WO2024061779A1 - System for projection onto a projection screen having a dark part and a transparent part - Google Patents

Abstract

One aspect of the invention relates to a projection system (1) comprising: - a projector (11); - a diffuse-reflection projection screen (12) having a dark part (12b) and a transparent part (12a), said projector (11) being positioned opposite the projection screen (12) such that a light beam (111) emitted by the projector (11) covers both the dark part (12b) and the transparent part (12a) of the projection screen (12).

Description

DESCRIPTION

TITLE: Projection system on a projection screen comprising a dark part and a transparent part

TECHNICAL FIELD OF THE INVENTION

[0001] The technical field of the invention is that of the projection of information for use in interior partitions in public transport (trains, buses, metros, trams, etc.) and more generally for any type of partition whatever. whatever the field (building, museums, commercial premises, etc.).

[0002] The present invention relates to a projection system, a projection method and manufacturing methods.

TECHNOLOGICAL BACKGROUND OF THE INVENTION

[0003] In certain places such as train stations or airports, or in certain vehicles such as trains or planes, the display of important information intended for passengers, such as arrival times of a train/plane , the destination, requires a specific contrast.

[0004] In trains for example, train stations or airports, the display devices on which the information can be projected are transparent glazing with diffuse reflection for example, which do not provide a specific contrast necessary for the good vision of information. Usually, the reflection by a glazing is said to be diffuse when radiation incident on the glazing with a given angle of incidence is reflected by the glazing in a plurality of directions. Reflection by a glazing is said to be specular when radiation incident on the glazing with a given angle of incidence is reflected by the glazing with an angle of reflection equal to the angle of incidence. By analogy, transmission through glazing is said to be specular when radiation incident on the glazing with a given angle of incidence is transmitted by the glazing with a transmission angle equal to the angle of incidence.

[0005] A solution for obtaining a specific contrast greater than with transparent glazing is the use of black or dark glazing onto which it is possible to project information, said glazing using absorbent layers for example to increase their contrast. . [0006] Transport regulations, however, require that the projection screens used, or in other words, the glazing, present a large transparent area - in order to be able to see through the glazing - and respect to the extent of the a usual aspect ratio (4:3, 16:9 or 16:10) is possible. The extent of the dark zone must therefore be relatively limited.

[0007] In view of these technical and regulatory constraints, a person skilled in the art is naturally encouraged to implement a projector having either a screen area having a usual aspect ratio but whose surface area is reduced in order to be contained in the dark area or, a screen area having an aspect ratio adapted to the extent of the dark area.

[0008] Such technical solutions, although partially satisfactory, have in return significant drawbacks, such as the reduction of the screen area or the specific adaptation of digital content and the projector to screen areas whose aspect ratio is unusual.

[0009] There is a need to improve such state-of-the-art solutions.

SUMMARY OF THE INVENTION

[0010] The invention offers a solution to the problems mentioned above, by making it possible to display content with better contrast than the information displays cited in the state of the art.

[0011] A first aspect of the invention relates to a projection system comprising: a projector; a diffuse reflection projection screen comprising a dark part and a transparent part; said projector being positioned facing the projection screen so that a light beam emitted by the projector covers both the dark part and the transparent part of the projection screen.

[0012] Thanks to the invention, it is possible to project the light beam of the projector onto a larger dark area, while maintaining a usual aspect ratio (4:3, 16:9 or 16:10), and without the need for any specific adaptation of the projector. It is also possible to project a light beam, including content such as written information or images, both on the dark part and on the transparent part and to observe a selective contrast depending on the sensitivity of the projected content, the use of the dark part making it possible to obtain a better contrast of the information displayed compared to the transparent screen. Note that the transparent and dark parts allow information to be projected thanks to the diffuse reflection properties of the projection screen. By projecting a light beam onto both the transparent part and the dark part of the screen, the regulations are respected and the contrast of the information displayed (included in the light beam) is improved. Additionally, a single projector is sufficient to display information on both the transparent and dark portions of the screen. A projection system according to the invention is therefore easier to integrate into a vehicle or a building.

[0013] We understand that the diffuse reflection projection screen is a passive device, that is to say in particular that the appearance of the diffuse reflection projection screen in itself is not modified by an external energy source, for example electrical. The diffuse reflection projection screen therefore has the same appearance whether an image is projected on it or not, apart from the formation of the image projected by the projector.

[0014] We therefore understand that the dark part and the transparent part of the diffuse reflection projection screen are static parts whose respective areas cannot be modified.

[0015] In addition to the characteristics which have just been mentioned in the previous paragraph, the projection system according to the first aspect of the invention may have one or more complementary characteristics among the following, considered individually or in all technically possible combinations:

An intensity of the light beam received by the dark part of the projection screen is different from an intensity of the light beam received by the transparent part of the projection screen.

The dark part has an area substantially equal to or different from a transparent part area.

The projection screen is a layered member comprising: a lower substrate including a smooth upper surface and a smooth lower surface; an absorbent layer extending along a portion of the lower substrate; a lower layer made of dielectric materials, said lower layer being arranged above the lower substrate; an upper layer made of dielectric materials, the lower layer and the upper layer having substantially identical refractive indices; a central layer interposed between the lower layer and the upper layer, this central layer being formed either by a single layer which is a dielectric layer with a refractive index different from that of the external layers or a metallic layer, or by a stack of layers which comprises at least one dielectric layer with a refractive index different from that of the external layers or a metallic layer, where each contact surface between two adjacent layers of the projection screen which are one dielectric and the other metallic, or which are two dielectric layers of different refractive indices, is textured and parallel to the other textured contact surfaces between two adjacent layers which are one dielectric and the other metallic or which are two dielectric layers of different refractive indices.

The projection screen includes a first exterior surface and a second exterior surface, and the projector faces the exterior surface of the projection screen furthest from the absorbent layer among the first exterior surface and the second exterior surface.

The top layer is a glass substrate including a smooth top surface and a textured bottom surface, with the textured bottom surface in contact with the core layer.

According to one embodiment: the first exterior surface of the projection screen is the upper surface of the upper layer; the second outer surface of the projection screen is the lower surface of the lower substrate; and the outer surface furthest from the absorbent layer is the first outer surface.

The projection screen comprises an exterior substrate in contact with the exterior layer and comprises an intermediate layer, preferably made of a polymer material, the assembly formed of the upper layer, the central layer, the lower layer and the intermediate layer being included between the lower substrate and the upper substrate.

[0016] According to one embodiment: the first exterior surface of the projection screen is the upper surface of the upper substrate; the second outer surface of the projection screen is the lower surface of the lower substrate; and the outer surface furthest from the absorbent layer is the first outer surface.

The bottom substrate is glass.

The bottom substrate is transparent.

The lower substrate is absorbent.

[0017] Another aspect of the invention relates to a projection method implemented by the projection system according to the invention comprising a step of positioning the projector facing the screen and a step of projecting a light beam covering both the transparent part and the dark part of the projection screen.

[0018] Another aspect of the invention relates to a method of manufacturing a projection system according to the invention, the method comprising the following steps: obtaining a first substrate, preferably made of glass, comprising a first smooth main surface and a second opposite smooth main surface, said substrate forming the lower substrate, the first smooth main surface being the lower surface of the lower substrate and the second main surface being the upper surface of the lower substrate; deposition, preferably by screen printing, of the absorbent layer on the lower substrate, the absorbent layer extending along a part of the lower substrate; obtaining a second substrate, preferably made of glass, comprising a smooth main surface and a textured main surface, said second substrate forming the upper layer, said smooth main surface being the upper surface of the upper layer and said textured surface being the lower surface of the upper layer; deposition, preferably by magnetron and/or screen printing, of a conformal layer on the upper layer and in particular on the lower, textured surface of the upper layer, said conformal layer forming the central layer; assembly by lamination of the assembly formed by the upper layer and the central layer with the lower substrate, the assembly being carried out via an interlayer, preferably made of polymer, adapted to deform in order to match a textured surface of the central layer , the interlayer forming the lower layer.

[0019] Another aspect of the invention relates to a method of manufacturing a projection system according to the invention, the method comprising the following steps: obtaining a first substrate, preferably made of glass, comprising a first smooth main surface and a second opposite smooth main surface, said first substrate forming the lower substrate, the first smooth main surface being the lower surface of the lower substrate and the second main surface being the upper surface of the lower substrate; deposition, preferably by screen printing, of the absorbent layer on the lower substrate, the absorbent layer extending along a part of the lower substrate; obtaining a second substrate, preferably made of glass, comprising a first smooth main surface and a second smooth main surface, said second substrate forming the upper substrate, said first smooth main surface being the upper surface of the upper substrate, and said second main surface smooth being the lower surface of the upper substrate; obtaining a third substrate, preferably in the form of a plastic film, comprising a smooth main surface and a textured main surface, said smooth main surface being the lower surface of the lower layer and said textured surface being the upper surface of the lower layer; deposition, preferably by magnetron and/or screen printing, of a conformal layer on the lower layer and in particular on the textured upper surface of the lower layer, said conformal layer forming the central layer; assembly by lamination of the lower substrate with the assembly formed by the lower layer and the central layer, the assembly being carried out via the intermediate layer; assembly by lamination of the upper substrate with the assembly formed by the lower layer, the central layer, the intermediate layer and the lower substrate, the assembly being carried out via the upper layer which is adapted to deform in order to match a textured surface of the central layer.

The invention and its various applications will be better understood on reading the following description and examining the accompanying figures.

BRIEF DESCRIPTION OF THE FIGURES

[0021] The figures are presented for information purposes only and in no way limit the invention.

[Fig. 1 ] shows a schematic representation of a projection system according to a first aspect of the invention.

[Fig. 2] shows a schematic representation of an embodiment of the projection screen included in the projection system.

[Fig. 3] shows a schematic representation of a variant of [Fig. 2].

[Fig. 4] shows a schematic representation representing the transparent and dark parts of the screen according to the embodiment of [Fig. 1].

[Fig. 5] shows a schematic representation of a second embodiment of the projection screen included in the projection system. [Fig. 6] shows a schematic representation of a variant of [Fig. 5] [Fig. 7] shows a schematic representation representing the transparent and dark parts of the screen according to the embodiment of [Fig. 5].

[Fig. 8] is a block diagram of a projection method implemented by the projection system according to the invention.

[Fig. 9] is a block diagram of a method of manufacturing the projection screen of the system according to the invention according to a first embodiment.

[Fig. 10] is a block diagram of a method of manufacturing the projection screen of the system according to the invention according to a second embodiment.

DETAILED DESCRIPTION

Unless otherwise specified, the same element appearing in different figures presents a unique reference.

[0023] A first aspect of the invention relates to a projection system comprising a projector and a diffuse reflection projection screen comprising a dark part and a transparent part. According to the invention, the projector is positioned so as to emit a light beam covering both the dark part of the screen and the transparent part of the screen, the dark part being facing said projector and the transparent part being facing the projector as well.

The projector is positioned so as to emit a beam totally or partially covering the dark part, and totally or partially covering the transparent part at the same time.

The transparent part of the projection screen forms a transparent screen, and the dark part of the projection screen forms a dark screen.

According to the invention, a transparent element is an element through which there is a transmission of radiation at least in the wavelength ranges useful for the intended application of the element. In the context of the invention, each layered element is transparent at least in the visible wavelength range. In particular, the transmission of radiation through said element is preferably specular. [0027] [Fig. 1] shows a schematic representation of the projection system 1 according to the invention.

The projection system 1 comprises the projector 11 and the projection screen 12.

Preferably, the projector 11 is a video projector.

[0030] Thus, the projector 11 is positioned so as to face the projection screen 12 with diffuse reflection.

The projection screen 12 comprises a transparent part 12a and a dark part 12b.

The transparent part 12a and the dark part 12b are both facing the projector 11.

The projector 11 is positioned so as to emit at least one light beam 111 covering both the transparent part 12a and the dark part 12b.

[0034] In particular, the beam 111 emitted by the projector makes it possible to display content on the projection screen 12, said content being able to comprise a first sub-content projected on the transparent part 12a and a second sub-content projected on the dark part 12b. Thus, a first part of the light beam covers the transparent part 12a and a second part of the beam covers the dark part 12b. For example, the light intensity of the part of the light beam received by the transparent part 12a differs from the light intensity of the part of the light beam received by the dark part 12b.

An area of the transparent part 12a can be substantially equal to or different from an area of the dark part 12b.

The area of the transparent part 12a may be less than or greater than the area of the dark part 12b.

[0037] In particular, the projection screen 12 is a layered element.

[0038] Throughout the description, a projection screen according to the invention is considered placed horizontally, with a first face oriented downwards defining a lower external surface and a second face, opposite the first face, oriented upwards defining an upper external surface. The meanings of the expressions “above” and “below” must therefore be considered in relation to this orientation. The terms “lower” and “higher” are also used here in reference to this positioning. The screen 12 comprises a lower substrate, a lower layer deposited on the lower substrate, an upper layer and a central layer interposed between the upper layer and the lower layer, and an absorbent layer extending along a portion of the lower substrate.

The screen 12 comprises a first exterior surface and a second exterior surface.

The projector 11 is positioned so as to face the exterior surface, among the first exterior surface and the second exterior surface, furthest from the absorbent layer. Part of the incident beams is thus reflected diffusely, before being able to reach the absorbing layer.

The lower substrate, the lower layer, the central layer and the absorbent layer are arranged in parallel.

The lower substrate comprises a smooth upper surface and a smooth lower surface.

[0044] A smooth surface (respectively interface) is a surface (respectively interface) for which the surface (respectively interface) irregularities are of dimensions less than the wavelength of the radiation incident on the surface/interface, so that the radiation is not deflected by these surface (respectively interface) irregularities. The incident radiation is then transmitted and reflected in a specular manner by the surface/interface.

The lower substrate is preferably made of glass (mineral) and is preferably transparent.

The lower substrate can also be made of polymer material. Examples of transparent polymers suitable for the lower substrate include, but are not limited to, polycarbonate and PMMA (acronym for “polymethyl methacrylate”).

[0047] An example of a glass substrate directly usable as a lower substrate is the glass substrate marketed by the company Saint-Gobain Glass in the PARSOL ULTRA GRAY VENUS range (VG10, VG20, VG40).

[0048] In particular, the lower substrate may be entirely transparent or absorbent and transparent.

[0049] No limitation is attached to the dimensions of the lower substrate.

For example, the lower substrate 121 may have a thickness of between 1.1 mm and 12 mm, more particularly between 1.6 mm and 6 mm, even more particularly between 1.6 mm and 2.6 mm, or even for example substantially equal to, or equal to, 2 mm.

The lower layer is formed of at least one electrical material.

The upper layer is formed of at least one dielectric material.

The dielectric material forming the lower layer has substantially a refractive index substantially equal to the dielectric material forming the upper layer.

[0053] Two dielectric materials have their refractive indices substantially equal, when the absolute value of the difference between their refractive indices at 550 nm is less than or equal to 0.15. Preferably, the absolute value of the index difference refraction at 550 nm between the respective dielectric materials of the two outer layers of the layered element is less than 0.05, more preferably less than 0.015.

[0054] According to one embodiment, the central layer comprises a single layer formed of a dielectric material with a refractive index different from the refractive index of the dielectric material forming the lower layer (and therefore different from the index refraction of the dielectric material forming the upper layer).

[0055] According to one embodiment, the central layer is formed by a stack of layers, the stack of layers comprising at least one layer formed of a dielectric material with a refractive index different from that of the dielectric material of the first outer layer and that of the dielectric material of the second outer layer.

According to one embodiment, the central layer comprises a single metal layer.

[0057] According to one embodiment, the central layer is formed by a stack of layers, the stack of layers comprising at least one metal layer.

The central layer comprises a first textured surface and a second textured surface.

[0059] In particular, the contact surface between two adjacent layers of the layered element which are one dielectric and the other metallic, or which are two dielectric layers of different refractive indices, is textured and parallel to the others. textured contact surfaces between two adjacent layers which are one dielectric the other metallic or which are two dielectric layers of different refractive indices.

[0060] A textured surface of a substrate is a surface for which the surface properties vary on a scale larger than the wavelength of the radiation incident on the surface. The incident radiation is then transmitted and reflected diffusely by the surface. The texturing of a surface can be obtained by any known texturing process, for example by embossing the surface of the substrate previously heated to a temperature at which it is possible to deform it, in particular by lamination using a roller having on its surface a texturing complementary to the texturing to be formed on the substrate; by abrasion using abrasive particles or surfaces, in particular by sandblasting; by chemical treatment, in particular acid treatment in the case of a glass substrate; by molding, in particular injection molding in the case of a thermoplastic polymer substrate, by etching.

Preferably, the absorbent layer is dark or black. The absorbent layer may be a dark enamel, for example a black enamel, or a dark paint, for example a black paint.

[0062] An element is said to be dark if it has a black luminance of less than 30 cd/m ² in an environment lit at 350 LUX measured according to the preferred diffusion direction. The "dark" color can also be evaluated using the colorimetric coordinates L*, a* and b* calculated by taking into account the illuminant D65 and the CIE-1931 reference observer. The L* component defines the lightness, which ranges from a value of 0 for black to a value of 100 for white. According to the invention, an element is said to be "dark" if it has a clarity such that the value L* measured in reflection is less than 50. According to a particular embodiment applicable to all of the configurations described in the present text, the absorbent layer is opaque, in the sense that its clarity is close to 0. In other words, it is not possible for a user to see through such an opaque layer.

[0063] Two embodiments of the projection screen 12 are presented below.

[0064] [Fig. 2] is a representation of a first embodiment of the projection screen 12.

[0065] In the remainder of the description, each surface mentioned is a surface parallel to the plane (O,X,Z). The screen 12 includes the lower substrate 121.

The lower substrate comprises the smooth lower surface 121_inf and the smooth upper surface 121_sup.

The lower substrate 121 is preferably made of (mineral) glass and is preferably transparent.

[0069] The projection screen 12 further comprises the lower layer 122, the central layer 123, the upper layer 124 and the absorbent layer 125 which extends partially along the smooth upper surface 121_sup of the lower substrate along the axis X, and which extends along the entire upper surface 121_sup along the Z axis.

[0070] With reference to [Fig. 2], lower layer 122 comprises a smooth lower surface 122_inf and a textured upper surface 122_sup.

[0071] With reference to [Fig.2], The upper layer 124 comprises a smooth upper surface 124_sup and a textured lower surface 124_inf.

The lower surface 122_inf of the lower layer 122, directed towards the outside of the screen 12, allows specular transmission of radiation to the upper surface 122_sup of the lower layer 122, that is to say the entrance of radiation in the lower layer 122 or the output of radiation from the lower layer 121.

[0073] The upper surface 124_sup of the upper layer 124, directed towards the outside of the screen 12, allows specular transmission of radiation to the lower surface 124_inf of the upper layer 124, that is to say the entrance of radiation in the upper layer 124 or the output of radiation from the upper layer 124.

[0074] The textures of the surfaces 124_inf and 122_sup are complementary to each other. As clearly visible in [Fig. 2], the textured surfaces 124_inf and 122_sup are positioned facing each other, in a configuration where their textures are strictly parallel to each other.

[0075] According to one embodiment, the upper layer 124 of the screen 12 is a textured glass. Examples of textured glass that can be used as a top layer are glass substrates marketed by the company Saint-Gobain Glass in the SATINOVO® range, which have on one of their surfaces a texture obtained by sandblasting or acid etching, glass substrates marketed by the Saint-Gobain Glass company in the ALBARINO® S, P range or G in the MASTERGLASS® range, which presents on one of their main surfaces a texture obtained by lamination.

According to the embodiment in which the upper layer 124 of the screen 12 is a textured glass, the lower layer 122 of the screen 12 is preferably made of PVB (acronym for the expression “polyvinyl butyral”). .

[0077] According to one embodiment, the central layer 123 of the projection screen 12 comprises at least one thin layer made of a dielectric material with a high refractive index, different from the refractive index of the material(s) forming the lower layer 121, such as SisN4, SnO2, ZnO, AIN, NbO, NbN, TiO2, or made of a dielectric material with a low refractive index, different from the refractive index of the outer layers, such as S iÛ2, AI2O3, MgF2, AIF3. The central layer 123 of the projection screen may also comprise at least one thin metallic layer, in particular a thin layer of silver, gold, titanium, niobium, silicon, aluminum, nickel-alloy chromium (NiCr), stainless steel, or their alloys.

[0078] For the purposes of the invention, a thin layer is a layer with a thickness of less than 1 micrometer.

[0079] The dimension of the absorbent layer 125 along the axis .

[0080] With reference to [Fig. 2], the absorbent layer 125 partially covers the upper surface 121_sup of the lower substrate 121 along the X axis and covers the entire upper surface 121_sup along the Z axis.

[0081] According to one embodiment, not shown, the absorbent layer 125 covers more than half of the upper surface 121_sup along the X axis and less than the entire upper surface 121_sup along the X axis and covers the entire of the upper surface 121_sup along the Z axis.

[0082] According to one embodiment, the absorbent layer 125 covers less than half of the upper surface 121_sup along the X axis and covers the entire upper surface 121_sup along the Z axis. [0083] According to a variant of the embodiment of [Fig. 1 ] shown in [Fig. 3], the absorbent layer 123 is located on the lower surface 121_inf of the lower substrate 121 and partially covers said lower surface 121_inf.

[0084] With reference to [Fig. 3], the absorbent layer 125 partially covers the lower surface 121_inf of the lower substrate 121 along the X axis and covers the entire lower surface 121_inf along the Z axis.

[0085] According to one embodiment, not shown, the absorbent layer 125 covers more than half of the lower surface 121_inf along the axis entire upper surface 121_sup along the Z axis.

[0086] According to one embodiment, the absorbent layer 125 covers less than half of the lower surface 121_inf along the X axis and covers the entire lower surface 121_inf along the Z axis.

The transparent part 12a of the projection screen 12 is the part of the projection screen 12 for which each plane perpendicular to the projection screen 12, that is to say each plane perpendicular to the plane ( O, Y, Z), and passing through the projection screen 12 does not pass through the absorbent layer 125.

The dark part 12b of the projection screen 12 is the part of the projection screen 12 for which each plane perpendicular to the projection screen 12, that is to say each plane perpendicular to the plane ( O, Y, Z), and passing through the projection screen 12 necessarily passes through the absorbent layer 125.

[0089] [Fig. 4] is a schematic representation of the projection screen 12 on which we can observe the transparent part 12a of the projection screen 12 and the dark part 12b of the projection screen.

[0090] Thus, the transparent part 12a of the projection screen does not include the absorbent layer 125, and comprises a first part of each layer among the lower substrate 121, the lower layer 122, the central layer 123 and the upper layer 124.

[0091] Thus, the dark part 12b of the projection screen does not include the absorbent layer 125, and comprises the second part of each layer among the lower substrate 121, the lower layer 122, the central layer 123 and the upper layer 124 and includes the entire absorbent layer 125. The projection screen 12 comprises a first exterior surface and a second exterior surface. According to the embodiment of [Fig. 2], the first exterior surface of the projection screen 12 is the upper surface 124_sup of the upper layer 124 and the second exterior surface of the projection screen 12 is the lower surface 121_inf of the lower substrate 121.

[0093] Advantageously, the upper layer 124 may comprise on its upper surface 124_sup (which represents the first exterior surface of the projection screen 12 according to the embodiment of [Fig. 2]) an anti-reflective coating, not represented at the interface between the air and the material constituting the upper layer 127 forming this main external surface. Thanks to the presence of this anti-reflective coating, radiation incident on the projection screen 12 on the side of this upper surface 124_sup is reflected in a preferred manner on each textured contact surface rather than on the smooth upper surface 124_sup of the screen. projection 12, which corresponds to a diffuse reflection mode rather than a specular reflection mode. A diffuse reflection of the radiation by the projection screen 12 is thus favored compared to a specular reflection.

[0094] [Fig. 5] is a representation of a second embodiment of the projection screen 12.

[0095] With reference to [Fig. 5], the projection screen 12 comprises, from bottom to top, the lower substrate 121, the intermediate layer 126 extending along the lower substrate, the lower layer 122, the central layer 123, the upper layer 124 and the upper substrate 127.

The upper substrate 127 comprises a smooth upper surface 127_sup and a smooth lower surface 127_inf.

[0097] The upper layer 124 is in contact with the upper substrate 127_sup along a smooth interface.

[0098] With reference to [Fig. 5], the lower layer 122 comprises the smooth lower surface 122_inf and a textured upper surface 122_sup'.

The intermediate layer 126 is interposed between the lower layer 122 and the lower substrate 121. [00100] The upper substrate 127 is transparent and can be formed from a transparent polymer, transparent glass or transparent ceramic. When the transparent substrate 127 is made of polymer, it can be rigid or flexible.

[00101] Preferably, the upper substrate 127 is the glass substrate sold by the company Saint-Gobain Glass in the SGG PLANICLEAR range. [00102] With reference to [Fig. 5], the upper layer 124 is preferably formed from OCA (Optical Clear Adhesive) or transparent optical adhesive material in French. The transparent adhesive material “OCA” refers to a set of polymeric materials which, in the case of the present invention, are used as transparent adhesives. Examples of polymeric materials suitable for the dielectric layer of the inner layer include, but are not limited to, polyurethane, polyepoxy, polysiloxane, polyacrylate, polyester, etc.

[00103] Advantageously, an upper layer 124 formed of OCA makes it possible to reduce or even eliminate a potential “waviness” effect through the assembly {layered element + central substrate} when the exterior major surface of the exterior substrate is observed. Indeed, a cowling effect tends to give a visual impression of undulation of the layers placed between the outer substrate and the central substrate.

[00104] For example, according to the previous embodiment, the lower layer 127 has a thickness of between 200 pm and 250 pm. However, such thickness values are not limiting to the invention.

[00105] The upper layer 124 can be formed from the transparent adhesive material OCA, or from PVB ("Polyvinyl butyral") which is a synthetic thermoplastic polymer, or from EVA ("ethylene-vinyl acetate") from PU (polyurethane). ).

[00106] The intermediate layer 126 is preferably made of PMMA and can for example have a thickness of between 50 pm and 250 pm. However, nothing excludes considering other materials for producing said intermediate layer, such as for example polycarbonate. Still other examples of materials suitable for said intermediate layer include, in particular, polyesters such as polyethylene terephthalate (PET), polybutylene terephthalate (PBT), polyethylene naphthalate (PEN), polyacrylates such as polymethacrylate (PMMA), polycarbonate, polyurethane, polyamides, polyimides, cellulose triactetate (TAC), etc.

[00107] Advantageously, an upper layer 124 formed of PU is more chemically compatible with an intermediate layer 126 formed of PMMA.

[00108] Advantageously, the upper substrate 127 can comprise on its upper surface 127_sup (which represents the first exterior surface of the projection screen 12 according to the embodiment of [Fig. 5]) an anti-reflective coating, not shown, at the interface between the air and the material constituting the external layer forming this main external surface. Thanks to the presence of this anti-reflective coating, radiation incident on the projection screen 12 on the side of this upper surface 127_sup is reflected in a preferred manner on each textured contact surface rather than on the smooth upper surface 127_sup of the screen. projection, which corresponds to a diffuse reflection mode rather than a specular reflection mode. A diffuse reflection of the radiation by the projection screen 12 is thus favored compared to a specular reflection.

[00109] With reference to [Fig. 5], the central layer 123 of the projection screen 12 comprises at least one thin layer made of a dielectric material with a high refractive index, different from the refractive index of the material(s) forming the lower layer 121, such as SisN4, SnO2, ZnO, AIN, NbO, NbN, TiC, or made of a dielectric material with a low refractive index, different from the refractive index of the external layers, such as SiC>2, AI2O3, MgF2, AIF3. The central layer 123 of the projection screen may also comprise at least one thin metallic layer, in particular a thin layer of silver, gold, titanium, niobium, silicon, aluminum, nickel-alloy chromium (NiCr), stainless steel, or their alloys.

[00110] With reference to [Fig. 5] The dimension of the absorbent layer 125 along the X axis is strictly smaller than the dimension of the lower substrate 121 along the Y axis and is substantially identical to the dimension of the lower substrate 121, and the dimension of the absorbent layer 125.

[00111] With reference to [Fig. 5], the absorbent layer 125 partially covers the upper surface 121_sup of the lower substrate 121 along the X axis and covers the entire upper surface 121_sup along the Z axis. [00112] According to one embodiment, not shown, the absorbent layer 125 covers more than half of the upper surface 121_sup along the X axis and less than the entire upper surface 121_sup along the X axis and covers the entire of the upper surface 121_sup along the Z axis.

[00113] According to one embodiment, the absorbent layer 125 covers less than half of the upper surface 121_sup along the X axis and covers the entire upper surface 121_sup along the Z axis.

[00114] According to a variant of the embodiment of [Fig. 5] shown in [Fig. 6], the absorbent layer 125 is located on the lower surface 121_inf of the lower substrate 121 and partially covers said lower surface 121_inf.

[00115] According to the embodiment of [Fig. 5], the first exterior surface of the projection screen 12 is the upper surface 127_sup of the upper substrate 127 and the second exterior surface of the projection screen 12 is the lower surface 121_inf of the lower substrate 121.

The transparent part 12a of the projection screen 12 is the part of the projection screen 12 for which each plane perpendicular to the projection screen 12, that is to say each plane perpendicular to the plane ( O, Y, Z), and passing through the projection screen 12 does not pass through the absorbent layer 125.

[00117] The dark part 12b of the projection screen 12 is the part of the projection screen 12 for which each plane perpendicular to the projection screen 12, that is to say each plane perpendicular to the plane ( O, Y, Z), and passing through the projection screen 12 necessarily passes through the absorbent layer 125.

[00118] [Fig. 7] is a schematic representation of the projection screen 12 on which we can observe the transparent part 12a of the projection screen 12 and the dark part 12b of the projection screen when the projection screen 12 is produced according to the embodiment of [Fig. 5],

[00119] Thus, the transparent part 12a of the projection screen does not include the absorbent layer 125, and comprises a first part of each layer among the lower substrate 121, the lower layer 122, the central layer 123 and the upper layer 124.

[00120] Thus, the dark part 12b of the projection screen does not include the absorbent layer 125, and includes the second part of each layer among the lower substrate 121, the lower layer 122, the central layer 123 and the upper layer 124 and comprises the entire absorbent layer 125.

[00121] Another aspect of the invention relates to a projection method, the synoptic diagram of which is shown in [Fig. 8], The projection method 100 is implemented by the projection system 1 according to the invention, said method comprising a first step 101 consisting of positioning the projector 11 facing the screen 12 and a step 102 of projection a light beam 111 covering both the transparent part 12a and the dark part 12b the projection screen 12.

Another aspect of the invention relates to a method of manufacturing the screen 12 according to the first embodiment shown in [Fig. 2], of the projection system 1 according to the invention. The block diagram of the manufacturing process of the screen 12 according to the embodiment of [Fig. 2] is shown in [Fig. 9], [00123] The manufacturing method 200 comprises a first step 201 of obtaining a first glass substrate comprising a first smooth main surface and a second smooth main surface opposite each other, said substrate forming the lower substrate 121, the first smooth main surface being the lower surface 121_inf of the lower substrate 121 and the second main surface being the upper surface 121_sup of the lower substrate 121.

[00124] The method 200 comprises a step 202 of deposition by screen printing of the absorbent layer 125 on the lower substrate 121, the absorbent layer 125 extending along a part of the lower substrate 21, the part of the lower substrate 121 does not cannot be the entirety of the lower substrate 121.

[00125] According to a first embodiment, the absorbent layer 125 is deposited on an upper surface portion 121_sup of the lower substrate 121.

[00126] According to a first embodiment, the absorbent layer 125 is deposited on a lower surface portion 121 _inf of the lower substrate 121.

[00127] The manufacturing method 200 comprises a step 203 of obtaining a second glass substrate comprising a smooth main surface and a textured main surface, said second glass substrate forming the upper layer 124, said smooth main surface being the upper surface 124_sup of the upper layer 124 and said textured surface being the lower surface 124_inf of the upper layer 124. The manufacturing method 200 comprises a step 204 of depositing by magnetron a conformal layer on the upper layer 124 and in particular on the textured lower surface 124_inf of the upper layer 124, said conformal layer forming the central layer 123.

[00129] The manufacturing process further comprises a step 205 of assembling by lamination the assembly formed by the upper layer 124 and the central layer 123 with the lower substrate 121, the assembly being carried out via a polymer interlayer. adapted to deform thanks to a lamination step in order to match the textured surface of the central layer, the interlayer forming the lower layer 122.

[00130] Another aspect of the invention relates to a method of manufacturing the projection screen 12 according to the embodiment shown in [Fig. 5], of the projection system 1 according to the invention. Said method of manufacturing the projection screen 12 according to the embodiment of [Fig. 5] is shown in [Fig. 10],

[00131] The manufacturing method 300 comprises a first step 301 of obtaining a first glass substrate comprising a first smooth main surface and a second smooth main surface opposed to each other, said first substrate forming the lower substrate 121, the first main surface smooth being the lower surface 121_inf of the lower substrate 121 and the second main surface being the upper surface 121_sup of the lower substrate 121.

[00132] The method 300 comprises a step 302 of deposition by screen printing of the absorbent layer 125 on the lower substrate 121, the absorbent layer 125 extending along a part of the lower substrate 21, the part of the lower substrate 121 does not cannot be the entirety of the lower substrate 121.

[00133] According to a first embodiment, the absorbent layer 125 is deposited on an upper surface portion 121_sup of the lower substrate 121.

[00134] According to a first embodiment, the absorbent layer 125 is deposited on a lower surface portion 121 _inf of the lower substrate 121.

[00135] The manufacturing method 300 comprises a step 303 of obtaining a second glass substrate comprising a first smooth main surface and a second smooth main surface, said second glass substrate forming the upper substrate 127, said first main surface smooth being the upper surface 127_sup of the upper substrate 127, and said second smooth main surface being the lower surface 127_inf of the upper substrate 127. [00136] The manufacturing method 300 comprises a step 304 of obtaining a third substrate 122 in the form of a plastic film, comprising a smooth main surface and a textured main surface, said smooth main surface being the lower surface 122_inf of the lower layer 122 and said textured surface being the upper surface 122_sup of the lower layer 122.

[00137] The manufacturing method 300 comprises a step 305 of depositing by magnetron a conformal layer on the lower layer 122 and in particular on the textured upper surface 122_sup of the lower layer 122, said conformal layer forming the central layer 123. [00138] The manufacturing method further comprises a step 306 of assembling by lamination the lower substrate 121 with the assembly formed by the lower layer 122 and the central layer 123, the assembly being carried out via the intermediate layer 126.

[00139] The manufacturing method further comprises a step 307 of assembling by lamination the upper substrate 127 with the assembly formed by the lower layer 122, the central layer 123, the intermediate layer 126 and the lower substrate 121, the assembly being carried out via the upper layer 124 which is adapted to deform in order to match a textured surface of the central layer 123.

Claims

[Claim 1] Projection system (1) comprising:

- a projector (11);

- a projection screen (12) with diffuse reflection comprising a dark part (12b) and a transparent part (12a); said projector (11) being positioned facing the projection screen (12) so that a light beam (111) emitted by the projector (11) covers both the dark part (12b) and the part transparent (12a) of the projection screen (12).

[Claim 2] Projection system (1) according to the preceding claim characterized in that the intensity of the light beam received by the dark part (12b) of the projection screen is different from the intensity of the light beam received by the transparent part (12a) of the projection screen.

[Claims] Projection system (1) according to any one of the preceding claims characterized in that the dark part (12b) has an area substantially equal to or different from an area of the transparent part (12a).

[Claim 4] Projection system (1) according to any one of the preceding claims characterized in that the projection screen (12) is a layered element comprising:

- a lower substrate (121) comprising a smooth upper surface (121_sup) and a smooth lower surface (121_inf);

- an absorbent layer (125) extending along a part of the lower substrate (121);

- a lower layer (122) made of dielectric materials, said lower layer (122) being arranged above the lower substrate (121);

- an upper layer (124) made of dielectric materials, the lower layer (122) and the upper layer (124) having substantially identical refractive indices;

- a central layer (123) interposed between the lower layer (122) and the upper layer (124), this central layer (123) being formed either by a single layer which is a dielectric layer with a refractive index different from that of the external layers or a metallic layer, or by a stack of layers which comprises at least one dielectric layer with a refractive index different from that of the external layers or a metallic layer; where each contact surface between two adjacent layers of the projection screen (12) which are one dielectric and the other metallic, or which are two dielectric layers of different refractive indices, is textured and parallel to the other surfaces textured contact layers between two adjacent layers which are one dielectric and the other metallic or which are two dielectric layers of different refractive indices.

[Claim s] Projection system (1) according to the preceding claim characterized in that the projection screen (12) comprises a first exterior surface and a second exterior surface, and in that the projector (11) faces the outer surface of the projection screen (12) furthest from the absorbent layer (125) among the first outer surface and the second outer surface.

[Claims] Projection system (1) according to any one of claims 4 to 5 characterized in that the upper layer (124) is a glass substrate comprising a smooth upper surface (124_sup) and a lower surface (124_inf) textured, the textured lower surface (124_inf) being in contact with the central layer (123).

[Claim 7] Projection system (1) according to the preceding claim characterized in that:

- the first exterior surface of the projection screen (12) is the upper surface (124_sup) of the upper layer (124);

- the second exterior surface of the projection screen (12) is the lower surface (121_inf) of the lower substrate (121); and in that the outer surface furthest from the absorbent layer (125) is the first outer surface.

[Claim 8] Projection system (1) according to one of claims 4 to 5 characterized in that the projection screen (12) comprises an exterior substrate (127) in contact with the exterior layer (124) and comprises a intermediate layer (126), preferably made of a material polymer, in contact at a smooth interface with the lower layer (122) and in contact at a smooth interface with the lower substrate (121), the assembly formed of the upper layer (124), the central layer (123), the lower layer (122) and the intermediate layer (126) being included between the lower substrate (121) and the upper substrate (127).

[Claim 9] Projection system (1) according to the preceding claim characterized in that:

- the first exterior surface of the projection screen (12) is the upper surface (127_sup) of the upper substrate (127);

- the second exterior surface of the projection screen (12) is the lower surface (121_inf) of the lower substrate (121); and in that the outer surface furthest from the absorbent layer (125) is the first outer surface.

[Claim 10] Projection system (1) according to any one of claims 4 to 9 characterized in that the lower substrate (121) is made of glass.

[Claim 11] Projection system (1) according to any one of claims 4 to 9 characterized in that the lower substrate (121) is transparent.

[Claim 12] Projection system (1) according to the preceding claim characterized in that the lower substrate (121) is absorbent.

[Claim 13] Projection method (100) implemented by the projection system (1) according to any one of claims 1 to 12 and comprising a step (101) of positioning the projector (11) facing the screen (12) and a step (102) of projecting a light beam (111) covering both the transparent part (12a) and the dark part (12b) of the projection screen (12).

[Claim 14] Method (200) for manufacturing a projection system (1) according to any one of claims 1 to 7 and claims 10 to 12, characterized in that it comprises the following steps:

- obtaining (201) a first substrate, preferably made of glass, comprising a first smooth main surface and a second smooth main surface opposite each other, said substrate forming the lower substrate (121), the first smooth main surface being the surface lower surface (121_inf) of the lower substrate (121) and the second main surface being the upper surface (121_sup) of the lower substrate (121);

- deposition (202), preferably by screen printing, of the absorbent layer (125) on the lower substrate (121), the absorbent layer (125) extending along a part of the lower substrate (121);

- obtaining (203) a second substrate, preferably made of glass, comprising a smooth main surface and a textured main surface, said second substrate forming the upper layer (124), said smooth main surface being the upper surface (124_sup) of the upper layer (124) and said textured surface being the lower surface (124_inf) of the upper layer (124);

- deposition (204), preferably by magnetron and/or screen printing, of a conformal layer on the upper layer (124) and in particular on the textured lower surface (124_inf) of the upper layer (124), said conformal layer forming the central layer (123);

- assembly (205) by lamination of the assembly formed by the upper layer (124) and the central layer (123) with the lower substrate (121), the assembly being carried out via an interlayer layer, preferably made of polymer, adapted for deform in order to match a textured surface of the central layer (123), the interlayer forming the lower layer (122).

[Claim 15] Method (300) for manufacturing a projection system (1) according to any one of claims 1 to 5 and 8 to 12, characterized in that it comprises the following steps:

- obtaining (301) a first substrate, preferably made of glass, comprising a first smooth main surface and a second smooth main surface opposite each other, said first substrate forming the lower substrate (121), the first smooth main surface being the lower surface ( 121_inf) of the lower substrate (121) and the second main surface being the upper surface (121_sup) of the lower substrate (121); Tl

- deposition (302), preferably by screen printing, of the absorbent layer (125) on the lower substrate (121), the absorbent layer (125) extending along a part of the lower substrate (121);

- obtaining (303) a second substrate, preferably made of glass, comprising a first smooth main surface and a second smooth main surface, said second substrate forming the upper substrate (127), said first smooth main surface being the upper surface (127_sup ) of the upper substrate (127), and said second smooth main surface being the lower surface (127_inf) of the upper substrate (127);

- obtaining (304) a third substrate (122), preferably in the form of a plastic film, comprising a smooth main surface and a textured main surface, said smooth main surface being the lower surface (122_inf) of the lower layer (122) and said textured surface being the upper surface (122_sup) of the lower layer

(122);

- deposition (305), preferably by magnetron and/or screen printing, of a conformal layer on the lower layer (122) and in particular on the textured upper surface (122_sup) of the lower layer (122), said conformal layer forming the central layer (123);

- assembly (306) by lamination of the lower substrate (121) with the assembly formed by the lower layer (122) and the central layer

(123), the assembly being carried out via the intermediate layer (126);

- assembly (307) by lamination of the upper substrate (127) with the assembly formed by the lower layer (122), the central layer (123), the intermediate layer (126) and the lower substrate (121), the assembly being achieved via the top layer (124) which is adapted to deform to match a textured surface of the core layer (123).