Patent Application
20240004122
This U.S. patent application claims the benefit of United Kingdom patent application No. GB 2209669.7, filed Jul. 1, 2022, which is hereby incorporated by reference.
This disclosure relates to display apparatus, in particular large sized, curved displays and more in particular display apparatus for use in motor vehicles.
Display apparatus are commonly used for displaying contents to users. Such display apparatus may be placed under outdoor or indoor condition. Increasingly, digital display apparatus replaces traditional analogue instrument clusters for displaying vehicular information to users.
A common challenge of digital display apparatus in motor vehicle applications is the nature of demanding lighting conditions in a motor vehicle. For example, content displayed will be influenced by uncontrollable external lighting conditions such as sunlight when driving during daytime and dim streetlights when driving during night-time.
For aesthetic reasons and for betterment of user experience, demand for curved digital displays is increasing in the automotive industry. However, existing curved display apparatus are not suitable for use in motor vehicles, due to uncontrollable external lighting influences as explained above. While there are existing displays which uses optics with conical shapes to extract light rays to increase illumination, such conical shapes are usually produced for general consumer electronics, for example monitors or screens which does not address the issues as discussed above for motor vehicle applications.
There is therefore a need to provide a digital display apparatus that overcomes, or at least ameliorates, the problems described above. Furthermore, other desirable features and characteristics will become apparent from the subsequent detailed description and the appended claims, taking in conjunction with the accompanying drawings and this background of the disclosure.
A purpose of this disclosure is to ameliorate the problem of implementing curved digital displays for use in motor vehicles, by providing the subject-matter of the independent claims.
Further purposes of this disclosure are set out in the accompanying dependent claims.
The objective of this disclosure is solved by a digital display apparatus for use in a motor vehicle, in which a light source operable to emit light rays from an edge of the digital display apparatus, and a rigid light transporter operable to transmit emitted light rays from the light source towards a viewing area, wherein the digital display apparatus further comprises a flexible optical film operable to extract light rays transmitted through the rigid light transporter towards the viewing area, the flexible optical film further comprises at least one microstructure having a curvature, and the flexible optical film is adhered to a curved surface of the rigid light transporter, with a peak of the curvature of the at least one microstructure opposing the curved surface of the rigid light transporter.
The above-described aspect of this disclosure yields a digital display apparatus including a flexible optical film, in which the flexible optical film is arranged relative to a rigid light transporter such that the flexible optical film extracts light rays from the rigid light transporter to increase illumination towards a viewing area. For example, the microstructures are displaced on the flexible optical film strategically to achieve homogeneity.
In an embodiment of a digital display apparatus as described above, the flexible optical film has a total thickness ranging between 100 μm to 400 μm.
The above aspect of this disclosure is to optimize light rays extracted from the rigid light transporter towards the viewing area, to achieve homogeneity.
In an embodiment of a digital display apparatus as described above, the at least one microstructure has a height ranging between 5 μm to 100 μm.
The above aspect of this disclosure is to optimize light rays extracted from the rigid light transporter towards the viewing area, to achieve homogeneity.
In an embodiment of a digital display apparatus as described above, the digital display apparatus further comprises an optically transparent adhesive deposited between the rigid light transporter and the flexible optical film.
The above aspect of this disclosure is to integrate the flexible optical film with the rigid light transporter using an optically transparent adhesive, such that a single piece of thin, curved light guide is produced.
In an embodiment of a digital display apparatus as described above, the optically transparent adhesive, the rigid light transporter and the flexible optical film has a matching refractive index.
The above aspect of this disclosure is to an integrated light guide, of which all the optical elements share a matching refractive index, to achieve fluid transmission of light rays emitting from the light source through the integrated light guide towards a viewing area.
In an embodiment of a digital display apparatus as described above, the viewing area has a size of at least 16 inches and has a curved form factor.
The above aspect of this disclosure is to yield a large size, curved display suitable for use in motor vehicles.
In an embodiment of a digital display apparatus as described above, each of the at least one microstructure is systematically positioned on the flexible optical film relative to a position of the light source.
The above aspect of this disclosure is to distinctively position each of the microstructure on the flexible optical film to optimize homogeneity achievable by the motor vehicle display.
In an embodiment of a digital display apparatus as described above, a lower count of the at least one microstructure positioned nearer to the position of the light source, and a higher count of the at least one microstructure positioned nearer to the position of the light source.
The above aspect of this disclosure is to yield a flexible optical film having distinctively or systematically positioned microstructures, thereby achieving optimization of homogeneity. By way of example, at areas where light rays enter the integrated light guide, a lower count of microstructures, i.e., lesser number of microstructures may be required to extract light rays towards the viewing area. In contrast, areas further away from light source where light rays are expected to transmit further, a higher number of microstructures may be required to extract light rays towards the viewing area. Consequently, homogeneity is achieved. The aforesaid configuration is useful for edge-lit digital display apparatus.
In an embodiment of a digital display apparatus as described above, the rigid light transporter has a curved form factor, the curved form factor of the rigid light transporter approximately the same as the curved form factor of the viewing area.
The above aspect of this disclosure is to yield a curved rigid light transporter having a curve radius approximately matching to a display radius of a curved digital display apparatus.
The objective of this disclosure is solved by a method of assembling a digital display apparatus as disclosed herein, comprising fabricating a mould for producing at least one flexible optical film comprising the steps of laying a metal sheet for framing a flexible optical film on a flat plane, and producing, by way of lasering, at least one microstructure on the metal sheet, wherein the at least one microstructure lasered comprises a curvature.
The above-described aspect of this disclosure yields a master mould for fabricating one or more flexible optical film as discussed herein, which is suitable for reproducing the flexible optical film on a flat panel, to achieve even and symmetrical microstructures in the master mould.
In an embodiment of a method of assembling a digital display apparatus as described above, the method further comprises producing at least one flexible optical film, by way of the mould fabricated, through an injection moulding process.
The above aspect of this disclosure is to produce the flexible optical film though an injection moulding process using the master mould fabricated.
In an embodiment of a method of assembling a digital display apparatus as described above, the method further comprises providing a rigid light transporter, the rigid light transporter having a curve radius ranging from preferably 0 mm to 4000 mm, more preferably 500-4000 mm, and even more preferably, 1000 mm to 3000 mm.
The above aspect of this disclosure is to provide a rigid light transporter with a curved radius.
In an embodiment of a method of assembling a digital display apparatus as described above, the method comprises depositing an optically transparent adhesive on a curved surface of the rigid light transporter, and adhering the at least one flexible optical film produced onto the curved surface of the rigid light transporter.
The above aspect of this disclosure is to yield an integrated light guide suitable for large size, curved motor vehicle displays.
Other objects and aspects of this disclosure will become apparent from the following description of embodiments with reference to the accompanying drawings in which:
In various embodiments described by reference to the above figures, like reference signs refer to like components in several perspective views and/or configurations.
The following detailed description is merely exemplary in nature and is not intended to limit the disclosure or the application and uses of the disclosure. Furthermore, there is no intention to be bound by any theory presented in the preceding background of the disclosure or the following detailed description. It is the intent of this disclosure to present a digital display apparatus having an integrated light guide to achieve homogeneity. The integrated light guide includes a flexible optical film and a rigid light transporter, of which the integrated light guide is suitable for digital displays.
Hereinafter, the term “transparent” refers to an object or substance having transparent properties. Therefore, the term “optically transparent adhesive” refers to an adhesive having transparent properties, such that light rays are permitted to transmit through. In particular, when used as a means to adhere layers of optical elements together to produce an integrated, single optical element, incident light rays are transmitted through layers of optical elements or the integrated optical element. A type of optically transparent adhesive may be epoxy.
The term “digital display” used herein shall refer to electronic output device for presenting information in visual form. In the context of digital display within a motor vehicle, an example of a digital display includes a full digital dashboard (also known as digital cluster), and a hybrid digital dashboard. When used in the context herein, the term “digital dashboard” shall encompass both full digital dashboard and hybrid digital dashboard unless otherwise specified. The term “digital dashboard” shall refer to full digital instrument clusters which utilises digital display as an output apparatus for displaying vehicular information. The term “hybrid dashboard” shall encompass digital clusters which utilises a combination of analogue and digital electronic components, as a display apparatus for presenting vehicular information. Further, examples of digital display apparatus may include digital display apparatus having display layers fabricated using suitable digital display technologies. Example of digital display layers may include liquid crystal displays (LCD) organic light emitting diode (OLED) displays and thin film transistors (TFT) display layers.
The term “curve” refers to a line or an outline which gradually deviates from being a straight line, for at least a part of its length. Henceforth, the terms “curve”, “curved”, “curvature”, “curve form” and its variation thereof shall be taken to encompass line or outline as such, including convex and concave line or outline.
The term “display radius” refers to a display curvature or curve form factor of a display, which is measured in millimetres (mm) or denote by ‘R’.
Referring to
Although
To produce an integrated light guide 100, an optically transparent adhesive 104 may be applied to a side of the rigid light transporter 102. If the rigid light transporter 102 has a curved form factor or in other words, a curved rigid light transporter 102 is used, the optically transparent adhesive 104 is applied to a convex surface of the rigid light transporter 102. Henceforth, the integrated light guide 100 produced includes a flexible optical film 106 having at least one microstructure 108, 108′ and 108″ systematically positioned, each of the microstructure 108, 108′, 108″ having a curvature C, with a peak P of the curvature C of the at least one microstructure 108, 108′, 108″ opposing the curved surface of the rigid light transporter 102. Preferably, the optically transparent adhesive 104, the rigid light transporter 102 and the flexible optical film 106 has a matching refractive index, such that light rays may be transmitting though the integrated light guide 100.
A main advantage of the flexible optical film 106 as disclosed herein is the total thickness of the flexible optical film 106 ranges between 100 μm to 400 μm, thus yielding thin integrated light guide, therefore a total thickness of digital display apparatus is also reduced. Another advantage of the flexible optical film 106 disclosed is that shape accuracy, i.e., curvature of each of the at least one microstructure 108, 108′, 108″ may be produced, as a result of the flexible optical film 106 being produced on a flat panel in contrast with moulding microstructure directly on the light guide itself. Yet another advantage is that the flexible optical film 106 may be applied on curved rigid light transporter of any radius or curve form factor. Naturally, the microstructures 108, 108′, 108″ orientates to a curve surface of the rigid light transporter, reducing distortion of the microstructures 108, 108′, 108″.
Optionally, an optical film diffusor 404 may be placed forward of the rigid light guide 102. Optionally, the optical elements are placed within a housing of a digital display apparatus, applied with reflector foil 406, 406′ to optimise reflection of light rays within an ambient of a digital display apparatus 400, to be extracted by the flexible optical film 106 and transmitted through the rigid light transporter 102, towards a viewing area.
In an exemplary embodiment, a master mould may be fabricated, for producing the flexible optical film 106 and producing an integrated light guide 100 as disclosed herein.
Referring now to
At step 510, an optically transparent adhesive is applied or deposited on the rigid light transporter. In a preferred embodiment where the rigid light transporter has a curved form factor, the optically transparent adhesive is applied or deposited on a curved side of the rigid light transporter. At step 512, the at least one optical film produced is adhered to a side of the rigid light transporter. More specifically, the at least one optical film produced is adhered to a curved side of the rigid light transporter, thereby producing an integrated light guide for assembling a digital display apparatus.
A known method of producing conical shaped optical elements within layers of displays is to apply lasering techniques directly on a light guide such that the conical-shaped optical elements are produced on the light guide itself. However, if the display is a curved display and a curved light guide is used, the resultant conical shaped optical elements produced may be inconsistent, with distortion of cavities and lens on the light guide element. A main advantage of producing a master mould for fabricating a flexible optical film to be adhered to a rigid light transporter aims to ameliorate the aforesaid problem.
Thus, it can be seen that a large, curved digital display apparatus having an integrated light guide which achieves homogeneity has been provided. In particular, the integrated light guide is produced using a combination a flexible optical film and a rigid light transporter. In addition, the flexible optical film includes at least one microstructure with a curvature to extract light rays which passes through to the rigid light guide for transmitting light rays towards the viewing area of the large, curved digital display apparatus, thereby optimizing light rays being transmitted through to the viewing area. Further thereto, in contrast with conventional method which apply lasering method directly to a curved light transporter to produce structures for extracting light rays to achieve homogeneity, which may result in distorted structures due to fabricating of structures on a curved surface, the present disclosure proposes to at least ameliorate the problems as discussed above by using a flexible optical film that may be adhered to a rigid light transporter. While exemplary embodiments have been presented in the foregoing detailed description of the disclosure, it should be appreciated that a vast number of variation exist.
It should further be appreciated that the exemplary embodiments are only examples, and are not intended to limit the scope, applicability, operation or configuration of the disclosure in any way. Rather, the foregoing detailed description will provide those skilled in the art with a convenient road map for implementing an exemplary embodiment of the disclosure, it being understood that various changes may be made in the function and arrangement of elements and method of operation described in the exemplary embodiment without departing from the scope of the disclosure as set forth in the appended claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2209669.7 | Jul 2022 | GB | national |
