FR3111274A1 - Air distribution device - Google Patents

Abstract

The invention relates to a one-piece air diffusion device (100) in an enclosure comprising a so-called internal volume (110) for air circulation between: an intake opening (112) for an air flow (FP), called primary flow, and a diffusion opening (114) for an air flow (FD), called diffused flow, in said enclosure; said device (100) further comprising at least one light source (130), called UV source, provided to emit ultraviolet (UV) radiation in the air flow within said internal volume (110). It also relates to an air diffusion installation implementing such an air diffusion device (100) Figure: Fig. 1

Description

Air diffusion device

The present invention relates to a device for diffusing air into an enclosure. It also relates to an air diffusion installation implementing such an air diffusion device.

The field of the invention is the field of air diffusion devices in an enclosure, and in particular the field of air diffusion devices installed in an enclosure such as a room, a bedroom, a cabin, a corridor , etc. within a building such as a detached house, a hospital, a school, a hotel, a reception establishment, and more broadly in any place welcoming people.

State of the art

There are currently many air diffusion devices in an enclosure. These devices are generally installed in a ceiling or in a wall of the enclosure and produce an air diffusion, in a horizontal direction or in a vertical direction within the enclosure.

These devices are, most of the time, connected to a fresh air distribution network, called primary air flow, and making it possible to diffuse this primary air flow supplied by said air distribution network in the enclosure , optionally after treatment of said primary air flow, for example to heat or cool it. Some of the air diffusion devices are also sized to create an induction effect allowing an air flow, called secondary air flow, coming from the enclosure to be taken up. This secondary airflow is mixed with the primary airflow, for example in the diffusion device, to form the diffused airflow in the room.

It seems necessary to treat the air flow diffused in the enclosure, before its diffusion, to reduce, or even eliminate, organisms that could be in said diffused air flow. Currently, this treatment is generally carried out using filters positioned in front of the diffused air flow so that the latter passes through it before being delivered into the enclosure.

However, this solution reduces the blowing performance of the air diffusion device, by causing a pressure drop in said air diffusion device. Indeed, the filter forms a physical obstacle that opposes the flow of air. In addition, this solution requires heavy maintenance requiring frequent cleaning or changing of the filters. In addition, this solution is not very effective, or even ineffective, against organisms such as viruses which are generally not filtered out due to their small size.

An object of the present invention is to remedy at least one of the aforementioned drawbacks.

Another object of the present invention is to propose a device for diffusing air into an enclosure making it possible to ensure better sanitation of the air diffused into said enclosure, in particular with regard to microorganisms such as viruses, fungi and bacteria.

Another object of the present invention is to propose a device for diffusing air into an enclosure making it possible to clean up the air diffused into the enclosure without impacting the blowing performance of said device.

Yet another object of the present invention is to propose a device for diffusing air into an enclosure making it possible to ensure sanitation of the air diffused into the enclosure, which is easier and less cumbersome to maintain.

• une ouverture d’admission d’un flux d’air, dit flux primaire, dans un volume interne (110) dudit dispositif, et
• une ouverture de diffusion d’un flux d’air, dit flux diffusé, depuis ledit volume interne vers ladite enceinte.

The invention makes it possible to achieve at least one of these goals by means of a one-piece air diffusion device in an enclosure, said device comprising:

• an opening for admitting an air flow, called primary flow, into an internal volume (110) of said device, and
• an opening for diffusing an air flow, called diffused flow, from said internal volume towards said enclosure.

The device according to the invention further comprises at least one light source, called UV source, provided to emit ultraviolet (UV) radiation within said internal volume.

Thus the air diffusion device according to the invention makes it possible to purify the flow of air circulating in the internal volume, and in particular the flow of air diffused in the enclosure, by emitting ultraviolet (UV) radiation in said airflow, within said device itself, before the airflow is diffused into the enclosure. The use of UV radiation makes it possible to better sanitize the air flow, in particular with regard to the elimination of viruses and microorganisms, which are not, or only slightly, eliminated with the devices of the state of the technique that uses filters.

In addition, the use of UV radiation makes it possible not to cause a pressure drop, compared to filters which would be placed in the air flow and which the air flow must cross. Thus, the invention makes it possible to purify the air diffused in an enclosure without degrading the blowing performance of the air diffusion device.

In addition, the use of UV radiation makes it possible to reduce the maintenance of the air diffusion device compared to devices using filters that must be cleaned and/or changed frequently.

In addition, the use of UV radiation makes it possible not to use chemicals to clean the air diffused in the enclosure, which makes it possible to better preserve the environment but also the health of the people in the enclosure. .

The air diffusion device according to the invention can be used to diffuse air in an enclosure such as a room, a bedroom, a cabin, a corridor, etc. within a building such as a private house, a hospital, a school, a hotel, a reception establishment for people, and more broadly in any place welcoming people, but also within a vehicle, such such as a land, rail, sea or air vehicle.

In particular, the at least one UV source makes it possible to create a curtain of UV light through which the primary air flow passes, and preferably the flow diffused in the enclosure.

More generally, the at least one UV source makes it possible to create a curtain of UV light through which the air flow circulating in the internal volume passes.

According to an advantageous embodiment, at least one UV source can be oriented so as to emit UV radiation in a direction different from that of the air flow in the internal volume.

In particular, at least one UV source can be oriented so as to emit UV radiation in a direction perpendicular to the direction of the air flow in the internal volume.

Such a characteristic makes it possible to emit UV radiation in the diffused air flow while ensuring that said UV radiation is contained in the internal volume of the device according to the invention and to limit, in particular to avoid, the diffusion of UV radiation. outside the air diffuser.

In addition, the fact of emitting the UV radiation in a direction different from that of the diffused air flow, and in particular in a direction perpendicular to the direction of the air flow, it is possible to treat a greater part of said diffused air flow. Indeed, it is then possible to create a kind of UV light curtain crossed by the diffused air flow.

In the direction of the airflow, the width of the UV light curtain can be adjusted according to sanitation needs, and in particular according to the flow rate, or speed, of the airflow.

According to an advantageous characteristic, at least one UV source can be arranged, in part or in whole, outside the internal volume of said device, and in particular in the thickness or outside an external envelope defining said internal volume.

In this case, the device according to the invention may comprise an opening allowing the passage of UV radiation emitted by the UV source into said internal volume.

Thus, it is possible to arrange the at least one UV source elsewhere than in the flow of air circulating in the internal volume, which makes it possible to prevent said UV source from forming a physical obstacle opposing the circulation of the air in the internal volume and does not cause a pressure drop in the device according to the invention. In addition, this makes it possible to facilitate the intervention on the UV source, since this intervention can then be carried out from the outside without having to access the internal volume of the device according to the invention.

Preferably, at least one, in particular each, UV source can be arranged on an external face of the device according to the invention opposite an opening allowing the passage of UV radiation into the internal volume.

According to an advantageous characteristic, at least one UV source can be arranged outside the internal volume of said device so that it does not protrude into said internal volume of said device.

Thus, the UV source does not constitute any obstacle to the circulation of the air flow in the internal volume.

Of course, alternatively or in addition, at least one UV source can be placed in the internal volume of the device according to the invention.

• l’ouverture de diffusion peut être prévue sur une face, dite avant, dudit dispositif, et
• l’ouverture d’admission peut être prévue sur une face, dite arrière, dudit dispositif, opposée à ladite face avant ;

au moins une source UV étant disposée sur une face latérale se trouvant entre lesdites faces avant et arrière.According to a non-limiting embodiment:

• the diffusion opening can be provided on a so-called front face of said device, and
• the inlet opening may be provided on a so-called rear face of said device, opposite to said front face;

at least one UV source being arranged on a side face located between said front and rear faces.

The front face may in particular correspond to the face directed towards the enclosure.

Such a configuration makes it possible to facilitate the architecture of the air diffusion device, in particular with regard to the UV source.

In particular, at least one UV source can be arranged on an upper side face of the device according to the invention, when it is installed in an enclosure, in a horizontal orientation.

According to an exemplary embodiment, the device according to the invention may comprise a single UV source.

Alternatively, the device according to the invention can comprise several UV sources.

• dans la direction de circulation du flux dans le volume interne entre les ouvertures d’admission et de diffusion, ou
• dans une direction perpendiculaire à ladite direction de circulation.

The UV sources can for example be arranged, aligned or not:

• in the direction of flow circulation in the internal volume between the inlet and outlet openings, or
• in a direction perpendicular to said direction of flow.

For example, the device according to the invention may comprise several UV sources arranged one behind the other in the direction of circulation of the air flow in the internal volume. Thus, the flow of air circulating in the internal volume passes through several UV rays, and in particular several curtains of UV light, before being blown into the enclosure.

Alternatively or more, the device according to the invention can comprise several UV sources arranged next to each other in the direction of circulation of the air flow in the internal volume. Thus, it is possible to ensure that the UV radiation is diffused to a large extent, within the internal volume of said device, in the directions perpendicular, or in the plane perpendicular, to the direction of circulation of the air flow in the internal volume. It is thus possible to ensure that most or all of the air flow circulating in the internal volume receives, or passes through, UV radiation.

According to a particularly advantageous characteristic, the device according to the invention may comprise, for at least one UV source, a surface absorbing UV radiation facing said UV source, in the direction of the UV radiation emitted by said UV source.

Such a surface makes it possible to absorb the UV radiation emitted by said UV source, after the latter has passed through the internal volume of the air diffusion device, and to reduce, or even avoid, a reflection of the UV radiation.

Such an absorbing surface can be positioned to receive most or all of the UV radiation emitted by said UV source.

Such an absorbent surface can preferably be positioned on the side of a face/wall opposite to that comprising the UV source emitting the UV radiation.

The absorbing surface may be formed by a UV absorbing material.

Carefully or additionally, the absorbing surface may be formed by a coating absorbing UV radiation, such as for example a dark colored paint such as black paint. In particular, the absorbent surface can be formed by a paint deposited on an internal face of the internal volume of the device according to the invention facing and opposite said UV source. Thus, the UV radiation emitted by said source forms a UV curtain through which the flux diffused in the room passes, and which is incident on the absorbent surface. The latter avoids, or at least reduces, the reflection of the UV curtain, which makes it possible to limit its diffusion outside the internal volume of the device according to the invention.

Advantageously, at least one UV source can be sized so as to emit UV radiation with a width greater than or equal to 80% of the width of the internal volume, in at least one, and in particular each, of the directions perpendicular to the direction of the flow. of air in the internal volume.

• au moins émetteur UV, et
• une paroi de fond réfléchissante, disposée derrière ledit au moins un émetteur UV, pour réfléchir le rayonnement UV vers ledit volume interne.

At least one UV source can comprise, seen from the internal volume of the device according to the invention:

• at least UV emitter, and
• a reflective bottom wall, arranged behind said at least one UV emitter, to reflect UV radiation towards said internal volume.

Such a feature makes it possible to direct a greater part of the UV radiation emitted by said at least one UV emitter into the internal volume, which makes it possible to achieve better sanitation of the air flow which receives, or must pass through, more UV radiation. concentrated and/or more potent.

• au moins émetteur UV, et
• une paroi de fond convexe, disposée derrière ledit au moins un émetteur UV, pour concentrer le rayonnement UV.

At least one UV source can comprise, seen from the internal volume of the device according to the invention:

• at least UV emitter, and
• a convex bottom wall, arranged behind said at least one UV emitter, to concentrate the UV radiation.

Such a feature makes it possible to direct a greater part of the UV radiation emitted by said at least one UV emitter into the internal volume, which makes it possible to achieve better sanitation of the air flow which receives more UV radiation, or UV radiation more powerful and/or more concentrated.

In addition, such a characteristic also makes it possible to concentrate the UV radiation in a given zone in the internal volume of the device according to the invention, and thus to reduce its propagation outside the internal volume of the device according to the invention.

• au moins émetteur UV, et
• un élément optique, disposé devant ledit au moins un émetteur UV, pour concentrer, et ou diriger, le rayonnement UV dans une direction donnée en vue de contenir ledit rayonnement UV dans le volume interne dudit dispositif.

At least one UV source may comprise, from the internal volume,

• at least UV emitter, and
• an optical element, arranged in front of said at least one UV emitter, for concentrating, and/or directing, UV radiation in a given direction in order to contain said UV radiation in the internal volume of said device.

Such an optical element makes it possible to better control the UV radiation emitted by the UV source and to better orient it in the internal volume of the device according to the invention, so as to avoid as much as possible, or even completely, that said UV radiation comes out of said internal volume.

In particular, the optical element can be an optical grid, or an optical labyrinth comprising a multitude of openings in the shape of a honeycomb.

The inventors have observed that such a grid comprising such openings in the shape of a honeycomb makes it possible to better contain the UV radiation in the internal volume of the device according to the invention, while optimizing the quantity of UV radiation which passes into said internal volume.

Of course, the grid can include openings of any other shape, such as longitudinal openings.

Advantageously, at least one UV source can be of variable power, making it possible to adjust the power of the UV radiation emitted.

The power of the UV radiation can be adjusted manually or automatically.

The power of the UV radiation can be adjusted according to at least one parameter such as the speed of the air flow, the flow rate of the air flow, the presence or absence of people in the enclosure, and/or a range schedule, etc.

According to a non-limiting embodiment, the device according to the invention may comprise between the inlet opening and the diffusion opening, at least one diffusion nozzle, through which the primary flow passes, and separating the internal volume into a first zone, called admission, comprising the admission opening and a second zone, called diffusion, comprising the diffusion opening.

In this case, at least one UV source can preferentially be positioned to emit UV radiation in said diffusion zone.

Thus, the UV treatment of the air flow is carried out in the diffusion zone. This makes it possible to treat the air flow diffused as late as possible in the internal volume, and in particular just before its diffusion into the enclosure, which allows better sanitation of the air flow blown into the enclosure.

According to a non-limiting exemplary embodiment, at least one diffusion nozzle may have a shape creating a venturi effect when it is crossed by the primary flow so as to promote the admission, through the diffusion opening, of a flow of air, called secondary flow, coming from the enclosure, said secondary flow mixing with the primary flow in the diffusion zone to form the diffused flow.

Thus, the diffusion nozzles creating a venturi effect make it possible to increase the speed of the air blown into the enclosure. This creates, by induction, an air intake through the diffusion opening, and an admission of the secondary air flow coming from the enclosure into the internal volume. This secondary air flow mixes with the primary to form the diffused air flow, it is therefore treated by the UV radiation emitted by the at least one UV source. Thus, the device according to the invention makes it possible to purify the air found in the room, by sucking it into the internal volume of the device according to the invention by induction effect and causing it to pass through UV radiation.

Moreover, when at least one UV source is arranged in the diffusion zone, then the air coming from the enclosure and forming the secondary air flow passes through the UV radiation, a first time when it is sucked into the internal volume and a second time when it is played in the speaker. Thus, the device according to the invention makes it possible to better sanitize the air located in the enclosure by having it pass through twice UV radiation, or a curtain of UV light.

• un réseau de distribution d’un flux d’air primaire, et
• au moins un dispositif de diffusion d’air selon l’invention, relie audit réseau de distribution.

According to another aspect of the same invention, there is proposed an air diffusion installation comprising:

• a primary air flow distribution network, and
• at least one air diffusion device according to the invention, connects to said distribution network.

The air distribution network can be formed by ducts connecting the or each air diffusion device to an air handling unit, or to an outside air intake opening/vent.

The installation according to the invention may comprise several air treatment devices. Each air distribution device can be associated with a room or enclosure. At least one enclosure may include one or more air diffusion devices.

The installation according to the invention may comprise a communication network, wired or not, making it possible to control each air diffusion device individually or in groups.

For example, the communication network can make it possible to switch off, switch on, or even modify the emission power of at least one UV source fitted to the device according to the invention.

Alternatively or in addition, the communication network can also be used to trace, for at least one UV source, data on the lifetime of said UV source, in particular to provide for its replacement.

Description of figures and embodiments

• les FIGURES 1a et 1b sont des représentations schématiques d’un exemple de réalisation non limitatif d’un dispositif de diffusion d’air dans une enceinte, respectivement selon une vue de coupe et selon une vue isométrique ;
• les FIGURES 2-4 sont des représentations schématiques d’autres exemples de réalisation non limitatifs d’un dispositif de diffusion d’air selon l’invention ; et
• la FIGURE 5 est une représentation schématique d’un exemple de réalisation non limitatif d’une installation de diffusion d’air selon l’invention.

Other advantages and characteristics will appear on examination of the detailed description of a non-limiting embodiment, and of the appended drawings in which:

• FIGURES 1a and 1b are schematic representations of a non-limiting embodiment of an air diffusion device in an enclosure, respectively in a cross-sectional view and in an isometric view;
• FIGURES 2-4 are schematic representations of other non-limiting embodiments of an air diffusion device according to the invention; And
• FIGURE 5 is a schematic representation of a non-limiting embodiment of an air diffusion installation according to the invention.

It is understood that the embodiments which will be described below are in no way limiting. In particular, variants of the invention may be imagined comprising only a selection of characteristics described below isolated from the other characteristics described, if this selection of characteristics is sufficient to confer a technical advantage or to differentiate the invention from other the prior state of the art. This selection includes at least one preferably functional feature without structural details, or with only part of the structural details if this part is only sufficient to confer a technical advantage or to differentiate the invention from the state of the prior art.

In the figures, the elements common to several figures retain the same reference.

FIGURES 1a and 1b are schematic representations of a non-limiting embodiment of an air diffusion device in an enclosure, respectively in a sectional view and in an isometric view

The device 100 represented in FIGURES 1a and 1b can be used to diffuse air in an enclosure such as a room, a bedroom, a cabin, a hallway, etc. within a building such as a private house, a hospital, a school, a hotel, a reception establishment for people, and more broadly in any place welcoming people, but also within a vehicle, for example a land, rail, sea or air vehicle.

The device 100 is in the form of a one-piece assembly, which in the non-limiting example shown in FIGURES 1a and 1 is parallelepipedic. Of course, the one-piece assembly can have any other shape, such as for example a cylindrical shape, a pyramidal shape, or even an L shape.

The device 100 comprises a face 102, called the rear face, a face 104, called the front face, opposite to the said rear face 102, as well as side faces 106 between the said front 104 and rear 102 faces. In particular, the device 100 comprises a upper face 106 ₁ , a lower face 106 ₂ , a right face 106 ₃ and a left face 106 ₄ . Of course, the expressions “upper”, “lower”, “left” and “right” used here do not imply any limitation as regards the architecture, nor the orientation of the device 100.

The device 100 comprises an outer casing 108 which delimits an internal volume 110.

The device 100 comprises, on its rear face 102, an opening 112 for admitting a flow of primary air FP, from outside or from an air distribution network, into the internal volume 110 of said device.

The device 100 comprises, on its front face 104, an opening 114 for the diffusion of an air flow FD, called diffused air flow, in an enclosure. As shown in the example of FIGURES 1a and 1b, the diffusion opening 114 can optionally be equipped with a grid 116 making it possible to adjust the diffusion direction of the diffused air flow FD.

In addition, still optionally, the device 100 may comprise, in the internal volume 110, a plate 120, separating said internal volume 110 into two zones: a first zone 122 on the side of the inlet opening 112 and a second zone 124 on the side of the diffusion opening 114. The separation plate 120 comprises diffusion nozzles 126 through which the primary air flow FP passes and which create a venturi effect increasing the speed of said flow FP when passing said plate of diffusion 120. These diffusion nozzles 126 make it possible to increase the diffusion speed of the diffused air flow FD in the enclosure and cause the admission into the internal volume 110, and in particular into the diffusion zone 124, by a induction effect, and through the diffusion opening 114, of an air flow FS, called secondary air flow, coming from the enclosure. This secondary air flow FS mixes with the primary air flow FP, after the latter has passed through the separation plate 120 through the nozzles 126, in the diffusion zone 124, at the level of the separation plate 120. Thus, in the example shown, and in no way limiting, the diffused air flow FD is formed by mixing the primary air flow FP with the secondary air flow FS.

It is understood that if the primary air flow FP, or the secondary air flow FS if necessary, contain viruses or microorganisms, the latter will be diffused in the enclosure with the diffused air flow FD, if they are not eliminated in the internal volume 110.

The air diffusion device according to the invention proposes to clean up the air flow diffused in the enclosure by eliminating, or at least reducing, the microorganisms in said diffused air flow FD, in the internal volume.

To do this, the air diffusion device 100 of FIGURES 1a and 1b comprises a light source 130, called UV source, emitting radiation, or light, UV 132, in the internal volume 110 of the air diffusion device .

UV source 130 includes one or more UV emitters 134 that emit UV light. In the example represented, the UV source 130 comprises a single UV emitter, which can for example be a neon.

Optionally, as seen in FIGURE 1a, the UV source comprises a bottom wall 136 of convex shape to direct the UV light emitted by the UV emitter 134, towards the internal volume 110 of the air diffusion device 100 .

Still optionally, the bottom wall 136 is reflective. To do this, the bottom wall 136 may have a reflective coating, for example in the form of a mirror coating or a reflective paint, etc.

According to an optional characteristic, the UV source 130 can comprise, in front of the UV emitter 134, an optical element 138 to contain and guide the UV light emitted by said UV emitter 134, in a desired direction. In the example represented, the optical element 138 is an aluminum grid comprising openings in the shape of a honeycomb, allowing the UV light emitted by the UV emitter 134 to pass.

To limit the diffusion of the UV rays emitted by the UV source 130, outside the internal volume 110, the device 100 further comprises a surface 140, absorbing the UV rays, arranged facing the UV source 130 in the direction of emission of the UV radiation 132. This absorbing surface 140 has the role of limiting the reflection of the UV rays emitted by the UV source 130 and of preventing these rays from being reflected on a wall of the internal volume 110 of the device 100 and leaving said internal volume 110.

In the example shown, and preferably, the UV source 130 is placed outside the internal volume 110 of the device so that it does not protrude into the internal volume 110. In particular, the UV source 130 is placed on the upper wall 106 ₁ , possibly partly in the thickness of said upper wall 106 ₁ . Thus, the UV source does not constitute any obstacle to the circulation of air in the internal volume 110 and does not cause any loss of pressure within said device 100. In addition, the maintenance of the UV source 130 can be done without having to access the internal volume 110.

According to an alternative, the UV source, or at least one UV source, can emerge, or be arranged, in the internal volume 110 of the device 100.

In addition, in the example represented, and preferably, the UV source 130 is arranged on the side of the diffusion opening 114, in particular in the diffusion zone 124. Thus, the UV light 132 emitted by the UV source 130 makes it possible to process both the diffused airflow FD but also the secondary airflow FS coming from the enclosure. According to an alternative, the UV source, or at least one UV source can be arranged elsewhere, for example on the side of the admission zone 122.

Furthermore, in the example represented, the device 100 comprises a single UV source 130. According to an alternative, the device 100 can comprise several UV sources.

FIGURE 2 is a schematic representation of another non-limiting embodiment of a device according to the invention.

Device 200 is shown in FIGURE 2 in a cross-sectional view.

Device 200 of FIGURE 2 includes all of the elements of device 100 of FIGURES 1a and 1b, but differs from said device 100 in the following.

Device 200 of FIGURE 2 further includes a second UV source 202, which may be different from, the same or similar to UV source 130.

The UV source 202 is arranged on the side of the diffusion opening 114, in particular at the level of the diffusion zone 122.

The UV sources 130 and 202 are arranged on the same wall, namely the upper wall 106 ₁ of the device 200 one behind the other in the direction of circulation of the air flow in the internal volume 110.

The use of a second UV source makes it possible to improve the sanitation of the air flow diffused in the room by increasing the UV light in the internal volume 110.

Like the UV source 130, the UV source 202 is arranged outside the internal volume 110 of the device 200 so that it does not protrude into the internal volume 110 of said device 200. In particular, the UV source 202 is arranged partly in the thickness of the upper wall 106 ₁ . Thus, the UV source 202 does not constitute any obstacle to the circulation of air and does not cause any loss of pressure within said device 100. In addition, the maintenance of the UV source 202 can be done without having to access the internal volume. 110.

FIGURE 3 is a schematic representation of another non-limiting embodiment of a device according to the invention.

Device 300 is shown in FIGURE 3 in cross-section.

Device 300 of FIGURE 3 includes all of the elements of device 200 of FIGURE 2, but differs from said device 200 in the following.

In the device 300 of FIGURE 3, unlike the device 200 of FIGURE 2, the second UV source 202 is arranged on the side of the lower wall 106 ₂ , opposite to the upper wall 106 ₁ on the side of which the source UV 130.

An absorbent surface 302 is arranged facing the second UV source 202 on the internal face of the upper wall 106 ₁ , on the side of which the UV source 130 is located.

FIGURE 4 is a schematic representation of another non-limiting embodiment of a device according to the invention.

The device 400 is represented in FIGURE 4 according to a front view, that is to say according to a side view of the front face 104.

Device 400 of FIGURE 4 includes all of the elements of device 300 of FIGURE 3, but differs from said device 300 in the following.

In the device 400 of FIGURE 4, unlike the device 300 of FIGURE 3, the second UV source 202 is arranged on the side of the left wall 106 ₄ , adjacent to the upper wall 106 ₁ , on the side of which find the source UV 130.

FIGURE 5 is a schematic representation of a non-limiting embodiment of an air diffusion installation according to the invention.

The installation 500, shown in FIGURE 5, comprises "n" air diffusion devices 502 ₁ -502 _n according to the invention. Each device 502 _i can for example be any one of the devices 100, 200, 300 or 400 described above, or any combination of at least two of these devices.

Each of the air diffusion devices 502 _i is connected to an air distribution network 504 which supplies said device 502 _i with a primary air flow, coming from a primary flow source 506, which can be a central air treatment or an outside air intake.

Each of the air diffusion devices 502 _i is also connected, through a communication network 508, wired or wireless, to a control module 510 of said air diffusion devices 502 ₁ -502 _n . The control module can be configured to control each of the air diffusion devices 502 ₁ -502 _n , and in particular at least one UV source of at least one of said air diffusion devices 502 ₁ -502 _n .

Of course, the invention is not limited to the examples detailed above.

For example, the device according to the invention may comprise at least one UV source on the side of the admission zone.

Alternatively or additionally, at least one UV source may comprise several emitters.

The device according to the invention may comprise a number of UV sources different from that given in the examples.

The device according to the invention can comprise a UV source whose architecture is different from that of the UV sources described in the examples.

Claims (15)

One-piece device (100; 200; 300; 400) for diffusing air into an enclosure, said device comprising:

• an inlet opening (112) for an air flow (FP), called primary flow, into an internal volume of said device, and
• a diffusion opening (114) for an air flow (FD), called diffused flow, from said internal volume towards said enclosure;

said device (100; 200; 300; 400) further comprising at least one light source (130; 202), called UV source, designed to emit ultraviolet (UV) radiation within said internal volume (110). Device (100; 200; 300; 400) according to the preceding claim, characterized in that at least one UV source (130; 202) is oriented so as to emit UV radiation in a direction perpendicular to the direction of the flow of air in the internal volume (110). Device (100; 200; 300; 400) according to any one of the preceding claims, characterized in that at least one UV source (130; 202) is arranged, in part or in whole, outside the internal volume (110) of said device (100;200;300;400), and in particular in the thickness or outside of an outer casing (108) defining said internal volume (110), said device (100;200;300;400 ) comprising an opening allowing the passage of UV radiation into said internal volume (110). Device (100;200;300;400) according to any one of the preceding claims, characterized in that:

• the diffusion opening (114) is provided on a face (104), called front, of said device (100; 200; 300; 400), and
• the inlet opening (112) is provided on a so-called rear face (102) of said device (100; 200; 300; 400), opposite to said front face (104);

at least one UV source (130; 202) being disposed on a side face (106₁;106_{4 )}lying between said front (104) and rear (102) faces. Device (200; 300; 400) according to any one of the preceding claims, characterized in that it comprises several UV sources (130; 202):

• in the direction of flow circulation in the internal volume (110) between the admission (112) and diffusion (114) openings, or
• in a direction perpendicular to said direction of flow.

Device (100; 200; 300; 400) according to any one of the preceding claims, characterized in that it comprises, for at least one UV source (130; 202), a surface (140; 302) absorbing UV radiation facing said UV source (130;202), in the direction of the UV radiation emitted by said UV source (130;202). Device (100; 200; 300; 400) according to any one of the preceding claims, characterized in that at least one UV source (130; 202) is dimensioned so as to emit UV radiation with a width greater than or equal to 80 % of the width of the internal volume (110), in each of the directions perpendicular to the direction of the air flow in the internal volume (110). Device (100;200;300;400) according to any one of the preceding claims, characterized in that at least one UV source (130;202) comprises, seen from the internal volume (110):

• at least UV emitter (134), and
• a reflective bottom wall (136), disposed behind said at least one UV emitter (134), to reflect UV radiation towards said internal volume (110).

Device (100;200;300;400) according to any one of the preceding claims, characterized in that at least one UV source (130;202) comprises, seen from the internal volume (110):

• at least one UV emitter (134), and
• a convex bottom wall (136), arranged behind said at least one UV emitter (134), to concentrate the UV radiation.

Device (100;200;300;400) according to any one of the preceding claims, characterized in that at least one UV source (130;202) comprises, seen from the internal volume (110):

• at least one UV emitter (134), and
• an optical element (138), arranged in front of said at least one UV emitter (134), for concentrating, and or directing, UV radiation in a given direction in order to contain said UV radiation in the internal volume (110) of said device ( 100;200;300;400).

Device (100;200;300;400) according to any one of the preceding claims, characterized in that the optical element is an optical grid (138), or an optical labyrinth comprising a multitude of openings in the form of a honeycomb 'bee. Device (100; 200; 300; 400) according to any one of the preceding claims, characterized in that at least one UV source (130; 202) is of variable power making it possible to adjust the power of the UV radiation emitted. Device (100; 200; 300; 400) according to any one of the preceding claims, characterized in that it comprises between the inlet opening (112) and the diffusion opening (114), at least one nozzle diffusion (126), traversed by the primary flow (FP), and separating the internal volume (110) into a first zone (122), called admission, comprising the admission opening (112) and a second zone (124), called diffusion, comprising the diffusion opening (114), at least one UV source (130; 202) being positioned to emit UV radiation in said diffusion zone (124). Device (100; 200; 300; 400) according to any one of the preceding claims, characterized in that at least one nozzle (126) has a shape creating a venturi effect when it is crossed by the primary flow (FP) so as to promote the admission, through the diffusion opening (114), of an air flow (FS), called secondary flow, coming from the enclosure, said secondary flow (FS) mixing with the primary flow (FP) in the diffusion zone (124) to form the diffused flux (FD). Air diffusion installation (500) comprising:

• a network (504) for distributing a primary air flow (FP), and
• at least one air diffusion device (100;200;300;400;502 ₁ -502 _n ) according to any one of the preceding claims connected to said distribution network (504).