Compartment

FIELD OF THE INVENTION

The present invention relates to light emissive textile lining and more particularly to compartments of passenger vehicles or public places incorporating light emissive textile lining. The invention further relates to a light emissive element adapted for providing a room interior lining in a compartment of a vehicle and a method of manufacturing a light emissive element.

BACKGROUND OF THE INVENTION

The invention concerns a compartment, for instance, a vehicle compartment, or a lined compartment found in public places, such as restrooms, hotel lobbies or the like, provided with light emissive lining. Generally, a compartment is understood as a room in a building or vehicle, in particular, a passenger compartment or storage compartment. In such places, lining may be provided on any of the inner surfaces of the compartment, such as compartment floor, sidewalls or compartment ceiling, functioning as acoustic damping and/or shielding against thermal influences, wear and tear or even for decorative purposes.

The illumination may be integral with a passenger seat in a vehicle or with a door into the passenger compartment.

The illumination may be integral with the interior of the compartment, e.g. a wall, floor or roof. Thus the illumination may be integral with a roof lining in an automobile or the like. A plurality of such illuminators may be arranged in the vehicle.

The compartment may comprise a plastics or fibrous molded component in or forming part of the compartment, and the light emissive lining may be integral with the component.

Where light emissive systems are incorporated in vehicles, the light emissive lining principle allows them to be fully integrated in prefabricated units including related services such as roof lights and related control and display technology served by as little as one wiring harness for reduced assembly cost. In addition the integration of more advanced facilities in, for example, a vehicle roof lining, adds engineering value to this product.

The integration of illumination systems with vehicle design is an important aspect of modern practice. The light emissive lining of the present invention is uniquely suited to these applications where unobtrusive even totally concealed illumination systems may be designed. Vehicle components which are provided with light emissive lining may include parcel shelves, head linings and door interior panels.

In manufacture, small light emissive linings may be molded into place in a headlining or the like to simplify construction. An light emissive lining according to the present invention may be incorporated in a conventional vehicle using, for example, existing or partially modified surfaces, or by molding and suitable attachment of the light emissive lining to the different linings and trimmings of the vehicle, for example in panels of the headrest remote from occupant head contact.

The light emissive lining can be attached to or installed in the vacuum- forming or other molding process of the internal trimmings, in particular the headlining, the door- lining, parcel-shelf, sun visor or the dashboard of an automobile.

In a particular application, a vehicle foot-well can be provided with a light emissive lining as herein described. In addition, side walls and roof lining can be equipped with the light emissive lining.

WO2006/057531 discloses a light-emitting mat for vehicles. The light- emitting mat comprises a carpet part covered with lots of cilia for the purposes of soundproofing, warmth and impact-absorption and having an opening at a portion thereof; a transparent decoration plate having decorative patterns which correspond to a shape of the opening of the carpet part and supporting the carpet part; a support plate having a recess with a shape which corresponds to the shape of the opening and the decorative patterns for supporting the transparent decoration plate; a transparent light-emitting plate having a size that allows it to be mounted in the recess of the support plate; a plurality of LEDs installed in a plurality of insertion grooves, respectively, formed along edges of the transparent light- emitting plate; a power supply unit for supplying electric power to the light-emitting diodes; and a binder for binding the carpet part, the transparent decoration plate and the support plate.

DE 102006012606 discloses an interior lining for a vehicle that is light emissive. The lining is formed as a woven textile sheet, which is placed in front of a planar light source provided on a molded component. The woven textile sheet structure may impact the light transmissivity of the lining, and may have less favorable acoustic properties since

the thickness of the sheet affects the light transmissivity while thinner sheets reduce acoustic isolation/damping properties.

SUMMARY OF THE INVENTION It is an object of the invention to provide an improved light emissive lining for compartments, in particular, vehicle compartments.

According to an aspect, the present invention provides a compartment comprising a tufted textile, the tufted textile comprising: a backing, and yarns forming tufts extending from a first side of the backing, the compartment further comprising a light source and a conductor arrangement for the light source, wherein the light source, the conductor arrangement and the backing are arranged on a side facing away from the first side of the backing, so as to radiate light from the light source at least partly through the backing, the backing being substantially permeable to light.

The compartment may be provided in a vehicle or public place, the compartment provided with an interior having the tufted textile, light source and conductor arrangement arranged as a light emissive lining.

Although not necessary, the interior may be fully provided with light emissive lining.

Tufted textiles are typically made by providing a backing with yarns which form tufts on its side facing the user during use. Examples of tufted textiles include carpets, draperies and upholstery fabrics. Throughout the description, carpet is taken as an example of the tufted textiles for explaining the present invention. It will be understood that most of the advantages of the present invention explained in relation to carpets are also applicable for other types of tufted textiles such as draperies and upholstery fabrics. Carpet backings generally comprise a primary backing layer provided with yarns forming tufts, a second backing layer, an adhesive layer provided between the primary backing layer and the second backing layer. The yarns penetrate the primary backing layer to form tufts projecting from the pile surface on which people can walk. Stitches are present on the opposite side. The adhesive layer present on the stitch side adheres the stitches to the primary backing layer and holds the tufts in place, as well as adhering the primary backing layer and the second backing layer.

As used in this description, the term 'second backing layer' includes the backing layer which forms the surface of the carpet opposite from the pile surface. Such a layer is usually referred as a 'secondary backing layer' and is commercially available. These

'secondary backing layers' have an advantage that they are well- suited for carpet backing and fit in well with the carpet manufacturing method used in carpet factories. However, it is to be noted that a second backing layer is not restricted to a secondary backing layer, and further layers may be present. For many applications, it is required for the carpets to pass a number of tests.

The carpets may be tested for, among other things, appearance retention, colorfastness to light, cleaning and crocking, tuft bind, delamination strength and electrostatic propensity. An appearance retention test may be performed using the Hexapod Drum, Vettermann Drum or Tetrapod Drum. In these tests, a ball with multiple projections modeling feet tumbles over the pile surface of a carpet, and the appearance is subsequently evaluated. Examples of the appearance retention test method are described in ISO TR 10361 and ISO/CD 12950 and ASTM D-5252 of Hexampod Drum Tester guidelines. The delamination strength of the second backing layer from the primary backing may be performed according to a test described in ASTM D-3936. A test for the strength of the adhesion of the stitches to the backing layer structure may be ASTM D 1355. The second backing layer of the carpet also may need to be tested for air permeability. During curing of the binders, vaporized binders must be able to escape from the backings. The air permeability of the second backing layer may be tested according to ASTM D-737.

The structure of the lining may be multi- layered, comprising a backing in which tufts are fixed, typically using nylon yarns. The backing may be provided with one or more backing layers. In addition, a coating of latex may be spread onto the bottom of the backing in order to further lock the tufts in place. This is conventionally known as the pre- coat latex layer. After the pre-coat layer has dried, an additional layer of latex may be applied (the so-called adhesive layer), onto which a secondary backing layer may be applied. The carpet is then typically placed in an oven (autoclave) to cure the latex. The purpose of the secondary backing layer is to give the carpet structure extra strength.

The lining may be provided in a vehicle compartment typically as a carpet material that has acoustic damping properties and provides decorative covering. In one embodiment the headlining is provided as a translucent carpet, having a backing structure (mono or multilayer structure) that is translucent so that light can be transmitted from a light source provided behind the carpet when mounted in the vehicle. In this embodiment, the carpet fully covers the light source and is fixed onto the light source as a translucent part, which can be manufactured as a conventional carpet provided with a translucent tuft backing.

An element which is substantially permeable to light refers e.g. to an element through which at least a portion of light hitting the element is allowed to transmit. The element may partly or completely be made of a translucent material, or the element may have apertures through which light can penetrate. The invention is based on the realization that the yarns forming tufts of the textile form a structure having enough openings to transmit light, even though the textile appears to be opaque to human eyes. For appearance reason, the tufts are provided in such a way that the primary backing layer is not visible, but the light can still penetrate through the tuft structure. Placing a light source under a primary backing layer which is permeable to light results in that the light from the light source is emitted from the tufted surface.

Such a tufted textile has the advantage that it has less size restriction of the light emitting part.

The adhesive layer holding the tufts in place may also be used to hold the light source and the conductor arrangement in place under the primary backing layer. The light source may be positioned between a second side of the primary backing layer and the adhesive layer. Opening(s) may be provided on the surface of the adhesive layer facing the primary backing layer, in which the light source can be placed.

According to a preferred embodiment of the invention, the adhesive layer is at least partially permeable to light for allowing transmission of the light from the light source to the primary backing layer. This allows that the light source and the conductor arrangement are arranged on the side of the adhesive layer facing away from the primary backing layer, i.e., for instance, on the surface of the adhesive layer. In this case, the light source and the conductor arrangement may be fixed in place with an additional adhesive means. The light source may also be fully encapsulated in the adhesive layer. Alternatively, the light source may be positioned under the adhesive layer with a space between the light source and the adhesive layer.

According to a further embodiment of the invention, the tufted textile further comprises a second backing layer provided on a side of the adhesive layer facing away from the primary backing layer, wherein - the primary backing layer, the adhesive layer and the second backing layer have substantially the same surface area, the adhesive layer is substantially permeable to light and the light source, the conductor arrangement and the second backing layer are arranged so as to allow light from the light source to reach the adhesive layer.

Without the second backing layer, the textile may be more flexible. This may be preferable for draperies and upholstery fabrics. On the other hand, the addition of the second backing layer to the tufted textile as in this embodiment enhances the strength of the textile. This may be preferable for carpets. Compared to draperies and upholstery fabrics, carpets have the specific advantage of having more robustness and thickness, due to which the light source is better protected. Preferably, the light source is provided behind the secondary backing layer of the carpet, in mounted condition, since this allows straightforward fabrication of the carpet without the need for integration of the light sources in the carpet. In this embodiment, the carpet is formed having a translucent backing, which can be provided in one piece on a (planar) light source provided behind the carpet in mounted condition in a vehicle. Additionally, or alternatively the manufacturing method for carpets allows easy incorporation of the light source inside the carpet structure.

The light source may be one or more LEDs. With a structure defined above, there is no restriction in how to distribute the LEDs in, below, or on the second backing layer. Unlike the prior art mat, the LEDs can be placed over substantially the whole area of the second backing layer. The lack of the opening above the LEDs as in the prior art mat makes the carpet according to the present invention more suitable for use in places where light emission is not always needed. There is also no step required for cutting the primary backing layer in the portion above the LEDs, so the manufacturing of the carpet is simple. Furthermore, the primary backing layer contributes to the protection of the LEDs from possible damages caused by e.g. feet or chair legs.

According to a further embodiment of the invention, the LEDs and the conductor arrangement are integrated in the second backing layer, wherein the second backing layer is at least partially permeable to light for allowing transmission of the light from the LEDs to the adhesive layer, or the LEDs and the conductor arrangement are provided on the surface of the second backing layer facing the adhesive layer. These two arrangements of the LEDs, the conductor arrangement and the second backing layer ensure that the light from the LEDs reach the adhesive layer, to be further transmitted to the pile surface of the carpet. The advantage of this approach is that the LEDs are protected within the laminated structure of the carpet. The LEDs are protected, e.g. against abrasion or impact, which could damage e.g. the electronics or damage a water-tight seal around the electronics. On the pile surface side, the LEDs are protected by the primary backing with tufts, and on the opposite side the LEDs are protected by the second backing. Protection of the backside is especially important during installation of the carpet.

According to a further embodiment of the invention, the primary backing layer is substantially translucent. As used in this description, the term 'translucent' means that all or part of the wavelengths of the visible light is permitted to pass through the material, with or without being diffused. This has the advantage that the decrease of the intensity of the light emitted from the LEDs by the primary backing layer is reduced. For example, more than 5%, or more than 10%, or more than 30% of light intensity may be transmitted.

According to a further embodiment of the invention, the primary backing layer has apertures which are covered by the tufts. In such an arrangement where the apertures are not visible to human eyes, the carpet can be used as a regular carpet when the LEDs are off. The apertures increase the intensity of the emitted light. The freedom of the choice of material for the primary backing layer is high, because the primary backing layer material is not necessarily translucent. An example of such a backing layer may be a woven backing layer.

According to a further embodiment of the invention, at least one of the primary backing layer and the second backing layer comprises polypropylene, nylon or jute. These materials have the advantage that they are of relatively low cost. It is easy to manufacture a translucent structure with polypropylene or nylon. Also, the fact that these materials are commonly used in existing tufted carpets makes the carpet according to the invention easy to manufacture. It is noted that these backing layers may substantially consist of the above materials.

According to a further embodiment of the invention, the adhesive layer comprises latex. The latex may be a translucent latex. It is noted that the adhesive layer may substantially consist of latex. The latex may be based on terpolymers of styrene, butadiene and an acidic vinyl monomer. When the adhesive layer substantially consists of translucent latex and comprise substantially no light scattering particles, the light from the LEDs can leave the carpet efficiently. Thus, preferably no light scattering fillers are used in the adhesive and the adhesive layer is translucent.

According to a further embodiment of the invention, the adhesive layer comprises acrylics. The acrylics may be a translucent acrylics. It is noted that the adhesive layer may substantially consist of acrylics. An example of acrylics is polyacrylate ester.

Advantages of acrylics are hardness, flexibility and resistance against UV. Acrylics are also highly resistant to heat, which makes it an especially suitable material for use in combination with LEDs which generate a relatively large amount of heat. Latex and acrylics may also be used in combination.

According to a further embodiment of the invention, the adhesive layer comprises light scattering particles, which are also referred as fillers. Fillers have the advantage of reducing the cost of the carpet, while bulking up the adhesive at the same time. Because the fillers scatter light, this results in that the light from the carpet appears to originate from an area larger than the original emission spot. It is advantageous when a homogeneous light emission is desired. The light scattering particles may be calcium carbonate. The advantage of calcium carbonate is that it is of relatively low cost. Calcium carbonate may be in the form of calcite or chalk. The light scattering particles may also be kaolinite such as china clay fillers. Typically the fillers are used in quantities such as for example 600 g/1, but for many embodiments of the current invention it is preferred that much lower amounts are used in order to increase the light transmittance for example, lower than 60 g/1 or even lower than 6 g/1. In the latter case, the fillers function a light diffuser without substantially hindering the optical translucence. When reducing the amount of filler, the total amount of adhesive may also be reduced, for example to 400 g/m2 (instead of typically 700 g/m2) for the pre-coat layer and 400 g/m2 (instead of typically 600 g/m2) for the adhesive layer (dry weight).

According to a further embodiment of the invention, the adhesive layer comprises electrically conductive particles. The electrically conductive particles give the carpet anti-static properties. The electrically conductive particles may be e.g. carbon black, potassium formate (HCOOK), tin-oxide, indium-tin-oxide or silver.

According to a further embodiment of the invention, the adhesive layer comprises anti-oxidants. The amount of anti-oxidants may be in the range of 1-3 parts per 100 parts latex (per weight), but more preferably it is in the range 4-6 parts per 100 parts latex, or even 7-9 parts per 100 parts latex. The anti-oxidants make the adhesive layer more resistant to heat. This is advantageous because LEDs can generate a substantial amount of heat. Also, latex without anti-oxidants may age faster and become yellow after some time.

According to a further embodiment of the invention the second backing layer has an air permeability of at least 76.2 m ³ /min/m ² . Air permeability of the second backing layer can be determined according to ASTM D-737, with a pressure differential equal to 0.5 inch (1.27 cm) water. An acceptable value is 250 ft ³ /min/ft ² (76.2 m ³ /min/m ² ), but more preferred values are in the range of 350-800 ft ³ /min/ft ² (106.7-243.8 m ³ /min/m ² ). Second backing layers with an air permeability of only 80 ft ³ /min/ft ² (24.4 m ³ /min/m ² ) are considered to be less favorable for high binder cure rates.

According to a further embodiment of the invention, the second backing layer has apertures for air passage. Vaporized binders used for the adhesive layer can pass through the apertures during curing of the carpet. With this embodiment, it is promoted that the air permeability of the second backing layer is sufficiently high. According to a further embodiment of the invention, the carpet has a de lamination strength of at least 44.6 kg/m between the primary backing layer and the second backing layer.

According to a further embodiment of the invention, the conductor arrangement and connections between the LED and the conductor arrangement are embedded in a water-tight enclosure. This promotes the electrical safety of the carpet, even when the carpet is wet.

According to a further embodiment of the invention, the LEDs are connected to form a circuit comprising sets of LEDs connected in series, the sets being connected in parallel. This arrangement has an advantage that the construction is simple and easy to manufacture. The conductor arrangement may be pre-manufactured on a sheet of e.g. plastic, after which it is provided on or integrated in the second backing layer.

According to a further embodiment of the invention, the conductor arrangement comprises two grids of conductive wires, which are electrically isolated from each other. According to a further embodiment of the invention, each of the LEDs is covered with a protective cover. The protective cover may be made of silicone rubber. This not only promotes the electrical safety of the carpet, but also that the carpet performs better in the appearance retention test mentioned above. During the test, the LEDs are better protected against the impact of the balls tumbling over the carpet. Additionally, the silicone rubber is soft and flexible, due to which is becomes less likely for a person to feel the presence of the light source within the carpet structure.

According to a further embodiment of the invention, the LEDs and the circuit arrangement are arranged so that at least a part (and preferably a substantial part, or more preferably all) of the LEDs is operable when the carpet is reduced in size. This may be achievable by a carpet in which the second backing layer comprises, successively from the side facing away from the adhesive layer, a first electrically insulating layer, a first electrically conductive layer, a second electrically insulating layer, a second electrically conductive layer and a third electrically insulating layer, wherein each of the LEDs has a first and a second connector respectively connected to the first and the second electrically

conductive layer. The first and the second electrically conductive layers act as the conductor arrangement. When the carpet is cut in an area between discrete LEDs, the remaining LEDs are still connected to the power source, resulting in that the LEDs are still able to be turned on and off. This substantially reduces the limitation in the size or shape the carpet is cut. Also, a carpet in which the LEDs are connectable to the power source in parallel may achieve the above-mentioned enhanced freedom in cutting. When part of the carpet comprising some of the LEDs is cut away in an embodiment where the LEDs are connected in parallel to the power source, the LEDs in the remaining portion are still connected to the power source, and remain operable. According to a further embodiment of the invention, at least the second electrically conductive layer and the third electrically insulating layer are substantially translucent.

According to a further embodiment of the invention, the first and the second conductive layers substantially consist of a material embedded with electrically conductive particles. The electrically conductive particles give the layers electrical conductivity, so the material itself may be electrically insulating. The electrically conductive particles may be e.g. tin-oxide, indium-tin-oxide, or silver.

According to a further embodiment of the invention, the material of the first and the second conductive layers substantially consists of a translucent rubber. According to a further embodiment of the invention, the electrically conductive particles are light scattering. Because the electrically conductive particles also have light scattering properties in this embodiment, there is no need for additional light scattering particles in the carpet for a homogeneous light output.

According to a further embodiment of the invention, the carpet further comprises a third backing layer adhered to a side of the second backing layer facing away from the adhesive layer.

According to a further embodiment of the invention, the LEDs are Red-Green- Blue (RGB) LEDs. For example, a portion of the LEDs is red LED, another portion is green LEDs and yet another portion is blue LEDs. The use of RGB LEDs is advantageous because it allows the color of the carpet to be changed. For example when white tufts are used in combination with RGB LEDs, it is possible to change the color of the carpet into any desired color. For example, by setting the RGB LEDs to the color green, the tufts of the carpet will look green. This effect may be combined with colored tufts in carpet zones that are not changing color.

According to a further embodiment of the invention, the light source comprises a light emitting sheet arranged on a side of the second backing layer facing away from the adhesive layer. The light emitting sheet may be adhered to the second backing layer by a second adhesive layer. The light emitting sheet may also be adhered to the second backing layer by mean of an adhesive tape. In this case, the second adhesive layer between the light emitting sheet and the second backing layer is not required. It is also noted that the light emitting sheet may be positioned under the second backing layer with a spacing in between. This can be realized, e.g. by adhering only a part, e.g. the rim of the light emitting sheet, to the second backing layer. It is also possible to use no adhesive at all. According to a further embodiment of the invention, the light emitting sheet comprises an electroluminescent panel, an LED panel or an OLED panel. The advantage of an electroluminescent panel, an LED panel or an OLED panel is that they may be made flexible and thin, which makes them more suitable for use in the present invention. The light emitting sheet may also comprise other light sources such as incandescent and fluorescent lighting.

According to a further embodiment of the invention, the tufted textile further comprises a reflecting layer positioned to a side of the light emitting sheet facing away from the second backing layer. The reflecting layer can direct the light from the light emitting sheet to the pile surface and increase the intensity of the light emitted from the tufted textile. The invention also provides a second backing layer structured as defined in any one of the embodiments above.

The invention also provides an illumination system comprising a carpet as defined in any one of the embodiments above, control circuits of the LEDs and a lighting controller for controlling signals provided to the control circuits. The invention also provides a method of manufacturing a carpet comprising a light source and a conductor arrangement for the light source, comprising the step of: adhering a primary backing layer which is substantially permeable to light provided with yarns forming tufts and a second backing layer having substantially the same surface area as the primary layer with an adhesive layer which is substantially permeable to light and having substantially the same surface area as the primary backing layer and the second backing layer, wherein the light source, the conductor arrangement and the second backing layer are arranged so as to allow light from the light source to reach the adhesive layer. The light source may be one or more LEDs. Alternatively, the light source may comprise a light

emitting sheet arranged on a side of the second backing layer facing away from the adhesive layer.

According to a preferred embodiment of the invention, the step of adhering comprises the sub-steps of: - applying a first adhesive sub-layer on the side of the primary backing layer facing away from the tufts; drying the first adhesive sub- layer; applying a second adhesive sub-layer on the dried first adhesive sub-layer and applying the second backing layer to the second adhesive sub-layer. During manufacturing of the carpet, the adhesive layer may be applied in two steps. First a pre-coat of an adhesive material is applied to the stitch side of the primary backing layer, in order to lock the tufts in place. After the pre-coat layer has dried, a second adhesive layer is applied on the dried pre-coat layer, which is used to adhere the second backing to the primary backing. The pre-coat adhesive layer and the second adhesive layer may be made of different types of latex. For example, different amount of calcium carbonate particles may be added.

The invention also provides a method of manufacturing a second backing layer of a carpet, comprising the steps of: providing a first electrically isolating layer substantially consisting of translucent rubber; applying a first layer of uncured translucent electrically conductive rubber on top of the first layer of electrically isolating translucent rubber; immersing a light source into the first layer of uncured translucent electrically conductive rubber; - curing the first layer of uncured translucent electrically conductive rubber to form a first electrically conductive layer; providing a second electrically isolating translucent layer on top of the first electrically conductive layer; applying a second layer of uncured translucent electrically conductive rubber on top of the electrically isolating translucent layer; curing the second layer of uncured translucent electrically conductive rubber to form a second electrically conductive layer; and providing a third electrically isolating translucent layer on top of the second electrically conductive layer.

According to a preferred embodiment, the light source is a plurality of LEDs. In this embodiment, the step of immersing the light source may comprise a step of immersing LEDs each having a first electrode and a second electrode into the first layer of uncured translucent electrically conductive rubber such that the first electrode is at least partially immersed in the rubber.

According to an embodiment the textile is used as automotive textile, covering one or more parts of the interior of an automotive vehicle (for example floor, roof, and sidelines). Automotive vehicles have the advantage that it is easy to supply the light source with power, and that the surface is often metallic, which allows effective cooling of the light source(s). In addition, the textile has favorable acoustic damping properties which increases the travel comfort. The textile in addition provides convenient illumination or coloring of the interior.

In one embodiment, the light emissive lining is provided as an emergency lighting system, arranged to provide emergency lighting and or emergency information display. The embodiment comprises a light emissive carpet controlled by a display controller in a first operation mode, wherein the light emissive function of the carpet is shut off or only used for decorative light emissive purposes; and wherein, in a second operation mode, the display controller instructs the light emissive carpet to display safety or information signals. The controller may be receiving instructions from a central safety control system and additionally, the controller and/or light emissive carpet may be fed by emergency power supply.

It is noted that the invention relates to all possible combinations of features recited in the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other aspects of the invention will be apparent from and elucidated with reference to the drawings in which:

Figure 1 schematically illustrates a cross sectional view of an embodiment of the carpet according to the invention; Figures 2a, 2b and 2c schematically illustrate a cross sectional view of further two embodiments of the carpet according to the invention;

Figure 3 schematically illustrates a cross sectional view of a further embodiment of the carpet according to the invention;

Figure 4 schematically illustrates an electric scheme of the LEDs and the conductor arrangement for the second backing layer according to the invention;

Figure 5 schematically illustrates a perspective view of an embodiment of the second backing layer according to the invention; Figure 6 schematically illustrates a cross sectional view of a further embodiment of the second backing layer according to the invention;

Figure 7 schematically illustrates a cross sectional view of a further embodiment of the second backing layer according to the invention and

Figure 8 schematically illustrates a cross sectional view of an embodiment of the carpet according to the invention;

Figures 9a-d schematically illustrate an exemplary method of manufacturing the second backing according to the invention using translucent rubber

Figures 10a and 10b show experimental results of the optical properties of a conventional carpet and the carpet according to the present invention; Figure 11 illustrates an example of a tufted textile (100) in the form of a tufted carpet;

Figure 12 and Figure 13 show examples of a vehicle having a passenger compartment provided with light emissive lining;

Figure 14 shows an alternative example of a vehicle having a passenger compartment;

Figure 15 shows an additional safety or information application;

Figure 16 shows another embodiment;

Figure 17 shows yet another embodiment; and

Figure 18 and Figure 19 show liner systems that may be arranged modularly.

DETAILED DESCRIPTION OF EMBODIMENTS

It is noted that the same reference numbers have been used for corresponding elements in the embodiments whenever possible.

A carpet is taken as an example of the tufted textile according to the present invention to describe the present invention. It should be noted that the description is also applicable to other types of tufted textiles.

Referring to Figure 1, the cross section of an embodiment of a carpet 100 according to the present invention is shown. The carpet 100 comprises a primary backing layer 10, a second backing layer 20 and an adhesive layer 30 between the primary backing

layer 10 and the second backing layer 20. Tufts 40 formed by yarns are provided on and held in place by the primary backing layer 10. LEDs 50 and a conductor arrangement 60 are integrated in the second backing layer 20. It is noted that the LEDs 50 and the conductor arrangement 60 may also be provided on top of the second backing layer 20. The LEDs 50 are distributed over substantially the whole area of the second backing layer 20. Preferably, the distance between the LEDs 50 is 1-20 cm, more preferably 5-15 cm. The primary backing layer 10, the second backing layer 20 and the adhesive layer 30 have substantially the same surface area. The primary backing layer 10 and the adhesive layer 30 are substantially permeable to light. In this embodiment wherein the LEDs 50 and the conductor arrangement 60 are integrated in the second backing layer 20, the second backing layer 20 is at least partially permeable to light for allowing transmission of the light from the LEDs 50 to the adhesive layer 30. The light permeability of the layers 10, 20, 30 may be realized by the layers 10, 20, 30 being substantially translucent or the layers 10, 20, 30 having apertures for the transmission of the light. In case the apertures are present in the primary backing layer 10, they may at least partly be covered by the tufts 40 so that they will hardly/not be visible to human eyes. The primary backing layer 10 and the second backing layer 20 may substantially consist of e.g. polypropylene, nylon or jute. The adhesive layer 30 may substantially consist of e.g. latex.

When the LEDs 50 are turned on, the light from the LEDs 50 goes through the second backing layer 20, the adhesive layer 30 and the primary layer 10 because of their light permeable properties. The light will then pass through the gaps between the tufts 40, and will be emitted to the outside of the carpet. The density and the type of the tufts 40 used can control the amount and/or distribution of light emitted from the carpet 100. When the LEDs 50 are turned off, only the tufts 40 will be visible, and the carpet 100 will not look different from a regular carpet.

The second backing layer 20 may be based upon an existing product for the secondary backing layer, such as the one known under the name ActionBac®. For example, this is a backing made of a leno weave of slit film and spun olefin yarns. It has a 2.1 ounce per square yard (0.71 gram per square meter) fabric with polypropylene warp tapes and polypropylene multifilament picks in a leno wave with averages of 16 warps per inch (per 2.54cm) and 5 picks per inch (per 2.54cm). Such a backing layer imparts dimensional stability with good delamination strength in carpets. This backing layer also has openness well suited for robust curing rates during manufacture. The air permeability of this backing, determined according to ASTM D-737 with a pressure differential equal to 0.5 inch water,

exceeds about 750 ft ³ /min/ft ² (229 m ³ /min/m ² ), which is ample for robust binder cure rates. Another such product with a higher count, 18x13, leno wave construction, has average air permeability above about 720 ft ³ /min/ft ² (219 m ³ /min/m ² ). This is also well suited for efficient cure rates. Preferably, the second backing layer 20 has a high adhesive compatibility with the material used for the adhesive layer 30, so that the carpet 100 will pass delamination test such as the test described in ASTM D-3936. The delamination resistance-imparting properties should preferably be such that the backing when laminated in the reference carpets described has a delamination strength of at least 2.5 pounds/in (44.6 kg/m). However, preferred values are greater than 3-4 pounds/in (53.6-71.4 kg/m), more preferably at least 5.5 pounds/in (98.2 kg/m) and even more preferably at least 6 pounds/in (107.1 kg/m).

It should be noted that any other existing second backing material may be used as basis for the second backing used in this invention. Other examples are needlefelt backings, rubber backings, PVC backings, polyurethane backings, vinyl backings, cushion backings, nylon backings. The fibers in the needlefelt backings are needled for bonding. It is also noted that a cushion or padding may be integrated in the second backing. Another example of a second backing material is bitumen. This material is used when extra sturdy carpet is required, such as for example in carpet tiles, or in car mats. In some embodiments (for example as in figure 2a), bitumen may also be used as adhesive.

Referring to figures 2a and 2b, the cross section of two further embodiments of a carpet 100 according to the present invention is shown. This embodiment is similar to the embodiment shown in figure 1 except for the lack of the second backing layer 30 which is present in the embodiment of figure 1. In figure 2a, the LEDs 50 are provided directly on the primary backing layer 10. The LEDs 50 and the conductor arrangement 60 are embedded in the adhesive layer 30. In figure 2b, the LEDs 50 and the conductor arrangement 60 are provided on the surface of the adhesive layer 30.

Additionally, in Figure 2c, the LEDs 50 and conductor arrangement 60 may be provided as separate elements possibly attached to a mounting element 220 to provide a planar light source 200; where the light permeable carpet 100, including primary backing 10, adhesive layer 30 and secondary backing, in the form of second backing layer 20, is attached via an optional adhesive layer 300 to the planar light source 200. Alternatively, spotlights may be used.

Referring to Figure 3, the cross section of a further embodiment of a carpet 100 according to the present invention is shown. This embodiment is similar to the embodiment shown in figure 1 except for the light scattering particles 70 embedded in the

adhesive layer 30. The light scattering particles 70 may be e.g. calcium carbonate. The use of calcium carbonate has an advantage that it is relatively inexpensive. The adhesive layer 30 may comprise, in addition or alternatively to the light scattering particles 70, electrically conductive particles. The electrically conductive particles improve the anti-static properties of the carpet. The electrically conductive particles may be e.g. carbon black, potassium formate (HCOOK), tin-oxide, indium-tin-oxide or silver. It is to be noted that the size of the electrically conductive particles may be chosen to have light scattering properties. Furthermore, in addition or alternatively to the above-mentioned particles, the adhesive layer may comprises anti-oxidants. The anti-oxidants make the adhesive layer more resistant to heat.

It is to be noted that the primary backing layer 10 and the second backing layer 20 may also comprise light scattering particles 70.

Figure 4 schematically illustrates an electric scheme of the LEDs and the conductor arrangement for the second backing layer 20 according to the invention. In this embodiment, the LEDs 50 are connected to form a circuit comprising sets of LEDs 50 connected in series wherein the sets are connected in parallel. The advantage of this embodiment is that the construction is simple and easy to manufacture. The conductor arrangement 60 may be pre-manufactured on a sheet of for example plastic, after which it is embedded in the second backing layer material. Figure 5 schematically illustrates the perspective view of an embodiment of the second backing layer 20 according to the invention.

In this embodiment, the LEDs 50 and the conductor arrangement 60 are provided on top of the second backing layer 20. The second backing layer 20 may also have recesses on its surface, into which the LEDs 50 are mounted. The conductor arrangement 60 comprises two grids of conductive wires 61, 62 which are electrically isolated from each other. When the carpet 100 is cut in the portions between the LEDs 50, the LEDs 50 are still connected to the power source, resulting in that the LEDs 50 are still able to be turned on and off. This substantially reduces the limitation in the size or shape the carpet 100 is cut.

In this embodiment, a protective cover 80 is disposed over each of the LEDs 50. The protective covers 80 may substantially consist of a silicone rubber. One of the LEDs 50 is shown without the protective cover. The second backing layer 20 may have apertures for air passage. Vaporized binders used for the adhesive layer 30 pass through the apertures during curing of the carpet 100. This ensures that the air permeability of the second backing layer 20 is sufficiently high. These apertures allow more freedom in the choice of materials

for the second backing layer 20 in that the second backing layer 20 with low air permeability may be used.

It is to be noted that the conductor arrangement 60 may be made with more than two grids. For example, when four grids are used, it is possible to control the color of RGB LEDs.

Figure 6 schematically illustrates the cross section of a further embodiment of the second backing layer 20 according to the invention. For the carpet 100 to emit light from its pile surface, the LED 50 used herein may be a side emitting LED, or a normal LED with adapted electrode connectors. In this embodiment, the second backing layer 20 comprises, successively from the side facing away from the adhesive layer, a first electrically insulating layer 21, a first electrically conductive layer 22, a second electrically insulating layer 23, a second electrically conductive layer 24 and a third electrically insulating layer 25. The LED 50 is embedded in the second backing layer 20. Each of the LEDs 50 has a first and a second connector 51 and 52 respectively connected to the first and the second electrically conductive layers 22 and 24. A single power supply is required to connect all LEDs 50. An installer can cut this carpet in any size and the LED system will still operate in the same way. This multilayer construction also has an advantage that the LEDs are protected well against damage and water. In this embodiment, the layers 21-25 may be translucent. The electrically insulating layers 21, 23, 25 may be made of a translucent rubber. The electrically conductive layers 22, 24 may be a translucent rubber comprising electrically conductive particles.

Figure 7 schematically illustrates the cross section of a further embodiment of the second backing layer 20 according to the invention. In this embodiment, light from the LED 50 is emitted in horizontal direction, which is perpendicular to the preferred light output direction. For emitting the light in the direction of the pile surface of the carpet, light scattering particles 70 are embedded in the conductive layers 22 and 24. The light scattering particles 70 scatter the light from the LED 50 and the light is emitted outside of the second backing layer. It is to be noted that the electrically conductive particles imparting the conductivity to the electrically conductive layers 22 and 24 may be used for light scattering purpose. In other words, the size of the electrically conductive particles may be adapted to also serve as the light scattering particles 70. A reflecting layer may be provided under the layer 21 for redirecting light in the direction of the side facing the adhesive layer 30.

Figure 8 schematically illustrates the cross section of an embodiment of a carpet 100 according to the present invention. This embodiment shows, in contrast to the embodiment shown in figure 1 a light emitting sheet 90 instead of individual LEDs. The light emitting sheet may be e.g. an electroluminescent panel, a LED panel comprising a plurality of LEDs or an OLED panel. The LED panel may be a string of LEDs mounted on a flexible PCB, on which electronics are arranged that allow the LED panel to be cut at a desired length. The conductive arrangement 60 is not shown for clarity's sake.

This light emitting panel 90 is adhered on a side of the second backing layer 20 facing away from the adhesive layer by a second adhesive layer 91. The second backing layer 20 and the second adhesive layer 91 may be at least partially permeable to light for allowing transmission of the light from the light emitting panel 90 to the adhesive layer 30 between the primary backing layer 10 and the second backing layer 20. This may be achieved by the use of a second backing layer 20 and a second adhesive layer 91 which are at least partly translucent. Such a second backing layer 20 may be obtained by providing the second backing layer 20 with apertures large enough to transmit light but small enough to maintain its surface substantially the same as the primary backing layer 10 and the adhesive layer 30. The second adhesive layer 91 may be made at least partly translucent in a similar manner as the adhesive layer 30 between the primary backing layer 10 and the second backing layer 20. Translucent latex, without light scattering particles such as calcium carbonate, may be used for this purpose. The carpet 100 may further comprise a reflecting layer (not illustrated) positioned to a side of the light emitting panel 90 facing away from the second backing layer 20. This reflector may also be integrated within the light emitting panel 90. It is also possible to provide an alternative fixing and to not glue the light emitting panel to the carpet, in effect not providing an adhesive 91. Figures 9a-d schematically illustrates an exemplary method of manufacturing the second backing according to the invention using translucent rubber.

As illustrated in figure 9a, first, a layer 22a of uncured translucent electrically conductive rubber is applied on top of a layer 21 of cured electrically isolating translucent rubber. While the layer 22a applied on top of the layer 21 is in a liquid form, a LED 50 is immersed into the rubber. The immersion is done in such a way that the electrode 51 of the LED 50 is at least partly immersed in the rubber. Subsequently the rubber layer 22a is cured to form the translucent electrically conductive layer 22, for example with vulcanization, or any other suitable means for curing the rubber.

After the electrically conductive layer 22 is formed, a layer of electrically isolating translucent rubber 23 is applied on top of the layer 22, as illustrated in figure 9b. The thickness of this layer 23 is such that the electrode 51 is now fully immersed, and that the electrode 52 is at least partially uncovered. The layer 23 may be applied in liquid form after which it is cured, but it is also possible to use a pre-shaped sheet, which is glued to layer the layer 22.

Subsequently, another layer 24a of uncured translucent electrically conductive rubber is applied onto the electrically isolating layer 23, as illustrated in figure 9c. Subsequently the rubber is cured to form the electrically conductive layer 24. The amount of the uncured rubber is chosen such that at least part of the electrode 52 is immersed in the electrically conductive layer 24 formed by the curing of the rubber.

Then, as illustrated in figure 9d, another layer of electrically isolating translucent rubber 25 is applied in order to seal off the device such that no electrical voltage is on the outside and the device may be handled safely. In the above manufacturing example uncured rubber is used. However, it should be noted that also pre-shaped cured sheets may be used.

An advantage of this method is that the manufacturability is improved because the LEDs do not have to be connected by wires.

Figure 10a and b show experimental results of the optical properties of the conventional carpet and the carpet according to the present invention. Figure 10a shows the reflection, transmission and absorption of a conventional carpet consisting of a primary backing layer, a second backing layer (sold under the name of ActionBac®) and an adhesive layer. The measurement shows that the optical transmission is below 1% over the wavelength range of 200 nm to 800 nm and the absorption is so high that even with back-reflector less than 1% of light will be transmitted. This results from the fact that the conventional adhesive layer comprises a too high amount of calcium-carbonate particles which makes the adhesive layer opaque.

In an embodiment, the materials for the adhesive layer and the second backing layer are chosen so that these layers will transmit light. An experimental result of the transmission and the reflection of the carpet according to the present invention is shown in figure 10b in comparison with a conventional carpet. In the figure, IR, 2R, IT and 2T refer to reflection of the conventional carpet, reflection of the carpet according to the present invention, transmission of the conventional carpet and transmission of the carpet according to the present invention, respectively. The carpet according to the present invention comprises

an adhesive layer made of transparent latex that does not comprise calcium carbonate particles and a second backing layer having apertures (e.g. Action Bak ®). At 550nm, the transmission increased to 11% in the carpet according to the present invention compared to below 0.2% in the conventional carpet. The reflectivity increased from 32% to 37% at 550nm. It should be noted that with back-reflector the total light transmittance can be increased further. Also, by integrating the light source in the carpet structure (see for example figure 2A) the optical transmittance may be increased further.

Figure 11 shows an example of a conventional tufted textile 400 in the form of a tufted carpet, comprising a backing 10, yarns forming tufts 40 extending from a first side of the backing. The backing 10 of the tufted carpet 100 comprises a primary backing layer 10 in which tufts are made, typically using nylon yarns 40. Subsequently a coating of latex 30 is spread onto the bottom of the carpet in order to lock the tufts in place. This is called the pre- coat latex layer. After the pre-coat layer has dried, an additional layer of latex is applied (the so-called adhesive layer 30), onto which a secondary backing is applied. The carpet is then placed in an oven (autoclave) to cure the latex. The purpose of the second backing layer 20 is to give the carpet structure extra strength. In a preferred embodiment a polyolefin dispersion is used as pre-coat (on for instance the primary layer for subsequent providing the adhesive layer) and/or the adhesive layer itself. A suitable polyolefin dispersion may for instance be HYPODTM of Dow Chemical. These are propylene- and ethylene-based dispersions that combine the performance of high-molecular- weight thermoplastics and elastomers with the application advantages of a high- so lids waterborne dispersion. Polyolefin dispersions can provide benefits to carpet manufacturers by allowing them to apply a thermoplastic backing using conventional coating equipment. For example, using a carpet backing of PVB (poly vinyl20 butyral), or polypropylene, the problem of UV sensitivity may be solved, while at the same time increasing the light permeability. Hence, another suitable polyolefin dispersion maybe a pvb-based dispersion. However, other thermoplastics might have an even higher light permeability. In this example the backing is formed by the primary backing layer 10, the pre-coat latex layer 35, the adhesive layer 30 and the secondary backing layer 20. In alternative embodiments, the backing may be comprised of additional layers, including adhesive layers, or may even be comprised of a monolayer wherein the tufted textile is fixed to extend from a first side of the backing. According to an aspect, the backing is substantially permeable to light.

Figure 12 and Figure 13 show examples of a vehicle having a passenger compartment provided with light emissive lining, the lining being formed as a tufted textile

100. In Figure 12 an automobile interior is shown having emissive lining 100 embedded in the headliner to recreate a night sky on the roof. The system may comprise separately addressable areas, such that illumination can also be done for different sections of the vehicle. For example, a passenger car might have a separately controllable section to illuminate the roof above the driver, a section illuminating the person next to the driver, and a section illuminating the back of the car. In addition, the carpet may be used to cover the sides of the vehicle, such as for example the inside of a door. This has especially a decorative effect, but it may also be used to help a person find buttons or handles on the door. In this respect, the invention additionally relates to a vehicle having a compartment 1200 provided with light emissive lining, the lining being formed as a tufted textile 100 wherein the light emissive liner is arranged to indicate the presence of manual controllers in the car, in particular, handles, door knobs and window controls. For example, a light emissive striping may be arranged in the liner provided around a door handle (not shown). In yet another embodiment the carpet is used to illuminate the floor of the vehicle. For example, the carpet in the footwell of the vehicle may be emitting light, or strips of illuminated carpet may be used on the floor of the vehicle close to the door, in order to help passengers get into the vehicle.

In Figure 13 roof and roof lining of a vehicle 1300 is omitted in the interests of clarity, and illustrate that tufted textile illumination of the kind described above provided in the interior lining 1314 of the passenger footwells 1313 and may benefit from such positioning to improve, in addition to illumination, the noise, vibration and harshness (NVH) characteristics of the interior since the lining may provide additional acoustic damping. In particular a light emissive liner system according to the invention will reflect and/or transmit less sound than for instance a light emissive liner having LEDs placed on top of the lining surface. In addition, this liner is well protected against wear since the tufts function as additional protection for the light source 1350. For example, in the case of a fibre-optic carpet wherein end points of the fiber optics extend through the carpet face, the optics will wear and may be damaged. In addition, the light output of such fibre-optic carpet may not generate sufficient light to be able to provide interior lighting in the car. Figure 14 shows an alternative example of a vehicle 1410 having a compartment 1400, in this example, the interior of a booth, provided with light emissive lining. In this example, a signaling function, such as emergency lighting is provided in the booth 1400 of a car having light emissive liner provided on the interior. The main function of this system is safety. If there is an emergency and the vehicle is now stopped along the road,

the booth can be opened to make the light emissive carpet visible. The carpet can show a warning/danger sign. Main advantage of this embodiment is that the sign can be placed on a relative high position which increases visibility and increases the safety.

Figure 15 shows an additional safety or information application of the light emissive carpet in a compartment 1500, such as a corridor, aisle or the like. In this embodiment, the carpet 1510 is controlled by a display controller in a first operation mode, wherein the light emissive function of the carpet is shut off or only used for decorative light emissive purposes. In a second operation mode, the display controller 1520 instructs the light emissive carpet 1510 via a data connection 1530 to display safety or information signals. The controller may be receiving instructions from a central safety control system 1540 and additionally, the controller 1520 and/or light emissive carpet 1510 may be fed by emergency power supply 1550. This application may be provided within moving vehicles but is also suited for other compartments, such as in public places, buildings etc. The provision of emergency exit information via the light emissive carpet provides an advantage over emergency systems provided on the ceiling in situations where smoke is present and emergency systems are invisible due to debris or smoke. In figure 15 the safety information is shown in the form of text and an arrow. It may be clear that other safety information types can be applied, such as a line or dots forming a line, to guide people to safety. Switching of light dots in a line can be used to provide a safety direction. Preferably, the lighting system is chosen such that the peak light output intensity through the carpet is at least 35 mcd with a minimum spacing between lamps of 12 inches (30.5 cm). More preferably, the peak light intensity is more than 150 mcd with a spacing of 10 cm between lamps, and even more preferably more than 1000 mcd.

When using LEDs below the carpet, this translates into a LED power between roughly 18 mW and 500 mW.

The safety system may be applied in passenger vehicles, such as buses, trains, ships and airplanes.

Figure 16 shows another application wherein a vehicle compartment 1600 is provided with a light emissive liner 1610. In this application, the light emissive liner 1610 comprises a controller 1620 connected to a multimedia device such as a video screen 1630. The controller 1620 is arranged to instruct the light emissive carpet 1610 to display pixelated light patterns in conformity with a video signal. For instance, the controller 1620 may be responsive to the video signal, in that it analyses a primary color or primary patterns

derivable from the video signal. One application may be to color the interior of the compartment 1600 in conformity with a background color of the video signal.

Alternatively or additionally, the light patterns may be controlled by a pattern generator (for instance, included in controller 1620) which reacts to ambient signals, such as a sound, temperature, light or rain sensors (not shown). For instance, a color tone or light intensity of the lining may be adjusted to an ambient light condition or temperature.

Figure 17 shows yet another embodiment, wherein a light emissive carpet is used as an additional illumination source in a passenger compartment 1700. As shown, in a conventional floor lighting setup, pointed shoes 1701 may damage or obstruct the light emission of light sources 1750 arranged in or on the floor 1701 . The present invention provides floor lighting, wherein light sources, such as spot lights or high brightness led lights 1750 may be provided in the floor for illumination purposes, while being protected against wear and impact by the light permeable tufted carpet 1710. Here, the light permeable carpet 1710 is covering the light sources 1750 to protect the light source. The tufted textile 1710 may be provided on the floor 1701, and may be kept free from adhesive while covering the light sources 1750.

In this way, optimal light transmission through the tufted textile can be arranged.

Figure 18 shows a liner system 1810 that may be arranged modularly, in particular, for passenger compartments or public places 1800. Such system 1810 may combine flexibility of design with robustness and may function as electronic carpet systems which may be easily coupled. To this end, the light emissive lining is provided on a body 1820 for attachment to an inner room surface, in particular, floor surface . In an embodiment, the body comprises a planar light source provided on the body and a tufted textile provided on the light source being substantially permeable to light. The body may further comprise control circuitry to control the light source, in particular, to control a color or light pattern generated by the light source. The control circuitry may further comprise connectors 1840 for coupling to another body, to arrive at a modularly connected liner system.

In some aspects, embodiments of the invention may be characterized as follows:

A tufted textile comprising: a primary backing layer which is substantially permeable to light, yarns forming tufts on a first side of the primary backing layer,

an adhesive layer provided on a second side of the primary backing layer opposite from the first side, and a light source and a conductor arrangement for the light source arranged in a position facing the second side of the primary backing layer, wherein the adhesive layer, the light source and the conductor arrangement, are arranged so as to allow light from the light source to reach the primary backing layer;

The adhesive layer may be at least partially permeable to light for allowing transmission of the light from the light source to the primary backing layer;

The adhesive layer may comprise at least one of latex and acrylics; The adhesive layer may be translucent;

The tufted textile may further comprise a second backing layer provided on a side of the adhesive layer facing away from the primary backing layer, wherein the primary layer, the adhesive layer and the second layer have substantially the same surface area, - the adhesive layer and the primary backing layer are substantially permeable to light and the light source, the conductor arrangement and the second backing layer are arranged so as to allow light from the light source to reach the adhesive layer.

The light source and the conductor arrangement may be integrated in the second backing layer, wherein the second backing layer is at least partially permeable to light for allowing transmission of the light from the light source to the adhesive layer, or the light source and the conductor arrangement are provided on the surface of the second backing layer facing the adhesive layer.

The light source may also be located below the carpet structure, without the light source being attached or adhered to the carpet structure.

The light source may be one or more LEDs .

The LEDs and the circuit arrangement may be arranged so that at least a substantial part of the LEDs is operable when the tufted textile is reduced in size.

The LEDs may be Red-Green-Blue LEDs. The light source may comprises a light emitting sheet arranged on a side of the second backing layer facing away from the adhesive layer

The light emitting sheet may comprise an electroluminescent panel, an LED panel or an OLED panel.

The tufted textile may further comprise a reflecting layer positioned to a side of the light emitting sheet facing away from the second backing layer.

The tufted textile may be a carpet. Various modifications of the exemplary embodiments described above will be apparent to those skilled in the art. For example, the number of the backing layers is not limited to two or three. In addition, although the tufted textile is generally shown to be a liner fixedly arranged in a compartment, the liner may be provided in the form of a separate mat, that can be placed for example in a footwell. Also, the liner may be provided as a liner element that may be attached to a conventionally lined ceiling of a vehicle. Furthermore, although the liner systems may be provided in vehicle compartments, other public places such as restrooms, hotel lobbies and rooms may be provided with the light emissive tufted textile system according to the invention. In particular, according to an aspect, the invention may be characterized as a compartment provided with light emissive lining, the lining being formed as a tufted textile 100 comprising: a backing 10, yarns 40 forming tufts extending from a first side of the backing, the lining further comprising a light source 50; 80 and a conductor arrangement 60 for the light source, wherein the light source, the conductor arrangement and the backing are arranged so as to radiate light from the light source at least partly through the backing, the backing being substantially permeable to light.

In the claims, any reference signs placed between parentheses shall not be construed as limiting the claim. Use of the verb "comprise" and its conjugations does not exclude the presence of elements or steps other than those stated in a claim. The article "a" or "an" preceding an element does not exclude the presence of a plurality of such elements.

If not specifically defined, the term "substantially" herein, will be understood by the person skilled in the art. Where applicable, the term "substantially" may also include embodiments with "entirely", "completely", "all", etc. Hence, where applicable, in embodiments the adjective substantially may also be removed. Where applicable, the term "substantially" may also relate to 10% or higher, or, at least, being able to provide a perceptually relevant effect.

In particular, for the term "substantially permeable" it is intended that light permeability generates a perceptually relevant light emission through the tufted textile (for example a light transmission of at least 5%), for example having a transmission ratio of at least 25% in the visible spectrum such as disclosed in figure 10.

In other cases where applicable, the term "substantially" may indicate values such as 90% or higher, especially 90% or higher, even more specifically, and especially 99%

or higher, including 100%. This is for example the case for 'substantially the same surface area' and 'substantially consists of.

The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to advantage.