EP4242544A1 - Air diffuser capable of generating comfort bubble - Google Patents

Abstract

An air diffuser having a grille (45).

The grille comprises a central zone (46) formed by a suction opening, and a peripheral zone (47) extending from the central zone and comprising blowing openings (48).

In the peripheral zone, the porosity is substantially uniform, between 15% and 60%.

The grille is adapted to simultaneously allow blown air, in a first direction, to pass through the blowing openings, and sucked air, in a second direction opposite the first direction, through the suction opening.

The invention also relates to an air treatment and/or conditioning system comprising such a grid and to a use of such a system to form an air quality treated and/or conditioned atmosphere in a reduced space.

Description

Technical area

This disclosure relates to the field of thermal comfort and air quality.

More particularly, the present disclosure relates to an air diffuser, to an air conditioning and/or treatment system comprising such a diffuser and to a use of such a system for the conditioning and/or treatment of air. 'air.

Prior art

Commonly, in the field of thermal comfort, there are well-tested technical solutions for heating workstations. The most used for localized heating is by radiation through infrared radiants. These devices are limited to heating only.

Air-displacement air conditioning solutions are also known, which avoid air-conditioning the entire volume of a room, by having an action restricted to the occupancy volume (0 to 2 m in height in general). These solutions are particularly interesting for high-rise premises. But for large industrial premises (several thousand ^m2 ), air conditioning by displacement ultimately requires very high power, whereas in many cases there are only a few operators located on a few dozen workstations scattered throughout the area. the entire industrial premises.

• " Thermal and dynamic study of a new concept of HVAC system using an annular air jet", F. Penot, Ph. Meyer, Air Distribution in Rooms: Ventilation for Health and sustainable environment, H.B. Awbi, Elsevier, 2000, vol. 1, p 657-662 ,
• "Experimental Study of Non-Isothermal Diverging Swirling and Non-Swirling Annular Jets with Central Aspiration", F. Penot, M. D. Pavlović, International Journal of Ventilation, 2010, vol. 8, n°4, p347-357.

The theoretical aspects for generating an air-conditioned environment around a person have been the subject of various publications, in particular:

• " Thermal and dynamic study of a new concept of HVAC system using an annular air jet", F. Penot, Ph. Meyer, Air Distribution in Rooms: Ventilation for Health and sustainable environment, HB Awbi, Elsevier, 2000, vol. 1, p 657-662 ,
• “Experimental Study of Non-Isothermal Diverging Swirling and Non-Swirling Annular Jets with Central Aspiration”, F. Penot, MD Pavlović, International Journal of Ventilation, 2010, vol. 8, n°4, p347-357.

The French patent FR2799534B1 describes a solution for producing and distributing cold air. This solution ultimately did not result in a finalized and marketed device, because the production of hot and cold required a complex heat exchanger to create mixing cold and hot water near an electrical source.

There is a need for a device capable of going beyond just air conditioning, that is to say capable, depending on the needs, of heating or cooling and/or improving the quality of the air in a reduced volume , for example of the order of a cubic meter, around a person.

This problem of heating, air conditioning and air quality limited to a reduced volume is well known: it is a challenge of the energy transition and the control of energy consumption.

Summary

This disclosure improves the situation.

• une zone périphérique s'étendant à partir de la zone centrale, la zone périphérique comprenant une pluralité d'ouvertures de soufflage,
• la grille ayant, dans la zone périphérique, une porosité sensiblement uniforme, comprise entre 15% et 60%, de préférence entre 20% et 40%, plus préférentiellement entre 25% et 35%,
• la grille étant adaptée pour laisser simultanément passer un air soufflé, dans une première direction, à travers la pluralité d'ouvertures de soufflage, et un air aspiré, dans une deuxième direction opposée à la première direction, à travers l'ouverture d'aspiration.

An air diffuser is proposed comprising a grille, the grille comprising: a central zone formed by a suction opening, and

• a peripheral zone extending from the central zone, the peripheral zone comprising a plurality of blowing openings,
• the grid having, in the peripheral zone, a substantially uniform porosity, of between 15% and 60%, preferably between 20% and 40%, more preferably between 25% and 35%,
• the grille being adapted to simultaneously allow blown air, in a first direction, to pass through the plurality of blowing openings, and sucked air, in a second direction opposite the first direction, through the suction opening .

Due to the specific configuration of the grille, the air diffuser creates a comfort bubble where the blown air circulating in the first direction is air supplied to the comfort bubble, and where the sucked air circulating in the second direction is air evacuated from the comfort bubble.

As a result, the air diffuser is capable, depending on needs, of renewing the air in a reduced volume, for example of the order of a cubic meter, around a person with heated or cooled air, treated or untreated in air quality.

The porosity of the grid provides a uniform flow of the blown air leaving the blowing openings, independently of the temperature and quality of the blown air.

This uniform flow makes it possible to regulate the temperature and air speed in the comfort bubble in order to prevent the flow of blown air from locally reaching excessive temperatures and speeds, incompatible with the comfort of the person.

• un tel diffuseur d'air,
• un dispositif de soufflage d'air, configuré pour entretenir une circulation de l'air soufflé dans la première direction, et un dispositif d'aspiration d'air raccordé à l'ouverture d'aspiration, configuré pour entretenir une circulation de l'air aspiré dans la deuxième direction.

An air treatment and/or conditioning system is also proposed comprising:

• such an air diffuser,
• an air blowing device, configured to maintain circulation of the blown air in the first direction, and an air suction device connected to the suction opening, configured to maintain circulation of the air sucked in the second direction.

Thanks to the specific configuration of the air diffuser, the proposed system solves the problem of ensuring, depending on needs, heating or air conditioning and/or improved air quality in a reduced volume for controlled energy output.

Such a system may for example comprise an air/air heat pump as an air blowing device and as an air suction device.

It is also proposed to use such a system to form an air quality treated and/or conditioned atmosphere in a small space, in particular around a person.

The air diffuser above may optionally include certain additional functions as defined below.

For example, the grid can be quadrangular, for example square.

Such a shape, applicable to the grille as well as to the air diffuser as a whole, is compatible with the comfort requirements within the comfort bubble and also has the advantage of simplicity of manufacture.

For example, the grid can have a dimension of between 50 cm and 150 cm, preferably between 70 cm and 90 cm.

Such dimensions are suitable for ensuring the comfort of a person.

For example, the peripheral zone can be subdivided, relative to the central zone, into a proximal subzone and a distal subzone, the porosity of the grid in the proximal subzone being greater than the porosity of the grid in the distal subzone.

Increasing the porosity in the proximal sub-zone serves the objective of achieving homogenization of blown air over the entire grid, including the central zone. The central zone being occupied by an suction opening and not a blowing opening, the flow of air blown through the central zone is zero. Increasing the porosity in the proximal subzone makes it possible to compensate for this lack of flow through the central zone, by ensuring a faster flow of blown air near the center of the grid than at the edges of the grid.

For example, the peripheral area of the grid may include a center of symmetry.

This makes it possible to homogenize the flow of the blown air around the edge of the comfort bubble.

• la face inférieure comprenant, en bordure, une fente de soufflage,
• la face inférieure comprenant une fente d'aspiration circonscrite par la fente de soufflage,
• la fente de soufflage étant raccordée à la pluralité d'ouvertures de soufflage de manière à former, dans l'espace interne inférieur, un passage inférieur d'air soufflé,
• la fente d'aspiration étant raccordée à l'ouverture d'aspiration de manière à former, dans l'espace interne inférieur, un passage d'air aspiré cloisonné du passage inférieur d'air soufflé.

For example, the grid can be arranged, in the air diffuser, so as to delimit a border between an upper internal space and a lower internal space extending to a lower face,

• the lower face comprising, at the edge, a blowing slot,
• the lower face comprising a suction slot circumscribed by the blowing slot,
• the blowing slot being connected to the plurality of blowing openings so as to form, in the lower internal space, a lower blown air passage,
• the suction slot being connected to the suction opening so as to form, in the lower internal space, a suction air passage partitioned from the lower blown air passage.

The specific configuration of the lower internal space makes it possible to delimit the comfort bubble using a curtain of blown air, forming an immaterial barrier, coming from the blowing slot, while ensuring an air return from inside the comfort bubble, this air intake being compatible with comfort requirements, through the suction slot.

For example, the upper internal space may extend inside a housing comprising two opposite blowing vents connected to the plurality of blowing openings so as to form, in the upper internal space, an upper passage of blown air.

Opposing the blowing vents makes it possible to partially homogenize the flow of the blown air even before it passes through the blowing openings.

Brief description of the drawings

• Fig. 1
  [Fig. 1] illustre un système de conditionnement et/ou de traitement d'air dans un exemple de réalisation.
• Fig. 2
  [Fig. 2] représente schématiquement un circuit de conditionnement et/ou de traitement d'air recyclé dans un exemple de réalisation.
• Fig. 3
  [Fig. 3] représente schématiquement un circuit de renouvellement d'air, dans un exemple de réalisation.
• Fig. 4
  [Fig. 4] illustre une partie supérieure d'un diffuseur d'air dans un exemple de réalisation.
• Fig. 5
  [Fig. 5] illustre une grille pouvant être intégrée au diffuseur d'air de la figure 4.
• Fig. 6
  [Fig. 6] illustre une division en quadrants de la zone périphérique grille de la figure 5 dans un exemple de réalisation.
• Fig. 7
  [Fig. 7] illustre une division en sous-zones de la zone périphérique de la grille de la figure 5 dans un exemple de réalisation.
• Fig. 8
  [Fig. 8] illustre une partie inférieure d'un diffuseur d'air dans un exemple de réalisation.

Other characteristics, details and advantages will appear on reading the detailed description below, and on analyzing the appended drawings, in which:

• Fig. 1
  [ Fig. 1 ] illustrates an air conditioning and/or treatment system in an exemplary embodiment.
• Fig . 2
  [ Fig. 2 ] schematically represents a recycled air conditioning and/or treatment circuit in an exemplary embodiment.
• Fig. 3
  [ Fig. 3 ] schematically represents an air renewal circuit, in an exemplary embodiment.
• Fig. 4
  [ Fig. 4 ] illustrates an upper part of an air diffuser in an exemplary embodiment.
• Fig. 5
  [ Fig. 5 ] illustrates a grille that can be integrated into the air diffuser of the Figure 4 .
• Fig. 6
  [ Fig. 6 ] illustrates a division into quadrants of the peripheral grid area of the Figure 5 in an exemplary embodiment.
• Fig. 7
  [ Fig. 7 ] illustrates a division into sub-zones of the peripheral zone of the grid of the figure 5 in an exemplary embodiment.
• Fig. 8
  [ Fig. 8 ] illustrates a lower part of an air diffuser in an exemplary embodiment.

Description of embodiments

The drawings and description may not only be used to better understand this disclosure, but also contribute to its definition, if necessary.

The general principle of the invention is based on the inexpensive association of a conventional residential air/air heat pump (PAC) with an air diffuser adapted both to blow hot air and cold air, recycled air, fresh air or a mixture of both.

The ingenuity of the invention lies at the level of the air diffuser, which includes both means of spatial homogenization of an air flow coming from the heat pump and means of air return. Together, these means help to create under the air diffuser, that is to say around for example a person located under the air diffuser, a bubble of comfort, in the form of an environment of of the order of one or two cubic meters which is comfortable in terms of heating, air conditioning, and/or air quality.

• une vitesse d'air inférieure ou égale à 0,3 m/s,
• une température comprise entre 19°C et 25°C en toute saison, et
• une dépollution de l'air ambiant, relativement à au moins un polluant donné, d'au moins 10% et de préférence d'au moins 20%.

By comfortable environment we mean an environment meeting one or more of the following comfort criteria:

• an air speed less than or equal to 0.3 m/s,
• a temperature between 19°C and 25°C in all seasons, and
• depollution of ambient air, relative to at least one given pollutant, of at least 10% and preferably of at least 20%.

The invention finds numerous applications in particular in the field of indoor or outdoor air treatment and conditioning in low-wind conditions, in an industrial, tertiary or residential environment for example.

In particular, the structure of the diffuser gives it a compactness compatible with industrial constraints, the heat pump being able in particular to be housed above the diffuser.

The entire air conditioning or air quality system combining the diffuser with a heat pump can be mounted on mobile supports on casters, which allows the comfort bubble to be easily moved.

Such a system is also both simple to put into operation for a user and autonomous in this operation, requiring only a simple connection to an ordinary power outlet.

Furthermore, the total cost of such a system remains under control, because the diffuser is compatible with any air/air heat pump typically found in the residential market.

In the remainder of the description, we attempt to describe in detail an example of implementation of the invention.

We now refer to the figure 1 , which illustrates an air conditioning and/or treatment system. The system comprises a conventional air/air heat pump, having an indoor unit 1 and an outdoor unit 2, connected by a refrigerant connection 3. Connection 3 is typically flexible.

The system also includes an air diffuser 4 connected to the heat pump. The dimensions of the air diffuser are linked to those of the atmosphere to be created around the person. These dimensions are chosen by a compromise between the heating or cooling power required and the needs of the person. An air diffuser with a surface area of the order of magnitude of one square meter, for example a square air diffuser, with a length and width of approximately 1.5 m, is suitable for most static activities . The other characteristics and arrangement of the diffuser are detailed below.

There figure 1 represents the air diffuser mounted, with the indoor unit of the heat pump, on a support 5 positioned at height, above a space suitable for one person. The support 5 is optionally mounted on casters 6, for example on locking casters. Optionally, the height of the support 5 is adjustable depending on the size of the person and their posture, for example in a standing or sitting position. The exterior unit of the heat pump can be mounted on a separate support 7, also optionally mounted on casters 8, for example on locking casters.

Regarding air conditioning, a heat pump can be reversible or non-reversible. An activatable functionality common to reversible and non-reversible heat pumps is to allow heating of the air in the vicinity of the indoor unit. This involves capturing energy through the outdoor unit to disseminate it by rejecting heated air at the indoor unit. Only reversible heat pumps can also be used as air conditioners. To do this, they absorb energy through the indoor unit and radiate it to the outdoor unit. By this means, a reversible heat pump is able to reject cooled air at the indoor unit and provide a drop in temperature. The heating or air conditioning power is typically of the order of kW, and is optionally adjustable.

The heat pump comprises at least one suction air inlet and at least one, for example two, blown air outlets. Commercially available heat pumps already include means of activating the conditioned air. The suction and blowing of air can, for example and in a known manner, be obtained passively, or on the contrary actively by means of fans. which can optionally be activated alone, independently of the heating or cooling function of the heat pump.

The system may also include, upstream, downstream or within the heat pump, one or more air treatment devices. For example, an air filtration device may be provided, such as a G3, G4, M5, M6, F7, F8, F9, EPA, HEPA, ULPA or ISO ePM1, ISO ePM2.5 or ISO ePM10 filter. . A bactericidal and/or germicidal or other device may also be provided, such as a UV-C light source which can be activated so as to disinfect the air to be injected. Generally speaking, the system as a whole is capable of conditioning and/or treating a flow of air to be diffused around a person, this air flow passing through the heat pump and any type of air treatment device. intended air.

There figure 2 shows an implementation of such a system for conditioning and/or treating a recycled air flow. The air circulation between the indoor unit 1 of the heat pump and the air diffuser 4 takes place in two branches. The first branch 10 corresponds to the circulation of air extracted at the level of the air diffuser from an environment with a volume of the order of one or two cubic meters, around a person. This extracted, recycled air is then conditioned in the indoor unit 1 of the heat pump. This extracted air can also be treated as air quality upstream or downstream of its conditioning. The second branch 11 corresponds to the circulation of the air thus conditioned, and optionally treated in air quality, towards the air diffuser 4 with a view to its diffusion into the person's environment. In this implementation, the system causes only little incoming circulation of air coming from outside the system towards the person's environment, and only little outgoing circulation of air coming from the person's environment towards outside the system.

There Figure 3 shows another implementation of such a system supplied with all fresh air. Air circulation occurs in three branches. The first branch 12 brings air coming entirely from outside the system (for example outside air) to the indoor unit 1 of the heat pump. This air is conditioned and/or treated to air quality then transported, by the second branch 13, to the air diffuser 4 where it is diffused into the person's environment. The third branch 14 transports a flow of air extracted by the air diffuser 4 from the person's environment in order to reject it outside the system (for example with an additional extractor). Optionally, the air can undergo additional treatment before its blowing and before its rejection. The implementation according to Figure 3 allows the air around the person to be continually renewed, which is particularly interesting in a context where they have to stay temporarily in a potentially polluted interior space.

An example of a structure suitable for a diffuser usable both in heating and in air conditioning, and also in the implementation of the figure 2 and in that of the Figure 3 , is now detailed.

In this example, the diffuser comprises a housing 40 in which a grid is mounted, for example in a substantially horizontal position. The grid is for example metallic. The thickness of the grid can for example be of the order of a few millimeters. The grid rests for example at the bottom of the case, or a few millimeters or centimeters above the bottom of the case, or can constitute the underside of the case. The grid delimits, within the air diffuser, an upper internal space which represents all or part of the internal space of the housing, and a lower internal space.

An example of a structure suitable for forming the upper internal space of the air diffuser is shown on the Figure 4 .

In this example, the upper internal space 401 of the air diffuser is delimited by an upper internal wall of the housing, by internal side walls of the housing and by an upper wall of the grille.

A side face of the housing 40 is crossed, above the grid, by a suction mouth 41. This suction mouth is connected, on one side, to the internal unit of the heat pump and the the other side has a central through opening 42 arranged in the grid. This configuration is particularly interesting for the conditioning of low-height premises because it makes it possible to limit the total height of the assembly formed by the diffuser and the indoor unit of the heat pump to below one meter when it is located above above the diffuser. Another configuration where the suction mouth would pass through not a side face but the upper face of the housing is not strictly excluded, but it has the disadvantage of less compactness in height. However, it is desirable to be able to use the system in low-height premises.

Advantageously, the housing and/or the air diffuser as a whole is of parallelepiped shape. When the housing is metallic, such a shape is particularly easy to achieve without cutting, by simple folding of metal sheets combined with welding, unlike a cylindrical or conical shape. The grid is similar in shape to that of the lower face of the housing, that is to say in this case quadrangular, for example square.

At least one additional opening 43 is provided, in the upper internal space of the air diffuser, through one face of the housing. This additional opening is an inlet of conditioned air and/or treated air quality from the heat pump. This air, blown, is intended to be supplied, via openings arranged in a peripheral zone of the grille, in the lower internal space of the air diffuser, then in the environment of the person located under the air diffuser .

Thus, in the upper internal space of the air diffuser, the internal wall of the suction mouth 41 forms an upper passage of air sucked through the opening of the central zone of the grille, and the internal walls of the housing form, together with the external wall of the suction mouth, an upper passage of air blown through the openings in the peripheral zone of the grille. These passages are therefore partitioned from each other.

For the already specified reason of vertical compactness of the system, it is desirable that this additional opening be arranged not in the upper face but in a side face of the housing. However, for the blown air to create an atmosphere that meets the comfort criterion in terms of temperature and air speed, it is also imperative that the diffuser provides means of homogenizing the flow of blown air. An example of such a means is to provide not just one but two additional opposite openings 43, 44.

Numerical simulations have confirmed that two air flows arriving through two additional opposite openings arranged in the side faces of a square section housing mix to form a partially homogenized air flow. Homogenization would hardly be satisfactory due to the sole presence of these two opposite blowing openings. One reason is that the upper internal space of the air diffuser is not empty but includes, at least, a portion of the suction mouth.

Another possibility is to provide one or more internal walls of the housing, in the upper internal space 401 of the air diffuser, so as to guide, and thus help to homogenize, the air flow(s) arriving through the(s) additional openings.

The possibility mainly retained by the inventors was to structurally optimize the grid, by validating this optimization by 3D digital simulations of fluid mechanics and by thermal tests in the laboratory. More particularly, the number of openings arranged in the peripheral zone has been optimized as well as their diameter and their position, in order to homogenize at least one flow of blown air as it passes from the upper internal space of the diffuser. air towards the lower internal space of the air diffuser.

Reference is now made to an example of a structure suitable for the grid, as shown in top view on the Figure 5 .

The grille 45 includes a central zone 46 which coincides with the central through opening for the suction of air from the person's environment. The grid also includes, around the central zone, a peripheral zone 47 in which a plurality of openings 48 are arranged.

In this particular example, the grid is square, its central area is circular and has a diameter equal to approximately a quarter of the side of the grid. Generally speaking, the absolute and relative dimensions of the central zone and the peripheral zone are chosen according to a comfort criterion for a given suction flow rate and a given blowing flow rate.

The porosity of the peripheral zone of the grid, defined as the ratio of the total surface area of the openings 48 which are arranged in the peripheral zone over the total surface of the peripheral zone, is substantially uniform and between 15% and 60%, preferably between 20% and 40%, more preferably between 25% and 35%.

The notion of uniformity of porosity is now defined by reference to figures 6 And 7 : this uniformity can be considered relative to an angular coordinate and/or relative to a radial coordinate.

There Figure 6 corresponds to the grid of the Figure 5 whose peripheral zone is divided into quadrants 50, 51, 52, 53 whose borders are materialized by two axes 54, 55. Generally speaking, the porosity of the peripheral zone of the grid is said to be substantially uniform relative to an angular coordinate, the absolute difference in porosity from one quadrant to another is less than 15%, preferably less than 10%, more preferably less than 5%. In this case, in the example of the Figure 6 , the boundaries of the quadrants are also axes of symmetry of the grid, the quadrants are therefore identical and have the same porosity.

• d3 désigne le rayon du cercle inscrit à la grille, et
• d3-d2 = d2-d1 = d1-d0,
• où d0 désigne le rayon d'un cercle C0, concentrique aux cercles C1, C2 et C3, englobant la zone centrale et tangent intérieurement à la zone centrale.

There Figure 7 corresponds to the grid of the Figure 5 whose peripheral zone is divided into four sub-zones like Russian dolls or the layers of an onion. The borders of these sub-zones are materialized by three concentric circles C1, C2, C3 of respective radii d1, d2 and d3, such that:

• d3 designates the radius of the circle inscribed on the grid, and
• d3-d2 = d2-d1 = d1-d0,
• where d0 designates the radius of a circle C0, concentric with circles C1, C2 and C3, encompassing the central zone and tangent internally to the central zone.

Three sub-zones thus have the shape of concentric rings of the same width named relative to the central opening. The first subzone or proximal ring 56 is delimited by the circles C0 and C1, the second subzone or intermediate ring 57 is delimited by the circles C1 and C2 and the third subzone or distal ring 58 is delimited by the circles C2 and C3. Finally, in this example where the grid is not circular, a fourth sub-zone 59 is delimited, on one side, by the circle C3 and on the other side by the edges, in this case square, of the grid.

The porosity of the grid is said to be substantially homogeneous relative to a radial coordinate when at least two of the four sub-zones considered, preferably at least three of the four sub-zones considered, and more preferably the four sub-zones considered, each have a porosity included in an interval whose lower limit is greater than or equal to 15% and whose upper limit is less than or equal to 60%. The lower limit of this interval is preferably greater than or equal to 20% and more preferably greater than or equal to 25%. The upper limit of this interval is preferably less than or equal to 40% and more preferably less than or equal to 35%.

Optionally, the porosity can be chosen higher in the proximal ring than in the other three sub-zones, while remaining within the limits specified previously, in order to compensate for the imposed absence of a blow opening in the central area.

Grid dimensions are now provided as specific examples of absolute and relative dimensions suitable for providing uniform flow of supply air combined with suction of air from the person's surroundings.

The dimension of the grid can be chosen for example between 500 and 1500 mm, and taken for example equal to 800 mm. The relative dimension of the suction opening compared to that of the grid can be chosen for example in a range of 20% to 30%, and the absolute dimension of the suction opening can for example be equal to 200 mm. The dimension of the blowing openings can be common or conversely different from one blowing opening to another: such a dimension can be chosen between 20 and 50 mm and can for example be taken equal to 30 mm. The minimum distance between any two adjacent blow openings can be chosen greater than or equal to 10 mm, for example greater than or equal to 20 mm. The maximum distance between any two adjacent blow openings can be chosen less than or equal to 50 mm, for example less than or equal to 40 mm. The distance between the edge of the grille and the nearest blow openings can be chosen greater than or equal to 8 mm. The distance between the central zone and the openings nearest blowing pipes can be chosen greater than or equal to 20 mm, for example greater than or equal to 30 mm. The number of blowing openings can be chosen greater than or equal to 50, for example greater than or equal to 100, for example greater than or equal to 150, for example greater than or equal to 180, and less than or equal to 300, for example less or equal to 250, for example less than or equal to 200.

Reference is now made to an example of a structure suitable for forming the lower space 402 of the air diffuser, as illustrated in the figure 8 .

The lower space extends from the grid, shown here in side view, with the central zone 46 corresponding to the central suction opening and the peripheral zone 47 corresponding to the blowing openings.

In the lower space, a suction air passage, shown on the figure 8 by a hatched pattern, connects the central zone 46 of the grid to a suction slot 66. Still in the lower space, a blown air passage, which forms a blowing mouth and is shown on the figure 8 by a dotted pattern, connects the peripheral zone 47 of the grid to a blowing slot 67. These air passages are partitioned from each other.

As already indicated, the structure of the peripheral zone 47 of the grid has the effect of homogenizing the blown air in the blown air passage.

The blowing slot 67 is a peripheral slot of the air diffuser. The blowing slot follows a first closed line which may be of any shape, for example round, oval or square, along the edge of the underside of the air diffuser. Thus, the air flow blown by the blower creates a curtain of air from top to bottom which delimits a bubble of comfort around the person located under the air diffuser. In a circuit supplied with all fresh air, such an air curtain also constitutes a sort of immaterial barrier against possible pollutants. The width of the blowing slot is chosen according to a target flow rate of blown air and a target speed of the air in the air curtain.

The suction slot 66 is a slot which also extends around the periphery of the lower face of the air diffuser, following a second closed line located inside the area delimited by the first closed line. The passage of sucked air thus creates an air flow from the bottom to the top of the comfort bubble which is delimited by the blowing air curtain. The size, shape, relative position and width of the suction and blowing slots were validated by 3D fluid mechanics simulations and laboratory thermal tests. These simulations and tests revealed in particular that, for reasons of comfort, it was preferable to offset the suction slot towards the periphery rather than in the center of the lower face of the air diffuser. In other words, it is desirable to maximize the area delimited by the second closed line followed by the suction slot.

• la face inférieure du diffuseur d'air peut être de forme carrée avec un bord de longueur d'environ 1,5 m,
• la fente de soufflage peut être elle aussi de forme carrée, le long des bords de la face inférieure du diffuseur d'air et de largeur comprise entre 8 et 15 mm, par exemple 11 mm, et
• la fente d'aspiration peut s'étendre autour d'une ligne fermée ayant la forme d'un carré de côté d'environ 1,3 m, 1,4 m ou plus et de largeur comprise entre 30 et 60 mm, par exemple 40 mm.

As examples of dimensions,

• the underside of the air diffuser can be square in shape with an edge length of approximately 1.5 m,
• the blowing slot can also be square in shape, along the edges of the lower face of the air diffuser and of width between 8 and 15 mm, for example 11 mm, and
• the suction slot can extend around a closed line having the shape of a square with a side of approximately 1.3 m, 1.4 m or more and a width of between 30 and 60 mm, for example 40mm.

It has also been revealed that it is preferable for the width of the suction slot to be greater than that of the blowing slot, for essentially two reasons. One of these reasons is that the air speed at the person under the air diffuser is the speed of the air flow being drawn in. Therefore, the wider the suction slot, the more it is possible to obtain a significant flow of sucked air without requiring a significant air speed at the person's level, which contributes to the comfort provided. The other reason is that at equal power and equal slot width, the efficiency of suction is less than that of blowing. Providing a suction slot wider than the blowing slot is therefore desirable to balance the flow of air blown towards the person's environment with the flow of air sucked in from the person's environment.

The performance of the air diffuser was qualified when combined with a commercially available reversible air/air heat pump, of the built-in mono split type, with 1 kW of power. Such a heat pump only requires a socket conventional electric for its operation and, in this example, also includes means for moving the conditioned air and filtration means which make it possible to improve the quality of the conditioned air.

In this example, the heat pump is also equipped with two blower vents and a suction vent, these vents each being covered with an aluminum sheath which is insulated. The air/air heat pump is connected, via the suction port, to the suction opening in the upper part of the air diffuser. The air/air heat pump is also connected, via the two blower vents, to two additional opposite openings of the air diffuser.

A temperature measuring probe is positioned in return from the air diffuser, more specifically at a height corresponding to an expected position of a person's head under the air diffuser, so that the heat pump regulates its operation on the air felt in the vicinity of the person's head, the head being the most sensitive part of the body with regard to thermal discomfort.

The system thus described, comprising the air/air heat pump combined with the diffuser, is therefore an integrated and ready-to-use air conditioning and treatment system.

The measured air flow speeds within the comfort bubble do not exceed 0.3 m/s, whatever the use, that is to say in air treatment alone or combined with heating or cooling.

A cooling of up to 4°C could be obtained at the level of the head of a person located under the air diffuser, and up to 2.5°C at the level of the body.

In heating, the measured values are closer to 3°C for the head and 1.5°C for the body. It is envisaged, based on this example, to further improve the heating performance by adding a heating mat and/or by adding a radiant heating device. Such additions are advantageous with a view to use in particularly cold premises.

The depollution of the air in the person's environment, in a circuit supplied with all fresh air, was evaluated by modeling considering gaseous ethanol as the pollutant.

When the heat pump is used exclusively as a means of renewing air in the comfort bubble with air treated in air quality, without adding an activated heating or air conditioning function, air depollution in the comfort bubble is of the order of 25% at the level of the person's head, 24% at the level of the bust, and 21% at the level of the legs. When the heat pump is also used as a means of air conditioning, these values are unchanged. When the heat pump is used, on the other hand, as a means of heating, the depollution of the air in the comfort bubble is slightly lower, of the order of 20% at the level of the person's head, 15% at level of the bust, and 6% at the level of the legs. Regarding air quality, it is understood that the most relevant values thus calculated are those obtained at head level.

When the air conditioning and treatment system is applied to the heating of isolated workstations within a building, energy savings can be up to 75% compared to known overall building heating systems ( for the entire volume).

Claims (10)

Air diffuser comprising a grid (45), the grid comprising: a central zone (46) formed by a suction opening, and a peripheral zone (47) extending from the central zone, the peripheral zone comprising a plurality of blowing openings (48), the grid having, in the peripheral zone, a substantially uniform porosity, of between 15% and 60%, preferably between 20% and 40%, more preferably between 25% and 35%, the grille being adapted to simultaneously allow blown air, in a first direction, to pass through the plurality of blowing openings, and sucked air, in a second direction opposite the first direction, through the suction opening . Air diffuser according to claim 1, in which the grid is quadrangular, for example square. Air diffuser according to claim 1 or 2, in which the grille has a dimension of between 50 cm and 150 cm, preferably between 70 cm and 90 cm. Air diffuser according to one of claims 1 to 3, in which the peripheral zone is subdivided, relative to the central zone, into a proximal sub-zone and a distal sub-zone, the porosity of the grid in the sub-zone proximal zone being greater than the porosity of the grid in the distal subzone. Air diffuser according to one of claims 1 to 4, in which the peripheral zone of the grid comprises a center of symmetry. Air diffuser according to one of claims 1 to 5, in which the grille is arranged, in the air diffuser, so as to delimit a border between an upper internal space (401) and a lower internal space (402) extending to a lower face, the lower face comprising, at the edge, a blowing slot (67), the lower face comprising a suction slot (66) circumscribed by the blowing slot, the blowing slot being connected to the plurality of blowing openings so as to form, in the lower internal space, a lower blown air passage, the suction slot being connected to the suction opening so as to form, in the lower internal space, a suction air passage partitioned from the lower blown air passage. Air diffuser according to claim 6, the upper internal space extending inside a housing (40) comprising two opposite blowing vents connected to the plurality of blowing openings so as to form, in the The upper internal space, an upper passage of blown air. Air treatment and/or conditioning system comprising: - an air diffuser according to one of claims 1 to 7, - an air blowing device configured to maintain circulation of the blown air in the first direction, - an air suction device connected to the suction opening, configured to maintain circulation of the air sucked in the second direction. System according to claim 8, comprising an air/air heat pump as an air suction device, as an air blowing device and, optionally, as an air filtration device. Use of a system according to claim 8 or 9 to form an air quality treated and/or conditioned atmosphere in a small space, in particular around a person.

Images