KR102395734B1 - Flexible Cover Window - Google Patents

Abstract

The present invention relates to a flexible cover window. In a glass-based flexible cover window which is composed of a flat part formed by corresponding to a flat area of a flexible display and a flexible part formed in succession to the flat part and formed by corresponding to a folding area of the flexible display, the flexible cover window comprises: a window substrate; a pattern part for a buffer formed on both sides or a rear surface of the window substrate; a resin filling layer formed on the pattern part for the buffer formed on the rear surface of the window substrate; and a first adhesive layer formed on the resin filling layer. The present invention provides the glass-based cover window for protecting a flexible display which is foldable, rollable, slidable, and stretchable. Also, the pattern part for a buffer is formed on both sides or a rear surface of the window substrate to disperse impact force, and minor deformation by difference in elongation between the window substrate and a display panel is absorbed, and thus there is no delamination or buckling in the flexible part. As a result, the cover window can be used for a long time, and distortion of a screen in the flexible part is minimized.

Description

Flexible Cover Window

The present invention relates to a flexible cover window, wherein a pattern portion for a buffer is formed on a window substrate to absorb micro-deformation occurring in the flexible portion to prevent delamination or buckling in the flexible portion. It's about windows.

In recent years, electrical and electronic technologies are rapidly developing, and various types of display products are emerging to meet the needs of the new era and the needs of various consumers.

In the case of flexible displays, research is being conducted in the form of basically folding, rolling, sliding, or stretchable starting from foldable, and not only the display panel but also the cover window to protect it is flexible should be formed

Such a flexible cover window should basically have good flexibility, and should not cause marks on the folding part even when repeatedly folding, and there should be no distortion of image quality.

For the cover window of the existing flexible display, a polymer film such as PI or PET film has been used on the surface of the display panel.

However, in the case of a polymer film, the mechanical strength is weak, and it merely serves to prevent scratches on the display panel, but it is weak in impact resistance, has low transmittance, and is known to be relatively expensive.

In addition, in the case of such a polymer film, as the number of folds of the display increases, marks are left on the foldable portion, resulting in damage to the foldable portion. For example, pressing or tearing of the polymer film occurs during the evaluation of the folding limit (normally 200,000 times).

Recently, various studies on glass-based cover windows have been made in order to overcome the limitations of polymer film cover windows.

In the case of such a glass-based cover window, basic required properties such as satisfying folding characteristics, no screen distortion, and sufficient strength even in repeated contact with a touch pen and constant pressure are required.

Recently, as consumer demand for flexible displays of various folding methods, for example, Foldable, Rollable, Slidable, and Stretchable, increases, researches are being actively conducted, and the cover window used to protect these display (OLED) panels Attention is also focused on research.

In the case of a polymer film or glass such as CPI or PET as a material of the existing cover window, when folding is repeated as shown in FIGS. 1 and 2, delamination or buckling occurs depending on the difference in elongation in the flexible part. (Buckling) phenomenon occurs frequently.

This phenomenon is more severe as the cover window is thicker or has higher hardness, and thus the thickness and hardness of the cover window have been limited in the selection of the material of the cover window.

That is, when the thickness of the cover window is relatively thin, the occurrence of the phenomenon is weak because the deformation is small when bent. However, the thicker the thickness of the cover window and the higher the hardness, the greater the deformation during folding. there was

Also, the delamination or buckling problem is more likely to occur as the number of times of folding increases, regardless of the material of the cover window.

As described above, in preparation for various folding methods of the flexible display, there is a need for research on a cover window without distortion of the screen while solving the problem of deformation in the folding area and satisfying the strength characteristics and folding characteristics.

An object of the present invention is to provide a flexible cover window that forms a buffer pattern portion on a window substrate to absorb micro-deformation occurring in the flexible portion so that there is no delamination or buckling in the flexible portion. do.

In order to achieve the above object, the present invention provides a glass-based flexible cover including a flat portion formed to correspond to a flat area of a flexible display, and a flexible portion formed to be connected to the flat portion and formed to correspond to a folding area of the flexible display. In the window, a window substrate, a buffer pattern portion formed on both surfaces or a rear surface of the window substrate, a resin-filled layer formed on the buffer pattern portion formed on the rear surface of the window substrate, and a third formed on the resin-filled layer 1 A flexible cover window comprising an adhesive layer is a technical gist.

In addition, the pattern portion for the buffer is formed on the flexible portion, or is formed on the flat portion and the flexible portion, respectively, and is preferably made of a pattern of concavo-convex shape, and the pattern portion for the buffer has the same size regularly or irregularly Alternatively, they are formed in different sizes, and the buffer pattern part is preferably implemented in a grid arrangement or a cross arrangement form.

In addition, it is preferable that the pattern part for the buffer is implemented by an etching process.

In addition, the first adhesive layer is preferably a single layer or a multilayer.

In addition, the flexible cover window according to an embodiment of the present invention includes a window substrate, a buffer pattern portion formed on both surfaces or a rear surface of the window substrate, and a resin formed on the buffer pattern portion formed on the rear surface of the window substrate. A filling layer, a first adhesive layer formed on the resin filling layer, an elastic film layer formed on the first adhesive layer to absorb deformation occurring in the flexible part, and a second adhesive layer formed on the elastic film layer It is preferable to include

In addition, the elastic film layer is formed between the first adhesive layer and the second adhesive layer, and it is preferable that a plurality of layers are laminated through an intermediate adhesive layer.

In addition, the elastic film layer is preferably any one of an EPU (Elastic Poly Urethane) film, a TPU (Thermoplastic Polyurethane) film, and a PO (PolyOlefin) film.

In addition, the first adhesive layer and the second adhesive layer, it is preferable to use OCA or OCR.

In addition, the thickness of the elastic film layer, it is preferable that 25 ~ 150㎛.

In addition, the thickness of the first adhesive layer and the second adhesive layer is preferably 10 ~ 150㎛, respectively.

In addition, the second adhesive layer is preferably a single layer or a multilayer.

In addition, it is preferable that a functional layer or an antibacterial layer is further formed on the front surface of the window substrate.

In addition, the antibacterial layer is preferably formed by coating the antibacterial coating composition in which the antibacterial nanoparticles are dispersed in an amount of 0.001 to 0.5 parts by weight based on 100 parts by weight of the resin coating solution on the window substrate.

In addition, it is preferable that the said antibacterial layer has a pencil hardness of 3H-9H.

Moreover, it is preferable that the thickness of the said antibacterial layer is 2-20 micrometers.

Moreover, it is preferable that the thickness of the said window substrate is 30-400 micrometers.

In addition, the flexible cover window is laminated on the upper side of a flexible display panel having a CPI film or a PET film attached to the front, or a flexible display panel having a CPI film or a PET film attached to the front, and an AF coating layer is formed on the upper layer. desirable.

In addition, in the flexible cover window, a CPI film or a PET film is preferably formed on the entire surface of the window substrate, and a functional layer is preferably formed on the entire surface of the CPI film or the PET film.

The present invention relates to a cover window for protecting a flexible display, and to provide a glass-based cover window for protecting a flexible display of a foldable, rollable, slidable, and stretchable method.

In particular, the present invention forms a pattern portion for a buffer on both sides or one surface of the window substrate to disperse the impact force and absorbs micro-deformation caused by the difference in elongation between the window substrate and the display panel to prevent delamination or buckling ( Buckling), the lifespan of the cover window is improved, and distortion of the screen in the flexible part is minimized.

In addition, the present invention forms an elastic film layer on the back side of the window substrate to more effectively absorb the micro-deformation so that there is no delamination or buckling in the flexible part.

In addition, in the present invention, by forming an elastic film layer on the back side of the window substrate, it is possible to minimize the restrictions on the material, thickness, and hardness of the window substrate, so that the window substrate of various materials can be manufactured according to the folding method or product specification of the flexible display. can be used

In addition, by forming an elastic film layer on the rear side of the window substrate, it is possible to provide a flexible cover window that absorbs and disperses an impact force such as a pen drop, improves impact resistance, and secures strength characteristics and folding characteristics.

In addition, the present invention provides a flexible cover window in which functionality or antibacterial properties are imparted to the window substrate by forming a functional layer or antibacterial layer) on the front surface of the window substrate.

1 and 2 - A schematic diagram showing the lifting and buckling phenomenon in the flexible portion of the conventional flexible cover window.
3 to 11 - A schematic diagram of a flexible cover window according to various embodiments of the present invention.
12, 13 and 14 - a schematic diagram showing various embodiments of applying the embodiment of Fig. 7 to a flexible display panel.

The present invention relates to a cover window for protecting a flexible display, and to a glass-based cover window for protecting a flexible display of a foldable, rollable, slidable, and stretchable method.

In particular, the present invention forms a pattern portion for a buffer on both sides or one surface of the window substrate to disperse the impact force and absorbs micro-deformation caused by the difference in elongation between the window substrate and the display panel to prevent delamination or buckling ( Buckling), the lifespan of the cover window is improved, and distortion of the screen in the flexible part is minimized.

In addition, the present invention forms an elastic film layer on the buffer pattern portion on the rear surface of the window substrate to more effectively absorb the micro-deformation so that there is no delamination or buckling in the flexible portion. .

In addition, the present invention can minimize restrictions on the material, thickness, and hardness of the window substrate by forming an elastic film layer on the rear surface of the window substrate. can

In addition, by forming an elastic film layer on the rear surface of the window substrate, it is possible to provide a flexible cover window that absorbs and disperses an impact force such as a pen drop, improves impact resistance, and secures strength characteristics and folding characteristics.

In addition, the present invention provides a flexible cover window in which functionality or antibacterial properties are imparted to the window substrate by forming a functional layer or antibacterial layer) on the front surface of the window substrate.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. 3 to 11 are schematic diagrams of a flexible cover window according to various embodiments of the present invention, and FIGS. 12, 13 and 14 are schematic diagrams showing various embodiments in which the embodiment of FIG. 7 is applied to a flexible display panel.

As shown, the flexible cover window according to the present invention is a glass base including a flat portion formed to correspond to the flat area of the flexible display, and a flexible portion formed to connect to the flat portion and formed to correspond to the folding area of the flexible display. In the flexible cover window of , a window substrate 100, a buffer pattern portion 200 formed on both sides or a rear surface of the window substrate 100, and a buffer pattern portion formed on a rear surface of the window substrate 100 ( 200) is characterized in that it includes a resin-filled layer 300 formed on the resin-filled layer 300, and a first adhesive layer 410 formed on the resin-filled layer (300).

The present invention is used as a protective cover window of the flexible display panel 10 of various types such as Foldable, Rollable, Slidable, Stretchable, etc., and is laminated on the front surface of the flexible display panel 10 to be laminated.

In the present invention, the term "front" means a surface that a user can touch or a surface in a direction facing the touch surface, and means a surface in an upward direction in the drawing. And, in the present invention, the back (rear side) means a surface opposite to the touch or a surface in the opposite direction to the touch, that is, a surface in the direction toward the display panel, and means a surface in the downward direction in the drawing.

Conventionally, in order to be adopted as a cover window of a display of various folding methods (Foldable, Rollable, Slidable, Stretchable method), folding characteristics and hardness characteristics must be satisfied at the same time. That is, as described above, a lifting or buckling phenomenon occurred in the folding area, or the folding characteristics and strength characteristics were deteriorated.

In the present invention, by forming the pattern portion 200 for a buffer on both sides or the rear surface of the window substrate 100 , the thickness restriction of the window substrate 100 is minimized, lifting or buckling phenomenon is minimized, and strength or folding characteristics are maintained. it was made to be

The buffer pattern part 200 is formed on both sides or the back surface of the window substrate 100, is formed on the flexible part, or is formed on the flat part and the flexible part, respectively, and is concave and convex for shock absorption and micro-strain absorption It is formed in a shape pattern. That is, the buffer pattern part 200 may be formed on the flexible part of the window substrate 100 or may be formed on the total surface of the window substrate 100 .

In the present invention, the flexible area of the display means a folding part, a curling part, a pushing and pulling part, and a sagging part in the case of a display folding, bending, rolling, sliding, or stretchable method. In the present invention, a portion of the cover window corresponding to the above area is referred to as a "flexible portion" of the cover window, and a flat area excluding the flexible portion is referred to as a "planar portion" of the cover window.

In particular, the present invention is formed on a glass basis, and the flat portion and the flexible portion may have a uniform thickness as a whole, or the flexible portion may be formed by slimming to a thinner thickness than the flat portion.

When the flexible portion is slimmed to be thinner than the flat portion, the thickness of the flat portion of the window substrate 100 is generally 30 to 400 μm, and the thickness of the flexible portion is 10 to 150 μm. A flexible part is formed by processing a thin plate of glass.

Here, the length of the flexible portion is designed in consideration of the radius of curvature of the portion where the cover window is deformed, such as being pushed or rolled in response to the deformation of the display panel, and is approximately set to the radius of curvature x π , and in the flexible portion The thickness of the window substrate 100 is formed in a range of 10 to 150 μm.

If the depth of the flexible portion is too deep, that is, if the flexible region of the window substrate is too thin, foldability is good, but wrinkles or strength are disadvantageous during reinforcement. Since the folding characteristic is deteriorated, the thickness of the window substrate in the flexible part is preferably about 10 to 150 μm.

The window substrate 100 in the present invention is formed of about 30 to 400 μm in thickness based on glass, and is chemically strengthened and used. In this thickness, as described above, the width and depth of the flexible part are appropriately designed. If the thickness is thinner than the above thickness, the thickness of the flexible region of the window substrate 100 is too thin after the formation of the flexible portion, and thus the above problems occur. This will cause trouble in reducing the weight of the display product.

In an embodiment of the present invention, the flexible part is formed in a shape of a rectangular trench as a whole in a shape that is slimmed inward in a flexible area of the cover window, and one or both ends of the flexible part has a thickness in the flexible part. may be formed so as to form an inclined portion that is gradually thickened to lead to a planar area of the cover window.

In particular, by forming a slope with a low inclination on both ends of the flexible part (the boundary with the flat part), the size of the reflection angle by the reflective surface is similarly adjusted in the entire area of the flexible part, so that interference of light and visual visibility on the reflective surface can be minimized. is to make it

The present invention maintains the folding characteristics and strength characteristics, so that it is laminated (laminated) on the front surface of the display panel 10 to be used for protecting the display panel 10, and is disposed on a CPI (Clear Polyimide) cover to ensure that the CPI It can also be used to protect the cover.

As described above, the present invention is to provide a cover window that is formed on a glass basis and has a flexible part that is a thin plate and has reinforced strength and folding characteristics so that it can be applied to foldable, rollable, slideable and stretchable displays, It is characterized in that the buffer pattern part 200 is provided in the part or the flat part and the flexible part, respectively.

As shown in FIGS. 3 to 11 , in the present invention, the buffer pattern part 200 is included on the window substrate 100 , and the buffer pattern part 200 is formed of a concave-convex pattern. characterized.

The buffer pattern part 200 may be formed on the surface on which the flexible part is formed, that is, on both sides or the back surface of the window substrate 100 , and also the front surface (Total) of the flat part, ie, the window substrate 100 as well as the flexible part. surface) may be formed.

Here, the buffer pattern portion 200 formed on the flexible portion of the front surface of the window substrate 100 and the buffer pattern portion 200 formed on the flexible portion of the rear surface (rear surface) of the window substrate 100 are , the size of the patterns, the spacing between the patterns, the height of the patterns, etc. may be the same or different from each other depending on product specifications or uses.

The pattern part 200 for the buffer is a pattern in which patterns of the same size or different sizes are continuously formed on the window substrate 100 in a regular or irregular manner using a dry or wet etching process, and is formed in a concave-convex pattern.

In particular, the buffer pattern unit 200 may have a horizontal cross-sectional shape of any one or more of polygonal, elliptical, and circular shapes or a combination thereof, and a grid arrangement or cross arrangement pattern for improving folding characteristics and evenly distributing impact force can be formed with

That is, in the process of slimming etching to form the flexible portion in order to strengthen the folding characteristics of the cover window, a predetermined pattern is formed inside the flexible portion, or a predetermined pattern is implemented on the flat portion and the flexible portion by a predetermined patterning process. to make it happen

The pattern of the pattern unit 200 for a buffer according to the present invention is formed in a concave-convex shape, and the corners are formed to be inclined at a certain angle to minimize light reflection on the mirror surface by the pattern so that the visual visibility of the pattern can be minimized. This may be formed by controlling the etching process conditions or adjusting the degree of adhesion of the patterned mask on the window substrate.

In the present invention, in the case of these foldable, rollable, slideable and stretchable cover windows, micro-deformation in the flexible part is minimized, and the inherent defects of the window substrate 100 itself and physical defects in the processing process are resolved. In order to do this, the pattern part 200 for a buffer is formed on the window substrate 100 .

The buffer pattern unit 200 is preferably formed on one surface and preferably the rear surface of the window substrate 100 as shown in FIGS. 3, 4, 6, 7, 9 and 10, or in FIGS. 5 and 10 . 8 and 11 , it may be formed on both surfaces of the window substrate 100 .

As a result, the floating portion of the flexible portion due to micro-deformation caused by the difference in stretching amount between the window substrate 100 and the display panel 10 by the buffer pattern portion 200 on both sides or the rear surface of the window substrate 100 ( By eliminating delamination or buckling, the lifespan of the cover window is improved, and distortion of the screen in the flexible part is minimized.

In addition, the pendrop characteristics are improved by the pattern unit 200 for a buffer according to the present invention, and stress on glass inherent defects and physical defects is dispersed to improve strength characteristics and folding characteristics. will improve the yield.

In particular, the buffer pattern unit 200 may be formed in a stripe shape or a pattern in which the pattern is dispersed as a whole, preferably, a horizontal cross-sectional shape of any one or more of a polygonal, an oval, and a circular shape, or a combination thereof. It is formed at the same time as the etching of the flexible portion or is formed on the flat portion and the flexible portion by a patterning process.

In addition, in the present invention, the height of the buffer pattern part 200 is preferably formed to be less than half the thickness of the window substrate 100 , and is formed in a range of 10 to 30% with respect to the thickness of the window substrate 100 . It is preferable to be

When the height is lower than the above range, the effect of impact force dispersion is insignificant, and when it is higher than this, the overall strength characteristics are deteriorated due to a decrease in the effective thickness.

The width of the upper end of the pattern of the pattern part 200 for buffer according to an embodiment of the present invention is 0 to 1000 µm, and the width of the lower end of the pattern is 30 to 2000 µm, and the width of the pattern becomes wider toward the center of the window substrate. Preferably, the interval between the patterns is about 30 to 4000 μm.

When the size of the pattern is larger than the above range, the folding characteristic is lowered, and when the size of the pattern is smaller than the above range, the pendrop characteristic is lowered. When it is smaller than the above range, the folding characteristic is lowered.

In addition, the height (etching depth) of the pattern of the buffer pattern part 200 is preferably 0.0005 to 0.28 mm. In addition, in the buffer pattern unit 200, the slope of the side surface of the pattern is formed at a slope of 0.1 to 50° with respect to the horizontal plane of the cover window. This depends on the etching process conditions of the pattern part 200 for the buffer, and is formed by adjusting the height and inclination of the pattern according to product specifications and the like.

If the height of the pattern is smaller than the above height, the impact force absorption and dispersion function is insignificant, and if the height of the pattern is higher than the height of the pattern, light reflection may occur on the mirror surface of the pattern or the strength characteristic may be deteriorated.

When the slope is lower than the slope, the height of the pattern is too small to absorb and disperse the impact force.

In addition, the height of the pattern portion 200 for the buffer is preferably formed to be equal to or smaller than the depth of the flexible portion.

This is to improve folding characteristics. When the height of the pattern part for buffer 200 and the depth of the flexible part are the same, it is a case in which an etching process to be described later is performed once, and the height of the pattern part 200 for buffer is the same. When is smaller than the depth of the flexible part, the etching process to be described later is performed twice or more.

The pattern part 200 for the buffer may be implemented by a dry or wet etching process, and is implemented by an etching process according to photomasking according to an embodiment of the present invention.

A resist pattern layer for forming a flexible portion including a first step of forming a resist layer on the window substrate 100 , and patterning the resist layer to include a buffer pattern portion 200 on the window substrate 100 . A second step of forming a layer, a third step of forming a flexible portion including a buffer pattern portion 200 between the flat portion using the resist pattern layer as a mask, and a third step of removing the resist pattern layer It is formed through a four-step process.

After that, through a fifth step of strengthening the window substrate 100 on which the flexible portion including the pattern portion for buffer 200 is formed, the cover window 100 on which the flexible portion including the pattern portion 200 for buffer is formed. will complete

A resin filling layer 300 is formed on the buffer pattern part 200 formed on the rear surface of the window substrate 100 .

The resin filling layer 300 is to fill the pattern of the pattern part 200 for the buffer with a transparent resin material so that the total surface of the display panel 10 and the cover window are joined without an empty space.

A transparent resin material is filled between the patterns of the pattern part 200 for the buffer by the resin filling layer 300 to provide a uniform cover window as a whole, absorb the impact force, and bond to the front surface of the display panel 10 By preventing the presence of empty space (air layer), visibility and bonding are improved.

In addition, the resin-filled layer 300 is a first adhesive layer 410 or a first adhesive layer 410 / elastic film layer 420 / second adhesive layer 430 to be described later in a laminated structure stably and uniformly on the window substrate. to be formed on the back side of That is, the contactability between the window substrate 100 made of glass and the first adhesive layer 410 made of resin is excellent.

The resin filling layer 300 uses a transparent resin such as OCR (Optical Clear Resin) that is almost the same as the refractive index (1.5) of glass. For example, acrylic, epoxy, silicone, urethane, urethane compound, urethane acrylic compound, hybrid sol gel, siloxane-based, etc. may be used, and these may be mixed in various combinations to enhance strength and elasticity.

The resin filling layer 300 is formed with a predetermined thickness, for example, about 2 to 20 μm, while being filled between the patterns of the pattern part 200 for the buffer, and may be formed as a single layer or multiple layers if necessary.

The present invention is implemented as a composite material of glass and a resin material as described above, so that the flexibility, restoring force, elasticity and strength characteristics of the resin material are reinforced while maintaining the texture of the glass as much as possible.

In particular, in the present invention, the pattern portion 200 for a buffer is included on the window substrate 100 , and a resin filling layer 300 is formed on the pattern portion 200 for a buffer formed on the rear surface of the window substrate 100 . By forming, the impact force on the pendrop is further dispersed or absorbed, thereby further improving impact resistance.

In addition, while minimizing the occurrence of cracks in the flexible part and preventing the shape of the pattern part 200 for buffer from being visually recognized from the outside, the resin filling layer 300 is evenly distributed inside the pattern part 200 for the buffer. It is filled so that flatness of the portion in contact with the display panel 10 can be secured.

As described above, by the combination of the pattern part 200 for the buffer and the resin filling layer 300, the adhesion of the adhesive layer to be described later in the flexible part is stably maintained, and the window substrate 100 and the display panel 10 while dispersing the impact force. By absorbing micro-deformation due to the difference in elongation between the two parts, the lifespan of the cover window is improved by preventing delamination or buckling in the flexible part, and distortion of the screen in the flexible part is minimized.

And a first adhesive layer 410 is formed on the resin filling layer (300).

The first adhesive layer 410 is for bonding the cover window to the display panel 10, and may use OCA (Optical Clear Adhesion) or OCR (Optical Clear Resin), which is almost the same as the refractive index (1.5) of glass. As the transparent resin, for example, acrylic, epoxy, silicone, urethane, urethane compound, urethane acrylic compound, hybrid sol gel, siloxane type, etc. can be used.

The thickness of the first adhesive layer 410 is preferably 10 ~ 150㎛, the thickness of the first adhesive layer 410 is 25 ~ 75㎛, the thickness of the second adhesive layer 430 is 10 ~ 50㎛ more preferably.

If it is thinner than the thickness, the fixing effect for adhesion is reduced, and if it is thicker than this, the material is wasted without reducing folding characteristics and transparency or improving adhesion.

By forming the first adhesive layer 410 on the resin-filled layer 300 according to the present invention, the micro-deformation in the flexible part is primarily absorbed by the buffer pattern part 200 and the resin-filled layer 300 . Thus, delamination or buckling of the first adhesive layer 410 is reduced.

The first adhesive layer 410 may be formed as a single layer or multi-layer depending on the folding method or product specifications of the display panel to be adhered, and may be formed of the same material as a multi-layer with different hardness, or may be formed of different materials as a multi-layer. there is.

An adhesive protective film is laminated on the first adhesive layer 410 to provide a cover window according to the present invention.

In addition, the present invention provides an elastic film for absorbing the deformation occurring in the flexible part on the first adhesive layer 410 in order to eliminate the delamination or buckling phenomenon due to the micro-deformation in the above-described flexible part. A second adhesive layer 430 formed on the layer 420 and the elastic film layer 420 may be further formed.

That is, an elastic film layer between the first adhesive layer 410 and the second adhesive layer 430 on the buffer pattern part 200 formed on the rear surface of the window substrate 100 and the resin filling layer 300 formed thereon. (420) is formed.

6 to 11 , according to the present invention, a window substrate 100 and a pattern part 200 for a buffer are formed on a rear surface of the window substrate 100, and the pattern part 200 for a buffer is formed on the pattern part 200 for the buffer. A resin-filled layer 300 is formed on the resin-filled layer 300 to form an elastic film layer 420 for absorbing the deformation occurring in the flexible part, but the elastic film layer 420 has an upper portion and a A first adhesive layer 410 and a second adhesive layer 430 are formed on the lower portion, respectively, and are laminated with the window substrate 100 .

That is, as an embodiment of the present invention, the window substrate 100 / buffer pattern portion 200 / resin filling layer 300 / first adhesive layer 410 / elastic film layer 420 / second adhesive layer 430 this will be formed

In particular, by forming a laminated structure including the elastic film layer 420 on the rear side of the window substrate 100 , in the flexible part due to micro-deformation due to the difference in stretching amount between the window substrate 100 and the display panel 10 , The lifespan of the cover window is improved by eliminating delamination or buckling, and distortion of the screen in the flexible part is minimized.

In addition, by forming a laminated structure including an elastic film layer 420 on the rear side of the window substrate 100, it absorbs and disperses impact force such as a pendrop to improve impact resistance, and flexible with strength characteristics and folding characteristics A cover window will be provided.

In general, when an impact such as a pendrop is applied on the cover window, the impact force transmitted vertically is stronger than the impact force transmitted horizontally. It is formed on the back surface of the substrate 100 to effectively disperse or absorb the vertical impact force, and serves to hold the window substrate 100, thereby improving pendrop characteristics.

The elastic film layer 420 may be provided in a single-layer or multi-layer structure according to the folding method of the display or product specifications.

6 to 9 illustrate a case in which the elastic film layer 420 is formed as a single layer.

When the elastic film layer 420 is formed as a single layer, the first adhesive layer 410, the elastic film layer 420 formed under the first adhesive layer 410, and the elastic film layer 420 formed under A laminate structure including the second adhesive layer 430 is formed on the upper portion of the resin filling layer 300 formed on the buffer pattern portion 200 on the rear surface of the window substrate 100 .

That is, an adhesive layer is formed on both surfaces of the elastic film layer 420 and laminated on the back surface of the window substrate 100 , and this is attached to the front surface of the display panel 10 , and the difference in stretching amount between the window substrate 100 and the display panel 10 . By alleviating the delamination or buckling phenomenon in the flexible part, it is prevented.

The first adhesive layer 410 fixes the window substrate 100 and the elastic film layer 420 on which the buffer pattern part 200 and the resin filling layer 300 are formed, and the second adhesive layer 430 is a display panel ( 10) and the elastic film layer 420 are fixed, and the elastic film layer 420 serves to alleviate the difference in the amount of stretching between the flexible cover window and the display panel 10 .

When a cover window made of the window substrate 100 is laminated with an adhesive layer without the existing laminated structure including an elastic film layer, micro-deformation is caused in the flexible part according to the difference in elongation amount between the upper or lower structures in the flexible part, causing lifting in the flexible part ( Delamination or buckling is more likely to occur.

The present invention provides a laminated structure in which an adhesive layer is formed on both sides of the elastic film layer 420 with a window substrate 100 (window substrate 100/buffer pattern unit 200/resin filling layer 300) and a display panel 10. By laminating therebetween, the difference in the stretching amount with the display panel 10 is alleviated, so that the delamination or buckling phenomenon of the window substrate 100 in the flexible part can be eliminated.

In addition, the buffer pattern part 200 (buffer pattern part 200/resin filling layer 300) is disposed between the laminate structure and the window substrate 100 so that the first adhesive layer 410 is lifted or It also solves the buckling problem.

As the elastic film layer 420, any material in the form of a transparent and elastic film may be used, and in an embodiment of the present invention, an EPU (Elastic Poly Urethane) film, a TPU (Thermoplastic Polyurethane) film and PO ( PolyOlefin) film may be used.

The thickness of the elastic film layer 420 according to an embodiment of the present invention is preferably 25 ~ 150㎛, more preferably 50 ~ 100㎛. If it is thinner than this, the function of buffering the stretching amount and absorbing the impact force may be insufficient.

Table 1 below shows an example of the elastic properties of the elastic film layer 420 , and is physical property data that can alleviate the difference in the amount of stretching between the thin-panel window substrate 100 and the display panel 10 .

In addition, the surface of the elastic film layer 420 is subjected to plasma surface treatment, etc. to improve the wettability of the surface of the elastic film layer 420 , thereby improving the coatability of the adhesive layer on the surface of the elastic film layer 420 . and to ensure uniform and precise coating.

The first adhesive layer 410 and the second adhesive layer 430 in the present invention may use OCA (Optical Clear Adhesion) or OCR (Optical Clear Resin), which is a transparent resin almost identical to the refractive index (1.5) of glass. For example, acrylic, epoxy, silicone, urethane, urethane compound, urethane acrylic compound, hybrid sol gel, siloxane type, etc. can be used.

The thickness of the first adhesive layer 410 and the second adhesive layer 430 is preferably 10 ~ 150㎛, the thickness of the first adhesive layer 410 is 25 ~ 75㎛, the second adhesive layer (430) It is more preferable that thickness is 10-50 micrometers.

If it is thinner than the thickness, the fixing effect for adhesion is reduced, and if it is thicker than this, the material is wasted without reducing folding characteristics and transparency or improving adhesion.

The second adhesive layer 430 may be formed as a single layer or multi-layer according to the folding method or product specification of the display panel to be adhered, and may be formed as a multi-layer with different hardness of the same material, or may be formed with different materials as a multi-layer. there is.

An adhesive protective film is laminated on the second adhesive layer 430 to provide a cover window according to the present invention.

In another embodiment of the present invention, as shown in FIGS. 9 to 11 , when the elastic film layer 420 is formed in a multilayer structure, a first adhesive layer 410 is formed, and the first adhesive layer ( 410) is formed in the lower portion, and a plurality of elastic film layers 421 and 422 are formed in a laminated structure via an intermediate adhesive layer 440, and a second adhesive layer 430 is formed under the elastic film layer 420 laminated structure. ) is formed. An adhesive protective film is laminated on the second adhesive layer 430 to provide a cover window according to the present invention.

When the elastic film layers 421 and 422 are formed in a multi-layer structure, the plurality of elastic film layers may be formed of the same material, the same hardness, and the same thickness, and the window substrate according to the folding method of the display or the product specification. The closer to (100), the lower the elongation (modulus of elasticity) (in the case of in-folding), or the closer to the window substrate 100, the higher the elongation (modulus of elasticity) may be formed (out-folding) folfing).

Thereby, a laminated structure composed of the same or different types of elastic film layers is implemented according to various folding methods of the display, and the elongation difference in the flexible part is alleviated, thereby defects such as delamination or buckling in the flexible part. is to be minimized.

Meanwhile, in the present invention, as shown in FIGS. 4, 5, 7, 8, 10 and 11, a functional layer or an antibacterial layer 500 is further provided on the front surface of the window substrate 100. can be formed.

The functional layer or the antibacterial layer 500 may be formed as a single layer or a multilayer, and since it is formed on the front surface of the window substrate, it is implemented as a hard coating layer.

For the functional layer, transparent resins such as acrylic, epoxy, silicone, urethane, urethane composite, urethane acrylic composite, organic-inorganic hybrid sol gel, siloxane-based, etc. may be used, and strength is reinforced by mixing them in various combinations according to the properties of the resin. can be used for

Here, the functional layer is formed on the window substrate 100 by any one of a process such as spraying, dip coating, bar coating, stamping, slot coating, etc. can be implemented by

The functional layer can be used by increasing the content of a resin having a relatively high hardness, such as acrylic or epoxy, when cured, or by adjusting the content of organic and inorganic substances in the organic-inorganic hybrid sol-gel to reinforce strength.

In addition, when the functional layer is formed in multiple layers, the functional layer formed on the front surface of the cover window is preferably formed of a relatively hard material toward the upper layer.

In addition, the functional layer, particularly the functional layer formed on the uppermost layer, is formed to reinforce the scattering prevention function and the surface scratch resistance (3H), and the thickness thereof is suitable about 2 to 20 μm.

In addition, the functional layer may be provided with an AF (Anti Finger) or AR (Anti Reflective) function as needed, and may be implemented by synthesizing a resin having such a function, or various patterns such as a moth eye may be applied to the functional layer. It can also be implemented by forming a pattern.

In addition, the antibacterial layer 500 is formed on the front surface of the cover window, that is, the touch surface, and serves to impart antibacterial properties and antibacterial durability to the cover window. The antimicrobial layer 500 may be used by mixing the antimicrobial composition with the composition constituting the functional layer.

Preferably, the antibacterial layer 500 is made of a resin composite antibacterial coating composition in which antibacterial nanoparticles are dispersed in an amount of 0.001 to 0.5 parts by weight based on 100 parts by weight of the resin coating solution, and can be formed by coating on the window substrate 100 . there is.

The size of these antibacterial nanoparticles is about 0.01 to 30 nm, and 0.001 to 0.5 parts by weight of the antibacterial nanoparticles are dispersed in an amount of 0.001 to 0.5 parts by weight with respect to 100 parts by weight of the resin coating solution, so that they have overall transparent or translucent transparency.

Here, the antibacterial layer 500 is sprayed on the window substrate 100 through a process such as spray, dip coating, bar coating, stamping, slot coating, etc. It may be implemented by any one of them.

The antibacterial layer 500 uses antibacterial nanoparticles to impart antibacterial properties, and resin and antibacterial nanoparticles are used together to promote even dispersion of antibacterial nanoparticles, and are coated with antibacterial nanoparticles impregnated in resin. , the uniformity of antibacterial performance and the prevention of detachment of antibacterial nanoparticles, while simultaneously improving the folding characteristics and dispersing the impact force due to the use of resin.

(400)의 강도를 개선시키게 되며 본 발명에 따른 항균층(500)은 연필경도 3H~9H를 갖는 것을 특징으로 한다.In addition, since the antibacterial nanoparticles are impregnated and coated in the resin, the overall antibacterial

The strength of 400 is improved, and the antibacterial layer 500 according to the present invention has a pencil hardness of 3H to 9H.

The antibacterial nanoparticles are preferably silver nanoparticles, platinum nanoparticles, copper nanoparticles, titanium dioxide nanoparticles, or a mixture thereof.

The silver nanoparticles, platinum nanoparticles, and titanium dioxide nanoparticles are excellent in antibacterial properties, and the copper nanoparticles are known to have excellent bacterial removal functions. Any one of particles, platinum nanoparticles, titanium dioxide nanoparticles, and copper nanoparticles may be mixed and used.

In the case of the existing antibacterial film, an antibacterial material such as copper particles was coated on the surface of the substrate and provided. It was not uniform, and there was a problem in that the antibacterial performance was deteriorated due to the oxidation of the antibacterial material.

In addition, when used on the surface of a flexible product, there was a problem in that waveness was generated in the folding part, or the antibacterial material was separated from the folding part.

In the case of the antibacterial coating composition according to the present invention, the antibacterial nanoparticles are coated on the window substrate 100 in a state in which they are uniformly dispersed inside the resin coating solution, and the antibacterial nanoparticles are discharged to the outside while maintaining uniform transparency as a whole. There is no problem such as oxidation and oxidation, so it has high antibacterial properties and long-lasting antibacterial properties.

In particular, the antibacterial nanoparticles are contained in an amount of 0.001 to 0.5 parts by weight based on 100 parts by weight of the resin coating solution, and while having a degree of transparency or translucent transparency, it maintains a state evenly dispersed in the resin coating solution. It has high economic advantages.

을 구현함으로써, 강도가 높은 항균층(500)을 제공할 수도 있다.In addition, the resin coating solution uses a transparent resin such as OCR (Optical Clear Resin), for example, any one of acrylic, epoxy, silicone, urethane, urethane compound, urethane acrylic compound, hybrid sol gel, and siloxane-based resin can be used. . These materials can be mixed in various combinations to control strength and elasticity, and as described above, the antibacterial composition is mixed with the composition constituting the functional layer.

By implementing the, it is possible to provide the antibacterial layer 500 with high strength.

The flexible cover window in which the antibacterial layer 500 according to the present invention is implemented has a pencil hardness of 3H to 9H.

In general, a coating layer using a resin is known to have a hardness of 1H to 2H of pencil hardness, but in the present invention, it is provided as a vertical composite antibacterial layer 500, and has a hardness of 3H to 9H, so not only antibacterial properties but also strength It plays a role in protecting the surface of the product by reinforcing its properties.

In particular, the antibacterial layer 500 according to the present invention is formed by coating an antibacterial coating composition evenly dispersed in a resin coating solution on the window substrate 100, and even when the window substrate 100 is folded or bent, the antibacterial layer 500. It can be usefully used in recent wearable electronic products and flexible displays as it does not cause cracks or separation.

It exhibits excellent antibacterial properties, strength properties, and folding properties, so it can be used as a cover window for a display panel or as a cover window for various operation buttons of electronic products or products with curved surfaces or products requiring antibacterial properties.

In an embodiment of the present invention, a flexible cover window may be provided by coating the antibacterial layer 500 using copper nanoparticles on the window substrate 100 having a thickness of about 150 μm, in which case the antibacterial layer ( 500) was formed to a thickness of about 10 μm.

In addition, the anti-finger layer 500 can be provided with an anti-finger (AF) or anti-reflective (AR) function as needed. It can also be implemented as a pattern.

The antibacterial layer 500 may be formed together with a primer layer, and the primer layer surrounds one or both sides (front and back) of the window substrate 100 , or the entire surface of the window substrate 100 . It may be formed by wrapping.

The primer layer is formed on the window substrate 100 to prevent scattering of the window substrate 100 and to reinforce environmental reliability, and has a thickness of about 0.1 to 10 μm.

Table 2 below shows an embodiment of the present invention (an antibacterial layer using silver nanoparticles was formed on a window substrate having a thickness of about 150 μm, and the thickness of the antibacterial layer was formed to be about 10 μm). Antibacterial test results according to the size and content of silver nanoparticles are shown.

Silver Nanoparticle Size and Content antibacterial activity Staphylococcus aureus coli antibacterial% Staphylococcus aureus coli control after the exam control after the exam Staphylococcus aureus coli 2nm, 0.01% 4.8 5.9 1,500,000 24 22,000,000 28 99.998% 99.99987% 2nm, 0.05% 4.8 5.9 1,500,000 24 22,000,000 28 99.998% 99.99987% 2nm, 0.1% 4.8 5.9 1,500,000 24 22,000,000 35 99.998% 99.99988% 15nm, 0.01% 3.2 5.9 1,500,000 1,000 22,000,000 35 99.93% 99.99988% 15nm, 0.05% 4.8 5.9 1,500,000 24 22,000,000 35 99.998% 99.99988% 15nm, 0.1% 4.8 5.9 1,500,000 24 22,000,000 35 99.998% 99.99988%

As shown in Table 2, it was confirmed that there was little difference in antimicrobial properties according to the size and content of the silver nanoparticles. That is, it exhibited excellent antibacterial performance in all examples.

The following Table 3 shows the antibacterial test results for one embodiment of the present invention, Comparative Example 1 (in the case of a substrate without an antibacterial layer), and Comparative Example 2 (commercially available copper antibacterial film).

[ Table 3 ]

As shown in Table 3, it was confirmed that the antibacterial performance was very good. In addition, as a result of measuring the change in antimicrobial properties with time, it was confirmed that there was little change in the performance.

In addition, one embodiment of the present invention shows a pencil hardness of 7H, which is applied to touch panels or operation buttons of electronic products, etc. It has excellent properties and can be applied to the cover window of a flexible display as it has foldability.

Even when copper nanoparticles were used as another embodiment of the present invention, antibacterial properties and antibacterial persistence were very excellent, and as described above, strength characteristics and folding characteristics were also very excellent.

As described above, the present invention provides a flexible cover window having excellent antibacterial properties while continuously maintaining an antibacterial action by forming an antibacterial layer on a window substrate.

In addition, the antibacterial layer is formed by coating an antibacterial coating composition in which antibacterial nanoparticles are dispersed in a resin coating solution on a window substrate, and satisfies not only antibacterial properties but also strength properties and folding properties.

As shown in FIG. 12 , the flexible cover window according to the exemplary embodiment ( FIG. 7 ) of the present invention may be laminated (Lami) on the upper layer of the display panel 20 .

In addition, the flexible cover window according to an embodiment (FIG. 7) of the present invention is laminated ( Lami), or a CPI film or PET film 20 may be attached to the front side, and laminated on the upper side of the flexible display panel 10 having an AF coating layer formed thereon (Lami).

In addition, as shown in FIG. 14 as an embodiment of the present invention, a CPI film or a PET film 20 may be formed on the front surface of the window substrate 100 , and the front surface of the CPI film or PET film 20 . A functional layer or an antibacterial layer 500 may be formed there.

By omitting the protective CPI film or PET film 20 formed on the front surface of the existing flexible display panel 10, the CPI film or PET film 20 is formed on the front surface of the window substrate 100, and then, if necessary, the A functional layer or an antibacterial layer 500 may be formed.

That is, as shown in FIG. 14 , a cover window according to the present invention is directly laminated (Lami) on a flexible display panel 10, a CPI film or a PET film 20 is formed thereon, and then, if necessary Accordingly, the functional layer or the antibacterial layer 500 is formed.

As such, the present invention relates to a cover window for protecting a flexible display, and to provide a cover window for protecting a flexible display of a Foldable, Rollable, Slidable, Stretchable method.

In particular, the present invention forms a pattern portion for a buffer on both sides or one surface of the window substrate to disperse the impact force and absorbs micro-deformation caused by the difference in elongation between the window substrate and the display panel to prevent delamination or buckling ( Buckling) improves the lifespan of the cover window and minimizes screen distortion in the flexible part.

In addition, the present invention forms a resin-filled layer 300 on the buffer pattern portion of the rear surface of the window substrate, and forms an elastic film layer in an upper direction thereof, to more effectively absorb the micro-deformation, and thereby There is no delamination or buckling.

In addition, in the present invention, by forming an elastic film layer on the back side of the window substrate, it is possible to minimize the restrictions on the material, thickness, and hardness of the window substrate, so that the window substrate of various materials can be manufactured according to the folding method or product specification of the flexible display. can be used

In addition, by forming a laminated structure including an elastic film layer on the rear side of the window substrate, it is possible to absorb and disperse an impact force such as a pendrop to improve impact resistance, and to provide a flexible cover window in which strength characteristics and folding characteristics are secured.

In addition, the present invention provides a flexible cover window in which functionality or antibacterial properties are imparted to the window substrate by forming a functional layer or antibacterial layer) on the front surface of the window substrate.

In addition, in an embodiment of the present invention, when a window substrate is used as a glass, it is implemented as a composite material of glass and a resin material so that the flexibility, restoring force, elasticity and strength characteristics of the resin material are reinforced while maintaining the texture of the glass as much as possible. do.

10: display panel 20: CPI film or PET film
100: window board 200: pattern part for buffer
300: resin-filled layer 410: first adhesive layer
420: elastic film layer 430: second adhesive layer
500: antibacterial layer

Claims (21)

In the glass-based flexible cover window comprising: a flat portion formed to correspond to the flat area of the flexible display;
window substrate;
a buffer pattern portion formed on both sides or the rear surface of the window substrate by an etching process, and an edge thereof is inclined at a predetermined angle;
a resin filling layer formed on the buffer pattern portion formed on the rear surface of the window substrate;
a first adhesive layer formed on the resin-filled layer;
an elastic film layer formed on the first adhesive layer and absorbing deformation occurring in the flexible part due to a difference in stretching amount between the window substrate and the flexible display panel;
Including; a second adhesive layer formed on the elastic film layer;
The elastic film layer,
Flexible cover window, characterized in that any one of EPU (Elastic Poly Urethane) film, TPU (Thermoplastic Polyurethane) film, and PO (PolyOlefin) film. The method of claim 1, wherein the buffer pattern unit,
A flexible cover window formed in the flexible part or formed in the flat part and the flexible part, respectively, and formed in a pattern of concavo-convex shapes. The method of claim 1, wherein the buffer pattern unit,
A flexible cover window, characterized in that it is regularly or irregularly formed in the same size or different sizes. [4] The flexible cover window according to claim 3, wherein the buffer pattern part is implemented in a grid arrangement or a cross arrangement form. delete According to claim 1, wherein the first adhesive layer,
A flexible cover window, characterized in that it is a single layer or multiple layers. delete According to claim 1, wherein the elastic film layer,
It is formed between the first adhesive layer and the second adhesive layer, and a flexible cover window, characterized in that formed by stacking a plurality of the intermediate adhesive layer as a medium. delete According to claim 1, wherein the first adhesive layer and the second adhesive layer,
Flexible cover window, characterized in that using OCA or OCR respectively. According to claim 1, wherein the thickness of the elastic film layer,
Flexible cover window, characterized in that 25 ~ 150㎛. According to claim 1, wherein the thickness of the first adhesive layer and the second adhesive layer,
Flexible cover windows, characterized in that each of 10 ~ 150㎛. According to claim 1, wherein the second adhesive layer,
A flexible cover window, characterized in that it is a single layer or multiple layers. The flexible cover window according to claim 1, wherein a functional layer or an antibacterial layer is further formed on the front surface of the window substrate. 15. The method of claim 14, wherein the antibacterial layer,
A flexible cover window, characterized in that it is formed by coating an antibacterial coating composition dispersed in an amount of 0.001 to 0.5 parts by weight of antibacterial nanoparticles based on 100 parts by weight of the resin coating solution on the window substrate. The method of claim 15, wherein the antibacterial layer,
A flexible cover window, characterized in that the pencil hardness is 3H to 9H. The method of claim 14, wherein the thickness of the functional layer or the antibacterial layer,
Flexible cover window, characterized in that 2 ~ 20㎛. According to claim 1, wherein the thickness of the window substrate,
Flexible cover window, characterized in that 30 ~ 400㎛. According to claim 1, wherein the flexible cover window,
The upper side of the flexible display panel with CPI film or PET film attached to the front,
Or CPI film or PET film is attached to the front surface, the flexible cover window, characterized in that the laminated on the upper side of the flexible display panel with an AF coating layer formed thereon. According to claim 1, wherein the flexible cover window,
A flexible cover window, characterized in that a CPI film or a PET film is formed on the front surface of the window substrate. The flexible cover window according to claim 20, wherein a functional layer is formed on the entire surface of the CPI film or the PET film.

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