably at least 1.8 m, and further preferably more than 2 m. An air disinfection device according to any one of the preceding claims, wherein an air outflow direction of the disinfected air from the air outlet is substantially horizontal. An air disinfection device according to any one of the preceding claims, wherein the air outflow velocity is in the range of 0.2 m/s to 2 m/s, preferably in the range of 0.4 m/s to 2 m/s, and more preferably 0.5 m/s to 2 m/s. An air disinfection device according to any one of the preceding claims, wherein the air displacing means comprise a flow rate of 300 m3/hr to 4000 m3/hr. Air disinfection device as claimed in any of the foregoing claims, wherein the air disinfection means further comprise an ionizer. The air disinfection device of claim 7, wherein the UV-C light has a wavelength of 200 nm to 300 nm, 240 nm to 280 nm, or about 254 nm. An air disinfection device according to any one of the preceding claims, further comprising an air filter received in the housing and adapted to filter air flowing through the housing from the air inlet to the air outlet. The air disinfection device of claim 9, wherein the air filter comprises at least one of an EPA filter, a HEPA filter, a pleated filter, a bag filter, and a carbon filter. Air disinfection device according to any one of the preceding claims, wherein the air outlet is further provided with a distribution screen, which ensures that the air flowing from the air outlet is distributed evenly, preferably wherein the distribution screen is made of an air-permeable textile, and/or a perforated plate. A room, comprising an air disinfection device according to any one of the preceding claims, wherein the air inlet is arranged near a ceiling of the room, and the air outlet is arranged near a floor of the room. 13. Method for disinfecting air in a space accessible to persons, comprising the steps of: sucking air through an air inlet by means of air displacing means, wherein the sucking in air takes place near a ceiling of the space; disinfecting the drawn-in air by means of air disinfectants, wherein the disinfecting of the drawn-in air is achieved by irradiating the drawn-in air with UV-C light; and blowing out the disinfected air through an air outlet by means of the air displacing means, wherein the blowing out of disinfected air takes place near a floor of the room, and wherein the blowing out of the disinfected air takes place according to the air displacement principle, wherein an air outflow rate of the disinfected air from the air outlet is set in such a way that mixing of the disinfected air with ambient air is minimized. A method according to claim 13, wherein the disinfection of the drawn-in air is also achieved by ionizing the drawn-in air.