FR3144630A1 - Process for producing a support intended to partially obscure light radiation - Google Patents

Abstract

Process for producing a support intended to partially obscure light radiation The present invention relates to a method for producing a support (1) for partial occultation of light radiation incident on the support (1). The support (1) comprises at least one opaque zone (6) intended to obscure the light radiation incident on the support (1) and a transparent zone (7) intended to allow the light radiation transmitted by the support to pass. The production method comprises at least one step of forming a plurality of transparent figures (8) which jointly constitute the transparent zone (7). The transparent figures (8) have a center (9), and the centers (9) of the transparent figures (8) are arranged at intersections of a plurality of columns (10) parallel to each other and a plurality of lines ( 11) which are parallel to each other and which are orthogonal to the columns (10). Two neighboring transparent figures (8) of the same line (11) are separated by a first spacing (E1), and two contiguous lines (11) are separated by a second spacing (E2). The first spacing (E1) is between 1.4 mm and 1.8 mm and a surface (S) of each transparent figure (8) is of the order of the product obtained by multiplying the first spacing (E1), the second spacing (E2) and a factor which is a ratio between a transmitted light power of the light radiation passing through the support (1) and an incident light power reaching the support (1), to within +/- 10%. (Figure 2)

Description

Method for producing a support intended to partially obscure light radiation

The field of the present invention is that of methods for producing a support intended to partially obscure light radiation, such as light radiation external to an enclosure. The subject of the present invention is such a method as well as a support obtained from such a method.

We know a support, such as a blind canvas, an advertising display, which is intended to be positioned in front of or on an opening of an enclosure. The opening is for example a window, a French window, a bay window, a display window, a room or a building. The opening is for example also a window of a vehicle. The support is in particular intended to at least partially obscure a light radiation external to the enclosure which illuminates the opening. In other words, the support aims to protect from external light radiation an observer located inside the enclosure. In the case where the support is an advertising display, the support aims to deliver a message to an observer indifferently located inside or outside the enclosure.

It is understood that the support aims in its generality to ensure that a luminous power coming from the external light radiation and transmitted by the support inside the enclosure is lower than an incident luminous power reaching the support.

For this purpose, such a support comprises at least one opaque zone offering opacity to external light radiation, and/or allowing absorption and/or reflection of light radiation, and/or forming a printing zone.

Such a support also includes transparent areas formed by micro-perforations and/or orifices, for example made during the production of the support, by weaving, by thermoplastic manufacturing, by printing or the like. The transparent areas allow, in addition to obtaining certain mechanical properties, the passage of a portion of the external light radiation to the interior of the enclosure, thus maintaining natural lighting in the enclosure. The transparent areas allow a certain amount of brightness to be maintained inside the enclosure.

By nature, transparent areas also allow for a certain view of the outside from inside the enclosure, which is of very variable quality. Since this view of the outside from the enclosure is not the main functionality sought for the support, it is not subject to optimization.

Thus, a view by an observer of an external object through the medium generally turns out to be blurred, or at least devoid of optical quality, which constitutes a disadvantage.

An aim of the present invention is to propose a method for producing a support that makes it possible to at least partially obscure light radiation external to an enclosure and that also makes it possible to optimize a vision of an external object through the support by an observer located inside the enclosure. In other words, the present invention aims to make an image of an external object perceived by the eye of an observer located inside the enclosure as clear as possible. In other words, the present invention aims to propose a method for producing a support that is the best compromise between at least partial obscuration of light radiation and clear vision through the support.

Another object of the present invention is to propose a method of producing a support which allows an observer located on a first side of the support to see objects located on the other side of the support, i.e. a second side of the support, another observer located simultaneously on the second side not being able to distinctly see objects located on the first side of the support.

Another aim of the present invention is to propose a method for producing such a support which is simple to implement, quick to execute and which allows easy industrialization, in particular industrialization by weaving the support, without unduly weakening the support.

Another aim of the present invention is to provide a support obtained by means of such a production method.

These aims are achieved by the present invention which proposes a method for producing a support for partially obscuring light radiation incident on the support. The support comprises at least one opaque zone intended to obscure the light radiation incident on the support and a transparent zone intended to allow the light radiation transmitted by the support to pass through.

According to the present invention, the production method comprises at least one step of forming a plurality of transparent figures which jointly constitute the transparent area, the transparent figures having a center. The centers of the transparent figures are arranged at intersections of a plurality of columns parallel to each other and of a plurality of lines which are parallel to each other and which are orthogonal to the columns. Two neighboring transparent figures of the same line are spaced apart by a first spacing, and two contiguous lines are spaced apart by a second spacing. The first spacing is between 1.4 mm and 1.8 mm and an area of each transparent figure is of the order of the product obtained by multiplying the first spacing, the second spacing and a factor which is a ratio between a transmitted light power of the light radiation passing through the support and an incident light power reaching the support, to within +/- 10%.

The center of the transparent figure is understood to be the isobarycenter of this transparent figure, particularly in the case where the transparent figure is an irregular geometric figure.

Luminous power is understood to mean an energy flux included in the visible, infrared and ultraviolet ranges, which is expressed indifferently in Watts or in Watt/ ^m2 when it is a surface luminous power. Thus, the incident luminous power corresponds to the quantity of energy flux that reaches the support and the transmitted luminous power corresponds to the quantity of energy flux that the support lets pass.

The method of the present invention aims to obtain a support which allows both a partial occultation of light radiation which is satisfactory while allowing a clear vision of an object through the support.

It is understood that the partial occultation of the light radiation is obtained by the opaque zone which forms an obstacle to the external light radiation by allowing absorption and/or reflection of the light radiation, the opaque zone possibly forming a zone for printing a message intended to be read or seen by an observer.

Optimization of the vision of an object means the optimal sharpness of an image formed by an optical system, which consists of the support and the eye of the observer, of an object located on the other side of the support relative to the observer. The eye is considered here as an optical system with self-adapting focal length.

This sharpness is commonly defined as the quality of perception of the details and contours of the object. Sharpness is objectively defined by physico-physiological criteria, sharpness of vision estimated for example in 1/ ^10th , or by purely physical criteria, such as the angular power of separation of the optical system formed by the support and the eye of the observer, or its Optical Modulation Transfer Function.

If the distance between the support and the observer's eye is too small, the image of the object is likely to be screened by a geometric structure of the opaque part of the support, the object then appears partially obscured, which greatly degrades its vision and it is no longer possible to define the sharpness of the image. We will therefore exclude this case by taking a sufficiently large distance between the support and the observer's eye. However, we will seek to minimize this distance in order to maintain a quality image by approaching as close as possible to the support.

It is noted that light radiation is light radiation that is located in particular in the visible, this light radiation coming from a light source and/or its reflections on objects that are located on the other side of the support relative to the observer's eye. In other words, the support is interposed between the light source and/or its reflections on objects on the one hand and the observer on the other hand.

It is understood that this light radiation is of an incident light power when the light radiation reaches the support. It is also understood that the support forms at least a partial screen for the light radiation and only allows transmission of a transmitted light power, which is lower than the incident light power.

Finally, we understand that the transparent area formed by the transparent figures of the support is an area through which an observer located on one side of the support can see an object located on the other side of the support.

• deux figures transparentes voisines d’une même colonne sont distantes du deuxième espacement,
• deux figures transparentes voisines d’une même colonne sont distantes du double du deuxième espacement,
• le deuxième espacement est égal au premier espacement, à +/- 10% près.
• le deuxième espacement est égal à 0.87 fois le premier espacement, à +/- 10% près,
• le premier espacement est égal à 1,6 mm,
• chaque figure transparente est l’une quelconque d’un cercle ou d’un polygone,
• l’étape de formation de la pluralité de figures transparentes est simultanée à une étape d’impression de la zone opaque sur le support, initialement transparent. On comprend que les figures transparentes sont réalisées en même temps que la zone opaque. On comprend aussi que la zone opaque est réalisée par impression sur le support. Autrement dit, au cours d’une étape d’impression, on ménage en même temps les figures transparentes, qui sont exemptes d’une encre d’impression, et la zone opaque recouverte de l’encre d’impression,

• l’étape de formation de la pluralité de figures transparentes est simultanée à une étape de réalisation de la zone opaque indifféremment par tissage ou par fabrication thermoplastique. On comprend que les figures transparentes sont réalisées en même temps que la zone opaque. On comprend aussi que la zone opaque est réalisée par tissage du support ou bien par fabrication thermoplastique, extrusion par exemple, du support. Autrement dit, au cours d’une étape de tissage, on tisse la zone opaque en ménageant des figures transparentes. Autrement dit encore, au cours d’une étape de fabrication thermoplastique de la zone opaque, on forme la zone opaque en ménageant les figures transparentes,
• l’étape de formation de la pluralité de figures transparentes est une étape de perçage du support pour former les figures transparentes, l’étape de formation des figures transparentes étant postérieure à une étape d’obtention du support indifféremment par tissage ou par fabrication thermoplastique. Dans ce cas-là, on réalise le support indifféremment par tissage ou bien par fabrication thermoplastique, puis on réalise les figures transparentes postérieurement par perçage du support,
• le support est conformé pour équiper une paroi vitrée et pour occulter partiellement le rayonnement lumineux sur la paroi vitrée. Autrement dit, le support est apte à équiper une paroi vitrée pour affaiblir le rayonnement lumineux traversant la paroi vitrée. Le support présente les caractéristiques techniques de souplesse, de légèreté, de maniabilité pour être aisément affecté à une paroi vitrée d’un logement ou d’un véhicule.

The method of producing the support advantageously comprises at least one of the following technical characteristics, taken alone or in combination:

• two neighboring transparent figures of the same column are distant from the second spacing,
• two neighboring transparent figures in the same column are separated by twice the second spacing,
• the second spacing is equal to the first spacing, to within +/- 10%.
• the second spacing is equal to 0.87 times the first spacing, to within +/- 10%,
• the first spacing is equal to 1.6 mm,
• each transparent figure is any one of a circle or a polygon,
• the step of forming the plurality of transparent figures is simultaneous with a step of printing the opaque area on the support, initially transparent. It is understood that the transparent figures are produced at the same time as the opaque area. It is also understood that the opaque area is produced by printing on the support. In other words, during a printing step, the transparent figures, which are free of a printing ink, and the opaque area covered with the printing ink are provided at the same time,

• the step of forming the plurality of transparent figures is simultaneous with a step of producing the opaque area either by weaving or by thermoplastic manufacturing. It is understood that the transparent figures are produced at the same time as the opaque area. It is also understood that the opaque area is produced by weaving the support or by thermoplastic manufacturing, extrusion for example, of the support. In other words, during a weaving step, the opaque area is woven by creating transparent figures. In other words again, during a thermoplastic manufacturing step of the opaque area, the opaque area is formed by creating the transparent figures,
• the step of forming the plurality of transparent figures is a step of piercing the support to form the transparent figures, the step of forming the transparent figures being subsequent to a step of obtaining the support indifferently by weaving or by thermoplastic manufacturing. In this case, the support is produced indifferently by weaving or by thermoplastic manufacturing, then the transparent figures are produced subsequently by piercing the support,
• the support is shaped to equip a glass wall and to partially obscure the light radiation on the glass wall. In other words, the support is suitable for equipping a glass wall to weaken the light radiation passing through the glass wall. The support has the technical characteristics of flexibility, lightness, and maneuverability to be easily assigned to a glass wall of a home or a vehicle.

The present invention also relates to a support obtained by means of such a production method.

Such a support is particularly recognizable in that the support is a support for partially obscuring light radiation incident on the support, the support comprising at least one opaque zone intended to obscure the light radiation incident on the support and a transparent zone intended to allow the light radiation transmitted by the support to pass through, the support comprising a plurality of transparent figures which jointly constitute the transparent zone, the transparent figures comprising a center, the centers of the transparent figures being arranged at intersections of a plurality of columns parallel to each other and of a plurality of lines which are parallel to each other and which are orthogonal to the columns, two neighboring transparent figures of the same line being spaced apart by a first spacing, two contiguous lines being spaced apart by a second spacing, in which the first spacing is between 1.4 mm and 1.8 mm and in which a surface area of each transparent figure is of the order of the product obtained by multiplying the first spacing, the second spacing and a factor which is a ratio between a transmitted luminous power of the light radiation passing through the support and an incident light power reaching the support, to within +/- 10%.

• le support est un film souple apte à être collé sur la paroi vitrée, indifféremment sur une face intérieure ou une face extérieure de la paroi vitrée,
• le support est une toile de store destinée à être disposée en vis-à-vis de la paroi vitrée, indifféremment à l’intérieur ou à l’extérieur d’une enceinte équipée de la paroi vitrée,
• le support est apte à être disposé en vis-à-vis de la paroi vitrée mais aussi d’être escamoté de la paroi vitrée, notamment en fonction du rayonnement lumineux reçu par la paroi vitrée. Autrement dit, le support est par exemple mobile entre une position d’utilisation dans laquelle le support est disposé en vis-à-vis de la paroi vitrée et une position d’escamotage dans laquelle le support est écarté de la paroi vitrée. En position d’escamotage, le support est par exemple enroulé autour d’un axe de store disposé à distance de la paroi vitrée.
• le support est un support d’impression, tel qu’un film apte à recevoir et maintenir une encre d’impression,

• le support équipe une ouverture que comporte une enceinte,
• le support équipe une paroi vitrée logée à l’intérieur de l’ouverture,
• le support est disposé à l’extérieur de l’enceinte, pour minimiser une énergie thermique transmise par le rayonnement lumineux à l’intérieur de l’enceinte.

The support advantageously has at least one of the following technical characteristics, taken alone or in combination:

• the support is a flexible film capable of being stuck to the glass wall, either on an interior face or an exterior face of the glass wall,
• the support is a blind fabric intended to be placed opposite the glass wall, either inside or outside an enclosure equipped with the glass wall,
• the support is able to be arranged facing the glass wall but also to be retracted from the glass wall, in particular depending on the light radiation received by the glass wall. In other words, the support is for example movable between a position of use in which the support is arranged facing the glass wall and a retracted position in which the support is spaced away from the glass wall. In the retracted position, the support is for example wound around a blind axis arranged at a distance from the glass wall.
• the support is a printing medium, such as a film capable of receiving and holding a printing ink,

• the support equips an opening which includes an enclosure,
• the support equips a glass wall housed inside the opening,
• the support is arranged outside the enclosure, to minimize thermal energy transmitted by light radiation inside the enclosure.

Other characteristics and advantages of the invention will become apparent from the description which follows on the one hand, and from several examples of embodiment given for information purposes and without limitation with reference to the attached schematic drawings on the other hand, in which:

is a sectional view of a support of the present invention,

is a front view of a first variant embodiment of the support illustrated in the previous figure,

is a front view of a second variant embodiment of the support illustrated in the ,

is a front view of a third variant embodiment of the support illustrated in the previous figure,

is a front view of a fourth variant embodiment of the support illustrated in the ,

is a sectional view of the support illustrated in the preceding figures, the support being a flexible film glued to a glass wall of an enclosure,

is a sectional view of the support illustrated in Figures 1 to 5, the support being a blind fabric fitted to a glass wall, inside an enclosure.

is a sectional view of the support illustrated in Figures 1 to 5, the support being a blind fabric fitted to a glass wall, outside an enclosure.

On the , a support 1 of the present invention is interposed between an object 2 and an eye 3 of an observer. Schematically, the support 1 partially delimits two zones Z1, Z2, including a first zone Z1 inside which the object 2 is placed and a second zone Z2 inside which the eye 3 of the observer is located, the eye 3 of the observer being located at a distance L from the support 1.

The first zone Z1 also contains a light source 4 capable of generating light radiation 5. The light source 4 is indifferently a natural light source, such as the sun, or an artificial light source, such as a bulb, a projector or the like. Thus, the light source 4 is indifferently located near the support 1 or at a long distance.

The light source 4 and/or its reflections on elements located in the first zone Z1 is capable of emitting the light radiation 5 which reaches the support 1 with an incident light power P1. It is understood that the incident light power P1 corresponds to the energy flow which is carried by the light radiation 5, in the visible, infrared and ultraviolet ranges, and which reaches the support 1. The incident light power P1 is indifferently expressed in Watt or in Watt/m ² if the incident light power P1 is reported per unit of surface.

The support 1 comprises an opaque zone 6 which forms an obstacle to the light radiation 5 and a transparent zone 7 which allows the light radiation 5 to pass from the first zone Z1 to the second zone Z2. The opaque nature of the opaque zone 6 is understood to mean its ability to stop the light radiation 5, and the transparent nature of the transparent zone 7 is understood to mean its ability to transmit the light radiation 5 through it from the first zone Z1 to the second zone Z2. It is also understood that the support 1 has a power to obscure vision from the first zone Z1 to the second zone Z2, in the usual case where a brightness in the second zone Z2 is lower than a brightness in the first zone Z1. This characteristic allows an observer located in the second zone Z2 to see objects located inside the first zone Z1, while another observer located simultaneously in the first zone Z1 cannot distinctly see objects located in the second zone Z2.

The light radiation 5 is transmitted inside the second zone Z2 with a transmitted light power P2 which is lower than the incident light power P1. It is understood that the transmitted light power P2 corresponds to the energy flow which is carried by the light radiation 5, in the visible, infrared and ultraviolet ranges, and which is restored by the support 1. The transmitted light power P2 is indifferently expressed in Watt or in Watt/m ² if the transmitted light power P2 is reported per unit of surface.

It is understood that the support 1 is a support for partial occultation of the light radiation 5 incident on the support 1, the opaque zone 6 partially occulting the light radiation 5 incident on the support 1, and the transparent zone 7 transmitting the light radiation 5 coming from the first zone Z1 to the second zone Z2.

In order for the observer, located in the second zone Z2, to have a clear and sharp view of the object 2, located in the first zone Z1, through the support 1, it is proposed that the opaque zone 6 and the transparent zone 7 have precise conformations visible in figures 2 to 5. More particularly, a choice has been made of conformation, dimension and positioning of transparent figures 8 jointly forming the transparent zone 7 relative to the opaque zone 6.

In Figures 2 to 5, the support 1 comprises a plurality of transparent figures 8 which jointly constitute the transparent zone 7. In other words, the transparent zone 7 is made up exclusively of a plurality of transparent figures 8. The transparent figures 8 are all identical to each other.

Each transparent figure 8 has a center 9. Note that depending on the regular or irregular nature of the transparent figure 8, the center 9 is indifferently the center of a regular figure or the isobarycenter of an irregular figure.

The centers 9 of the transparent figures 8 are placed at intersections of a plurality of columns 10 and a plurality of lines 11. The columns 10 are parallel to each other and the lines 11 are parallel to each other. The columns 10 are all orthogonal to the lines 11.

In other words, the centers 9 of the transparent figures 8 are arranged on a grid 12 formed of columns 10 and lines 11.

More particularly, two neighboring transparent figures 8 of the same line 11 are distant from each other by a first spacing E1. It is understood that the first spacing E1 is taken between the respective centers 9 of two neighboring transparent figures 8 of the same line 11. It is understood that two neighboring transparent figures 8 of the same line 11 are two transparent figures 8 encountered one immediately after the other while traveling along the same line 11. In other words, two neighboring transparent figures 8 of the same line 11 are contiguous to each other on this same line 11.

Furthermore, two contiguous lines 11 are separated from each other by a second spacing E2.

To achieve the above-mentioned aims of the present invention, the first spacing E1 is advantageously between 1.4 mm and 1.8 mm and a surface S of each transparent figure 8 is advantageously of the order of the product between the first spacing E1, the second spacing E2 and a factor p which is a ratio between the transmitted light power P2 of the light radiation passing through the support 1 and an incident light power P1 reaching the support 1, to within +/- 10%.

Note that the first spacing E1 is preferably equal to 1.6 mm.

It is also noted that the surface S of each transparent figure 8 is therefore preferentially obtained from a multiplication of the first spacing E1, the second spacing E2 and said factor p as defined above.

These characteristics allow the observer, located in the second zone Z2, to have a clear and sharp vision of the object 2, located in the first zone Z1, through the support 1.

In Figures 2 and 3, two neighboring transparent figures 8 of the same column 10 are distant from the second spacing E2. It is understood that two neighboring transparent figures 8 of the same column 10 are two transparent figures 8 encountered one immediately after the other while traveling through a column 10. In other words, two neighboring transparent figures 8 of the same column 10 are contiguous to each other on this same column 10.

These arrangements are such that the transparent figures 8 are arranged in a square tiling.

On the , the transparent figures 8 are shaped into a circle with center 9 and diameter D.

On the , the transparent figures 8 are shaped into a polygon with center 9, indifferently arranged in a square, a rectangle, or even in any regular or irregular polygon.

In Figures 4 and 5, two neighboring transparent figures 8 of the same column 10 are separated by twice the second spacing E2. It is understood that two neighboring transparent figures 8 of the same column 10 are two transparent figures 8 encountered one immediately after the other while traveling through a column 10. In other words, two neighboring transparent figures 8 of the same column 10 are contiguous to each other on this same column 10.

We also note that two contiguous 10 columns are separated by a third spacing E3 which is equal to half of the first spacing E1, to within +/- 10%.

These arrangements are such that the transparent figures 8 are arranged in a hexagonal tiling.

On the , the transparent figures 8 are shaped into a circle with center 9 and diameter D.

On the , the transparent figures 8 are shaped into a polygon with center 9, indifferently arranged in a square, a rectangle, or even in any regular or irregular polygon.

According to a first variant embodiment, the second spacing E2 is equal to the first spacing E1, to within +/- 10%.

According to a second variant embodiment, the second spacing E2 is equal to 0.87 times the first spacing E1, to within +/- 10%.

These choices were made taking into account a minimum distance L separating the eye 3 of the observer and the support 1, such that the observer does not distinguish the transparent figures 8 from each other, the support 1 being perceived continuously, the visual image of the object 2 then also being perceived continuously.

Indeed, for good visual comfort, it is necessary that the observer can approach as close as possible to the support 1 without distinguishing the opaque zone 6 and the transparent zone 7, that is to say by having a continuous visual perception of the object 2 located on the other side of the support 1. For this, the first spacing E1 and the second spacing E2 must have the lowest possible values.

Furthermore, diffraction-interference phenomena generated by the transparent figures 8 when they are crossed by light rays from the object 2 degrade the quality of the visual image of the latter. However, to minimize this degradation, it is necessary that the values of the first spacing E1 and possibly of the diameter D are as large as possible.

It is therefore impossible to simultaneously optimize these two contradictory approaches, and it is necessary to make a choice, in particular such as the one just stated.

In other words, it is appropriate to seek the optimal compromise between these two approaches, such as the one just stated.

This compromise is particularly applicable to different processes for producing such a support 1.

In Figures 6 to 8, the support 1 thus defined advantageously finds different uses adapted to an opening 21 of an enclosure 20, generally equipped with a glass wall 22, such as a glass surface of a business, a building, a vehicle or the like. It is then understood that an interior of the enclosure 20 comprises the second zone Z2 described above and that an environment outside the enclosure 20 comprises the first zone Z1 mentioned above.

As an example illustrated in Figures 2 and 4, the support 1 can be produced by micro-perforation of a printing support, such as a printable polymer film made indifferently of polyester, polycarbonate, PVC, acrylic or the like.

Such printing media are commonly used as advertising media. After printing the advertising message on the opaque area 6 on an outer face of the film, an inner face of the film is very generally glued to the glass wall 22. The support 1 is indifferently glued to an inner face of the glass wall 22, as illustrated, or to an outer face of the glass wall 22 relative to the enclosure 20.

The printing medium and printing inks are chosen and sized to withstand the constraints linked to their use: mechanical resistance, adaptation to the indoor or outdoor environment, etc.

The application of the optimized vision to this type of support 1 is then immediate, it suffices to adapt the dimension and the conformation of the transparent figures 8, in particular their surface S, as well as the first spacing E1 and the second spacing E2 so that they correspond to the optimal values defined above.

As an example illustrated in Figures 7 and 8, the support 1 can also be obtained by micro-perforation of a sheet of various types, such as a polymer film, a natural, synthetic or mixed, woven or non-woven fabric or the like. The micro-perforation can be carried out on a pre-existing sheet using a micro-perforation machine. It can also be integrated into the manufacturing process, for example during the extrusion of a polymer film or fabric or during the weaving of a natural, synthetic or hybrid fabric.

The support 1 can also be produced by printing, single or double-sided, the opaque zone 6 on a transparent polymer film made indifferently of polyester, polycarbonate, PVC, acrylic or the like. The polymer film and the printing inks must be chosen and sized so as to withstand the constraints linked to their use: mechanical resistance, adaptation to the environment inside or outside the enclosure 20, winding capacity, etc.

The support 1 is then a sunscreen blind canvas. It is then understood that the support aims in particular to protect against the thermal effects of the light radiation 5 inside the enclosure 20.

The application of the optimized vision to this type of support 1 is then immediate, it suffices to adapt the dimension and the conformation of the transparent figures 8 as well as the first spacing E1 and the second spacing E2 so that they correspond to the optimal values defined above.

As another example, the support 1 can be used to make an interior sun blind as illustrated in FIG. 7 or an exterior blind as shown in FIG. . Such a support 1 preserves the natural lighting of the enclosure 20 and ensures, from inside the enclosure 20, an optimal quality view of an environment outside the enclosure 20.

The term “anti-sun blind” is understood to mean a window blind, French window or bay window, equipping the opening 21 that the enclosure 20 comprises. The opening 21 is for example provided with a glass wall 22 on which the support 1 is glued to the inside or outside of the glass wall 22 or against which the support 1 is placed at a distance, in particular being arranged parallel to the glass wall 22 either inside the enclosure 20 or outside the enclosure 20.

When the opening 21 is directly exposed to the light radiation 5, such as solar radiation and/or its reflections on the elements located in the first zone Z1, it is possible to significantly reduce the energy of the light radiation 5 penetrating into the enclosure 20, and therefore to minimize a rise in temperature inside the enclosure 20 and the direct or indirect glare effects on the observer.

Thus, the light radiation 5, ultraviolet, visible and infrared, arriving on the opaque zone 6 of the support 1 is absorbed or reflected by the opaque zone 6, the anti-solar function thus being ensured. Only the small part of the light radiation 5 passing through the transparent figures 8 penetrates into the enclosure 20.

The support 1 comprising an interior surface which is advantageously matt, that is to say with a high diffusion coefficient, the interior surface strongly attenuates the parasitic effects of reflection towards the interior of the enclosure 20.

A ratio between a total surface area of the transparent zone 7 on a surface area of the support 1 determines the proportion of the light radiation 5 penetrating into the enclosure 20 through the support 1, thus ensuring natural lighting of the second zone Z2 (proportion generally between 5% and 20% of the incident light radiation 5) and, in complementarity, the proportion of the incident light radiation 5 stopped by the support 1 (therefore between 95% and 80%). Anti-heat characteristics and natural lighting rates are thus easily configurable.

The quality of vision from the second zone Z2 to the first zone Z1, for a percentage p of the light radiation 5 passing through the support 1 via the transparent figures 8, is optimized by the choice of the values of the first spacing E1 and the surface S, as defined previously.

Some examples are given below.

For a coefficient p = 20% in light power transmission, we obtain:

E1 = 1.6 mm, E2 = 1.6 mm S = 0.51 mm²

For a coefficient p = 10% in light power transmission, we obtain:

E1 = 1.6 mm, E2 = 1.6 mm S=0.26 mm²

For a coefficient p = 5% in light power transmission, we obtain:

E1 = 1.6 mm, E2 = 1.6 mm S = 0.13 mm²

Such a support 1 is advantageously obtained from the implementation of a method which comprises at least one step of forming a plurality of such transparent figures 8 which jointly constitute the transparent zone 7.

The step of forming the transparent zone 7 is for example simultaneous with a step of printing the opaque zone 6 on a transparent flexible film. This process can be used to produce a sunscreen blind fabric.

The step of forming the transparent zone 7 is for example carried out by micro-perforation of a printable flexible film. This support 1 is then printed to form an advertising film intended to deliver a message to an observer indifferently housed inside or outside the enclosure 20.

The step of forming the transparent zone 7 is for example still a step of piercing the support 1 to form the transparent figures 8, the step of forming the transparent figures 8 being subsequent to a step of obtaining the support 1 by weaving or thermoplastic or similar manufacturing, the support 1 then being formed of a natural, synthetic or hybrid textile sheet, woven or non-woven, in particular. This support then forms a sunscreen blind fabric.

The step of forming the transparent zone 7 is for example still simultaneous with a step of producing the opaque zone 6 indifferently by weaving or by thermoplastic or similar manufacturing. In other words, during a weaving step, the opaque zone 6 is woven while providing the transparent figures 8. In other words again, during a thermoplastic manufacturing step of the opaque zone 6, the transparent zone 7 is formed while providing the transparent figures 8. This support 1 then forms a sunscreen blind fabric.

It is noted that the polygonal conformation of the transparent figures 8 facilitates their formation, in particular by weaving.

Claims (15)

Method for producing a support (1) for partially obscuring light radiation (5) incident on the support (1), the support (1) comprising at least one opaque zone (6) intended to obscure the light radiation (5) incident on the support (1) and a transparent zone (7) intended to allow the light radiation (5) transmitted by the support (1) to pass through, characterized in that the production method comprises at least one step of forming a plurality of transparent figures (8) which jointly constitute the transparent zone (7), the transparent figures (8) comprising a center (9), the centers (9) of the transparent figures (8) being arranged at intersections of a plurality of columns (10) parallel to each other and of a plurality of lines (11) which are parallel to each other and which are orthogonal to the columns (10), two neighboring transparent figures (8) of the same line (11) being separated by a first spacing (E1), two contiguous lines (11) being separated by a second spacing (E1). spacing (E2), in which the first spacing (E1) is between 1.4 mm and 1.8 mm and in which a surface area (S) of each transparent figure (8) is of the order of the product obtained by multiplying the first spacing (E1), the second spacing (E2) and a factor (p) which is a ratio between a transmitted luminous power (P2) of the light radiation passing through the support (1) and an incident luminous power (P1) reaching the support (1), to within +/- 10%. Method for producing a support (1) according to claim 1, characterized in that two neighboring transparent figures (8) of the same column (10) are distant from the second spacing (E2). Method for producing a support (1) according to claim 1, characterized in that two neighboring transparent figures (8) of the same column (10) are separated by twice the second spacing (E2). Method for producing a support (1) according to any one of the preceding claims, characterized in that the second spacing (E2) is equal to the first spacing (E1), to within +/- 10%. Method for producing a support (1) according to any one of claims 1 to 3, characterized in that the second spacing (E2) is equal to 0.87 times the first spacing (E1), to within +/- 10%. Method of producing a support (1) according to any one of the preceding claims, characterized in that the first spacing is equal to 1.6 mm. Method of producing a support (1) according to any one of the preceding claims, characterized in that each transparent figure is any one of a circle or a polygon. Method for producing a support (1) according to any one of the preceding claims, characterized in that the step of forming the plurality of transparent figures (8) is simultaneous with a step of printing the opaque zone (6) on the support (1). Method for producing a support (1) according to any one of claims 1 to 7, characterized in that the step of forming the plurality of transparent figures (8) is simultaneous with a step of producing the opaque zone (6) either by weaving or by thermoplastic manufacturing. Method for producing a support (1) according to any one of claims 1 to 7, characterized in that the step of forming the plurality of transparent figures (8) is a step of piercing the support (1) to form the transparent figures (8), the step of forming the transparent figures (8) being subsequent to a step of obtaining the support (1) indifferently by weaving or by thermoplastic manufacturing. Method for producing a support (1) according to any one of the preceding claims, characterized in that the support (1) is shaped to equip a glass wall (22) and to partially obscure the light radiation (5) on the glass wall (22). Support (1) obtained by means of a production method according to any one of the preceding claims. Support (1) according to claim 12 obtained by implementing the production method according to claim 11, characterized in that the support (1) is a flexible film capable of being stuck to the glass wall (22), indifferently on an interior face or an exterior face of the glass wall (22). Support (1) according to claim 12 obtained by implementing the production method according to claim 11, characterized in that the support (1) is a blind canvas intended to be arranged opposite the glass wall (22), either inside or outside an enclosure (20) equipped with the glass wall (22). Support (1) according to any one of claims 12 to 14, characterized in that the support (1) is a printing support.