NL1044026B1 - METHOD AND DEVICE FOR PROTECTING PERSONS AGAINST INHALING AIR CONTAINING VIRUSES AND/OR BACTERIA - Google Patents

Abstract

EXTRACT METHOD AND DEVICE FOR PROTECTING PERSONS AGAINST INHALING AIR CONTAINING VIRUSES AND/OR BACTERIA The present invention relates to a method and a device which can prevent a person from inhaling or exhaling air into the environment in which pathogenic viruses and/or whether bacteria are present. In one embodiment, the device comprises a mouth-nose mask which does not comprise any flow-restricting measures, in contrast to the known mouth masks, which comprise a paper or textile filter as a means of preventing the spread of viruses and/or contamination by viruses. 1044026

Description

METHOD AND DEVICE FOR PROTECTING PERSONS AGAINST BREATHING AIR CONTAINING VIRUSES AND/OR BACTERIA bacteria are present.

In one embodiment, the device comprises a mouth-nose mask which does not comprise any flow-restricting measures, in contrast to the known mouth masks, which comprise a paper or textile filter as a means of preventing the spread of viruses and/or contamination by viruses.

The global Covid-19 pandemic, which in 2020 and 2021 has led to many fatalities and people with temporary and permanent health damage and has also caused a lot of economic damage, means that wearing a face mask, mouth nose mask or face mask has become almost automatic for many people.

The masks most commonly used for this purpose are the so-called FFP (Filtering Facepiece Particles) mouth masks, which are essentially no more than a paper or textile filter, usually comprising several layers.

The wearer of such a known mouth mask, hereinafter also referred to as a conventional mouth mask or face mask, must suck in air through the filter when inhaling and blow air out through the filter when exhaling, which can be experienced by the wearer of the mouth mask as a considerable resistance and therefore as tiring.

Moreover, such a face mask does not guarantee that the wearer cannot ingest virus particles and therefore cannot become ill.

The FFP face masks offer a reasonable degree of protection against inhalation of aerosols emitted by others, defined in this context as air with minuscule liquid droplets that may contain the SARS-CoV-2 virus, the virus that causes Covid-19.

These liquid droplets are in principle only a few micrometres in size.

A conventional face mask cannot completely prevent any viruses exhaled by the wearer of the face mask from reaching and infecting someone else. So it is for the time being at least virtually impossible to prevent a person infected with the Covid-19 virus from infecting other people, unless the infected person is isolated.

The device according to the present invention not only forms a barrier against the passage of air containing virus particles, but also comprises measures for rendering harmless viruses and/or bacteria which may be present in the air inhaled or exhaled by someone via the device. To this end, the device comprises one or more LED light sources which emit ultraviolet C light, hereinafter also referred to as UVC light, which is harmful to viruses. The device according to the invention will now be explained with reference to a few figures. In the drawing: Fig. 1 shows a schematic side view of a part of the face of a person wearing a simple exemplary embodiment of the device according to the invention; fig. 2a shows a schematic longitudinal section of the airlock with end caps as also shown in fig. 1; Fig. 2b shows a schematic cross-section along the line A-A of the exemplary embodiment of the airlock with end caps shown in Fig. 2a in longitudinal section; Fig. 3 shows a schematic exemplary embodiment of an embodiment variant of the airlock with end caps, which comprises measures to limit the chance that UVC light from the airlock of the device can irradiate objects or persons outside the airlock of the device; - fig. 4 shows an embodiment variant of the airlock and end caps of the device according to the invention, in which the airlock has a spherical shape.

In the figures, identical or similar parts have identical or similar reference numerals. fig. 1 shows a schematic side view of a part of the face 1, represented by a broken line, of a person wearing a simple embodiment of the device according to the invention. In this embodiment the device, hereinafter also referred to as the mouth-nose mask according to the invention, comprises a housing 2. In several of the preferred embodiments the housing is made of a transparent elastically deformable material such as for instance silicone rubber. The housing comprises an open side, the edge 2a of which is adapted to press against the face of the wearer during the intended use of the device, thereby deforming slightly so as to ensure a good seal. The edge 2a is hereinafter also referred to as the sealing edge 2a. The device also comprises a, preferably elastic, headband 3 attached to the housing 2 in the vicinity of the aforementioned edge of the open side of the housing, which, when a person wears the mouth-nose mask according to the invention, ensures that the edges of the open side of the housing are drawn against the wearer's face in a substantially sealing manner, also referred to as pressed.

The device according to the invention furthermore comprises, for example, a cylindrical airlock 4 which is provided at both ends with an end cap, 5 and 6 respectively, which end caps in the exemplary embodiment shown in Fig. 1 have a substantially flat bottom and a substantially perpendicular to said bottom standing cylindrical wall. The invention provides that the airlock and the end caps can, of course, also have a cross-section other than a circular one. The assembly of the airlock 4 and the end caps 5 and 6 accommodated in the housing 2 is designed in such a way that the air 7 inhaled and exhaled by the wearer of the mouth-nose mask moves along a flow path schematically shown by the dotted lines 7a from outside the mouth-nose mask to the mouth. and/or nasal entrance of the wearer and vice versa. In practice, these air flows will probably spread more over the space in the airlock than the limited paths schematically shown by the dotted lines 7a in Fig. 1.

In the exemplary embodiment shown, the airlock comprises a series of LEDs 8 emitting UVC light on the inside along the circumference of the airlock. All air moving through the airlock is therefore exposed to the UVC light emitted by the LEDs, whereby the airborne viruses, bacteria and/or other pathogens are rendered harmless.

The inner diameter of the upstanding cylindrical wall of the end caps is sufficiently larger than the outer diameter of the airlock to create a gap between the end cap and airlock in the assembly shown schematically in Figure 1 which is large enough not to cause appreciable breathing resistance. cause for the wearer of the mouth and nose mask according to the invention.

A mouth-nose mask with the feature mentioned in the previous sentence can hereinafter also be referred to as a substantially resistanceless mouth-nose mask.

At the same time, the gap may not be so large that there is a risk that the UVC light from the airlock can radiate into the tissue of the wearer of the mouth mask or of third parties in the vicinity of the wearer.

Studies by various research institutes and universities have shown that UVC light with a wavelength of 254 nanometers is most effective for inactivating microorganisms and viruses.

This light is harmful to human tissue and it is therefore important that human tissue is not exposed to such light directly or indirectly, i.e. via reflection.

It can be cautiously deduced from the results of American research that irradiating the air with virus-containing aerosols with far ultraviolet C light (wavelength range from 207 to 222 nanometers)

can be effective in inactivating viruses contained therein, without being harmful to human tissue.

However, this requires more research.

Therefore, in the present preferred embodiments of the device according to the invention use is made for the time being of UVC light with a wavelength of approximately 250 nanometers and the device comprises measures which prevent this light from escaping from the device.

It is inherent to the purpose of wearing the mouth-nose mask according to the invention that the LEDs placed in the airlock must be supplied with electrical power and that the electrical power source in the form of batteries or a battery is also mobile, as is the mouth-nose mask itself. .

In order to limit the size and/or weight of the electrical supply, some embodiments of the device according to the invention comprise measures to limit the energy consumption of the LEDs. A possible first measure aimed at this concerns limiting the width of the LED strip in the airlock to a relatively narrow LED strip, for example an LED strip in which the LEDs have a width of approximately 6 millimetres. The disadvantage of such a narrow direct radiation zone is obvious. Therefore, the invention provides that the inner surface of the, preferably cylindrical, airlock is reflective. This can be achieved, for example, by, in the case of a metal, for example stainless steel, airlock, by mechanically or electrolytically polishing the surface. Due to this reflective internal surface of the airlock, air moving through the airlock can be exposed to UVC radiation for longer and thus be better disinfected, without consuming more electrical energy. In an embodiment, the internal surface of the airlock is not completely cylindrical, but comprises, for example, facets, so that the light can be directed, when reflected from the wall of the airlock, to, for example, parts of the airlock located closer to the end caps. For example, the irradiation duration of the same packet of air flowing through the airlock is longer and the cumulative irradiation intensity is therefore higher. Of course, instead of or in addition to a polished internal surface, the airlock may also comprise mirrors.

fig. 2b is a schematic cross-sectional view along line A-A of the exemplary embodiment of the airlock with end caps shown in longitudinal section in FIG. 2a. In this schematic representation it can be seen that the LEDs 8 are distributed substantially evenly along the periphery of the airlock. However, the invention provides that the LEDs can be arranged in any desired or useful manner.

fig. 3 shows a schematic longitudinal section of an embodiment variant of the airlock with end caps, which includes measures to limit the chance that UVC light from the device can irradiate objects or persons outside the device. In this embodiment variant, the measures include inclining the upright edge inwards, i.e. in the direction of the center line of the airlock, which, if it unexpectedly appears, will result in the reflection of light mainly in the direction of the inside of the end cap. the light. Additional measures include, for example, matt black color, i.e. a color with the maximum possible degree of light absorption, provided with parts of the inside of the end caps and/or parts of the inside and/or outside of the cylindrical part of the airlock near the ends of the cylinder.

In addition to the exemplary embodiments discussed in this description and shown in the figures, the invention comprises a great diversity of possible embodiment variants of the airlock and end caps.

fig. 4 shows an embodiment of the airlock and end caps of the device according to the invention in which the airlock has a spherical shape. This embodiment can for instance be obtained by removing two opposing spherical segments from a thin-walled sphere 4a. The LEDs are not shown in Fig. 4, but in one embodiment they are located, for example, on the line formed substantially with the front wall of the housing 1, but then of course within the spherical body 4a of the airlock. Due to the reflective spherical shape of the inside of the airlock 4a, the UVC rays reflected in this airlock cover a large part of the contents of the airlock and the exposure of air flowing through this airlock to UVC light is considerable.

The end caps 5b and 6b of the airlock embodiment schematically shown in Fig. 4 comprise two spherical caps. Of course, if desired, these can also be provided with inwardly facing raised edges. The dotted lines 7a in Fig. 4 schematically show a possible flow path of inhaled and/or exhaled air.

In an embodiment of the device according to the invention, it comprises an electrical circuit which switches the LEDs on and off alternately with the aim of supplying the LEDs with electricity for only part, for example half, of the use time of the mask.

In the further description and/or in the claims, the aforementioned circuit can be referred to as an intermittent circuit.

If the switch-on and switch-off times are chosen very short, the risk that an amount of air can flow through the airlock without the air being exposed to UVC light is virtually excluded.

In another embodiment, the UVC light sources of the device are divided into two or more groups and alternately turned on and off intermittently per group with a different switching frequency such that one group is lit when the other is off and vice versa.

For example, UVC light is always present in the airlock when wearing the mouth-nose mask according to the invention.

By opting for an intermittent switching procedure, the energy consumption of the device can be considerably reduced, for example halved, and therefore the required frequency of battery replacement or battery charging can be reduced.

In addition to embodiments of the mouth-nose mask according to the invention in which the switching interval of the intermittent switching is fixed, the invention also comprises embodiments in which the wearer of a mouth-nose mask according to the invention can set the interval himself, within certain safe margins.

In several embodiments, the device according to the invention comprises the option of inductively charging the battery of the device for ease of use.

The invention provides both disposable and reusable versions of the device.

In view of durability, the reusable embodiments preferably comprise a rechargeable battery.

However, the disposable versions can of course also be provided with a rechargeable battery, which, when a disposable device is disposed of, is reused for supplying electricity to a subsequent disposable device.

The device also includes embodiments which include measures that exclude that someone wearing the mouth mask can forget to activate the LEDs for the disinfection of the inhaled and exhaled air with UVC light. An embodiment of such a measure comprises arranging a switch in or on the elastic headband 3 which, when the elastic headband is stretched, leads to conductive contact in one of the supply wires of the LEDs, which is interrupted in the unstretched state of the headband 3. and thus supplies the LEDs with electrical power. This embodiment of a switch based on stretching the elastic headband 3 by putting on the mouth mask will further be referred to as a stretch switch.

In several embodiments, the device according to the invention also comprises an alarm system that warns when the one or more light sources of the device do not emit UVC light, despite the switching on of the electrical supply. In such a situation, the device does not offer the wearer the intended protection. The alarm system referred to in the previous sentence is also referred to as a UVC alarm system.

The alarm system is designed not to send an alarm signal when the light sources are temporarily switched off by the intermittent circuit.

In the present context, the term nasal mask refers to a mask that encompasses the wearer's mouth and nose and allows the wearer to inhale and exhale air only through the designated airlock of the nasal mask.

The term “and/or” refers in particular to one or more of the items listed before and after “and/or”. For example, a sentence “item 1 and/or item 2” (and similar sentences) can refer to item 1 and item 2 or to item 1 or item 2.

The term “include” (or derivatives thereof) also includes embodiments in which the term “include” means “consist of”. The term "comprising" may therefore mean "consisting of" in some cases, but may mean "containing at least the defined species and optionally one or more other species" in other cases. In a claim, the use of the word include or a derivative thereof does not preclude the presence of elements or steps beyond those claimed in the claim.

The embodiments of the device according to the invention discussed in this description are only a few of the many possible embodiments within the scope of the invention and should therefore be regarded as non-limitative.

Claims (13)

CONCLUSIONS 1. A method for preventing air containing viruses, bacteria and/or other pathogens from being inhaled by persons and/or spreading to the environment via exhaled air, characterized in that the method comprises wearing a substantially resistanceless mouth-nose mask with an airlock comprising one or more built-in UVC light sources which are designed to disinfect the air inhaled and exhaled by the person via the airlock with UVC light while a person is wearing the mouth-nose mask. A method according to claim 1, characterized in that the airlock of the mouth-nose mask comprises measures which increase the exposure of the air passing through the airlock by extending the path traveled by the UVC light in the airlock by means of reflection. 3. A device for preventing air containing viruses, bacteria and/or other pathogens from being inhaled by persons and/or spreading to the environment via exhaled air, characterized in that the device comprises a housing (2) open on one side wherein the housing comprises a sealing edge (2a) and a substantially resistanceless and light-tight airlock (4,4a) with two end caps (5,6,5b,6b) incorporated in the housing, which airlock internally comprises one or more UVC light sources. A device according to claim 3, characterized in that the one or more UVC light sources comprise one or more LEDs (8). A device according to claim 3 or 4, characterized in that at least part of the inner surface of the airlock (4,4a) is reflective. A device according to claim 5, characterized in that the reflective portion of the inner surface comprises facets. A device according to one or more of claims 3-6, characterized in that at least one of the end caps (5,6) of the airlock comprises an inwardly sloping cylindrical wall (5a,6a). 8. Device as claimed in one or more of the claims 3-7, characterized in that the wall of the airlock has a matte black color substantially in the vicinity of the points of entry and/or exit of air flowing through the airlock. A device according to one or more of claims 3-8, characterized in that the device comprises an elastic headband (3) attached to the housing (2), which headband comprises a stretch switch. 10. Device as claimed in one or more of the claims 3-9, characterized in that the electrical supply of one or more of the UVC light sources comprises an intermittent circuit. 11. Device as claimed in one or more of the claims 3-10, characterized in that the device comprises a UVC alarm system. A device according to one or more of claims 3-11, characterized in that the airlock (4a) has a spherical shape. 13. Device as claimed in one or more of the claims 3-12, characterized in that the electrical supply of the UVC light sources of the device comprises a rechargeable battery or accumulator and comprises measures for inductive charging of the battery or accumulator.