Patent Description:
The present disclosure relates to a display device, and more particularly, to a rollable display device in which warpage of a display panel caused by moisture may be improved.

Display devices employed by the monitor of a computer, a TV, a mobile phone or the like include an organic light emitting display (OLED) that emits light by itself, and a liquid crystal display (LCD) that requires a separate light source.

As the display devices have been increasingly applied to diverse fields such as a computer monitor, a TV, and a personal mobile device, display devices having a large display area and a reduced volume and weight have been studied.

Further, recently, a rollable display device in which a display part, wiring lines, etc. are formed on a flexible substrate made of flexible plastic and which may display an image even when rolled up has attracted attention as a next-generation display device.

<CIT> presents a display device that includes: a plurality of display panels, which is capable of displaying images independently; a protection plate, which is disposed on a front surface of the plurality of display panels; and a transparent adhesive, which covers a display sur-face of each of the plurality of display panels to adhere the display panels to the protection plate, wherein the plurality of display panels includes: a pair of substrates, on which plural wirings and plural electrodes are formed, a driver circuit, which inputs signals to the plural wirings to drive the plural electrodes, and a detection circuit, which detects an abnormal value of signals output from the display panels.

<CIT> presents a polarizing plate and liquid crystal display using the same.

<CIT> presents a rollable display device that includes: a display unit divided into a display area and a non-display area, and including a flexible display panel and a cover window above the flexible display panel; a roller part connected to the lower side of the display unit to wind or unwind the display unit; and a protective pattern disposed on the upper rim of the cover window and made of a resin or polymer material having elasticity.

An object to be achieved by the present disclosure is to provide a display device in which moisture absorption of a polarization plate can be minimized.

Another object to be achieved by the present disclosure is to provide a display device in which moisture permeation occurring through side surfaces of a display panel and a polarization plate can be minimized.

Yet another object to be achieved by the present disclosure is to provide a display device in which warpage of a display panel caused by moisture absorption of a polarization plate can be improved.

Still another object to be achieved by the present disclosure is to provide a display device in which cracks in a substrate of a display panel caused by moisture absorption of a polarization plate can be suppressed.

Objects of the present disclosure are not limited to the above-mentioned objects, and other objects, which are not mentioned above, can be clearly understood by those skilled in the art from the following descriptions.

The object is solved by the features of the independent claim. The invention is set out by the features of the independent claim.

According to an aspect of the present disclosure, the display device includes a display panel including an active area and a non-active area; and a polarization plate on the display panel and including a polarization layer. The polarization layer includes a first pattern corresponding to the active area and a second pattern spaced apart from the first pattern and corresponding to the non-active area.

According to another aspect of the present disclosure, the display device includes a display panel including an active area and a non-active area; a polarization plate on the display panel and including a polarization layer and protection layers respectively disposed on both surfaces of the polarization layer; and a roller unit configured to wind or unwind the display panel. The polarization layer includes a first pattern corresponding to the active area and a second pattern surrounding the first pattern and corresponding to the non-active area. The first pattern and the second pattern are spaced apart from each other by any one of the protection layers respectively disposed on the both surfaces of the polarization layer.

Other detailed matters of the exemplary embodiments are included in the detailed description and the drawings.

According to the present disclosure, a barrier film is disposed to surround side portions of a display panel and a polarization plate. Thus, it is possible to suppress moisture permeation.

According to the present disclosure, a polarization layer corresponding to a non-active area is patterned. Thus, it is possible to delay moisture permeation occurring through the polarization layer.

According to the present disclosure, it is possible to suppress warpage of a display panel and cracks in a substrate by suppressing moisture absorption of a polarization layer.

Advantages and characteristics of the present disclosure and a method of achieving the advantages and characteristics will be clear by referring to exemplary embodiments described below in detail together with the accompanying drawings. However, the present disclosure is not limited to the exemplary embodiments disclosed herein but will be implemented in various forms. The exemplary embodiments are provided by way of example only so that those skilled in the art can fully understand the disclosures of the present disclosure. The present disclosure will be defined only by the scope of the appended claims.

The shapes, sizes, ratios, angles, numbers, and the like illustrated in the accompanying drawings for describing the exemplary embodiments of the present disclosure are merely examples, and the present disclosure is not limited thereto. Further, in the following description of the present disclosure, a detailed explanation of known related technologies may be omitted to avoid unnecessarily obscuring the subject matter of the present disclosure. The terms such as "including," "having," and "consist of" used herein are generally intended to allow other components to be added unless the terms are used with the term "only". Any references to singular may include plural unless expressly stated otherwise.

Hereinafter, the present disclosure will be described in detail with reference to accompanying drawings.

A rollable display device may refer to a display device which can display an image even when rolled up. The rollable display device may have higher flexibility than conventional typical display devices. The rollable display device can be freely changed in shape depending on whether the rollable display device is used or not. Specifically, when the rollable display device is not used, the rollable display device can be housed as rolled up to reduce its volume. When the rollable display device is used, the rolled rollable display device can be unrolled again to be used.

<FIG> and <FIG> are perspective views of a display device according to an exemplary embodiment of the present disclosure. Referring to <FIG> and <FIG>, a display device <NUM> according to an exemplary embodiment of the present disclosure includes a display part DP and a housing part HP.

The display part DP is configured to display images to a user. For example, display elements, circuits for driving the display elements, wiring lines, components, and the like may be disposed in the display part DP. Herein, the display device <NUM> according to an embodiment of the present disclosure is a rollable display device. Therefore, the display part DP may be configured to be wound or unwound. For example, the display part DP may include a display panel and a back cover which are flexible so as to be wound or unwound. More details of the display part DP will be described later with reference to <FIG>.

The housing part HP serves as a case where the display part DP may be housed. The display part DP may be wound and then housed inside the housing part HP, and the display part DP may be unwound and then presented outside the housing part HP.

The housing part HP includes an opening HPO through which the display part DP may move in and out of the housing part HP. The display part DP may move up and down through the opening HPO of the housing part HP.

Meanwhile, the display part DP of the display device <NUM> may transition from a full unwinding state to a full winding state, and vice versa.

<FIG> shows a full unwinding state of the display part DP of the display device <NUM>. The full unwinding state refers to a state where the display part DP of the display device <NUM> is presented outside the housing part HP. That is, the full unwinding state may be defined as a state where the display part DP is unwound to a maximum so as not to be further unwound and presented outside the housing part HP in order for the user to watch images on the display device <NUM>.

<FIG> shows a full winding state of the display part DP of the display device <NUM>. The full winding state refers to a state where the display part DP of the display device <NUM> is housed inside the housing part HP and may not be further wound. That is, the full winding state may be defined as a state where the display part DP is wound and housed inside the housing part HP when the user does not watch images on the display device <NUM> because the display part DP housed inside the housing part HP is preferable for the sake of external appearance. Further, in the full winding state where the display part DP is housed inside the housing part HP, the display device <NUM> is reduced in volume and easy to transport.

Meanwhile, a moving part for winding or unwinding the display part DP to change the display part DP to the full unwinding state or the full winding state is provided. The moving part is provided inside and fully accommodated in the housing part. In an wound state all parts of the moving part are accommodated inside the housing part HP. In an unwound state most of the parts of the moving part are accommodated inside the housing part HP.

<FIG> is a perspective view of the display device according to an exemplary embodiment of the present disclosure. <FIG> is a cross-sectional view of the display device according to an exemplary embodiment of the present disclosure. <FIG> is a schematic cross-sectional view provided to explain a roller <NUM> and the display part DP of the display device <NUM> according to an exemplary embodiment of the present disclosure. For convenience of description, <FIG> illustrates only the housing part HP, the roller <NUM>, and the display part DP.

First, referring to <FIG>, a moving part MP includes a roller unit <NUM> and an elevating unit <NUM>.

The roller unit <NUM> winds or unwinds the display part DP fixed to the roller unit <NUM> while rotating clockwise or counterclockwise. The roller unit <NUM> includes the roller <NUM> and a roller support <NUM>.

The roller <NUM> is a member around which the display part DP is wound. The roller <NUM> may have, e.g., a cylindrical shape. The lower edge of the display part DP may be fixed to the roller <NUM>. When the roller <NUM> rotates, the display part DP whose lower edge is fixed to the roller <NUM> may be wound around the roller <NUM>. On the contrary, when the roller <NUM> rotates in the opposite direction, the display part DP wound around the roller <NUM> may be unwound from the roller <NUM>.

Referring to <FIG>, the roller <NUM> may include at least a part of the outer peripheral surface having a flat surface and the other part of the outer peripheral surface having a curved surface. The roller <NUM> has a cylindrical shape overall but may be partially flat. That is, a part of the outer peripheral surface of the roller <NUM> is flat and the other part of the outer peripheral surface is curved. At least one flexible film <NUM> and a printed circuit board <NUM> of the display part DP may be mounted on the flat surface part of the roller <NUM>, thus the flexible film <NUM> and/or the printed circuit board <NUM> may be prevented from being bent when being wound onto the roller. The roller <NUM> may be a completely cylindrical shape or may have any shape around which the display part DP may be wound, but is not limited thereto.

Referring to <FIG> again, the roller support <NUM> supports the roller <NUM> from both sides of the roller <NUM>. Specifically, the roller supports <NUM> are placed on a bottom surface HPF of the housing part HP. Further, upper side surfaces of the respective roller supports <NUM> are combined with both ends of the roller <NUM>. Thus, the roller support <NUM> may support the roller <NUM> so as to be spaced apart from the bottom surface or bottom part HPF of the housing part HP. Herein, the roller <NUM> may be rotatably combined with the roller support <NUM>.

The elevating unit <NUM> moves the display part DP up and down according to driving of the roller unit <NUM>. The elevating unit <NUM> includes a link unit <NUM>, a head bar <NUM>, a slide rail <NUM>, a slider <NUM>, a motor <NUM>, and a rotating unit <NUM>.

The link unit <NUM> of the elevating unit <NUM> includes a plurality of links 161a and 161b and a hinge unit 161c that connects the plurality of links 161a and 161b. Specifically, the plurality of links 161a and 161b includes a first link 161a and a second link 161b. The first link 161a and the second link 161b are crossed in the form of scissors and rotatably hinged to each other via the hinge unit 161c. Thus, when the link unit <NUM> moves up and down, the plurality of links 161a and 161b may rotate in a direction to be farther from or closer to each other.

The head bar <NUM> of the elevating unit <NUM> is fixed to the uppermost end of the display part DP. The head bar <NUM> is connected to the link unit <NUM> and may move the display part DP up and down according to rotation of the plurality of links 161a and 161b of the link unit <NUM>. That is, the display part DP may be moved up and down by the head bar <NUM> and the link unit <NUM>.

The head bar <NUM> covers only a part of a surface adjacent to the uppermost edge of the display part DP so as not to cover images displayed on the front surface of the display part DP. The display part DP and the head bar <NUM> may be fixed by screws, but the present disclosure is not limited thereto.

The slide rail <NUM> of the elevating unit <NUM> provides travel paths of the plurality of links 161a and 161b. A part of the plurality of links 161a and 161b may be rotatably clamped to the slide rail <NUM> and its movement may be guided along the track of the slide rail <NUM>. A part of the plurality of links 161a and 161b may be clamped to the slider <NUM> movably provided along the slide rail <NUM> and moved along the track of the slide rail <NUM>.

The motor <NUM> may be connected to a power generation unit, such as a separate external power supply or a built-in battery, and supplied with power from the power generation unit. The motor <NUM> generates rotatory power and supplies driving force to the rotating unit <NUM>.

The rotating unit <NUM> is connected to the motor <NUM> and configured to covert rotational movement of the motor <NUM> into linear reciprocal movement. That is, the rotating unit <NUM> may convert rotational movement of the motor <NUM> into linear reciprocal movement of a structure fixed to the rotating unit <NUM>. For example, the rotating unit <NUM> may be implemented as a ball screw including a shaft and a nut clamped to the shaft, but is not limited thereto.

The motor <NUM> and the rotating unit <NUM> may elevate the display part DP in line with the link unit <NUM>. The link unit <NUM> has a link structure and may receive driving force from the motor <NUM> and the rotating unit <NUM> and repeatedly perform folding and unfolding operations.

Specifically, when the motor <NUM> is driven, the structure of the rotating unit <NUM> may make linear movement. That is, a part of the rotating unit <NUM> connected to one end of the second link 161b may make linear movement. Thus, the one end of the second link 161b may move toward the motor <NUM>. Also, the plurality of links 161a and 161b is folded, and, thus, the height of the link unit <NUM> may decrease. Further, while the plurality of links 161a and 161b is folded, the head bar <NUM> connected to the first link 161a is moved down. Also, one end of the display part DP connected to the head bar <NUM> is also moved down.

Therefore, when the display part DP is fully wound around the roller <NUM>, the link unit <NUM> of the elevating unit <NUM> maintains a folded state. That is, when the display part DP is fully wound around the roller <NUM>, the elevating unit <NUM> may have a minimum height. When the display part DP is fully unwound, the link unit <NUM> of the elevating unit <NUM> maintains an unfolded state. That is, when the display part DP is fully unwound, the elevating unit <NUM> may have a maximum height.

Meanwhile, when the display part DP is wound, the roller <NUM> may rotate and the display part DP may be wound around the roller <NUM>. Referring to <FIG>, as an example, the lower edge of the display part DP is connected to the roller <NUM>. Further, when the roller <NUM> rotates in a first direction DR1, i.e., clockwise, the display part DP may be wound around the roller <NUM> so that a rear surface of the display part DP may be closely contacted with a surface of the roller <NUM>.

When the display part DP is unwound, the roller <NUM> may rotate and the display part DP may be unwound from the roller <NUM>. Referring to <FIG>, as an example, when the roller <NUM> rotates in a second direction DR2, i.e., counterclockwise, the display part DP wound around the roller <NUM> may be unwound from the roller <NUM> and then presented outside the housing part HP.

In some embodiments, the moving part MP different in structure from the above-described moving part MP may also be applied to the display device <NUM>. That is, the roller unit <NUM> and the elevating unit <NUM> described above may be changed in configuration as long as the display part DP may be wound and unwound. Some of their components may be omitted or other components may be added.

<FIG> is a plan view of the display part of the display device according to an exemplary embodiment of the present disclosure. <FIG> is a cross-sectional view of the display part of the display device according to an exemplary embodiment of the present disclosure.

Referring to <FIG>, the display part DP includes the back cover <NUM> (<FIG>), the display panel <NUM>, the flexible film <NUM>, the printed circuit board <NUM>, a barrier film <NUM> and a polarization plate <NUM>.

The display panel <NUM> is configured to display images to the user. In the display panel <NUM>, display elements for displaying images, driving elements for driving the display elements, and wiring lines for transmitting various signals to the display elements and the driving elements may be disposed. The display elements may be defined differently depending on the kind of the display panel <NUM>. For example, if the display panel <NUM> is an organic light emitting display panel, the display elements may be organic light emitting elements each composed of an anode, an organic emission layer, and a cathode. For example, if the display panel <NUM> is a liquid crystal display panel, the display elements may be liquid crystal display elements. The display panel might be also include semiconductor LEDs or micro LEDs for displaying images. Hereinafter, the display panel <NUM> will be assumed as an organic light emitting display panel, but the display panel <NUM> is not limited to the organic light emitting display panel. Further, since the display device <NUM> according to an embodiment of the present disclosure is a rollable display device, the display panel <NUM> may be implemented as a flexible display panel to be wound around or unwound from the roller <NUM>.

The display panel <NUM> includes an active area AA and a non-active area NA.

The active area AA refers to an area where an image is displayed on the display panel <NUM>. In the active area AA, a plurality of pixels including a plurality of sub-pixels and a circuit for driving the plurality of sub-pixels may be disposed. The plurality of sub-pixels is a minimum unit of the active area AA, and a display element may be disposed on each of the plurality of sub-pixels. For example, an organic light emitting element composed of an anode, an organic emission layer, and a cathode may be disposed on each of the plurality of sub-pixels, but the present disclosure is not limited thereto. Further, the circuit for driving the plurality of sub-pixels may include a driving element, a wiring line, and the like. For example, the circuit may be composed of a thin film transistor, a storage capacitor, a gate line, a data line, etc., but is not limited thereto.

The non-active area NA refers to an area where an image is not displayed. The non-active area NA may be extended from the active area AA. In the non-active area NA, various wiring lines, circuits, and the like for driving the organic light emitting elements in the active area AA may be disposed. For example, link lines for transmitting signals to the plurality of sub-pixels and circuits in the active area AA or driver ICs such as a gate driver IC and a data driver IC may be disposed in the non-active area NA. However, the present disclosure is not limited thereto.

The barrier film <NUM> may be disposed and the polarization plate <NUM> is disposed on the display panel <NUM>. The barrier film <NUM> and the polarization plate <NUM> will be described later with reference to <FIG>.

The flexible film <NUM> includes various components on a flexible base film and serves to supply signals to the plurality of sub-pixels and circuits in the active area AA. The flexible film <NUM> may be electrically connected to the display panel <NUM>. The flexible film <NUM> is placed on one end of the non-active area NA of the display panel <NUM> and supplies power voltage, data voltage, etc. to the plurality of sub-pixels and circuits in the active area AA. The number of flexible films <NUM> illustrated in <FIG> is just an example and is not limited thereto. The number of flexible films <NUM> may be changed variously depending on the design and is not limited thereto.

Meanwhile, on the flexible film <NUM>, driver ICs such as a gate driver IC and/or a data driver IC may be disposed. The driver ICs are components configured to process data for displaying an image and a driving signal for processing the data. The driver ICs may be mounted in a Chip On Glass (COG) method, a Chip On Film (COF) method, a Tape Carrier Package (TCP), or the like. For convenience of description, the driver ICs are described as mounted on the flexible film <NUM> in the COF method, but the present disclosure is not limited thereto.

The printed circuit board <NUM> is disposed on one end of the flexible film <NUM> and connected to the flexible film <NUM>. The printed circuit board <NUM> is configured to supply signals to the driver ICs. The printed circuit board <NUM> supplies various signals such as a drive signal, a data signal, etc. to the driver ICs. In the printed circuit board <NUM>, various components may be disposed. For example, a timing controller, a power supply unit, etc. may be disposed on the printed circuit board <NUM>. Meanwhile, <FIG> illustrates two printed circuit boards <NUM>. However, the number of printed circuit boards <NUM> is not limited thereto and may be changed variously depending on the design.

Meanwhile, although not illustrated in <FIG>, an additional printed circuit board connected to the printed circuit board <NUM> may be further disposed. For example, the printed circuit board <NUM> may be referred to as a source printed circuit board (source PCB) S-PCB on which a data driver is mounted. The additional printed circuit board connected to the printed circuit board <NUM> may be referred to as a control printed circuit board (control PCB) C-PCB on which a timing controller or the like is mounted. The additional printed circuit board may be disposed inside the roller <NUM>, or may be disposed within the housing part HP outside the roller <NUM>.

The back cover <NUM> is disposed on rear surfaces of the display panel <NUM>, the flexible film <NUM>, and the printed circuit board <NUM> and supports the display panel <NUM>, the flexible film <NUM>, and the printed circuit board <NUM>. Thus, the back cover <NUM> may be larger in size than the display panel <NUM>. The back cover <NUM> may protect the other components of the display part DP against the external environment. The back cover <NUM> may be made of a rigid material, but at least a part of the back cover <NUM> may have flexibility so as to be wound or unwound along with the display panel <NUM>. For example, the back cover <NUM> may be made of a metal material such as Steel Use Stainless (SUS) or Invar, or plastic. However, the material of the back cover <NUM> is not limited thereto. The material of the back cover <NUM> may be changed variously depending on the design as long as it may satisfy property requirements such as amount of thermal deformation, radius of curvature, rigidity, etc..

The back cover <NUM> includes a plurality of supporting areas PA, a fixing area FA and a plurality of flexible areas MA. In the plurality of supporting areas PA and the fixing area FA, a plurality of openings <NUM> is not disposed. In the plurality of flexible areas MA, the plurality of openings <NUM> is disposed. Specifically, a first supporting area PA1, a first flexible area MA1, the fixing areas FA1 and FA2, a second flexible area MA2 and a second supporting area PA2 are disposed in sequence from the uppermost end of the back cover <NUM>.

The first supporting area PA1 of the back cover <NUM> is the uppermost area of the back cover <NUM> and clamped to the head bar <NUM>. The first supporting area PA1 includes first alignment holes AH1 so as to be clamped to the head bar <NUM>. In this case, the first supporting area PA1 may be clamped to head bar <NUM> by means of screws, but is not limited thereto. Since the first supporting area PA1 is clamped to the head bar <NUM>, the back cover <NUM> may move up or down at the same time when the link unit <NUM> clamped to the head bar <NUM> moves up or down. The display panel <NUM> attached to the back cover <NUM> may also move up or down. <FIG> illustrates five first alignment holes AH1, but the number of first alignment holes AH1 is not limited thereto. Further, <FIG> illustrates that the back cover <NUM> is clamped to the head bar <NUM> using the first alignment holes AH1. However, the present disclosure is not limited thereto. Further, the back cover <NUM> may be clamped to the head bar <NUM> without alignment holes.

The first flexible area MA1 is extended from the first supporting area PA1 to the lower side of the back cover <NUM>. In the first flexible area MA1, the plurality of openings <NUM> is disposed. The display panel <NUM> is attached to the first flexible area MA1.

When the display part DP is wound around the roller <NUM> so as to be housed inside the housing part HP, the first flexible area MA1 of the back cover <NUM> may be wound around the roller <NUM>. A lower end portion and a central portion of the display panel <NUM> attached to the first flexible area MA1 may also be wound around the roller <NUM>. Here, the first flexible area MA1 of the back cover <NUM> includes the plurality of openings <NUM>. Thus, the first flexible area MA1 of the back cover <NUM> may have high flexibility and may be easily wound around the roller <NUM> together with the display panel <NUM>.

The fixing area FA is extended from the first flexible area MA1 to the lower side of the back cover <NUM>. The fixing area FA enables the flexible film <NUM> and the printed circuit board <NUM> to be wound so as not to be curved but to be flat around the roller <NUM> to protect the flexible film <NUM> and the printed circuit board <NUM>. Further, the roller <NUM> may also be partially flat corresponding to the fixing area FA.

A plurality of fixing holes <NUM> is disposed in the fixing area FA. Each of the plurality of fixing holes <NUM> is disposed between flexible films <NUM>. Thus, it is possible to more stably fix the flexible films <NUM> and the printed circuit board <NUM> to the fixing area FA. Meanwhile, the number of fixing holes <NUM> illustrated in <FIG> is just an example and may be determined based on the number of printed circuit boards <NUM>, the number of flexible films <NUM>, etc..

Meanwhile, the back cover <NUM> may be divided into a first back cover 110a and a second back cover 110b with a plurality of fixing holes <NUM> in a first fixing area FA1 and a plurality of fixing holes <NUM> in a second fixing area FA2 interposed therebetween. That is, the first back cover 110a includes the first supporting area PA1, the first flexible area MA1 and the first fixing area FA1, and the second back cover 110b includes the second fixing area FA2, the second flexible area MA2 and the second supporting area PA2. However, the present disclosure is not limited thereto. The back cover <NUM> may be formed as one body.

The second flexible area MA2 is extended from the fixing area FA to the lower side of the back cover <NUM>. Further, in the second flexible area MA2, the plurality of openings <NUM> is disposed.

The second flexible area MA2 is extended to enable an active area AA of the display panel <NUM> to be presented outside the housing part HP. For example, when the back cover <NUM> and the display panel <NUM> are in the full unwinding state, an area ranging from the second supporting area PA2 of the back cover <NUM> fixed to the roller <NUM> to the fixing area FA to which the flexible film <NUM> and the printed circuit board <NUM> are attached may be placed inside the housing part HP. At the same time, the first flexible area MA1 to which the display panel <NUM> is attached and the fixing area FA may be presented outside the housing part HP. In this case, if a length from the second supporting area PA2 fixed to the roller <NUM> to the second flexible area MA2 and the fixing area FA is smaller than a length from the second supporting area PA2 to the opening HPO of the housing part HP, a part of the first flexible area MA1 to which the display panel <NUM> is attached may be placed inside the housing part HP. Thus, since a part of a lower end of the active area AA of the display panel <NUM> is placed inside the housing part HP, it may be difficult to watch images. Therefore, the length from the second supporting area PA2 fixed to the roller <NUM> to the second flexible area MA2 and the fixing area FA may be designed to be equal to the length from the second supporting area PA2 fixed to the roller <NUM> to the opening HPO of the housing part HP.

The second supporting area PA2 of the back cover <NUM> is the lowermost area of the back cover <NUM> and clamped and fixed to the roller <NUM>. The second supporting area PA2 may include second alignment holes AH2 so as to be clamped to the roller <NUM>. In this case, the second supporting area PA2 may be clamped to the roller <NUM> by screws, but is not limited thereto. Since the second supporting area PA2 is clamped to the roller <NUM>, the back cover <NUM> may be wound around or unwound from the roller <NUM> as the roller <NUM> is rotated. <FIG> illustrates two second alignment holes AH2, but the number of second alignment holes AH2 is not limited thereto. Also, <FIG> illustrates that the back cover <NUM> is clamped to the roller <NUM> using the second alignment holes AH2. However, the present disclosure is not limited thereto. The back cover <NUM> may be fixed to the roller <NUM> without alignment holes.

The flexible area MA of the back cover <NUM> is wound around or unwound from the roller <NUM> along with the display panel <NUM>. The flexible area MA may overlap at least the display panel <NUM> among the other components of the display part DP.

The plurality of openings <NUM> is disposed in the flexible area MA of the back cover <NUM>. During winding or unwinding of the display part DP, the plurality of openings <NUM> may be deformed by stress applied to the display part DP. Specifically, during winding or unwinding of the display part DP, the flexible area MA of the back cover <NUM> may be deformed as the plurality of openings <NUM> contracts or expands. Further, since the plurality of openings <NUM> contracts or expands, a slip phenomenon of the display panel <NUM> disposed on the flexible area MA of the back cover <NUM> may be minimized. Therefore, stress applied to the display panel <NUM> may be minimized.

Referring to <FIG>, the plurality of openings <NUM> is misaligned with the plurality of openings <NUM> of adjacent rows. For example, the plurality of openings <NUM> of one row is misaligned with the plurality of openings <NUM> of rows adjacent to the corresponding row. Specifically, the centers of plurality of openings <NUM> in odd-numbered rows may be misaligned with the centers of the plurality of openings <NUM> in even-numbered rows by as much as, e.g., <NUM>/<NUM> of a row-direction width of each opening <NUM>. The placement of the plurality of openings <NUM> shown in <FIG> is just an example, but is not limited thereto.

In this case, the plurality of openings <NUM> formed in the flexible area MA is not formed in the first supporting area PA1 and the second supporting area PA2. That is, only the first alignment holes AH1 and the second alignment holes AH2 are formed in each of the first supporting area PA1 and the second supporting area PA2. However, the plurality of openings <NUM> formed in the flexible area MA is not formed in the first supporting area PA1 and the second supporting area PA2. Further, the first alignment holes AH1 and the second alignment holes AH2 are different in shape from the plurality of openings <NUM>. The first supporting area PA1 and the second supporting area PA2 are fixed to the head bar <NUM> and the roller <NUM>, respectively. Thus, the first supporting area PA1 and the second supporting area PA2 need to have higher rigidity than the flexible area MA. Specifically, since the first supporting area PA1 and the second supporting area PA2 have rigidity, the first supporting area PA1 and the second supporting area PA2 may be securely fixed to the head bar <NUM> and the roller <NUM>. Therefore, the display part DP is fixed to the roller <NUM> and the head bar <NUM> of the moving part MP and may move in and out of the housing part HP according to an operation of the moving part MP.

In the display device <NUM> according to an embodiment of the present disclosure, the back cover <NUM> including the plurality of openings <NUM> is disposed on the rear surface of the display panel <NUM> to support and protect the display panel <NUM>. The back cover <NUM> may be made of a metal material and thus may have rigidity. Also, the flexible area MA of the back cover <NUM> in which the display panel <NUM> is disposed includes the plurality of openings <NUM>, and, thus, the back cover <NUM> may have improved flexibility. Therefore, in the full unwinding state in which the display part DP of the display device <NUM> is presented outside the housing part HP, the back cover <NUM> made of a rigid material and having high rigidity may support the display panel <NUM> to be spread flat. On the contrary, in the full winding state in which the display part DP of the display device <NUM> is housed inside the housing part HP, the back cover <NUM> having high flexibility due to the plurality of openings <NUM> may be wound around the roller <NUM> and housed together with the display panel <NUM>.

Further, in the display device <NUM> according to an exemplary embodiment of the present disclosure, the back cover <NUM> includes the first back cover 110a and the second back cover 110b spaced apart from each other. Thus, the back cover <NUM> may be formed so as to correspond to various sizes of the display panel <NUM>. As the size of the display device <NUM> increases, the size of the display panel <NUM> also increases. In this case, the back cover <NUM> needs to be larger in size than the display panel <NUM>. Therefore, the single back cover <NUM> needs to be manufactured to a large size. However, it is very difficult to manufacture the single back cover <NUM> corresponding to a large-size display device in the manufacturing process. Accordingly, in the display device <NUM> according to an exemplary embodiment of the present disclosure, the back cover <NUM> is configured including the first back cover 110a and the second back cover 110b. Thus, the first back cover 110a and the second back cover 110b which are smaller in size than the display device <NUM> may be used. Meanwhile, although not illustrated in the drawings, a base plate, a bottom cover, a top cover and a fixing member are used to fix the first back cover 110a and the second back cover 110b.

Referring to <FIG>, the back cover <NUM> is disposed on the rear surface of the display panel <NUM>, and the barrier film <NUM> and the polarization plate <NUM> are disposed on a front surface of the display panel <NUM>. Herein, the front surface of the display panel <NUM> may refer to a surface corresponding to a view direction, and the rear surface of the display panel <NUM> may refer to a surface on the opposite side to the view direction.

The display panel <NUM> includes a substrate <NUM>, a buffer layer <NUM>, a pixel unit <NUM>, an encapsulation layer <NUM>, and an encapsulation substrate <NUM>.

The substrate <NUM> serves as a base member to support various components of the display panel <NUM> and may be made of an insulating material. The substrate <NUM> may be made of a flexible material in order for the display panel <NUM> to be wound or unwound. For example, the substrate <NUM> may be made of a plastic material such as polyimide (PI).

The buffer layer <NUM> may suppress diffusion of moisture and/or oxygen permeating from the outside of the substrate <NUM>. The buffer layer <NUM> may be formed as a single layer or a multilayer of silicon oxide (SiOx) and silicon nitride (SiNx), but is not limited thereto.

The pixel unit <NUM> includes a plurality of organic light emitting elements and circuits for driving the organic light emitting elements. The pixel unit <NUM> may correspond to the active area AA. Each organic light emitting element may include an anode, an organic emission layer, and a cathode.

The anode may supply holes into the organic emission layer and may be made of a conductive material having a high work function. For example, the anode may be made of tin oxide (TO), indium tin oxide (ITO), indium zinc oxide (IZO), indium zinc tin oxide (ITZO), or the like, but is not limited thereto.

The organic emission layer may receive holes from the anode and electrons from the cathode and emit light. The organic emission layer may be one of a red organic emission layer, a green organic emission layer, a blue organic emission layer, a white organic emission layer, and the like depending on the color of light emitted from the organic emission layer. At this time, if the organic emission layer is a white organic emission layer, color filters of various colors may be further provided.

The cathode may supply electrons into the organic emission layer and may be made of a conductive layer having a low work function. For example, the cathode may be made of one or more materials selected from the group consisting of metals such as magnesium (Mg), silver (Ag), and aluminum (Al) and alloys thereof, but is not limited thereto.

Meanwhile, the display panel <NUM> may be classified into a top emission type or a bottom emission type according to a transmission direction of light emitted from the organic light emitting element.

In the top emission type, light emitted from the organic light emitting element is discharged toward the upper side of the substrate <NUM> on which the organic light emitting element is formed. If the display panel <NUM> is a top emission type, a reflective layer may be further provided under the anode. This is to discharge or guide light emitted from the organic light emitting element toward the upper side of the substrate <NUM>, i.e., toward the cathode.

In the bottom emission type, light emitted from the organic light emitting element is discharged toward the lower side of the substrate <NUM> on which the organic light emitting element is formed. If the display panel <NUM> is of bottom emission type, the anode may be made of a transparent conductive material only and the cathode may be made of a metal material having high reflectivity. This is to discharge light emitted from the organic light emitting element toward the lower side of the substrate <NUM>.

Hereafter, for convenience of description, the display device <NUM> according to an embodiment of the present disclosure will be described as a bottom emission type display device, but is not limited thereto.

In the pixel unit <NUM>, a circuit for driving organic light emitting elements is disposed. The circuit may be composed of a TFT, a storage capacitor, a gate line, a data line, a power line, etc. The components of the circuit may be changed variously depending on the design of the display device <NUM>.

The encapsulation layer <NUM> covering the pixel unit <NUM> is disposed on the pixel unit <NUM>. The encapsulation layer <NUM> seals the organic light emitting elements of the pixel unit <NUM>. The encapsulation layer <NUM> may protect the organic light emitting elements of the pixel unit <NUM> against external moisture, oxygen, impacts, and the like. The encapsulation layer <NUM> may be formed by alternately laminating a one or more of inorganic layers and a one or more of organic layers. For example, the one or more inorganic layers may be made of inorganic materials such as silicon nitride (SiNx), silicon oxide (SiOx), and aluminum oxide (AlOx), but are not limited thereto. For example, the one or more organic layers may be made of epoxy-based or acryl-based polymers, but are not limited thereto.

The encapsulation substrate <NUM> is disposed on the encapsulation layer <NUM>. The encapsulation substrate <NUM> protects the organic light emitting elements of the pixel unit <NUM> together with the encapsulation layer <NUM>. The encapsulation substrate <NUM> may protect the organic light emitting elements of the pixel unit <NUM> against external moisture, oxygen, impacts, and the like. The encapsulation substrate <NUM> may be made of a metal material which has high corrosion resistance and may be easily processed into foil or thin film. Examples of the metal material may include aluminum (Al), nickel (Ni), chromium (Cr), and an alloy of iron (Fe) and Ni. Accordingly, since the encapsulation substrate <NUM> is made of a metal material, the encapsulation substrate <NUM> may be implemented in the form of an ultra-thin film and may provide high resistance to external impacts and scratches.

A first adhesive layer AD1 may be disposed between the encapsulation layer <NUM> and the encapsulation substrate <NUM>. The first adhesive layer AD1 may bond the encapsulation layer <NUM> and the encapsulation substrate <NUM>. The first adhesive layer AD1 may be made of an adhesive material and may be a thermosetting or naturally-curable adhesive. For example, the first adhesive layer AD1 may be made of an optical clear adhesive (OCA), a pressure sensitive adhesive (PSA), or the like, but is not limited thereto. The adhesive layer AD1 may fully surround the encapsulation layer <NUM> and the pixel unit <NUM>. Thus, it contacts the buffer layer at the side surfaces of the pixel unit <NUM>.

The first adhesive layer AD1 may be disposed to cover the encapsulation layer <NUM> and the pixel unit <NUM>. That is, the pixel unit <NUM> may be sealed by the buffer layer <NUM> and the encapsulation layer <NUM> and the encapsulation layer <NUM> and the pixel unit <NUM> may be sealed by the buffer layer <NUM> and the first adhesive layer AD1. The first adhesive layer AD1 may protect the organic light emitting elements of the pixel unit <NUM> against external moisture, oxygen, impacts, and the like. together with the encapsulation layer <NUM> and the encapsulation substrate <NUM>. Herein, the first adhesive layer AD1 may further contain a moisture absorbent. The moisture absorbent may include hygroscopic particles and may absorb moisture and oxygen from the outside to minimize permeation of moisture and oxygen into the pixel unit <NUM>.

The back cover <NUM> is disposed on the encapsulation substrate <NUM>. The back cover <NUM> may be disposed to be in contact with the encapsulation substrate <NUM> of the display panel <NUM> to protect the display panel <NUM>. The back cover <NUM> may be made of a rigid material to protect the display panel <NUM>.

A second adhesive member AD2 is disposed between the encapsulation substrate <NUM> and the back cover <NUM>. The second adhesive member AD2 may bond the encapsulation substrate <NUM> and the back cover <NUM>. The second adhesive member AD2 may be made of an adhesive material and may be a thermosetting or naturally-curable adhesive. For example, the adhesive member AD2 may be made of an optical clear adhesive (OCA), a pressure sensitive adhesive (PSA), or the like, but is not limited thereto.

A micro seal MS may be disposed on side surfaces of the display panel <NUM>. The micro seal MS may be disposed between the substrate <NUM> and the back cover <NUM> so as to surround the side surfaces of the display panel <NUM>. That is, side portions of the display panel <NUM> may be sealed by the micro seal MS. The micro seal MS may protect the display panel <NUM> against external moisture, oxygen, impacts, and the like. The micro seal MS may be made of a photocurable acrylic resin, etc. but is not limited thereto.

The barrier film <NUM> is disposed on the front surface of the display panel <NUM>. The barrier film <NUM> may protect the display panel <NUM> against external impacts, moisture, heat, and the like. The barrier film <NUM> may be made of a polymer resin which is light and unbreakable. For example, the barrier film <NUM> may be made of a cyclo olefin polymer (COP), but is not limited thereto. The barrier film <NUM> may also be made of polyimide (PI), polycarbonate (PC), polyethylene terephthalate (PET), and the like.

A third adhesive layer AD3 may be disposed between the display panel <NUM> and the barrier film <NUM>. The third adhesive layer AD3 may bond the display panel <NUM> and the barrier film <NUM>. The third adhesive layer AD3 may be made of an adhesive material and may be a thermosetting or naturally-curable adhesive. For example, the third adhesive layer AD3 may be made of an optical clear adhesive (OCA), a pressure sensitive adhesive (PSA), or the like, but is not limited thereto. Meanwhile, the third adhesive layer AD3 and the barrier film <NUM> are illustrated as separate components, but are not limited thereto. The third adhesive layer AD3 may be a component of the barrier film <NUM>.

The polarization plate <NUM> is disposed on the barrier film <NUM>. The polarization plate <NUM> is configured to suppress reflection and recognition of external light incident upon the display device <NUM>. The polarization plate <NUM> may have a structure in which a plurality of layers is laminated.

A fourth adhesive layer AD4 may be disposed between the barrier film <NUM> and the polarization plate <NUM>. The fourth adhesive layer AD4 may bond the barrier film <NUM> and the polarization plate <NUM>. The fourth adhesive layer AD4 may be made of an adhesive material and may be a thermosetting or naturally-curable adhesive. For example, the fourth adhesive layer AD4 may be made of an optical clear adhesive (OCA), a pressure sensitive adhesive (PSA), or the like, but is not limited thereto. Meanwhile, the fourth adhesive layer AD4, the barrier film <NUM> and the polarization plate <NUM> are illustrated as separate components, but are not limited thereto. The fourth adhesive layer AD4 may be a component of the barrier film <NUM> or the polarization plate <NUM>.

Hereinafter, the polarization plate <NUM> will be described in more detail with reference to <FIG>.

<FIG> is an enlarged cross-sectional view of an area A of <FIG>.

Referring to <FIG>, the polarization plate <NUM> includes a phase delay layer <NUM>, a first protection layer <NUM>, a polarization layer <NUM>, a second protection layer <NUM>, and a surface layer <NUM>.

The phase delay layer <NUM> may have a transmission axis in the range of ±<NUM> degrees based on the angle of polarization of external light in the polarization layer <NUM>. Thus, external light incident upon the phase delay layer <NUM> may be circularly polarized through the phase delay layer <NUM>.

The polarization layer <NUM> may linearly polarize light incident from the outside of the display device <NUM>. The polarization layer <NUM> may be formed as a stretched film of a polyvinyl alcohol (PVA)-based polymer film containing iodine or dichroic dye, but is not limited thereto.

The first protection layer <NUM> and the second protection layer <NUM> are respectively disposed on both surfaces of the polarization layer <NUM>. The polarization layer <NUM> is made of a PVA-based material that absorbs moisture well. Thus, if the first protection layer <NUM> and the second protection layer <NUM> are respectively disposed on the both surfaces of the polarization layer <NUM>, it is possible to suppress damage to the polarization layer <NUM> caused by heat or moisture. The first protection layer <NUM> and the second protection layer <NUM> may be made of a material having no phase difference so as not to affect a polarization state of the polarization layer <NUM>. For example, the first protection layer <NUM> and the second protection layer <NUM> may be made of triacetyl cellulose (TAC), but is not limited thereto.

The surface layer <NUM> is disposed on an outermost side of the polarization plate <NUM> and enhances a mechanical strength of the polarization plate <NUM>. Further, the surface layer <NUM> serves to suppress glare and reflection and thus improves visibility of the display device <NUM>. The surface layer <NUM> may be formed as an anti-glare (AG) layer, a semi-glare (SG) layer, a low-reflection (LR) layer and an anti-glare & low-reflection (AGLR) layer formed by a surface treatment method, but is not limited thereto.

The polarization layer <NUM> includes a first pattern 183a and a second pattern 183b. The first pattern 183a and the second pattern 183b is formed by patterning a layer of a material forming the polarization layer <NUM>. Here, patterning of the polarization layer <NUM> may be performed only in a region corresponding to the non-active area NA of the display panel <NUM>. If patterning of the polarization layer <NUM> is also performed in a region corresponding to the active area AA, the patterned regions may be recognized or polarization efficiency may decrease. Thus, patterning of the polarization layer <NUM> may be performed only in a region corresponding to the non-active area NA.

The first pattern 183a corresponds to the active area AA, and the second pattern 183b corresponds to the non-active area NA. That is, the first pattern 183a overlaps the active area AA of the display panel <NUM>, and the second pattern 183b overlaps the non-active area NA of the display panel <NUM>. Thus, the second pattern 183b is formed to surround the first pattern 183a. In the drawing, the second pattern 183b is illustrated as including a plurality of second patterns 183b, but is not limited thereto. The second pattern 183b may be formed as a single second pattern 183b.

The first pattern 183a and the second pattern 183b is spaced apart from each other by a hole H formed by patterning. Further, if a plurality of second patterns 183b is formed, the plurality of second patterns 183b may be spaced apart from each other by the one or more holes H formed by patterning. That is, the first pattern 183a and the plurality of second patterns 183b may be spaced apart from each other. Also, at least one of the one or more holes H is filled with the second protection layer <NUM> or the first protection layer <NUM>. Since the polarization layer <NUM> is divided into the first pattern 183a and the second pattern 183b, moisture absorption of the polarization layer <NUM> may be delayed. Specifically, infiltration of moisture and oxygen may occur from the second pattern 183b, which is a side portion of the polarization plate <NUM>, toward the first pattern 183a, which is a central portion of the polarization plate <NUM>. Here, the divided patterns 183a and 183b of the polarization layer <NUM> may absorb moisture and oxygen independently of each other. Further, a moving path of moisture and oxygen may be lengthened or blocked by the protection layers <NUM> and <NUM> disposed on the one or more holes H between the patterns 183a and 183b. Therefore, infiltration of moisture and oxygen into the region of the polarization layer <NUM> corresponding to the active area AA may be delayed. Also, degradation in quality and warpage caused by moisture absorption of the polarization layer <NUM> may be suppressed.

In general, a polarization plate <NUM> of a display device includes a PVA-based polymer film as a polarization layer to polarize incident light. However, a PVA-based polymer material may decrease in modulus when exposed to moisture. Therefore, a neutral plane of a display panel is moved, which may cause an increase in stress applied to a substrate and thus results in cracks in the substrate.

Also, the PVA-based polymer material is excellent in moisture absorption and thus changes in volume depending on the humidity. That is, the polarization layer may absorb moisture and expand in a high-humidity environment, and may discharge moisture and contract in a low-humidity environment. Thus, warpage occurs in a stretching direction of the polarization layer. Accordingly, warpage occurs in the polarization plate and the display panel to which the polarization plate is attached.

However, in the display device <NUM> according to an exemplary embodiment of the present disclosure, a portion of the polarization layer <NUM> corresponding to the non-active area NA is patterned to delay moisture absorption. The polarization layer <NUM> is patterned so that the first pattern 183a corresponding to the active area AA and the second pattern 183b corresponding to the non-active area NA are spaced apart from each other. Also, the second pattern 183b is disposed to surround the first pattern 183a. Thus, even if moisture or oxygen infiltrates through side portions of the polarization plate <NUM>, the second pattern 183b disposed on a side portion of the polarization layer <NUM> may independently absorb moisture. Therefore, moisture absorption of the first pattern 183a may be delayed. Here, the second pattern 183b is a part of the polarization layer <NUM> corresponding to the non-active area NA. Thus, most of the polarization layer <NUM> is formed as the first pattern 183a. Therefore, the second pattern 183b may suppress overall deformation and warpage of the polarization layer <NUM>.

Also, in the display device <NUM> the protection layers <NUM> and <NUM> are disposed on the one or more holes H between the first pattern 183a and the second pattern 183b of the polarization layer <NUM>. That is, the first pattern 183a and the second pattern 183b are spaced apart from each other by the protection layers <NUM> and <NUM>. Thus, the protection layers <NUM> and <NUM> may block moisture or oxygen flowing from the second pattern 183b toward the first pattern 183a or lengthen a moving path thereof. Therefore, it is possible to minimize infiltration of moisture or oxygen into the first pattern 183a.

Further, in the display device <NUM> according to an exemplary embodiment of the present disclosure, a plurality of second patterns 183b may be formed, and the plurality of second patterns 183b may be spaced apart from each other by the protection layers <NUM> and <NUM>. That is, moisture absorption of the plurality of second patterns 183b may occur sequentially from the second pattern 183b disposed on an outer side of the polarization layer <NUM> toward the second pattern 183b adjacent to the first pattern 183a. Furthermore, the protection layers <NUM> and <NUM> may be disposed between a plurality of second patterns 183b adjacent to each other to minimize the progress of moisture absorption from the outside of the plurality of second patterns 183b toward the first pattern 183a. Thus, moisture absorption and deformation of the first pattern 183a may be suppressed. Therefore, it is possible to suppress a decrease in modulus of the polarization layer <NUM> and suppress cracks in the substrate <NUM>. Also, it is possible to minimize warpage of the polarization layer <NUM> and suppress warpage of the display panel <NUM>. Moreover, it is possible to suppress deformation of the polarization layer <NUM> and thus possible to improve the display quality and reliability of the display device <NUM>.

<FIG> are plan views of a polarization layer according to various exemplary embodiments of the present disclosure. <FIG> illustrate only one corner of the polarization layer <NUM> and its adjacent partial region for convenience in explanation, the same structure may be applied to the other non-illustrated regions. Meanwhile, any one or a combination of the structures of the polarization layer <NUM> shown in <FIG> may be applied to the polarization layer <NUM> shown in <FIG>. However, the present disclosure is not limited thereto. As long as a region of the polarization layer <NUM> corresponding to the non-active area NA is patterned, various pattern structures may be applied.

Referring to <FIG>, the polarization layer <NUM> includes a first pattern 710a and a second pattern 720a. The first pattern 710a corresponds to the active area AA of the display panel <NUM>, and the second pattern 720a corresponds to the non-active area NA of the display panel <NUM>. The second pattern 720a is disposed to surround the first pattern 710a. Particularly, the second pattern 720a may have a closed loop shape. The first pattern 710a and the second pattern 720a are spaced apart from each other by a hole H or an opening or gap. Also, the hole H between the first pattern 710a and the second pattern 720a may have a closed loop shape. Further, although not illustrated in the drawings, any one of the protection layers <NUM> and <NUM> disposed on the hole H may have a closed loop shape. Thus, even if moisture and oxygen infiltrate into the polarization plate <NUM>, the second pattern 720a corresponding to the non-active area NA may first absorb moisture independently. Also, even if moisture and oxygen infiltrate into the hole H, the protection layers <NUM> and <NUM> inside the hole H may block such infiltration and lengthen a moving path of moisture and oxygen. Therefore, the second pattern 720a and the hole H serve as a barrier and thus minimize moisture absorption of the first pattern 710a.

Referring to <FIG>, the polarization layer <NUM> includes a first pattern 710b and second patterns 721b and 722b. The first pattern 710b corresponds to the active area AA of the display panel <NUM>, and the second patterns 721b and 722b correspond to the non-active area NA of the display panel <NUM>. The second patterns 721b and 722b may include a plurality of first sub-patterns 721b and a plurality of second sub-patterns 722b. The plurality of first sub-patterns 721b may be disposed so as to correspond to edges of the first pattern 710b. The plurality of first sub-patterns 721b may have a line shape. The plurality of second sub-patterns 722b may be disposed between the plurality of first sub-patterns 721b so as to correspond to a corner of the first pattern 710b. The plurality of second sub-patterns 722b may have a dot shape. The plurality of first sub-patterns 721b and the plurality of second sub-patterns 722b may be disposed to surround the first pattern 710b. The plurality of first sub-patterns 721b and the plurality of second sub-patterns 722b may be disposed in a plurality of rows or a plurality of columns. The first pattern 710b, the plurality of first sub-patterns 721b and the plurality of second sub-patterns 722b may be spaced apart from each other by a hole H. Further, the hole H may be formed into a plurality of lines disposed in rows or columns.

Meanwhile, the numbers and shapes of the plurality of first sub-patterns 721b and the plurality of second sub-patterns 722b shown in <FIG> may be variously changed as necessary.

If moisture and oxygen infiltrate into the polarization plate <NUM>, moisture absorption may independently occur in some of the plurality of first sub-patterns 721b and the plurality of second sub-patterns 722b disposed on an outermost side. Also, the plurality of first sub-patterns 721b and the plurality of second sub-patterns 722b are disposed in a plurality of rows or a plurality of columns, and, thus, the spread of moisture and oxygen may be further delayed. Here, the plurality of first sub-patterns 721b and the plurality of second sub-patterns 722b may be spaced apart from each other by the hole H formed into a plurality of lines disposed in rows or columns. Thus, the protection layers <NUM> and <NUM> inside the hole H may block infiltration of moisture and oxygen and lengthen a moving path of moisture and oxygen. Therefore, the plurality of first sub-patterns 721b, the plurality of second sub-patterns 722b and the hole H serve as a barrier and thus minimize moisture absorption of the first pattern 710b.

Referring to <FIG>, the polarization layer <NUM> includes a first pattern 710c and a plurality of second patterns 720c. The first pattern 710c corresponds to the active area AA of the display panel <NUM>, and at least one of the plurality of second patterns 720c corresponds to the non-active area NA of the display panel <NUM>. The plurality of second patterns 720c may be formed into a dot shape. At least one of the plurality of second patterns 720c is disposed to surround the first pattern 710c. The plurality of second patterns 720c may be disposed in a plurality of rows or a plurality of columns. The first pattern 710c and at least one of the plurality of second patterns 720c is spaced apart from each other by a hole H. Further, the hole H may be formed into a plurality of lines disposed in rows or columns. The dot shaped second patterns 720c may have a similar form or shape.

Meanwhile, although the plurality of second patterns 720c is illustrated as being identical to each other in the drawing, the plurality of second patterns 720c may be formed in various sizes. Also, the plurality of second patterns 720c may be divided into a plurality of first sub-patterns corresponding to edges of the first pattern 710c and a plurality of second sub-patterns corresponding to a corner of the first pattern 710c. Further, the number and shape of the plurality of second patterns 720c shown in <FIG> may be variously changed as necessary.

If moisture and oxygen infiltrate into the polarization plate <NUM>, moisture absorption may independently occur in some of the plurality of second patterns 720c disposed on an outermost side. Also, the plurality of second patterns 720c is disposed in a plurality of rows or a plurality of columns, and, thus, the spread of moisture and oxygen may be further delayed. Here, the plurality of second patterns 720c may be spaced apart from each other by the one or more holes H formed as plurality of lines disposed in rows or columns. Thus, the protection layers <NUM> and <NUM> inside the one or more holes H may block infiltration of moisture and oxygen and lengthen a moving path of moisture and oxygen. Therefore, the plurality of second patterns 720c and the one or more holes H serve as a barrier and thus minimize moisture absorption of the first pattern 710c.

Referring to <FIG>, the polarization layer <NUM> includes a first pattern 710d and a plurality of second patterns 720d. Each of the plurality of second patterns 720d may also be referred to as a sub-pattern. The first pattern 710d corresponds to the active area AA of the display panel <NUM>, and the plurality of second patterns 720d may correspond to the non-active area NA of the display panel <NUM>. Each of the plurality of second patterns 720d may be disposed to surround the first pattern 710d. Particularly, each of the plurality of second patterns 720d may have a closed loop shape. That is, the plurality of second patterns 720d each formed into a closed loop shape may be sequentially disposed to be away from the first pattern 710d. The first pattern 710d and the plurality of second patterns 720d may be spaced apart from each other by a plurality of holes H. Also, the plurality of holes H between the first pattern 710d the plurality of second patterns 720d may have a closed loop shape. Further, although not illustrated in the drawings, any one of the protection layers <NUM> and <NUM> disposed on the holes H may have a closed loop shape.

Meanwhile, the number and shape of the plurality of second patterns 720d shown in <FIG> may be variously changed as necessary.

If moisture and oxygen infiltrate into the polarization plate <NUM>, moisture absorption may independently occur in the second patterns 720d disposed on an outermost side. Also, due to the placement of the plurality of second patterns 720d, the spread of moisture and oxygen may be further delayed. Here, the plurality of second patterns 720c may be spaced apart from each other by the plurality of holes H. Thus, the protection layers <NUM> and <NUM> inside the holes H may block infiltration of moisture and oxygen and lengthen a moving path of moisture and oxygen. Particularly, the plurality of holes H as well as the plurality of second patterns 720d has a closed loop shape, and, thus, moisture and oxygen may be trapped within the closed loops. Thus, the spread of moisture and oxygen may be more effectively delayed. Therefore, the plurality of second patterns 720d and the plurality of holes H serve as a barrier and thus minimize moisture absorption of the first pattern 710d.

Referring to <FIG>, the polarization layer <NUM> includes a first pattern 710e and second patterns 721e and 722e. The first pattern 710e corresponds to the active area AA of the display panel <NUM>, and the second patterns 721e and 722e may correspond to the non-active area NA of the display panel <NUM>. The second patterns 721e and 722e may include a plurality of first sub-patterns 721e and a plurality of second sub-patterns 722e. The plurality of first sub-patterns 721e may be disposed so as to correspond to edges of the first pattern 710e. The plurality of second sub-patterns 722e may be disposed between the plurality of first sub-patterns 721e so as to correspond to a corner of the first pattern 710e. At least some of outlines of the plurality of first sub-patterns 721e and outlines of the plurality of second sub-patterns 722e may have a zigzag shape. The plurality of first sub-patterns 721e and the plurality of second sub-patterns 722e may be disposed to surround the first pattern 710e. The plurality of first sub-patterns 721e and the plurality of second sub-patterns 722e may be disposed in a plurality of rows or a plurality of columns. The first pattern 710e, the plurality of first sub-patterns 721e and the plurality of second sub-patterns 722e may be spaced apart from each other by a hole H. Also, the hole H may be formed into a plurality of lines each having a zigzag outline and disposed in rows or columns.

Meanwhile, the numbers and shapes of the plurality of first sub-patterns 721e and the plurality of second sub-patterns 722e shown in <FIG> may be variously changed as necessary.

If moisture and oxygen infiltrate into the polarization plate <NUM>, moisture absorption may independently occur in some of the plurality of first sub-patterns 721e and the plurality of second sub-patterns 722e disposed on an outermost side. Also, the plurality of first sub-patterns 721e and the plurality of second sub-patterns 722e are disposed in a plurality of rows or a plurality of columns, and, thus, the spread of moisture and oxygen may be further delayed. Here, the plurality of first sub-patterns 721e and the plurality of second sub-patterns 722e may be spaced apart from each other by the hole H formed into a plurality of lines disposed in rows or columns. Thus, the protection layers <NUM> and <NUM> inside the hole H may block infiltration of moisture and oxygen and lengthen a moving path of moisture and oxygen. Particularly, the hole H as well as the plurality of first sub-patterns 721e and the plurality of second sub-patterns 722e has a zigzag shape, and, thus, the moving path of moisture and oxygen may be further lengthened. Therefore, the plurality of first sub-patterns 721e, the plurality of second sub-patterns 722e and the hole H serve as a barrier and thus minimize moisture absorption of the first pattern 710e.

<FIG> is an enlarged cross-sectional view of a display part of a display device according to another exemplary embodiment of the present disclosure. A display device <NUM> shown in <FIG> has substantially the same configuration as the display device <NUM> shown in <FIG> and <FIG> except the positions of the polarization plate <NUM> and a barrier film <NUM>. Thus, a repeated description will be omitted.

Referring to <FIG>, the polarization plate <NUM> is disposed on the front surface of the display panel <NUM>. Also, the barrier film <NUM> is disposed on the polarization plate <NUM>. That is, the barrier film <NUM> may be disposed on an outermost side of the display panel <NUM>. The barrier film <NUM> may protect the display panel <NUM> against external impacts, moisture, heat, and the like. The barrier film <NUM> may be made of a polymer resin which is light and unbreakable. For example, the barrier film <NUM> may be made of a cyclo olefin polymer (COP), but is not limited thereto. The barrier film <NUM> may also be made of polyimide (PI), polycarbonate (PC), polyethylene terephthalate (PET), and the like.

In the display device <NUM> according to another exemplary embodiment of the present disclosure, the barrier film <NUM> is disposed to cover the polarization plate <NUM> and thus more effectively protect the polarization plate <NUM>. Specifically, the barrier film <NUM> may minimize moisture permeation occurring through a front surface of the polarization plate <NUM>. Thus, it is possible to minimize moisture absorption of the polarization layer <NUM> and suppress warpage of the polarization layer <NUM>. Therefore, it is possible to suppress warpage of the display panel <NUM> and improve reliability of the display device <NUM>.

<FIG> is a plan view of a display part of a display device according to yet another exemplary embodiment of the present disclosure. <FIG> is an enlarged cross-sectional view of the display part of the display device according to still another exemplary embodiment of the present disclosure. A display device <NUM> shown in <FIG> and <FIG> has substantially the same configuration as the display device <NUM> shown in <FIG> except a barrier film <NUM>. Thus, a repeated description will be omitted.

Referring to <FIG> and <FIG>, the barrier film <NUM> may be extended to one surface of the back cover <NUM> while covering side surfaces of the display panel <NUM> and the polarization plate <NUM>. Herein, the one surface of the back cover <NUM> may refer to a surface on which the display panel <NUM> is disposed.

The barrier film <NUM> may be extended to cover a part of the side portions of the display panel <NUM> and the polarization plate <NUM>. Specifically, the barrier film <NUM> may be extended to cover the side portions of the display panel <NUM> and the polarization plate <NUM> from sides other than one side of the display panel <NUM> where the flexible film <NUM> is disposed. That is, the barrier film <NUM> may cover three side portions on the top, left and right sides of four sides of the display panel <NUM> shown in <FIG>. Since the barrier film <NUM> is not disposed in a region where the flexible film <NUM> is disposed, interference between the barrier film <NUM> and the flexible film <NUM> may be minimized. Also, the barrier film <NUM> may be extended to the one surface of the back cover <NUM> from the side portions of the display panel <NUM> and the polarization plate <NUM>, but is not limited thereto. The barrier film <NUM> may be extended to cover only the side portions of the display panel <NUM> and the polarization plate <NUM>.

In the display device <NUM> according to yet another exemplary embodiment of the present disclosure, the barrier film <NUM> covers a part of the side portions of the display panel <NUM> and the polarization plate <NUM>. Thus, the part of the side portions of the display panel <NUM> and the polarization plate <NUM> may be completely surrounded by the barrier film <NUM>, the back cover <NUM>, the micro seal MS and the second adhesive layer AD2. Therefore, the barrier film <NUM> may minimize moisture permeation occurring through the side portions of the display panel <NUM> and the polarization plate <NUM>.

Further, if the barrier film <NUM> disposed at the side portions of the display panel <NUM> and the polarization plate <NUM> is extended to the one surface of the back cover <NUM>, moisture permeation may be more effectively suppressed. That is, the barrier film <NUM> is extended along the one surface of the back cover <NUM>, and, thus, the sealing effect for the display panel <NUM> and the polarization plate <NUM> may be increased. Furthermore, a moisture permeation path may be further increased along a contact surface between the barrier film <NUM> and the back cover <NUM>. Therefore, it is possible to more effectively suppress moisture permeation occurring through the display panel <NUM> and the polarization plate <NUM>.

Also, even if moisture permeation occurs through the side portions of the polarization plate <NUM>, the second pattern 183b spaced apart from the first pattern 183a and surrounding the first pattern 183a may be disposed on an outside of the polarization layer <NUM>. Therefore, moisture absorption may independently occur in the second pattern 183b, and moisture absorption in the first pattern 183a may be delayed and suppressed. Accordingly, it is possible to suppress deformation of the polarization layer <NUM> and also possible to suppress cracks in the substrate <NUM> and warpage of the display panel <NUM>.

<FIG> show moisture absorption test results on polarization layers according to a comparative embodiment and an embodiment, respectively. <FIG> shows a moisture absorption test result on a polarization layer according to the comparative embodiment, and.

<FIG> shows a moisture absorption test result on a polarization layer according to the embodiment. A non-patterned polarization layer was applied to the comparative embodiment, and a polarization layer having a zigzag pattern similar to the pattern shown in <FIG> was applied to the embodiment. Also, moisture absorption progressed from the right side to the left side of the polarization layer. Thus, a part of the polarization layer where moisture is absorbed is transparent, and a normal part of the polarization layer where moisture is not absorbed has a dark color.

Referring to <FIG>, it may be seen that there is a difference between a normal part on the left side and a moisture-absorbed part on the right side due to moisture absorption of the polarization layer. That is, it may be seen that deformation of the polarization layer occurs along a progress direction of moisture absorption. Particularly, it may be seen that the polarization layer is not patterned, and, thus, deformation expands gradually in a middle part between the normal part and the moisture-absorbed part and most of the polarization layer absorbs moisture.

Referring to <FIG>, it may be seen that there is a distinct boundary between a normal pattern on the left side and a moisture-absorbed pattern on the right side. That is, the polarization layer according to the embodiment is patterned, and, thus, the left pattern and the right pattern may be spaced apart from each other. Therefore, even if moisture absorption occurs, moisture absorption occurs independently in the right pattern, and, thus, it is possible to suppress expansion of moisture absorption to the left pattern. Accordingly, moisture absorption over the entire polarization layer may be delayed, and, thus, warpage of the polarization layer may be suppressed.

The exemplary embodiments of the present disclosure can also be described as follows:.

The second pattern is disposed to surround the first pattern.

The second pattern may include a plurality of sub-patterns.

One or more of the plurality of sub-patterns may have a closed loop shape surrounding the first pattern.

The second pattern may include a plurality of first sub-patterns corresponding to edges of the first pattern.

The second pattern may include a plurality of second sub-patterns disposed between the plurality of first sub-patterns so as to correspond to a corner of the first pattern.

The plurality of first sub-patterns may have a line shape, and/or the plurality of second sub-patterns may have a dot shape.

The plurality of first sub-patterns and the plurality of second sub-patterns may have a dot shape.

At least some of outlines of the plurality of first sub-patterns and outlines of the plurality of second sub-patterns may have a zigzag shape.

The display device may further include a back cover on a rear surface of the display panel.

The display device may further include a barrier film on the polarization plate.

The barrier film may be extended to cover at least a part of side portions of the polarization plate and the display panel.

The display device may further include a flexible film on one side of the display panel.

The barrier film may be extended to cover the side portions of the polarization plate and the display panel from sides other than the one side of the display panel where the flexible film is disposed.

The barrier film may be extended to be in contact with one surface of the back cover.

The display device may further include a roller unit configured to wind or unwind the display panel and the back cover.

The display device includes protection layers respectively disposed on both surfaces of the polarization layer.

According to another aspect of the present disclosure, the display device includes a display panel including an active area and a non-active area; a polarization plate on the display panel and including a polarization layer and protection layers respectively disposed on both surfaces of the polarization layer; and a roller unit configured to wind or unwind the display panel. The polarization layer includes a first pattern corresponding to the active area and a second pattern surrounding the first pattern and corresponding to the non-active area.

The first pattern and the second pattern are spaced apart from each other by any one of the protection layers respectively disposed on the both surfaces of the polarization layer.

The second pattern may include a plurality of sub-patterns, and one or more of the plurality of sub-patterns may have a closed loop shape surrounding the first pattern.

The protection layers between the first pattern and the second pattern may have a closed loop shape.

The second pattern may include a plurality of sub-patterns, and some of outlines of the plurality of sub-patterns may have a line shape or a dot shape.

The second pattern may include a plurality of sub-patterns, and at least some of outlines of the plurality of sub-patterns may have a zigzag shape.

The display device may further include a back cover on a rear surface of the display panel; and a barrier film on the polarization plate.

The barrier film may be extended to one surface of the back cover while covering a part of side surfaces of the display panel.

Claim 1:
A display device (<NUM>, <NUM>, <NUM>), comprising:
a display panel (<NUM>) including an active area (AA) and a non-active area (NA); and
a polarization plate (<NUM>) on the display panel (<NUM>), the polarization plate (<NUM>) includes a polarization layer (<NUM>),
wherein the polarization layer (<NUM>) includes a first pattern (183a, 710a, 710b, 710c, 710d 710e) and a second pattern (183b, 720a, 721b+722b, 720c, 720d, 721e+722e),
formed by patterning a layer of material forming the polarization layer (<NUM>);
wherein the first pattern overlaps the active area (AA) and the second pattern (183b) is spaced apart from the first pattern by a hole (H);
wherein:
the second pattern overlaps the non-active area (NA) and is disposed to surround the first pattern;
wherein the display device further includes protection layers (<NUM>, <NUM>) including a first and a second protection layer (<NUM>, <NUM>) respectively disposed on both surfaces of the polarization layer (<NUM>), and
wherein the hole between the first and second pattern is filled by the first protection layer (<NUM>) or the second protection layer (<NUM>).