FR3140935A1 - Customized manufacturing process for a ventilation element and ventilation element thus obtained - Google Patents

Abstract

The present invention relates to a method of custom manufacturing a ventilation element intended to be interposed between an interior space and an exterior, in which the following steps are carried out: - providing a transparent or translucent plate (11), - producing a plurality of ventilation holes (12) in said plate, at least a majority of said holes (12) having a non-constant section over at least part of the thickness of this plate (11), to modify the temperature of the air passing through the ventilation element, and - the air flow rate for ventilating said interior space being fixed at D in m3/h, the number of holes made in said plate is at most equal to, with Stot the total surface for the free passage of air through said plate, Vmoy the average speed of the air through the holes, and N the number of openings of said interior space opening to the outside when each opening is equipped with a identical ventilation element. Use of this ventilation element as a barrier against arthropods and/or pests such as rodents. [Fig. 1]

Description

Customized manufacturing process for a ventilation element and ventilation element thus obtained

The present invention relates to a custom manufacturing method for a ventilation element intended to be interposed between an interior space and an exterior to ensure the ventilation of said space.

It also concerns a ventilation element for the renewal of air in an interior space, this ventilation element being configured to lower the temperature of the air passing through it, or to cool this air, when the latter is greater than a threshold value, and/or being configured to increase the temperature of the air passing through it, when the latter is below a threshold value.

Ventilation grilles are known formed in plates or sheets, in which openings of generally elongated rectangular shape are provided to allow the passage of air flows in non-pulsed natural circulation.

Not only does the implementation of this natural ventilation ensure that the building has sufficient indoor air quality for the health of the occupants, by replacing stale air with new air, but it contributes to the sustainability of the building by wicking away moisture.

The air flow required to renew the air in an interior space depends on several parameters, such as the purpose of this space (kitchen, living room, etc.) and the number of people occupying this space.

However, we note that these ventilations remain relatively basic and standardized technologies. They do not take into account, in particular, the weather conditions surrounding the building, which are nevertheless decisive in the control of the building.

Furthermore, we observe that their shape is solely linked to technical considerations without seeking an aesthetic that would be likely to contribute to the enhancement of a building.

In addition, the air passing through these grilles is at the same temperature as the outside air, resulting in usage constraints. For purely illustrative purposes, in summer, it may be necessary to limit the ventilation air flow when the outside temperature is higher than the inside temperature of the room to be ventilated so as not to heat it up.

Furthermore, the use of mosquito nets has long been known to combat the intrusion of insects, particularly mosquitoes and/or flies, into a home.

These mosquito nets are used to close openings and form a barrier to insects while allowing good air exchange.

The mosquito nets available today are typically made by weaving with a simple crossing of the warp and weft threads, which is perpendicular.

The meshes of these mosquito nets define openings typically having dimensions between one (1) and two (2) mm, to prevent the passage of insects while ensuring good ventilation.

However, we observe that these mosquito nets show poor resistance over time with a more or less rapid deterioration of at least some of their openings, for example following slipping of the wires, a snag, repeated friction, stretching, or even fraying linked to cutting the mosquito net, etc.

This structural degradation of the mosquito net reduces its effectiveness and can then give free rein to insects.

Furthermore, we note that the weaving processes generally implemented cannot guarantee a regular base mesh so that mosquito nets, even new ones, can have openings of variable dimensions.

However, a slight variation in the dimensions of an opening can allow the passage of an insect, in particular the aedes albopictus, also called the tiger mosquito, which has small dimensions.

However, the latter is well known to be the main vector of various viral diseases, such as dengue, chikungunya, zika or yellow fever.

In addition, and more generally, we observe that the mosquito nets currently on the market have low transparency and therefore reduce the field of vision, or, at best, cause visual discomfort.

There is therefore a pressing need for an ventilation grille whose original design makes it possible to overcome the disadvantages of the prior art exposed above.

Object of the invention

The present invention aims to overcome the drawbacks of the prior art by proposing a custom manufacturing process for a ventilation element, simple in its design and in its operating mode, taking into account not only the characteristics of the space interior to be ventilated, but also the climatic environment outside the latter, to obtain a tailor-made ventilation element for this interior space.

Another object of the present invention is such a manufacturing process making it possible to obtain a ventilation element which is naturally capable of cooling the air passing through it in hot periods and of heating this air in cold periods, without the addition of any energy source.

Another object of the present invention is a method of manufacturing a ventilation element that is as transparent as possible.

Yet another object of the present invention is a method of manufacturing a ventilation element further forming an effective protective screen against arthropods and/or pests such as rodents.

The present invention also aims at a ventilation element for naturally ventilating an interior space, or participating in its ventilation, which offers great transparency and, for example, makes it possible to replace clear glass in glazing, while being inexpensive.

Yet another object of the present invention is such an aeration element allowing naturally, without adding any energy, to lower the temperature of the air passing through it, or to cool this air, when the latter is greater than a threshold value. , and/or to increase the temperature of the air passing through it, when the latter is below a threshold value.

To this end, the invention relates to a custom manufacturing method for a ventilation element intended to be interposed between an interior space and an exterior, in which the following steps are carried out:
- provide a transparent or translucent plate, said plate comprising at least one glass or plastic core,
- produce a plurality of ventilation holes in said plate, at least a majority of said ventilation holes having a non-constant straight cross section over at least part of the thickness of said plate, to modify the air temperature passing through said ventilation element, when said outside air temperature is higher or lower than threshold temperatures, and
- the air flow rate for ventilating said interior space being fixed at D in m ³ /h, the number of holes made in said plate is at most equal to ,
with S _tot the total surface for the free passage of air through said plate, or the sum of the individual surfaces of the holes on the side of the face of the plate intended to be placed towards the outside, V _avg the speed average of the air through said holes, and where N is the number of openings of said interior space opening to the outside with N greater than or equal to 1, when each opening is equipped with an identical ventilation element.

This manufacturing process ensures the manufacture of a tailor-made ventilation element taking into account not only the destination of the interior space to be naturally ventilated, but also its climatic environment (building exposed to winds, wind fluctuations in the year, atmospheric pressure, etc.).

Very advantageously, the ventilation element thus produced ensures a natural modification, that is to say without input of energy, of the temperature of the air passing through it, when the temperature of the outside air is above or below threshold temperatures. These threshold temperatures can advantageously be predefined according to the characteristics of the filtration element. No external energy source is therefore used to modify the temperature of the air passing through the ventilation element and the latter is therefore used alone, or even “naked”.

In addition, this ventilation element thus produced can be transparent. It can for example have a light transmission coefficient which is greater than or equal to 70%, and even better greater than 80%. It can therefore be advantageously used to replace or complement a glazing element.

These ventilation holes can have any shape such as circular or elongated such as oblong, elliptical or even oval.

This ventilation element may include one or more functional layers covering the glass or plastic core on at least one of its faces. This ventilation element is then formed by a multilayer sheet, at least partly transparent or translucent, which is perforated.

Of course, this ventilation element can also have one or more fixing holes, which are then distinct from the ventilation holes.

According to a particular embodiment of this custom manufacturing process for a ventilation element, the thickness of said plate is previously determined as a function of the air flow considered for said interior space and as a function of a lowering or of a given increase in the temperature of the air passing through said ventilation element.

According to another particular embodiment of this custom manufacturing process for a ventilation element, for a given air flow rate to ventilate said interior space, the number of holes to be made in said plate is adjusted taking into account the thickness of said plate, and possibly the maximum and/or minimum average temperature outside.

Totally surprisingly, and counter-intuitively, it was noticed that increasing the number of ventilation holes made in the plate does not make it possible to obtain a cooling, or warming, effect on the outside air. passing through the larger ventilation element. On the contrary, a sometimes drastic reduction in this cooling or heating effect is observed when the number of ventilation holes made in the plate exceeds certain values. The thickness of the plate is an even more sensitive parameter on the cooling or heating obtained from the outside air passing through the ventilation element.

Preferably, for a given thickness of said plate and a given air flow rate to ventilate said interior space, the density of ventilation holes to be made in said plate is determined beforehand so that the lowering or increase of the temperature of the air passing through said ventilation element is maximum.

According to yet another particular embodiment of this custom manufacturing process for a ventilation element, the thickness of said plate is between 0.5 and 6 mm, and even better between 0.5 and 2.5 mm, and even more preferably between 1 and 2 mm.

According to yet another particular embodiment of this custom manufacturing process for a ventilation element, this average speed is first measured in situ or this average speed of the air is previously determined at the level of said holes from one or more meteorological parameters.
This preliminary determination of the speed can be measured on site or come for example from a survey of the climatic environment of a building including for example the exposure to wind of the building considered (annual fraction of time during which the wind comes from each direction, ie fluctuations depending on the season, average wind speed, etc.), atmospheric pressure at the site, etc.

According to yet another particular embodiment of this custom manufacturing method for a ventilation element, at least a majority of said ventilation holes are formed so as to present a progressive reduction in section in a direction extending between the two faces of said plate, such as conical and more generally, of flared shape.

The larger section of the hole could be placed on the exterior side, as well as the interior space side.

Alternatively, these ventilation holes can have a narrowing in a direction extending between the two faces of the plate and for example have a shape reminiscent of the general shape of a diabolo.

According to yet another particular embodiment of this custom manufacturing method of a ventilation element, at least a majority of said ventilation holes is configured to lower the temperature of the air passing through said ventilation element when the outside air temperature is greater than 26°C, and even better 23°C and increase the temperature of the air passing through said ventilation element when the air temperature is less than 18°C, and even better at 21°C.

According to yet another embodiment of this custom manufacturing method of a ventilation element, said ventilation element being intended to also form a barrier against arthropods and said ventilation holes having an elongated shape, we produce each of said holes so that it has a longitudinal axis and a transverse axis, the dimension of each of said portions along the longitudinal axis being greater than the largest dimension of the arthropods against which this ventilation element is intended to ensure protection, the dimension of each portion along the transverse axis being less than or equal to the largest dimension of the main body of these arthropods against which this ventilation element is intended to provide protection, this main body excluding the head and the appendages of the corresponding arthropods.

Preferably, the section of each hole has a Ga value of between 0.1 and 8 mm in its largest dimension and a Pa value of between 500 µm and 1.2 mm in its other dimension, the Ga value being greater than the largest of the dimensions of the arthropods against which this ventilation element is intended to provide protection, while its value Pa is less than or equal to the largest dimension of the main body of these arthropods against which this ventilation element is intended to provide protection, this main body excluding the head and appendages of the corresponding arthropods.

For at least some of the ventilation holes of this plate, at least one free end of these ventilation holes thus has a straight cross section, for example in the plane formed by the corresponding face, of elongated shape such as oblong, elliptical or even oval.
This elongated cross section thus comprises a longitudinal axis and a transverse axis, its dimension along the longitudinal axis being greater than the largest dimension of the arthropods against which this ventilation element provides protection, the dimension along the transverse axis being less than or equal to the largest dimension of the main body of these arthropods against which this ventilation element provides protection, this main body excluding the head and the appendages of the corresponding arthropods.

By “appendix” we mean, for example, a locomotor appendage such as an arthropod leg.

We thus observe that the present ventilation element ensures maximization of air exchanges through the plate while preventing the passage of arthropods, or by forming an impenetrable mechanical barrier for the arthropods against which it is intended to provide protection. .

According to yet another embodiment of this custom manufacturing process for a ventilation element, said ventilation holes are treated to improve the light transmission coefficient of said plate.

For purely illustrative purposes, having made said ventilation holes in said plate, and at least one face of said plate still being covered with at least one removable protective layer, at least a majority of said ventilation holes are formed , on the portion of at least one face of said plate delimiting the edge of each of these ventilation holes and/or the side wall, or the belt of side walls, delimiting each of the corresponding holes, at least one layer configured to increase the light transmission coefficient of this plate compared to the light transmission coefficient of the same plate whose ventilation holes are devoid of said layer(s).

Preferably, said at least one layer configured to increase the light transmission coefficient of this plate will be formed of at least one layer of colored charges, which or which will be obtained by:

- by using a laser beam to carry out a surface treatment such as for example the process called thermal foaming,

- by depositing an appropriate aerosol paint composition,

- by a sol-gel process

- or by depositing a solution comprising a solvent and colored fillers.

In the first case, the advantages of using a laser beam allowing “thermal foaming” are notably linked to obtaining particularly precise work and foaming shades that can be varied.

For purely illustrative purposes, we could use a laser source with a wavelength of 1.06 µm, with a power of 10W and having a scanning speed of 35m/min on a polycarbonate plate. We then obtain a dark gray coloring which can be localized in the immediate vicinity of the holes and on the walls of the ventilation holes accessible to the laser beam.

For the two other treatment processes identified above, the solvent is chosen according to the polymer constituting the plate in question to be able to dissolve its surface and embed the colored fillers.

For purely illustrative purposes, this solvent may be an organic solvent such as methanol, cyclohexanone, acetone, pyridine or methylene chloride. This solvent can be used pure or mixed, for example with water.

For example, the mixture can then be dispersed by spraying with a conventional paint gun with a small diameter nozzle, or by a screen printing type coating, or even a sol-gel dipping type coating. The masked surfaces, for example with the protective layer, will then be covered as well as at least the edge of the ventilation holes left visible by the drilling.

The main advantage of using these techniques is the speed of implementation on large areas.

For purely illustrative purposes, a mixture associated with PMMA can be composed of 95% by volume of acetone with 5% of carbon black, such as for example Emperor 1200 from the company Cabot®, or any other carbon having very fine particles. , compatible with solvents and good rheological behavior to ensure good implementation. This mixture is for example sprayed using a Revell® airbrush with a 0.1 mm nozzle.

In all cases, photochromic elements based on silver chloride (such as Sigma Aldrich® AgCl having a purity greater than 99%) can be added to the solvent, alone or with the dye, in particular for a glass plate, or spiro-oxazine (Tokyo Chemical Industries®) in particular for the case of polymers.

The advantage of photochromic agents is that they become darker with increasing light rays, that is, when the diffusion of light in the plate, largely caused by the large number of holes , must be limited. Compared to a situation without treatment, we observe that the small discomfort which could be caused by the presence of colored charges is non-existent when the light rays are of low intensity.

Colored fillers can also be incorporated into a polymer (via masterbatch) to ensure good mixing with the solvent.

According to yet another embodiment of this custom manufacturing process for a ventilation element, the ventilation holes are made:

- by pure water jet cutting to avoid impacts around the holes caused by additives added to the water to improve cutting. In fact, these impacts alter the optical qualities of the material. Purely as an example, we can use a Mecanumeric quickjet II® machine to make the cuts.

- by laser cutting with pulses of short duration typically less than a few milliseconds to avoid excessive heating around the holes. For example, we could use a Trotec Speedy 100® CO ₂ laser machine.

- by milling, for example with a single thread cutter allowing the ejection of chips, at a speed of around 10,000 rpm. We could, for example, use a CharlyRobot 2U® machine.

According to yet another embodiment of this custom manufacturing process for a ventilation element, we form or place at each of said ventilation holes, on the face of the plate intended to be placed at the exterior, transparent fins, each of said fins being configured to oppose the entry of snow and being connected to the plate in an inclined manner relative to it.
These fins can for example be attached. They are also advantageously removable.

The present invention also relates to the use of a ventilation element obtained by the custom manufacturing process as described above, to form a barrier against arthropods and/or against pests such as rodents, for example mice or rats.

The present invention also relates to a ventilation element, also called a ventilation grille, intended to be interposed between an interior space of volume V and an exterior, to ensure ventilation of said interior space, the air flow to ventilate said space interior being fixed at D in m ³ /h, said ventilation element comprising:

- a transparent or translucent plate, said plate comprising at least one glass or plastic core,

- said plate comprising a plurality of ventilation holes each having a non-constant straight cross section over at least part of the thickness of said plate, to modify the temperature of the air passing through said ventilation element, when said temperature outside air is above or below threshold temperatures,

- the air flow rate for ventilating said interior space being fixed at D in m ³ /h, the number of holes made in said plate is at most equal to ,
with S _tot the total surface for the free passage of air through said plate, or the sum of the individual surfaces of the holes on the side of the face of the plate intended to be placed towards the outside, V _avg the speed average of the air through said holes, and where N is the number of openings of said interior space opening onto the exterior with N greater than or equal to 1, when each opening is equipped with an identical ventilation element, and
- the thickness of said plate is between 0.5 and 6 mm, and even better between 1 and 2 mm.

This ventilation element can be flat or essentially flat, or even non-flat. In the latter case, it can for example be at least partly curved or curved.

According to one embodiment of this ventilation element for ventilating an interior space, said plate has a light transmission coefficient which is greater than or equal to 70%, and even better greater than 80%.

According to another embodiment of this ventilation element for ventilating an interior space, for a given thickness of said plate and a given air flow rate for ventilating said interior space, the density of ventilation holes made in said plate, or the number of holes per unit surface of the plate, is determined so that the reduction or increase in the temperature of the air passing through said ventilation element is maximum.

According to yet another embodiment of this ventilation element for ventilating an interior space, at least a majority of said ventilation holes have a progressive reduction in section in a direction extending between the two faces of said plate.

According to yet another embodiment of this ventilation element for ventilating an interior space, at least a majority of said ventilation holes is configured to lower the temperature of the air passing through said ventilation element when the temperature of the outside air is greater than 26°C, and even better 23°C, and increase the temperature of the air passing through said ventilation element when the air temperature is lower than 18°C, and even better 21°C .

According to yet another embodiment of this ventilation element for ventilating an interior space, said plate comprises a core made of a material chosen from the group comprising polycarbonate, poly(methyl methacrylate) (PMMA), polyethylene, a polypropylene, an ethylene/propylene copolymer, polyurethane, polystyrene, acrylonitrile butadiene styrene (ABS), polyethylene terephthalate (PET).

According to yet another embodiment of this ventilation element for ventilating an interior space, the plate can also be anti-UV treated.

For example, this plate then includes in its mass a UV absorber or at least one anti-UV film, which covers at least one face of said core.

According to yet another embodiment of this ventilation element for ventilating an interior space, said ventilation element is intended to form a barrier against arthropods and said ventilation holes having an elongated shape, each of said ventilation holes has a longitudinal axis and a transverse axis, the dimension of each of said portions along the longitudinal axis being greater than the largest dimension of the arthropods against which this ventilation element is intended to provide protection, the dimension of each portion along the transverse axis being less than or equal to the largest dimension of the main body of these arthropods against which this ventilation element is intended to provide protection, this main body excluding the head and the appendages of the corresponding arthropods.
Preferably, the section of each hole has a Ga value of between 0.1 and 8 mm in its largest dimension and a Pa value of between 500 µm and 1.2 mm in its other dimension, the Ga value being greater than the largest of the dimensions of the arthropods against which this ventilation element is intended to provide protection, while its value Pa is less than or equal to the largest dimension of the main body of these arthropods against which this ventilation element is intended to provide protection, this main body excluding the head and appendages of the corresponding arthropods

Preferably, the lateral displacement of a ventilation hole during elastic deformation of the plate being ∆x, 2 ∆x is less than or equal to the largest dimension, even better the smallest dimension, of the main body of these arthropods against which this ventilation element provides protection, this main body excluding the head and the appendages of the corresponding arthropods.

This advantageously ensures that even in the event of elastic deformation of the ventilation element, for example under the effect of wind, the arthropods against which this ventilation element provides protection remain effective by forming an impenetrable barrier. towards them.

This value of ∆x depends on the material(s) constituting the plate, its thickness, its dimensions and the applied stress. The value 2 ∆x is the maximum opening obtained when moving the upper and lower parts of a vent hole oppositely, without plastic deformation, when applying an external force to the vent element in a direction perpendicular or substantially perpendicular to it, while this ventilation element is held in position for example by its peripheral edge.

More generally, the present invention also relates to a barrier against pests such as rodents, for example mice or rats, and/or against arthropods, comprising a ventilation element as described above.
Such a barrier ensures the protection of an interior space such as a room, against pests and/or arthropods by preventing their migration towards this space, and at the same time, allows optimized ventilation of this interior space.

The present invention also relates to a building comprising a wall comprising one or more openings, each opening ensuring air communication between an interior space and the exterior, said or at least some of said openings receiving a ventilation element as described above , to ensure or participate in the ventilation of said corresponding interior space.

Description of the designs

Other advantages, aims and particular characteristics of the present invention will emerge from the description which follows, given, for explanatory and in no way limiting purposes, with reference to the appended drawings, in which:

Fig. 1

is a partial perspective view of a ventilation element according to a first embodiment of the present invention, one edge of this ventilation element being pressed against a wall delimiting an opening in a construction;

Fig. 2

is a schematic representation of ventilation holes of a ventilation element according to a second embodiment, these ventilation holes having an elliptical shaped section;

Description of an embodiment

The drawings and description below contain, for the most part, elements of a certain nature. They can therefore not only be used to better understand the present invention, but also contribute to its definition, if necessary.

First of all, note that the figures are not to scale.

There schematically and partially illustrates a ventilation element 10 according to a first embodiment of the present invention for the natural ventilation of a room, one edge of this ventilation element being pressed against a wall delimiting an opening in a construction .

This interior space requires an air flow of around 155 m ³ /h for the natural renewal of its air.

This ventilation element 10, which here forms a glazing element, comprises a plate 11 of plastic material, here polycarbonate. This plate 11 has a thickness of around one (1) mm.

This plate 11 is perforated with ventilation holes 12 of oblong shape, these ventilation holes 12 being aligned in two directions (x, y) in the plane of the plate 11 while being regularly spaced from each other.

Of course, the ventilation holes 12 could alternatively be arranged in a staggered manner.

The density of ventilation holes 12 of this plate 11 was determined taking into account the values displayed in table 1.

[Table 1]: Measurement results Air flow 155 m3/h
Density A
4075 holes/m2 Density B
8150 holes/m2 Density C
21800 holes/m2 Temperature of outside air passing through the ventilation element = 55°C Plate thickness 1mm 6°C 6 4.3 Thickness 1.5mm 5.8 7 4.6 Thickness 2mm 5 6.1 4.1 Temperature of outside air passing through the ventilation element = 40°C Plate thickness 1mm 3 2.5 3 Thickness 1.5mm 4 4.5 2.8 Thickness 2mm 3 2.8 2.8

This table 1 shows in particular the effects of the densities of holes made in the plate 11 for a given thickness of the latter on the variation of the temperature expressed in degrees Celsius, measured at the outlet of the ventilation element, for a given temperature outside air penetrating this ventilation element 10.

These measurements clearly show that the cooling generated by the ventilation element 10 under otherwise equal conditions is not proportional to the number of ventilation holes 12 per unit surface.

The cooling effect is not cumulative.

On the contrary, it is clear that there is an operating optimum.

The density of ventilation holes 12 made used here is density A, that is to say 4075 holes. These ventilation holes being identical, the surface S _ind of each of these ventilation holes is linked to the average speed of the air passing through the plate by the formula 155/ (4075 S _ind x Vmoy x 3600). This Vmoy is dependent on the external environment of the room.

This plate 11 advantageously has a light transmission coefficient of around 85%.

There is an enlarged and partial view of an ventilation grille 40 ensuring not only optimal ventilation of an interior space but also constituting a screen, or a barrier, against arthropods such as mosquitoes.

A single ventilation hole 41 of oblong shape of this ventilation grille 40 is shown.

This plate, which is formed in one piece from polycarbonate, comprises a first face 42 and a second face (not shown). This plate has a plurality of ventilation holes 41 extending and opening onto the two faces 42 of this sheet to allow the passage of air through it. The thickness of this plate here is 1.5 mm.

Only the free end of a ventilation hole 41 opening onto the first face 42 of this plate and therefore contained in this face, is shown for the sake of simplicity.

The part, or free end, of the ventilation hole opening onto the first face 42 thus has a first dimension along a transverse axis 43 to this hole and a second dimension along a longitudinal axis 44 to this hole.

Advantageously, the dimension of this ventilation hole 41 along its longitudinal axis 44 is greater than the largest dimension of the arthropods against which this ventilation element provides protection while its dimension along the transverse axis 43 is less than or equal to the largest dimension of the main body of these arthropods against which this ventilation element provides protection, this main body excluding the head and the appendages of the corresponding arthropods.

This ensures a greater air flow through the ventilation grille 40 while guaranteeing its role as a mechanical barrier against the corresponding arthropods.

Claims (17)

Customized manufacturing process for a ventilation element intended to be interposed between an interior space and an exterior, in which the following steps are carried out:
- provide a transparent or translucent plate (11), said plate (11) comprising at least one glass or plastic core,
- produce a plurality of ventilation holes (12) in said plate (11), at least a majority of said ventilation holes (12) having a non-constant straight cross section over at least part of the thickness of said plate (11), to modify the temperature of the air passing through said ventilation element, when said outside air temperature is higher or lower than threshold temperatures, and
- the air flow rate for ventilating said interior space being set at D in m ³ /h, the number of holes made in said plate (11) is at most equal to ,
with S _tot the total surface for the free passage of air through said plate (11), or the sum of the individual surfaces of the holes on the side of the face of the plate (11) intended to be placed towards the exterior, V _avg the average speed of the air through said holes, and where N is the number of openings of said interior space opening onto the exterior with N greater than or equal to 1, when each opening is equipped with an element identical ventilation. Method according to claim 1, characterized in that the thickness of said plate (11) is determined beforehand as a function of the air flow considered for said interior space and as a function of a given reduction or increase in the temperature of the air passing through said ventilation element. Method according to claim 1 or 2, characterized in that for a given air flow to ventilate said interior space, the number of holes to be made in said plate (11) is adjusted by taking into account the thickness of said plate ( 11), and possibly the average maximum and/or minimum temperature outside. Method according to claim 3, characterized in that for a given thickness of said plate (11) and a given air flow rate to ventilate said interior space, the density of ventilation holes (12) to be made in said plate (11) so that the reduction or increase in the temperature of the air passing through said ventilation element is maximum. Method according to any one of the preceding claims, characterized in that the thickness of said plate (11) is between 0.5 and 6 mm, and even better between 0.5 and 2.5 mm, and even more more preferential between 1 and 2 mm. Method according to any one of the preceding claims, characterized in that this average speed is measured beforehand in situ or this average air speed is determined beforehand at said holes from one or more meteorological parameters. Method according to any one of the preceding claims, characterized in that at least a majority of said ventilation holes (12) are formed so as to present a progressive reduction in section in a direction extending between the two faces of said plate (11). A method according to any one of the preceding claims, characterized in that at least a majority of said ventilation holes (12) are configured to lower the temperature of the air passing through said ventilation element when the temperature of the outside air is greater than 26°C, and even better 23°C and increase the temperature of the air passing through said ventilation element when the air temperature is below 18°C, and even better at 21°C. Method according to any one of the preceding claims, characterized in that said ventilation element being intended to also form a barrier against arthropods and said ventilation holes (12) having an elongated shape, each of said holes is made so that it has a longitudinal axis and a transverse axis, each of said ventilation holes having a portion opening out on the side of the face of the plate (11) intended to be placed towards the outside, the dimension of each of said portions along of the longitudinal axis being greater than the largest dimension of the arthropods against which this ventilation element is intended to provide protection, the dimension of each portion along the transverse axis being less than or equal to the largest dimension of the main body of these arthropods against which this ventilation element is intended to provide protection, this main body excluding the head and the appendages of the corresponding arthropods. Method according to claim 9, characterized in that the section of each hole has a Ga value of between 0.1 and 8 mm in its largest dimension and a Pa value of between 500 µm and 1.2 mm in its other dimension, the value Ga being greater than the largest dimension of the arthropods against which this ventilation element is intended to provide protection, while its value Pa is less than or equal to the largest dimension of the main body of these arthropods against which this ventilation element is intended to provide protection, this main body excluding the head and appendages of the corresponding arthropods. Ventilation element intended to be interposed between an interior space of volume V and an exterior, to ensure ventilation of said interior space, the air flow rate for ventilating said interior space being fixed at D in m ³ /h, said ventilation element including:
- a transparent or translucent plate (11), said plate (11) comprising at least one glass or plastic core,
- said plate (11) comprising a plurality of ventilation holes (12) each having a non-constant straight cross section over at least part of the thickness of said plate (11), to modify the temperature of the passing air said ventilation element, when said outside air temperature is higher or lower than threshold temperatures,
- the air flow rate for ventilating said interior space being set at D in m ³ /h, the number of holes made in said plate (11) is at most equal to ,
with S _tot the total surface for the free passage of air through said plate (11), or the sum of the individual surfaces of the holes on the side of the face of the plate (11) intended to be placed towards the exterior, V _avg the average speed of the air through said holes, and where N is the number of openings of said interior space opening onto the exterior with N greater than or equal to 1, when each opening is equipped with an element identical ventilation, and
- the thickness of said plate (11) is between 0.5 and 6 mm, and even better between 1 and 2 mm. Ventilation element according to claim 11, characterized in that for a given thickness of said plate (11) and a given air flow rate for ventilating said interior space, the density of ventilation holes (12) made in said plate (11) is determined so that the reduction or increase in the temperature of the air passing through said ventilation element is maximum. Ventilation element according to claim 11 or 12, characterized in that at least a majority of said ventilation holes (12) have a progressive reduction in section in a direction extending between the two faces of said plate (11). Ventilation element according to any one of claims 11 to 13, characterized in that at least a majority of said ventilation holes (12) are configured to lower the temperature of the air passing through said ventilation element when the temperature of the outside air is greater than 26°C, and even better 23°C and increase the temperature of the air passing through said ventilation element when the air temperature is less than 18°C, and even better 21 °C. Ventilation element according to any one of claims 11 to 14, characterized in that it has a light transmission coefficient greater than or equal to 70%, and even better 80%. Barrier against pests such as rodents, and/or against arthropods, comprising a ventilation element (10) according to any one of claims 11 to 15. Building comprising a wall comprising one or more openings, each opening ensuring air communication between an interior space and the exterior, said or at least some of said openings receiving a ventilation element (10) according to any one of claims 11 to 15 to ensure or participate in the ventilation of said corresponding interior space.