Patent Description:
An organic light-emitting diode (OLED for short) is considered to be one of the most promising display technologies for its characteristics such as high luminance, wide viewing angle, lower power consumption and wide working temperature. One of the biggest advantages of an OLED device, as a fully-cured display device, is that it can achieve flexible display, and can be used to manufacture a foldable electronic newspaper, a rollable wall-hanging television and a wearable display and so on, so as to exhibit fascinations of organic semiconductors.

In practical applications, the thin film transistor backplane of the OLED device includes a plurality of circuits, and different circuits are connected by wires. However, as for the manufactured OLED devices, such as the foldable electronic newspaper, the rollable wall-hanging television and the wearable display, the wire will be bent at portions where need to be folded. Although the wire itself has a certain degree of ductility, too long time of folding or too many times of folding will crack the wire. Once the wire fractures, normal use of the entire OLED device will be affected.

At present, in order to solve the above problem, the whole industry proposes a method in which the wires are fixed on the thin film transistor backplane by employing a manner of drilling holes and fixing. However, in practical applications, such manner is still hard to avoid the problem of wire fracture during folding.

<CIT> (also published as <CIT>) discloses a flexible display, and reference can be made to figure 8a-8d. the diamond trace design shown in FIG. <NUM> provides a significant electrical advantage over the single wire trace designs of the FIG. Splitting of the trace into multiple sub-traces may provide a backup eletrical pathway in case one of the sub-traces is damaged by cracks. As such, the diamond trace design can be used for the wire traces in the bend portion, and may be particularly helpful for the wire traces within the bend allowance section subjected to severe bending stress.

<CIT> provides a flexible wiring board which is thin in mounting thickness and elastic. The flexible printed board <NUM> is provided with wiring at a base portion, and includes a hole portion <NUM> formed penetrating the base portion, a deformable portion <NUM> formed of the base portion enclosing a periphery of the hole portion <NUM> and capable of curving in an extension direction with tensile force to deform, and a wiring portion <NUM> formed at the deformable portion <NUM> from an input end <NUM> to an output end <NUM> while bypassing the hole portion <NUM>. The hole portion <NUM> is shaped to have a different aspect ratio. A plurality of hole portions <NUM> are formed. The plurality of hole portions <NUM> have diagonals made longer other in the extension direction than that in the extension direction, and sides of the hole portions <NUM> are arranged opposite each other.

<CIT> discloses an environmental sensitive electronic device package. The environmental sensitive electronic device package may include a first substrate, a second substrate, an environmental sensitive electronic device, at least one side wall barrier structure, and a filler layer. The first substrate has at least one predetermined flexure area. The second substrate is located above the first substrate. The environmental sensitive electronic device is located on the first substrate and between the first substrate and the second substrate. The side wall barrier structure is located between the first substrate and the second substrate and surrounds the environmental sensitive electronic device. The side wall barrier structure has at least one flexure stress dispersing structure that is located in the predetermined flexure area. The filler layer is located between the first substrate and the second substrate and covers the side wall barrier structure and the environmental sensitive electronic device.

<CIT> provides a flexible display substrate, a flexible organic light emitting display device, and a method of manufacturing the same. The flexible display substrate comprises a flexible substrate including a display area and a non-display area extending from the display area, a first wire formed on the display area of the flexible substrate, and a second wire formed on the non-display area of the flexible substrate, wherein at least a part of the non-display area of the flexible substrate is curved in a bending direction, and the second wire formed on at least a part of the non-display area of the flexible substrate includes a first portion formed to extend in a first direction and a second portion formed to extend in a second direction.

<CIT> provides an array substrate and a display device. The array substrate comprises grid lines, data lines and a plurality of pixel units which are defined by intersection of the grid lines and the data lines, wherein a first anti-fracture structure is formed on each grid line, and/or a second anti-fracture structure is formed on each data line. According to the array substrate, due to the fact that the anti-fracture structures are formed on patterns of the grid lines and/or the data lines, when a flexible display device is bent, part of tension can be dispersed through the anti-fracture structures, the probability that the grid lines and the data lines are fractured when the flexible display device is bent can be reduced, and normal display of the flexible display device can be guaranteed.

<CIT> provides a display with an active central region and a peripheral inactive region. The display may have one or more flexible edges in the peripheral inactive region. Conductive lines may pass between components in the active central region such as display pixels and touch sensor electrodes and components in the inactive peripheral region such as gate driver circuitry and patterned interconnect lines. Each conductive line may have an unbent segment on a portion of a display layer in the active central region and may have a segment on the bent edge of the display layer. The display layer may be formed from a polymer or other flexible material. The bent segments may be configured to be less susceptible to increases in resistance from bending than the unbent segments.

In view of the above, the embodiments of the disclosure provide a wire and a method of manufacturing the same, aiming to solve the problem of OLED device unable to be normally used during folding due to wire fracture which is inevitable in the prior art.

A wire for use in an organic light-emitting diode (OLED) device in accordance with the present invention is defined in claim <NUM>. A method of manufacturing such wiring is defined in claim <NUM>.

By dividing a middle part of one wire into multiple wires, the purpose of changing a wire width of a single wire is achieved, which not only has no influence on use of the wires in the OLED device, but also enhances ductility of the wires, thereby efficiently avoiding the occurrence of the problem that the OLED device cannot normally work caused by wire fracture during folding, and efficiently improving the using efficiency of the OLED.

In order to more clearly describe the technical solution in the embodiments of the disclosure, in the following, a brief introduction will be made to the accompanying drawings used in the embodiments.

The embodiments of <FIG> do not form par of the present invention but are useful to understand it. The embodiment of <FIG> corresponds to the embodiment of the present invention. The embodiment of <FIG> is directed to the manufacture of the wiring of <FIG>.

To achieve an object of the disclosure, the embodiments of the disclosure provide a wire for use in an organic light-emitting diode (OLED) device and a method for manufacturing the wire, wherein the wire comprises three parts, and a first part and a third part are located at both ends of the wire respectively and each of the first part and third part is a single wire; a second part is located between the first part and the third part and is a composite wire, wherein the composite wire comprises at least two wires. By dividing a middle part of one wire into multiple wires, the purpose of changing a wire width of a single wire is achieved, which not only has no influence on use of the wire in the OLED device, but also enhances ductility of the wire, thereby efficiently avoiding the occurrence of the problem that the OLED device cannot normally work caused by wire fracture during folding, and efficiently improving the using efficiency of the OLED.

<FIG> is a structural schematic view of a wire provided in a first embodiment of the present disclosure not forming part of the present invention but useful to understand it. The wire comprises three parts, wherein a first part <NUM> and a third part <NUM> are located at both ends of the wire respectively and each of the first part <NUM> and third part <NUM> is a single wire; a second part <NUM> is located between the first part and the third part and is a composite wire, wherein the composite wire comprises at least two wires.

A wire, as a relatively important element inside the OLED device, determines whether the OLED device is able to work normally. A study teaches that the wire widths and bending lives of wires have following relationships, as shown in Table <NUM>:.

As can be seen from Table <NUM>, for the wires having the same shapes, the larger the wire widths of the wires are, the shorter the bending lives of the wires are, which is mainly because defects inside metal lines in the wires are increased, since the wire widths are increased, leading to relative concentration of the stress in the curved areas, cracks being prone to propagate, reducing the bending lives of the wires; the wires having the longest bending lives among the wires having the same wire widths belong to the curved wires, which is mainly because the curved wires are relatively suitable for releasing the stress when the wires are bent and fatigued; the stress of the folded wires are easily concentrated and accumulated at corners, thereby generating cracks and leading to fatigue failure, and reducing the bending lives of the wires.

Moreover, in the OLED device, the both ends for making the wire to be fixed (i.e., the first part and the third part), when being fixed, are also prone to fracture owing to being too thin. Thus the first part and the third part use a single wire, and the second wire uses a composite wire, so as to prolong the bending lives of the wires inside the OLED device.

In this way, in one wire, a middle part uses a smooth curve. When a middle part is bent, the stress distribution may become even, thereby avoiding a phenomenon of stress concentration and effectively avoiding the occurrence of the wire fracture.

In addition, since a middle part of the wire uses a composite wire, other wires may be in normal use even if fracture occurs to one of the wires, which will not affect normal use of the entire OLED device.

<FIG> is a structural schematic view of a wire provided in a second embodiment of the present disclosure not forming part of the present invention but useful to understand it.

As can be seen from <FIG>, cross-sectional areas of the first part and the third part of the wire are S, and a cross-sectional area of the second part is S/<NUM>; wherein the shape of the second part of the wire is elliptical.

<FIG> is a structural schematic view of a wire provided in a third embodiment of the present disclosure which represents the present invention.

As can be seen from <FIG>, cross-sectional areas of the first part and the third part of the wire are S, and a cross-sectional area of the second part is S/<NUM>; wherein the shape of the second part of the wire is elliptical and circular.

The wires shown in <FIG> and <FIG> not only have no effect on use of the wires in the OLED device, but also enhance ductility of the wires, and the parts having been folded and curved of the wires are made into elliptical shape, the problem that the OLED device cannot normally work caused by wire fracture during folding can be avoided efficiently, thereby efficiently improving the using life of the OLED.

The embodiments of the disclosure provide a wire for use in an organic light-emitting diode (OLED) device, wherein the wire comprises three parts, and a first part and a third part are located at both ends of the wire respectively and each of the first part and the third part is a single wire; a second part is located between the first part and the third part and is a composite wire, wherein the composite wire comprises at least two wires. By dividing a middle part of one wire into multiple wires, the purpose of changing a wire width of a single wire is achieved, which not only has no influence on use of the wires in the OLED device, but also enhances ductility of the wires, thereby efficiently avoiding the occurrence of the problem that the OLED device cannot normally work caused by wire fracture during folding, and efficiently improving the using life of the OLED.

<FIG> is a schematic flowchart of a method for manufacturing a wire provided in an embodiment of the disclosure. The method may be as follows.

Step <NUM>: for a target wire, selecting a predetermined first length of the target wire from a starting end as a first part of the target wire.

The predetermined length here may be set according to requirements for the OLED device and is not limited by the embodiment of the disclosure.

Step <NUM>: from a finishing end of the first part, according to a predetermined wire width, cutting the wire with a predetermined second length into at least two sub-wires satisfying the predetermined wire width to obtain a second part of the target wire.

In Step <NUM>, cutting the wire with a predetermined second length into at least two sub-wires satisfying the predetermined wire width may be made by adopting a manner of photo etching or other manners, and may also be made by employing a mask with a pattern of this wire to manufacture directly, which is not limited herein.

Step <NUM>: at finishing ends of the at least two sub-wires, combining the finishing ends of the at least two sub-wires into one wire to obtain a third part of the target wire.

Claim 1:
A wire for use in an organic light-emitting diode (OLED) device, the wire comprises a first part (<NUM>), a second part (<NUM>) and a third part (<NUM>), which are connected to each other, the first part (<NUM>) and the third part (<NUM>) are located at both ends of the wire respectively, wherein each of the first part (<NUM>) and third part (<NUM>) is a single wire; and
the second part (<NUM>) is located between the first part (<NUM>) and the third part (<NUM>) and is a composite wire, wherein the composite wire comprises at least two sub-wires;
characterized in that the composite wire comprises first, second, third and fourth sub-wires diverging and converging to form several loops in a row connected to each other and connecting the first part with the third part, each loop comprising the first and fourth sub-wires forming an outer loop having an elliptical shape which surrounds an inner loop having a circular shape and which is formed by the second and third sub-wires, wherein the width (S/<NUM>) of each of the first to fourth sub-wires is equal to a fourth of the width (s) of the wire at the first part and third part, the wires at the first part and third part having the same width (s),
wherein the outer loop has a same diameter as the inner loop in a longitudinal direction of the wire, and has a larger diameter than the diameter of the inner loop in a transverse direction perpendicular to the longitudinal direction of the wire.