The present invention relates to a light-emitting electronic textile and to a method for manufacturing such a light-emitting electronic textile.
By integrating light-sources, such as light-emitting diodes (LEDs), into textile applications and thereby creating light-emitting electronic textiles, attractive visual effects can be achieved.
In general, currently available light-emitting electronic textiles have a rather low resolution, that is, the spacing between adjacent light-sources is relatively large. Furthermore, it has been found that end users often prefer that the light-emitting electronic textile gives the impression that the light-sources are not isolated spots of light.
For this reason, currently proposed light-emitting electronic textiles may be provided with a diffusing element arranged on top of the light-sources to achieve a more uniform output of light from the light-emitting electronic textile.
To even further improve the uniformity of the light output by the light-emitting electronic textile disclosed therein, WO 2006/129246 discloses a diffusing element formed by two layers of non-woven fabric with different densities.
However, there still appears to be room for improvement in the strive for achieving a light-emitting electronic textile which has textile-like mechanical properties, provides a good uniformity of the light output thereby and is easy to manufacture.
In view of the above-mentioned and other drawbacks of the prior art, a general object of the present invention is to provide an improved light-emitting electronic textile.
According to a first aspect of the present invention there is provided a light-emitting electronic textile comprising a flexible component carrier having a plurality of light-sources arranged thereon; a cover textile arranged to allow passage through the cover textile of light emitted by the light-sources; and a light-diffusing member arranged between the light-sources and the cover textile, the light-diffusing member comprising a layered structure formed by a plurality of light-diffusing layers, wherein adjacent light-diffusing layers in the layered structure are spaced apart at least in portions of the light-diffusing member corresponding to positions of the light-sources.
The flexible component carrier may, for example, comprise a flexible printed circuit board or a textile substrate comprising conductor lines. Such a textile substrate may, for example, be formed using interwoven conductive and non-conductive yarns.
The present invention is based on the realization that a light-emitting electronic textile exhibiting output of uniform light as well as textile-like mechanical properties can be achieved by diffusing the light output by the light-sources comprised in the light-emitting electronic textile using a multi-layer diffusing structure in which adjacent light-diffusing layers are spaced apart.
Because of the interfaces between light-diffusing layers and air, very efficient light-diffusion can be achieved while using less light-diffusing material than in known light-emitting electronic textiles. The use of less light-diffusing material may reduce absorption and back-scattering occurring in the light-diffusing member, which increases the output efficiency of the light-emitting electronic textile.
Furthermore, the spacing between adjacent light-diffusing layers facilitates relative movement between the adjacent light-diffusing layers, which provides for more textile-like mechanical properties of the light-emitting electronic textile.
The spacing between adjacent light-diffusing layers in the layered structure may advantageously be achieved by configuring the layered structure comprised in the light-diffusing member such that at least one of the light-diffusing layers is curved in such a way that the adjacent light-diffusing layers, at points along a line passing through the layered structure, exhibit mutually different radii of curvature. Hereby, the inherent elasticity of the light-diffusing layer(s) will result in a spring force acting to keep the adjacent light-diffusing layers spaced apart. This configuration of the layered structure comprised in the light-diffusing member can be achieved in various ways. Below, a few different exemplary embodiments will be provided, in which adjacent light-diffusing layers exhibit mutually different radii of curvature at points along a straight line passing through all the light-diffusing layers of the layered structure substantially in perpendicular to the light-diffusing member.
According to various embodiments, the layered structure may advantageously be formed by a flexible sheet being folded over itself at least once. This way of providing the layered structure is very well-suited to conventional textile production, which allows for a low manufacturing cost and a wide selection of potential manufacturing facilities.
Furthermore, the layered structure may be formed by at least two flexible sheet portions being joined together by at least one joint arranged along respective boundaries thereof.
Obviously, the flexible sheet portions may be joined together using any joining technique known to the skilled person, such as through sewing, welding, fusing etc.
According to one example, the at least one joint may be arranged between adjacent light-diffusing layers in the layered structure comprised in the light-diffusing member.
Moreover, the at least two flexible sheet portions that are joined together may be differently sized. By joining differently sized sheet portions in this manner, a bulge can be achieved, whereby adjacent light-diffusing layers can be spaced apart without using additional structures, such as spacing members.
Furthermore, at least one of the light-diffusing layers may be a textile layer. In particular, the layered structure may be formed by a textile sheet being folded over itself at least once, or by at least two differently sized flexible sheet portions being joined together along respective boundaries thereof, where at least one of the flexible sheet portions is a textile sheet portion.
By “textile” should, in the context of the present application, be understood a material or product that is wholly or partly made of textile fibers. The textile may, for example, be manufactured by means of weaving, braiding, knitting, crocheting, quilting, or felting. In particular, a textile may be woven or non-woven.
The light-diffusing member may advantageously comprise at least one sheet of a non-woven textile material, since non-woven textile materials are well suited for providing for a combination of efficient diffusion of light and the desired textile-like mechanical properties of the light-emitting electronic textile.
To provide for a high degree of robustness of the spacing between the adjacent light-diffusing layers in the portions of the light-diffusing member corresponding to positions of the light-sources, the adjacent light-diffusing layers in the layered structure may advantageously be spaced apart a distance corresponding to at least one quarter of a thickness of one of the adjacent light-diffusing layers at least somewhere in the layered structure.
To provide for an even higher degree of robustness of the spacing between the adjacent light-diffusing layers in the portions of the light-diffusing member corresponding to positions of the light-sources, the adjacent light-diffusing layers in the layered structure may advantageously be spaced apart a distance corresponding to at least one half of the thickness of one of the adjacent light-diffusing layers at least somewhere in the layered structure.
In this context it should be noted that light-diffusing layers made of various light-diffusing materials, such as a non-woven textile, may have fibers extending from the surface thereof. Such fibers sticking out from the surface should not be taken as being included in the thickness of the light-diffusing layer.
According to various embodiments, the cover textile may, furthermore, be arranged to enclose the flexible component carrier and the light-diffusing member. In particular, the cover textile may be configured to compress the light-diffusing member, whereby a robust and uniform spacing between adjacent light-diffusing layers in the layered structure can be achieved.
Moreover, the cover textile may comprise a reflective cover textile portion and a transmissive cover textile portion, the reflective cover textile portion having a higher optical reflectance and a lower optical transmittance than the transmissive cover textile portion. Through this configuration, the light emitted by the light-sources can be diffused even further, and the output of light from the light-emitting electronic textile can be controlled to portions thereof where output of light is desired.
To this end, the transmissive cover textile portion may advantageously be arranged to receive light having passed through the diffusing member directly from at least one of the light-sources.
According to a second aspect of the present invention, there is provided a method of manufacturing a light-emitting electronic textile, the method comprising the steps of: providing a flexible component carrier having a plurality of light-sources arranged thereon; providing a light-diffusing member comprising a layered structure formed by a plurality of light-diffusing layers on top of the light-sources; enclosing the flexible component carrier and the light-diffusing member by a cover textile in such a way that adjacent light-diffusing layers in the layered structure are spaced apart at least in portions of the light-diffusing member corresponding to positions of the light-sources.
The step of enclosing may comprise the steps of: providing the cover textile in the form of a substantially tube-shaped textile structure; and introducing the flexible component carrier and the light-diffusing member into the substantially tube-shaped textile structure.
Further embodiments and effects associated with this second aspect of the invention are largely analogous to those provided above for the first aspect of the present invention.
These and other aspects of the present invention will now be described in more detail, with reference to the appended drawings showing currently preferred embodiments of the invention, wherein:
In the following description, the present invention is described with reference to a light-emitting electronic textile in which the light-diffusing member is formed by one or several sheets of a non-woven textile material enclosed by tubular cover textile.
It should be noted that this by no means limits the scope of the invention, which is equally applicable to other light-emitting electronic textiles in which the cover textile is differently provided, for example as a one-sided cover being attached to the flexible component carrier. Furthermore, the light-diffusing member can be formed by a layered structure in any other suitable layered configuration formed by a plurality of light-diffusing layers, such as woven textile layers, foam layers or layers of different light-diffusing materials suitable for use in a light-emitting electronic textile.
As is indicated in the drawing,
In the exemplary embodiment shown in
The light-diffusing member 6 comprises a layered structure in which at least one of the light-diffusing layers is curved in such a way that adjacent light-diffusing layers exhibit mutually different radii of curvature at points along a line passing through the layered structure of the light-diffusing member 6. The exemplary light diffusing member 6 visible in
With reference to
Referring again to
As is schematically shown in
As was mentioned briefly above in connection with
It should be noted that the arrows denoted R1, R2 etc in
An embodiment of a method for manufacturing a light-emitting electronic textile according to embodiments of the present invention will now be described with reference to the flow chart in
In a first step 601, a flexible component carrier 3 having a plurality of light-sources 4a-d arranged thereon is provided. Subsequently, a light-diffusing member 6 comprising a layered structure formed by a plurality of light-diffusing layers is provided on top of the flexible component carrier 3, to cover the light-sources 4a-d, in step 602. The light-diffusing member may advantageously be attached to the flexible component carrier through, for example, latching of the surface of the light-diffusing member to random points on the surface of the flexible component carrier 3, or using some kind of adhesion member, such as an adhesive or a connector for mechanical connection. A substantially tube-shaped cover textile 5 is provided in step 603, and finally the flexible component carrier 3 and the light-diffusing member 6 are introduced into the cover textile 5 in step 604.
Additionally, variations to the disclosed embodiments can be understood and effected by the skilled person in practicing the claimed invention, from a study of the drawings, the disclosure, and the appended claims. In the claims, the word “comprising” does not exclude other elements or steps, and the indefinite article “a” or “an” does not exclude a plurality. A single processor or other unit may fulfill the functions of several items recited in the claims. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measured cannot be used to advantage.
Number | Date | Country | Kind |
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09169404.2 | Sep 2009 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB2010/053679 | 8/16/2010 | WO | 00 | 2/22/2012 |