Patent Description:
In the field of manufacturing a flexible display screen, a flexible screen is quite easily damaged in the manufacturing process due to its own relatively fragile material, therefore in practice, it is usually necessary to attach the flexible screen to a substrate (such as tempered glass) and then perform circuit etching, bonding and other steps, and finally separate the flexible screen from the substrate in a manner of peeling-off. Taking the bonding as an example, elements such as a chip are usually boned in a bonding area on the flexible screen, and a large number of circuits are often distributed around the chip. Therefore, an operation of peeling-off the flexible screen and the substrate must be performed carefully, otherwise a product defective may be caused due to an extremely easy damage of the circuits.

In the prior art, a substrate A is located under the flexible screen, and since there is an obvious hardness difference between the chip B and the flexible screen C itself in the bonding area, relatively large stress will be generated in the bonding area during the actual peeling-off ( as shown in <FIG>), thus stress concentration is formed at a position where the chip B is located at (the area indicated by position D is a stress concentration area), in this way the circuits at this position are easily pulled broken, thereby greatly reducing the peeling-off yield after bonding the flexible screen. <CIT> discloses a flexible device and a fabricating method thereof. The flexible device has a flexible panel, a driver, and a restraining component. The flexible panel includes a main region and a driver bonding region outside the main region. The driver is electrically connected to the driver bonding region. The restraining component is disposed adjacent to the driver bonding region. Rigidity of the restraining component is greater than rigidity of the flexible panel, and coefficient of thermal expansion of the restraining component is smaller than coefficient of thermal expansion of the flexible panel. <CIT> discloses display device with suppressed occurrence of display unevenness. The display device includes a flexible base panel, a display panel mounted on the base panel, and a drive circuit component arranged on periphery of and spaced away from the display panel and mounted on the base panel. A deformation suppression member is disposed on the base panel at a predetermined portion between the display panel and the drive circuit component. <CIT> discloses a flexible screen comprising a display area and a bonding structure, the bonding structure comprising a bonding area connected to the display area and a chip mounted in the bonding area; wherein a flexible protective layer is arranged in the bonding area and the flexible protective layer surrounds around the chip, the flexible protective layer comprises a first protective layer arranged around the chip in the horizontal direction and a second protective layer arranged at the periphery of the first protective layer in the horizontal direction; an inner side of the first protective layer is attached at peripheral edges of the chip, so that the peripheral edges of the chip are connected to a surface of the flexible screen by the first protective layer, the first protective layer and the second protective layer have different materials and both are flexible materials, the second protective layer is distributed in the bonding area, and covers the peripheral areas of the chip, and the second protective layer is a UV adhesive layer coated at the periphery of the first protective layer.

The flexible screen and a manufacturing method thereof according to the present invention are as defined in the claims. The embodiments of the disclosure provide a bonding structure for a flexible screen, a flexible screen with the bonding structure and a manufacturing method of the same, which aim to improve a technical problem in the prior art which is low peeling-off yield of a bonding area in the flexible screen.

In order to solve the technical problem mentioned above, the disclosure provides a bonding structure for a flexible screen, including a bonding area and a chip mounted in the bonding area, and a flexible protective layer is arranged in the bonding area and the flexible protective layer surrounds around the chip.

Further, the flexible protective layer comprises a first protective layer arranged around the chip and a second protective layer arranged at the periphery of the first protective layer.

Further, the first protective layer is a UV adhesive layer coated around the chip, and the second protective layer is a silica gel layer coated at the periphery of the first protective layer, an example not forming part of the present invention but useful for understanding it.

According to the present invention, the first protective layer is a polyimide adhesive layer coated around the chip, and the second protective layer is a UV adhesive layer coated at the periphery of the first protective layer.

Further, an inner side of the first protective layer is attached around the chip, the second protective layer is joined at the periphery of the first protective layer, and the second protective layer has a thickness smaller than a thickness of the first protective layer.

Further, in an example not forming part of the present invention but useful for understanding it, the thickness of the flexible protective layer is gradually increased in a direction toward the chip.

The disclosure also provides a manufacturing method of a bonding structure for a flexible screen, the manufacturing method includes:.

Further, in an example not forming part of the present invention but useful for understanding it, said arranging a flexible protective layer around the chip specifically comprises: coating a UV adhesive layer and irradiating the UV adhesive layer with ultraviolet light to make it cure. Said arranging a second protective layer at the periphery of the first protective layer specifically comprises: coating a silica gel layer and distributing the silica gel layer throughout the bonding area located at the periphery of the UV adhesive layer.

Further, in an example not forming part of the present invention but useful for understanding it, said arranging a flexible protective layer around the chip specifically comprises: coating an adhesive layer made of a single material around the chip, and the thickness of the adhesive layer being gradually increased in a direction toward the chip.

The following technical effects can be achieved by employing at least one of the technical solutions of the disclosure: by forming the flexible protective layer with different hardness around the chip, the stress generated around the chip during the peeling-off are greatly dispersed, a stress gradient is formed, the stress concentration at the position closely adjacent to the periphery of the chip is avoided, the risk of the circuits around the chip being pulled broken can be reduced, and the peeling-off yield of the flexible screen can be finally increased.

The illustrated drawings herein are provided for further understanding of the disclosure and constitute a part of the disclosure. The exemplary embodiments of the disclosure and the descriptions thereof aim to explain the disclosure rather than improperly limit the disclosure. In the drawings:.

To make objects, technical solutions, and advantages of the disclosure more clear, the technical solutions of the disclosure will be described clearly and completely below in combination with specific embodiments and corresponding accompanying drawings of the disclosure. It is apparent that the described embodiment is only a part of the embodiments of the disclosure, not all the embodiments. On the basis of the embodiments of the disclosure, all other embodiments obtained by a person skilled in the art without paying creative work will fall within the protection scope of the disclosure.

The technical solutions provided by each embodiment of the disclosure are described in detail below in combination with the accompanying drawings.

In order to solve the problem of low peeling-off yield of an existing flexible screen, the embodiment of the disclosure provides a bonding structure for a flexible screen. With reference to <FIG>, the flexible screen includes a display area <NUM>, a bonding area <NUM> connected to the display area <NUM> and a chip <NUM> mounted in the bonding area. A flexible protective layer <NUM> surrounding around the chip <NUM> is arranged in the bonding area <NUM>, namely the flexible protective layer <NUM> surrounds around the chip <NUM> in the horizontal direction. Wherein the flexible protective layer <NUM> includes a first protective layer <NUM> arranged around the chip <NUM> in the horizontal direction and a second protective layer <NUM> arranged at the periphery of the first protective layer <NUM> in the horizontal direction. A material for the first protective layer <NUM> is different from a material for the second protective layer <NUM>, but both of them are flexible materials, and the first protective layer <NUM> has a thickness greater than that of the second protective layer <NUM>.

Wherein the bonding area <NUM> is arranged on the flexible screen for bonding the chip <NUM>. In the present embodiment, the bonding area <NUM> is located on one side of the flexible screen, and the chip <NUM> is bonded in the bonding area <NUM> and mounted on the flexible screen. The first protective layer <NUM> surrounds around the chip <NUM>, and an inner side of the first protective layer <NUM> is attached at the peripheral edges of the chip <NUM>, so that the peripheral edges of the chip <NUM> are connected to a surface of the flexible screen by the first protective layer <NUM>. The second protective layer <NUM> is distributed in the bonding area <NUM>, and covers the peripheral areas of the chip <NUM>, and the second protective layer <NUM> covers the first protective area <NUM>, or instead of covering the first protective layer <NUM>, the second protective layer <NUM> may be coated directly at the periphery of the first protective layer <NUM> and joined at the periphery of the first protective layer <NUM>, an example not forming part of the present invention but useful for understanding it. Both ways of which can improve the strength of the bonding area <NUM> and relieve the stress concentration caused during the peeling-off, which can be selected according to practical requirements. By arranging the first protective layer <NUM> and the second protective layer <NUM> with different materials, a double adhesive layer structure with gradually changing hardness is formed around the chip <NUM>, thus a stress gradient can be formed, so that the stress around the chip <NUM> is gradually increased in a direction gradually approaching the chip <NUM>, thereby achieving the purpose of dispersing stress and avoiding stress concentration.

In an embodiment not forming part of the present invention but useful for understanding it, preferably, the first protective layer <NUM> may be employed UV (Ultraviolet Rays) adhesive, which is also referred to as ultraviolet light curing adhesive, and the second protective layer <NUM> may be employed silica gel. The silica gel is coated and joined at the periphery of the UV adhesive, and the silica gel is coated throughout the bonding area <NUM> located at the periphery of the UV adhesive.

The embodiment of the present disclosure provides a flexible screen bonding structure. The embodiment of the present disclosure provides a bonding structure for a flexible screen. With reference to <FIG>, the flexible screen includes a display area <NUM>, a bonding area <NUM> connected to the display area <NUM> and a chip <NUM> mounted in the bonding area. A flexible protective layer <NUM> surrounding around the chip <NUM> is arranged in the bonding area <NUM>, and the flexible protective layer <NUM> is an adhesive layer made of a single material, which is coated in the bonding area <NUM> of the flexible screen. The thickness of the flexible protective layer <NUM> is gradually increased in a direction toward the chip <NUM>, as shown in <FIG>, that is, the thickness of the flexible protective layer <NUM> at the edges of the bonding area <NUM> is smaller than the thickness of which at the peripheral edges of the chip <NUM>, as such the flexible protective layer <NUM> with a gradually changing thickness can form a structure with gradually changing hardness around the chip <NUM>, thereby forming a stress gradient, and achieving the purpose of dispersing stress and avoiding stress concentration. The protective layer of the present embodiment is an adhesive layer made of a single material, and a stress gradient can be formed by controlling the thickness of the protective layer. Thus the process flow can be decreased and manufacturing difficulty can be reduced.

The embodiment of the present disclosure provides a manufacturing method of a bonding structure for a flexible screen, which includes the following steps:.

Wherein in S02, said "arranging a flexible protective layer around the chip" includes: arranging a first protective layer around the chip, so that the first protective layer is respectively connected to the chip and the surface of the flexible screen; and arranging a second protective layer at the periphery of the first protective layer, and the thickness of the second protective layer is smaller than the thickness of the first protective layer.

In an example not forming part of the present invention but useful for understanding it, preferably said "arranging a first protective layer" refers to coating a UV adhesive layer and irradiating the UV adhesive layer with ultraviolet light to make it cure. Said "arranging a second protective layer" refers to coating a silica gel layer, distributing the silica gel layer throughout the bonding area located at the periphery of the first protective layer and connecting the silica gel layer to the UV adhesive layer. Certainly, the materials for the first protective layer and the second protective layer may also be employed other flexible materials. According to the present invention, said "arranging a first protective layer" refers to coating a polyimide adhesive layer, and said "arranging a second protective layer" refers to coating a UV adhesive layer, which can also disperse the stress around the chip, the description of which will be omitted here.

Certainly, in the embodiment not forming part of the present invention but useful for understanding it, "arranging a flexible protective layer around the chip" in S02 may also be performed in other ways, which may include: coating an adhesive layer made of a single material with gradually changing thickness at the periphery of the chip, and the thickness of the adhesive layer being gradually increased in the direction toward the chip. With reference to <FIG>, as such a structure with gradually changing hardness is formed, so that a stress gradient can be formed, and the purpose of dispersing stress and avoiding stress concentration can be achieved.

It is shown experimentally that, by employing the bonding structure for the flexible screen and the manufacturing method of the same provided by the embodiments <NUM>, <NUM> and <NUM> of the present disclosure, the flexible protective layer <NUM> (such as the first protective layer <NUM> and the second protective layer <NUM>) with gradually changing hardness can be formed around the chip in the bonding area <NUM>. As shown in <FIG>, the stress within the bonding area <NUM> forms a stress gradient from its periphery to its center by the flexible protective layer <NUM>. That is, the stress at the edge of the bonding area <NUM> is minimum (which is because Moh's hardness is the smallest here), and the stress is gradually increased in the direction toward the chip (which is because Moh's hardness is gradually increased), so that the stress around the chip <NUM> can be greatly dispersed, and the stress concentration created at the position closely adjacent to the periphery of the chip <NUM> during the peeling-off is avoided, thereby reducing the risk of the circuits around the chip being pulled broken, and finally increasing the peeling-off yield of the flexible screen.

Claim 1:
A flexible screen comprising a display area (<NUM>) and a bonding structure,
the bonding structure comprising a bonding area (<NUM>) connected to the display area (<NUM>) and a chip (<NUM>) mounted in the bonding area (<NUM>);
wherein
a flexible protective layer (<NUM>) is arranged in the bonding area (<NUM>) and the flexible protective layer (<NUM>) surrounds around the chip (<NUM>),
the flexible protective layer (<NUM>) comprises a first protective layer (<NUM>) arranged around the chip (<NUM>) in the horizonal direction and a second protective layer (<NUM>) arranged at the periphery of the first protective layer (<NUM>) in the horizontal direction;
an inner side of the first protective layer (<NUM>) is attached at peripheral edges of the chip (<NUM>), so that the peripheral edges of the chip (<NUM>) are connected to a surface of the flexible screen by the first protective layer (<NUM>),
the first protective layer (<NUM>) and the second protective layer (<NUM>) have different materials and both are flexible materials, a thickness of the first protective layer (<NUM>) is greater than that of the second protective layer (<NUM>);
the second protective layer (<NUM>) covers the first protective layer (<NUM>), the second protective layer (<NUM>) is distributed in the bonding area (<NUM>), and covers the peripheral areas of the chip (<NUM>); and
the first protective layer (<NUM>) is a polyimide adhesive layer coated around the chip (<NUM>), and the second protective layer (<NUM>) is a UV adhesive layer coated at the periphery of the first protective layer (<NUM>).