KR102644261B1 - Display device - Google Patents

Abstract

A display device is disclosed. According to one embodiment of the present invention, a transparent plate; a first display panel located on one side of the transparent plate; a second display panel located on the other side of the transparent plate; a first transparent frame located on one side of the transparent plate and adjacent to a side of the first display panel; a second transparent frame located on the other side of the transparent plate and adjacent to a side of the second display panel; a first receiving portion located between the transparent plate and the first display panel; a third receiving portion located between the transparent plate and the second display panel; a slot formed in the transparent plate, the first transparent frame, or the second transparent frame; a first member layer connected to one side of the first display panel; a second member layer connected to one side of the second display panel; a first PCB connected to the first member layer and located in the first receiving portion; a second PCB connected to the second member layer and located in the third receiving portion; a first cable extending from the first PCB and inserted into the slot; Additionally, a display device including a second cable extending from the second PCB and inserted into the slot can be provided.

Description

Display device {DISPLAY DEVICE}

The present invention relates to a display device having a slim appearance and rigidity at the same time.

As the information society develops, the demand for display devices in various forms is increasing, and in response to this, in recent years, LCD (Liquid Crystal Display Device), PDP (Plasma Display Panel), ELD (Electro luminescent display), and VFD (Vacuum Fluorescent) have been developed. Various display devices such as OLED (Organic Light Emitting Diode) and OLED (Organic Light Emitting Diode) are being researched and used.

Among them, OLED panels can display images by depositing an organic material layer that can emit light on its own on a substrate with transparent electrodes. OLED panels are not only thin, but can also have flexible characteristics. Much research is being conducted on the structural characteristics of display devices equipped with such OLED panels.

The present invention aims to solve the above-mentioned problems and other problems. Another purpose may be to make the thickness of the display device slim.

Another goal may be to provide a display device with a transparent bezel.

Another purpose may be to provide a display device using glass as a skeleton.

According to one aspect of the present invention to achieve the above or other objects, a transparent plate; a first display panel located on one side of the transparent plate; a second display panel located on the other side of the transparent plate; a first transparent frame located on one side of the transparent plate and adjacent to a side of the first display panel; a second transparent frame located on the other side of the transparent plate and adjacent to a side of the second display panel; a first receiving portion located between the transparent plate and the first display panel; a third receiving portion located between the transparent plate and the second display panel; a slot formed in the transparent plate, the first transparent frame, or the second transparent frame; a first member layer connected to one side of the first display panel; a second member layer connected to one side of the second display panel; a first PCB connected to the first member layer and located in the first receiving portion; a second PCB connected to the second member layer and located in the third receiving portion; a first cable extending from the first PCB and inserted into the slot; Additionally, a display device is provided including a second cable extending from the second PCB and inserted into the slot.

According to another aspect of the present invention, the first accommodating portion is adjacent to one side of the first display panel and is formed along the longitudinal direction of one side of the first display panel, and the third accommodating portion is provided with the It is adjacent to one side of the second display panel and is formed along the longitudinal direction of one side of the second display panel, and the first accommodating portion may face the third accommodating portion.

According to another aspect of the present invention, the slot may be adjacent to other sides of the first and second display panels that meet one side of the first and second display panels.

According to another aspect of the present invention, the slot may be connected to an outer surface of the transparent plate, the first transparent frame, or the second transparent frame.

According to another aspect of the present invention, the slot includes: a first slot formed on one surface of the transparent plate or the first transparent frame; And, it further includes a second slot formed on the other side of the transparent plate or the second transparent frame, wherein the first cable can be inserted into the first slot, and the second cable can be inserted into the second slot. there is.

According to another aspect of the present invention, the first slot and the second slot may be integrated into one and connected to the outer surface of the transparent plate, the first transparent frame, or the second transparent frame.

According to another aspect of the present invention, the second accommodating part is located between the first accommodating part and the third accommodating part and may further include a second accommodating part formed through the transparent plate.

According to another aspect of the present invention, the first cable may face each other through the second cable and the second receiving portion.

According to another aspect of the present invention, the first cable and the second cable may each be bent or folded in the second receiving portion.

According to another aspect of the present invention, the first cable includes a first plurality of cables, the second cable includes a second plurality of cables, and the first and second plurality of cables each The cables overlap while being bent or folded, and overlapping portions of the first and second plurality of cables may be located in the second receiving portion.

According to another aspect of the present invention, the transparent plate and the first and second transparent frames may be formed integrally.

According to another aspect of the present invention, a boundary line may be formed between the transparent plate and the first transparent frame, and between the transparent plate and the second transparent frame.

According to another aspect of the present invention, a first touch panel located on an outer surface of the first display; In addition, it may further include a second touch panel located on the outer surface of the second display.

According to another aspect of the present invention, a first touch panel cable connected to the first touch panel; And it further includes a second touch panel cable connected to the second touch panel, and the first and second touch panel cables can be inserted into the slot.

According to another aspect of the present invention, the first touch panel cable is inserted into the slot through a gap between a side of the first display panel and the first transparent frame, and the second touch panel cable is inserted into the slot. 2 It can be inserted into the slot through a space between the side of the display panel and the second transparent frame.

According to at least one embodiment of the present invention, a slim display device can be provided.

According to at least one embodiment of the present invention, a display device having a transparent bezel can be provided.

According to at least one embodiment of the present invention, a display device using glass as a skeleton can be provided.

Further scope of applicability of the present invention will become apparent from the detailed description that follows. However, since various changes and modifications within the spirit and scope of the present invention may be clearly understood by those skilled in the art, the detailed description and specific embodiments such as preferred embodiments of the present invention should be understood as being given only as examples.

1 and 2 are diagrams showing examples of display devices according to an embodiment of the present invention.
3 and 4 are diagrams showing examples of the configuration of a display device according to an embodiment of the present invention.
5 and 6 are diagrams illustrating an example of a process for forming a transparent body of a display device according to an embodiment of the present invention.
7 and 8 are diagrams illustrating another example of a process for forming a transparent body of a display device according to an embodiment of the present invention.
9 to 31 are diagrams showing examples of transparent bodies according to an embodiment of the present invention.
32 to 35 are diagrams showing examples of display panels according to an embodiment of the present invention.
36 to 41 are diagrams showing examples of combination relationships between components of a display device according to an embodiment of the present invention.
Figures 42 to 48 are diagrams showing several examples of cross sections of a display device according to an embodiment of the present invention.
Figures 49 and 50 are diagrams showing examples of display devices according to an embodiment of the present invention.
51 and 52 are diagrams showing examples of the configuration of a display device according to an embodiment of the present invention.
53 and 54 are diagrams illustrating an example of a process for forming a transparent body of a display device according to an embodiment of the present invention.
Figures 55 and 56 are diagrams showing another example of a process for forming a transparent body of a display device according to an embodiment of the present invention.
Figures 57 to 70 are diagrams showing examples of transparent bodies according to an embodiment of the present invention.
71 to 74 are diagrams showing examples of display panels according to an embodiment of the present invention.
Figures 75 to 77 are diagrams showing examples of combination relationships between components of a display device according to an embodiment of the present invention.
Figures 78 to 81 are diagrams showing several examples of cross sections of a display device according to an embodiment of the present invention.

Hereinafter, embodiments disclosed in the present specification will be described in detail with reference to the attached drawings. However, identical or similar components will be assigned the same reference numbers regardless of reference numerals, and duplicate descriptions thereof will be omitted.

The suffixes “module” and “part” for components used in the following description are given or used interchangeably only for the ease of preparing the specification, and do not have distinct meanings or roles in themselves. Additionally, in describing the embodiments disclosed in this specification, if it is determined that detailed descriptions of related known technologies may obscure the gist of the embodiments disclosed in this specification, the detailed descriptions will be omitted. In addition, the attached drawings are only for easy understanding of the embodiments disclosed in this specification, and the technical idea disclosed in this specification is not limited by the attached drawings, and all changes included in the spirit and technical scope of the present invention are not limited. , should be understood to include equivalents or substitutes.

Terms containing ordinal numbers, such as first, second, etc., may be used to describe various components, but the components are not limited by the terms. The above terms are used only for the purpose of distinguishing one component from another.

When a component is said to be "connected" or "connected" to another component, it is understood that it may be directly connected to or connected to the other component, but that other components may exist in between. It should be. On the other hand, when it is mentioned that a component is “directly connected” or “directly connected” to another component, it should be understood that there are no other components in between.

Singular expressions include plural expressions unless the context clearly dictates otherwise.

In this application, terms such as “comprise” or “have” are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, steps, operations, components, parts, or combinations thereof.

Below, the display panel will be described using an organic light emitting diode (OLED) panel as an example, but the display panel applicable to the present invention is not limited to the OLED panel, and is not limited to the plasma display panel (Plasma Display Panel). , PDP), a field emission display (FED), or a liquid crystal display (LCD).

In addition, hereinafter, the display device includes a first long side (LS1), a second long side (LS2) opposing the first long side (LS1), a first long side (LS1), and a second long side (LS2). ) may include a first short side (SS1) adjacent to one end and a second short side (SS2) opposing the first short side (SS1).

Here, the first short side area (SS1) is called the first side area, the second short side area (SS2) is called the second side area opposite the first side area, and the second side area (SS2) is called the second side area opposite the first side area. 1 The long side area LS1 is called the third side area adjacent to the first and second side areas and located between the first and second side areas, and the second long side area ( It is possible to refer to LS2) as the fourth side area, which is adjacent to the first and second side areas, is located between the first and second side areas, and is opposed to the third side area. .

In addition, for convenience of explanation, the length of the first and second long sides (LS1, LS2) is shown and explained as being longer than the length of the first and second short sides (SS1, SS2), but the length of the first and second long sides (LS1, SS2) It may be possible that the length of LS2) is approximately the same as the length of the first and second short sides (SS1 and SS2).

In addition, hereinafter, the first direction (First Direction, DR1) is a direction parallel to the short side (SS1, SS2) of the display device, and the second direction (Second Direction, DR2) is a direction parallel to the long side (LS1) of the display device. , LS2) may be in a parallel direction.

The third direction (DR3) may be a direction perpendicular to the first direction (DR1) and/or the second direction (DR2).

The first direction (DR1) and the second direction (DR2) can be collectively referred to as the horizontal direction. In addition, the third direction (DR3) can be referred to as the vertical direction.

From another perspective, the side on which the display device displays the image may be referred to as the front or front side. When a display device displays an image, the side from which the image cannot be observed can be referred to as the rear or back side. When looking at the display from the front or the front, the second short side (SS2) can be referred to as the upper side or top surface. Likewise, the first short side (SS1) may be referred to as the lower side or lower surface. Likewise, the first long side (LS1) can be called the left or left side, and the second long side (LS2) can be called the right or right side.

For another example, when a display device displays images in two directions, one direction may be forward or front. At this time, when the image is displayed in another direction, the other direction may be rear or rear.

In addition, the first long side (LS1), the second long side (LS2), the first short side (SS1), and the second short side (SS2) may be referred to as edges of the display device. Additionally, the point where the first long side (LS1), the second long side (LS2), the first short side (SS1), and the second short side (SS2) meet each other may be called a corner. For example, the point where the first long side (LS1) and the first short side (SS1) meet is the first corner (C1), and the point where the first long side (LS1) and the second short side (SS2) meet is the second corner (C2) ), the point where the second short side (SS2) and the second long side (LS2) meet is the third corner (C3), and the point where the second long side (LS2) and the first short side (SS1) meet is the fourth corner (C4) It can be.

Here, the direction from the first short side SS1 to the second short side SS2 or from the second short side SS2 to the first short side SS1 may be referred to as the up-down direction UD. The direction from the first long side LS1 to the second long side LS2 or from the second long side LS2 to the first long side LS1 may be referred to as the left-right direction LR.

1 and 2 are diagrams showing examples of display devices according to an embodiment of the present invention.

The display panel 110 may be observed in front of the display device 100. The display panel 110 may provide an image toward the front of the display device 100. A transparent body 120 may be located behind the display panel 110.

The transparent body 120 can accommodate the display panel 110 at the rear. The transparent body 120 may face the side of the display panel 110. The transparent body 120 can fix the display panel 110. The transparent body 120 may be connected to or fixed to the outside. For example, the transparent body 120 may be suspended or mounted on the ceiling. For example, the transparent body 120 may be connected to or fixed to the top of an external structure. For example, the transparent body 120 may be connected to or fixed to the side of an external structure. For example, the transparent body 120 may be located between external structures.

The portion of the transparent body 120 that faces the side of the display panel 110 and the portion that faces the rear of the display panel 110 may be formed integrally, for example, as shown in FIG. 1 . A portion of the transparent body 120 facing the side of the display panel 110 and a portion facing the back of the display panel 110 may be distinguished, for example, as shown in FIG. 2 .

The transparent frame 127 may face the side of the display panel 110, as shown in FIG. 2. A portion of the transparent plate 128 may be coupled to the transparent frame 127. Another part of the transparent plate 128 may face the rear of the display panel 110. A boundary line LB may be formed between the transparent frame 127 and the transparent plate 128.

3 and 4 are diagrams showing examples of the configuration of a display device according to an embodiment of the present invention.

Referring to FIG. 3, one side of the display panel 110 can be observed from the front of the display device 100. One side of the display panel 110 can display an image. The display panel 110 can be divided into an active area (AA) that displays images, and an inactive area (IA) that does not display images.

The display panel 110 may be located on the front of the transparent body 120. The side of the display panel 110 may be surrounded by the transparent body 120. The display panel 110 may be coupled to the transparent body 120. The display panel 110 may be attached to or detached from the transparent body 120 . The display panel 110 may be flexible. The display panel 110 may receive certain rigidity from the transparent body 120.

The transparent body 120 may be divided into a transparent flange 126 facing the side of the display panel 110, and a transparent board 129 facing the rear of the display panel 110. The transparent flange 126 and the transparent board 129 may be formed integrally.

The transparent board 129 may face the rear of the display panel 110. The transparent board 129 may correspond to the shape of the display panel 110. For example, the first long side 129LS1, the second long side 129LS2, the first short side 129SS1, and the second short side 129SS2 of the transparent board 129 are the first long side 110LS1 of the display panel 110. ), the second long side (110LS2), the first short side (110SS1), and the second short side (110SS2).

The side of the transparent board 129 may be surrounded by the transparent flange 126. For example, the first long side (129LS1), the second long side (129LS2), the first short side (129SS1), and the second short side (129SS2) of the transparent board 129 may be located inside the transparent body 120. there is.

The transparent flange 126 may be shaped to surround the display panel 110. The transparent flange 126 may form sides corresponding to each side of the transparent board 129. For example, the first long side 126LS1, the second long side 126LS2, the first short side 126SS1, and the second short side 126SS2 of the transparent flange 126 are the first long side 129LS1 of the transparent board 129. ), the second long side (129LS2), the first short side (129SS1), and the second short side (129SS2) may be formed adjacent to or parallel to each other.

The transparent body 120 may form a side wall (SW). The side wall (SW) may be located on the first long side (126LS1), the second long side (126LS2), the first short side (126SS1), and the second short side (126SS2) of the transparent flange 126.

The length of the first long side 110LS1 of the display panel 110 may be slightly shorter than the length of the first long side 129LS1 of the transparent board 129. The length of the first short side 110SS1 of the display panel 110 may be slightly shorter than the length of the first short side 129SS1 of the transparent board 129. The display panel 110 may be fixed to the transparent board 129. The display panel 110 may be coupled to the transparent board 129 by magnetic force. The display panel 110 may be fitted into the transparent flange 126.

Referring to FIG. 4 , the transparent frame 127 may be shaped to surround the display panel 110 . The inside of the transparent frame 127 may form a space to accommodate the display panel 110.

The inside of the transparent frame 127 may have a shape corresponding to the shape of the display panel 110. For example, the first long side 127LS1, the second long side 127LS2, the first short side 127SS1, and the second short side 127SS2 inside the transparent frame 127 are the first long side (127LS2) of the display panel 110. 110LS1), the second long side (110LS2), the first short side (110SS1), and the second short side (110SS2).

The transparent plate 128 may be located on the rear side of the display panel 110. The transparent plate 128 may be located on the rear side of the transparent frame 127. The transparent plate 128 may be coupled to the transparent frame 127.

A side formed on the outside of the transparent plate 128 may be formed to correspond to a side formed on the inside of the transparent frame 127. For example, the first long side 128LS1, the second long side 128LS2, the first short side 128SS1, and the second short side 128SS2 of the transparent plate 128 are the first long side inside the transparent frame 127 ( It may be formed adjacent to 127LS1), the second long side 127LS2, the first short side 127SS1, and the second short side 127SS2, respectively.

The transparent body 120 may form a side wall (SW). The side wall SW may be located on the first long side 128LS1, the second long side 128LS2, the first short side 128SS1, and the second short side 128SS2 of the transparent plate 128.

The length of the first long side 110LS1 of the display panel 110 may be slightly shorter than the length of the first long side 127LS1 inside the transparent frame 127. The length of the first short side 110SS1 of the display panel 110 may be slightly shorter than the length of the first short side 127SS1 inside the transparent frame 127. The display panel 110 may be fixed to the transparent plate 128. The display panel 110 may be coupled to the transparent plate 128 by magnetic force. The display panel 110 may be fitted into the transparent frame 127.

5 and 6 are diagrams illustrating an example of a process for forming a transparent body of a display device according to an embodiment of the present invention.

Referring to FIG. 5, a flat transparent body 120 in the shape of a slab may be provided. The transparent body 120 may be made of a transparent material. For example, the transparent body 120 may include glass. For example, the transparent body 120 may contain silicon dioxide. For example, the transparent body 120 may include plastic.

The transparent body 120 may be made of a translucent material. For example, the transparent body 120 may include translucent glass. Alternatively, the transparent body 120 may include a transparent material and a translucent material. The transparent body 120 may be made of, for example, a transparent material containing an opaque/translucent material. For example, the transparent body 120 may form both a transparent area and a translucent area.

The transparent body 120 may, for example, pass, diffract, refract, or reflect at least a portion of the incident light. Transparent bodyTransparent bodyTransparent bodyTransparent bodyTransparent body

A mask (MSK) may be placed on the slab-shaped transparent body 120. The mask MSK may have a height and be located on one side of the transparent body 120 . The mask MSK may be positioned on the transparent body 120 along the edge of one side of the transparent body 120. The mask MSK may be placed on the transparent body 120 to form a partially open space.

The etching solution (ESL) may be contained in the space formed by the mask (MSK) and the transparent body 120. The etching solution (ESL) may chemically etch a region of the transparent body 120 exposed to the etching solution (ESL). The etching solution (ESL) may contain, for example, hydrofluoric acid. The mask MSK may have resistance to the etching solution ESL and thus protect the transparent body 120 from the etching solution ESL.

Although not shown in the drawing, the transparent body 120 may be etched, for example, by plasma etching. When plasma is applied to one side of the transparent body 120 with a mask (MSK) mounted on the transparent body 120, the area of the transparent body 120 exposed to the plasma is etched. It can be. The mask MSK may have resistance to plasma and thus protect the transparent body 120 from plasma. Plasma may be, for example, atmospheric plasma.

After etching is performed, the mask MSK may be separated from the transparent body 120. The slab-shaped transparent body 120 may have a shape in which steps are formed after etching. The area facing the mask MSK may be a transparent flange 126. The area that has undergone an etching process by being exposed to an etching solution (ESL) may become a transparent board 129. Due to etching, the thickness of the transparent flange 126 may be greater than the thickness of the transparent board 129.

Referring to FIG. 6, a cross section of a slab-shaped flat transparent body 120 may appear. The thickness of the slab-shaped transparent body 120 may be T1. A portion of one surface of the slab-shaped transparent body 120 may be exposed to an etching solution, etc.

Among the areas of the transparent body 120, the area exposed to the etching solution may be a transparent board 129 having a thickness T2. Among the areas of the transparent body 120, the area protected from etching may be the transparent flange 126 having a thickness T1. Thickness T2 may be smaller than thickness T1.

The step formed between the transparent flange 126 and the transparent board 129 may have a thickness T3. Thickness T3 may correspond to the thickness of the display panel. For example, the thickness T3 may be slightly larger than the thickness of the display panel.

7 and 8 are diagrams illustrating another example of a process for forming a transparent body of a display device according to an embodiment of the present invention.

Referring to FIG. 7, a flat transparent plate 128 in the shape of a slab may be provided. The transparent plate 128 may be made of a transparent material. For example, the transparent plate 128 may allow at least a portion of the incident light to pass through. For example, the transparent plate 128 may have a color. For example, the transparent plate 128 may contain at least one of glass, plastic, crystal, and quartz. The transparent plate 128 may be made of a translucent material. For example, the transparent plate 128 may have a rough outer surface, causing light to be diffusely reflected.

The transparent plate 128 may include fibers to reinforce rigidity. For example, the transparent plate 128 may include at least one of glass fiber, carbon fiber, metal wire, and metal fiber. The transparent plate 128 may include micro fibers.

A transparent frame 127 may be attached to one side of the transparent plate 128. The transparent frame 127 may be made of a transparent material. The transparent frame 127 may be made of the same material as the transparent plate 128.

For example, the transparent frame 127 may be made of a different material from the transparent plate 128. For example, the transparent frame 127 may have a different color, transparency, reflectivity, or refractive index than the transparent plate 128. For example, the transparent frame 127 may have a different rigidity than the transparent plate 128. For example, the transparent frame 127 may have an outline that is different from the transparent plate 128.

The transparent frame 127 may be coupled to the transparent plate 128 to form a boundary line LB. The boundary line LB may be formed along the outer side of the transparent body 120. The boundary line LB may mean the boundary between the transparent plate 128 and the transparent frame 127.

Referring to FIG. 8, a cross section of a flat transparent plate 128 in the shape of a slab can be seen. The thickness of the slab-shaped transparent plate 128 may be T2. A transparent frame 127 may be attached to one side of the transparent plate 128. For example, the transparent frame 127 may be coupled to the transparent plate 128 with an adhesive. For example, the transparent frame 127 may be coupled to the transparent plate 128 by heat. For example, the transparent frame 127 may be coupled to the transparent plate 128 by pressure. For example, the transparent frame 127 may be coupled to the transparent plate 128 using frit glass or frit glaze.

The transparent frame 127 may have a thickness T3. The transparent frame 127 may be surface treated to facilitate attachment to the transparent plate 128. Alternatively, at least a portion of one surface of the transparent plate 128 may be surface treated to facilitate attachment to the transparent frame 127.

When the transparent frame 127 is combined with the transparent plate 128, a step may be formed on one side of the transparent body 120. The step formed on one side of the transparent body 120 may have a thickness T3. Thickness T3 may correspond to the thickness of the display panel. For example, the thickness T3 may be slightly larger than the thickness of the display panel. The transparent body 120 may have a thickness T1 at one point. Thickness T1 may be the thickest among the thicknesses at various points of the transparent body 120.

9 to 31 are diagrams showing examples of transparent bodies according to an embodiment of the present invention. Hereinafter, the 'PCB accommodating part' may be referred to as a 'first accommodating part'. Hereinafter, the 'cable accommodating part' may be referred to as a 'second accommodating part'.

Referring to FIG. 9, the PCB receiving portion 122 may be formed on one side of the transparent body 120. For example, the PCB receiving portion 122 may be formed on one side of the transparent board 129. The PCB receiving portion 122 can be observed from the front of the transparent body 120. The PCB receiving portion 122 may be formed along a direction from the first short side 129SS1 to the second short side 129SS2 of the transparent board 129. The PCB receiving portion 122 may be formed adjacent to one of the first long side 129LS1 and the second long side 129LS2 of the transparent board 129. For example, the PCB receiving portion 122 may be formed adjacent to the first long side 129LS1 of the transparent board 129.

The PCB receiving portion 122 may be formed by physical action. For example, the PCB receiving portion 122 may be formed by cutting using a mechanism having a rigidity greater than that of the transparent board 129. The PCB receiving portion 122 may be formed by chemical action. For example, the PCB receiving portion 122 may be formed by reacting with chemicals that act on the transparent board 129.

The PCB accommodating portion 122 may accommodate at least a portion of the PCB connected to the display panel. The PCB receiving portion 122 may be formed to correspond to the shape of the PCB connected to the display panel. The PCB receiving portion 122 may have the shape of a groove.

Referring to a cross section cut along A-A' parallel to the longitudinal direction of the PCB receiving portion 122, the transparent flange 126 may have a thickness T1. The transparent board 129 may have a thickness T2. T2 may be smaller than T1. Thickness T1 may be the thickness of the outer side of the transparent body 120.

In the area where the PCB receiving portion 122 is formed, the transparent board 129 may have a thickness T4. The transparent board 129 may be divided into an area where the PCB receiving portion 122 is formed and another area. The area where the PCB receiving portion 122 is formed may have a thinner thickness than other areas. T4 may be smaller than T2.

Referring to FIG. 10, the PCB receiving portion 122 may be formed on one side of the transparent body 120. The PCB receiving portion 122 can be observed from the front of the transparent body 120. The PCB receiving portion 122 may be formed on one side of the transparent plate 128. The PCB receiving portion 122 may be formed adjacent to one of the first long side 127LS1 and the second long side 127LS2 inside the transparent frame 127. For example, the PCB receiving portion 122 may be formed adjacent to the first long side 127LS1 inside the transparent frame 127. The PCB receiving portion 122 may be formed along a direction from the first short side 127SS1 inside the transparent frame 127 toward the second short side 127SS2.

The PCB receiving portion 122 may be located inside an area defined by edges formed inside the transparent frame 127. For example, the PCB receiving portion 122 is partitioned by a first long side (127LS1), a first short side (127SS1), a second long side (127LS2), and a second short side (127SS2) inside the transparent frame 127. It can be formed inside the area.

The PCB receiving portion 122 may be formed by physical action. For example, the PCB receiving portion 122 may be formed by cutting using a mechanism having a rigidity greater than that of the transparent plate 128. The PCB receiving portion 122 may be formed by chemical action. For example, the PCB receiving portion 122 may be formed by reacting with chemicals that act on the transparent plate 128.

The PCB receiving portion 122 may face forward. The PCB accommodating portion 122 may accommodate at least a portion of the PCB connected to the display panel. The PCB receiving portion 122 may have the shape of a groove.

Referring to a cross section cut along A-A' parallel to the longitudinal direction of the PCB receiving portion 122, the thickness of the transparent plate 128 at one point in the area where the PCB receiving portion 122 is formed may be T4. The thickness of the transparent plate 128 at points other than the PCB receiving portion 122 may be T2. The outer side of the transparent body 120 may have a thickness T1.

Referring to FIG. 11, a grinder (GRD) may form a groove on one side of the transparent body 120. For example, the PCB receiving portion 122 may be formed using a grinder (GRD). Although not shown in the drawing, the grinder (GRD) may form a hole on one side of the transparent body 120.

The grinder (GRD) may include a blade (BLD). The rigidity of the blade (BLD) may be greater than the rigidity of the transparent body 120. The blade (BLD) can rotate. The blade (BLD) can be connected to the motor (MTR) to receive rotational force. The blade (BLD) can form a groove by applying rotational force to one side of the transparent board 129.

Referring to the cross section cut along A-A' parallel to the longitudinal direction of the PCB receiving portion 122, the blade BLD can reduce the thickness of the transparent board 129. The thickness of the transparent board 129 in the area where the blade BLD is not applied may be T2. The thickness of the transparent board 129 in the area where the blade BLD is applied may be T4. T4 may be smaller than T2.

Referring to FIG. 12, a grinder (GRD) may form a groove on one side of the transparent body 120. For example, a grinder (GRD) may form the PCB receiving portion 122 on one side of the transparent plate 128. Although not shown in the drawing, the grinder (GRD) may form a hole on one side of the transparent body 120.

The grinder (GRD) may include a blade (BLD). The rigidity of the blade BLD may be greater than the rigidity of the transparent plate 128. The blade (BLD) can receive rotational force from the motor (MTR) and transmit it to the transparent plate 128.

Referring to the cross section cut along A-A' parallel to the longitudinal direction of the PCB receiving portion 122, the blade BLD can reduce the thickness of the transparent plate 128. The thickness of the transparent plate 128 at one point of the area where rotational force is provided by the blade (BLD) is cut may be T4. The thickness of the transparent plate 128 at one point in the area where the blade BLD is not applied may be T2. T4 may be smaller than T2.

Referring to FIG. 13, the PCB receiving portion 122 can be observed from the front of the transparent body 120. Alternatively, the PCB receiving portion 122 may be observed from the front of the transparent board 129. The PCB receiving portion 122 may be a hole formed on one side of the transparent board 129.

The PCB receiving portion 122 may be formed adjacent to the first long side 129LS1 of the transparent board 129. The PCB receiving portion 122 may be formed along a direction from the first short side 129SS1 to the second short side 129SS2 of the transparent board 129. The PCB receiving portion 122 may be formed through physical processing. For example, the PCB receiving portion 122 may be formed using a grinder. The PCB receiving portion 122 may be formed through chemical processing. For example, the PCB receiving portion 122 may be formed by applying an etching solution to the transparent board 129.

Referring to the cross section cut along A-A' parallel to the longitudinal direction of the PCB receiving portion 122, the area where the PCB receiving portion 122 is formed may be a passage communicating the front and rear of the transparent board 129. .

Referring to FIG. 14, the PCB receiving portion 122 can be observed from the front of the transparent plate 122. The PCB receiving portion 122 may be a hole formed on one side of the transparent plate 128.

The PCB receiving portion 122 may be formed adjacent to the first long side 127LS1 inside the transparent frame 127. The PCB receiving portion 122 may be formed along a direction from the first short side 127SS1 inside the transparent frame 127 toward the second short side 127SS2. The PCB receiving portion 122 may be formed through physical processing. For example, the PCB receiving portion 122 may be formed through NC processing. The PCB receiving portion 122 may be formed through chemical processing. For example, the PCB receiving portion 122 may be formed by applying an etching solution or plasma to the transparent plate 128.

Referring to the cross section cut along A-A' parallel to the longitudinal direction of the PCB receiving portion 122 and passing through the PCB receiving portion 122, the area where the PCB receiving portion 122 is formed is the front of the transparent plate 128. It can communicate with the rear.

Referring to FIG. 15, the PCB receiving portions 122 and 123 can be observed from the front of the transparent board 129. The PCB receiving portion 122 may be in the shape of a groove formed in the transparent board 129. A plurality of PCB receiving portions 122 and 123 may be provided. For example, the PCB accommodating parts 122 and 123 may include a first PCB accommodating part 122 and a second PCB accommodating part 123.

The first PCB accommodating part 122 and the second PCB accommodating part 123 may be arranged in series. The first PCB accommodating portion 122 may be arranged in a long line with the second PCB accommodating portion 123. The first PCB accommodating part 122 and the second PCB accommodating part 123 may be formed adjacent to the first long side 129LS1 of the transparent board 129. The first PCB accommodating portion 122 and the second PCB accommodating portion 123 may be sequentially arranged along a direction from the first short side 129SS1 to the second short side 129SS2 of the transparent board 129.

Referring to a cross section cut along A-A' passing through the PCB receiving portions 122 and 123 in the longitudinal direction of the PCB receiving portions 122 and 123, at one point of the area where the PCB receiving portions 122 and 123 are formed. The transparent board 129 may have a thickness T4. The thickness of the transparent board 129 at a point in the area where the first PCB accommodating part 122 is formed is the same as or different from the thickness of the transparent board 129 at a point in the area where the second PCB accommodating part 123 is formed. You can.

The PCB receiving portions 122 and 123 may be formed on one side of the transparent board 129 by physical or/and chemical methods. For example, the PCB receiving portions 122 and 123 may be formed by a laser.

Referring to FIG. 16, the PCB receiving portions 122 and 123 can be observed from the front of the transparent plate 128. The PCB receiving portions 122 and 123 may have the shape of a groove formed in the transparent plate 128. A plurality of PCB receiving portions 122 and 123 may be provided. For example, the PCB accommodating parts 122 and 123 may include a first PCB accommodating part 122 and a second PCB accommodating part 123.

The first PCB accommodating part 122 and the second PCB accommodating part 123 may be arranged side by side. The longitudinal direction of the first PCB accommodating part 122 and the longitudinal direction of the second PCB accommodating part 123 may be parallel. The first PCB accommodating part 122 and the second PCB accommodating part 123 may be formed adjacent to the first long side 127LS1 inside the transparent frame 127. The first PCB accommodating part 122 and the second PCB accommodating part 123 may be arranged in parallel with a direction from the first short side 127SS1 inside the transparent frame 127 to the second short side 127SS2.

Referring to the cross section cut along A-A' parallel to the longitudinal direction of the PCB receiving portions (122, 123) and passing through the PCB receiving portions (122, 123), one of the areas where the PCB receiving portions (122, 123) are formed At point transparent plate 128 may have a thickness T4. The thickness of the transparent plate 128 at a point in the area where the first PCB accommodating part 122 is formed is the same as or different from the thickness of the transparent plate 128 at a point in the area where the second PCB accommodating part 123 is formed. You can.

The PCB receiving portions 122 and 123 may be formed on one side of the transparent plate 128 by physical or/and chemical methods. For example, the PCB receiving portions 122 and 123 may be formed by a laser.

Referring to FIG. 17, the PCB receiving portions 122 and 123 can be observed from the front of the transparent board 129. The PCB receiving portion 122 may be in the shape of a hole formed in the transparent board 129. A plurality of PCB receiving portions 122 and 123 may be provided. For example, the PCB accommodating parts 122 and 123 may include a first PCB accommodating part 122 and a second PCB accommodating part 123.

The first PCB accommodating part 122 and the second PCB accommodating part 123 may be arranged side by side. The longitudinal direction of the first PCB accommodating part 122 and the longitudinal direction of the second PCB accommodating part 123 may be parallel. The first PCB accommodating part 122 and the second PCB accommodating part 123 may be formed adjacent to the first long side 129LS1 of the transparent board 129. The first PCB accommodating part 122 and the second PCB accommodating part 123 may be arranged parallel to the direction from the first short side 129SS1 to the second short side 129SS2 of the transparent board 129.

Referring to the cross section cut along A-A' parallel to the longitudinal direction of the PCB receiving portions 122 and 123 and passing through the PCB receiving portions 122 and 123, the area where the PCB receiving portions 122 and 123 are formed is a transparent board. (129) can communicate the front and rear of the transparent board (129).

The PCB receiving portions 122 and 123 may be formed on one side of the transparent board 129 by an optical method. For example, the PCB receiving portions 122 and 123 may be formed using a carbon dioxide laser.

Referring to FIG. 18, the PCB receiving portions 122 and 123 can be observed from the front of the transparent plate 128. The PCB receiving portions 122 and 123 may be in the shape of holes formed in the transparent plate 128. A plurality of PCB receiving portions 122 and 123 may be provided. For example, the PCB accommodating parts 122 and 123 may include a first PCB accommodating part 122 and a second PCB accommodating part 123.

The first PCB accommodating part 122 and the second PCB accommodating part 123 may be arranged side by side. The longitudinal direction of the first PCB accommodating part 122 and the longitudinal direction of the second PCB accommodating part 123 may be parallel. The first PCB accommodating part 122 and the second PCB accommodating part 123 may be formed adjacent to the first long side 127LS1 inside the transparent frame 127. The first PCB accommodating part 122 and the second PCB accommodating part 123 may be arranged in parallel with a direction from the first short side 127SS1 inside the transparent frame 127 to the second short side 127SS2.

Referring to the cross section cut along A-A' parallel to the longitudinal direction of the PCB receiving portions (122, 123) and passing through the PCB receiving portions (122, 123), one of the areas where the PCB receiving portions (122, 123) are formed At this point, the transparent plate 128 may communicate with the front and rear sides of the transparent plate 128 .

The PCB receiving portions 122 and 123 may be formed on one side of the transparent plate 128 by an optical method. For example, the PCB receiving portions 122 and 123 may be formed using a carbon dioxide laser.

Referring to FIG. 19, the cable receiving portion 124 can be observed from the front of the transparent board 129. The cable receiving portion 124 may be in the shape of a groove formed on one side of the transparent board 129. The cable accommodating portion 124 may accommodate at least a portion of the cable connected to the PCB. The cable receiving portion 124 may be located at the center of the transparent board 129. The cable receiving portion 124 may be spaced apart from the PCB receiving portions 122 and 123.

The PCB accommodating portions 122 and 123 may be located between the cable accommodating portion 124 and one side of the transparent board 129. For example, the PCB accommodating portions 122 and 123 may be located between the cable accommodating portion 124 and the first long side 129LS1 of the transparent board 129.

Referring to a cross section cut along B-B' passing through the cable receiving portion 124, the transparent board 129 may have a thickness T5 at one point in the area where the cable receiving portion 124 is formed. The transparent board 129 may form a step at the border of the cable receiving portion 124.

Referring to FIG. 20, the cable receiving portion 124 can be observed from the front of the transparent plate 128. The cable receiving portion 124 may be in the shape of a groove formed on one side of the transparent plate 128. The cable accommodating portion 124 may accommodate at least a portion of the cable connected to the PCB. The cable receiving portion 124 may be located at the center of the transparent plate 128. The cable receiving portion 124 may be spaced apart from the PCB receiving portions 122 and 123.

The PCB accommodating portions 122 and 123 may be located between the cable accommodating portion 124 and one side inside the transparent frame 127. For example, the PCB accommodating portions 122 and 123 may be located between the cable accommodating portion 124 and the first long side 127LS1 inside the transparent frame 127.

Referring to the cross section cut along B-B' passing through the cable receiving portion 124, the transparent plate 128 may have a thickness T5 at one point in the area where the cable receiving portion 124 is formed. The transparent board 129 may form a step at the boundary of the cable receiving portion 124.

Referring to FIG. 21, the cable receiving portion 124L can be observed from the front of the transparent board 129. The cable accommodating portion 124L may accommodate at least a portion of the cable connected to the PCB. The cable receiving portion 124L is formed at the center of the transparent board 129 and may extend to one side of the transparent board 129.

One side of the transparent board 129 connected to the cable accommodating portion 124L may be connected to the other side of the transparent board 129 adjacent to the PCB accommodating portions 122 and 123. For example, the first short side 129SS1 of the transparent board 129 may be connected to the cable receiving portion 124L. For example, the first short side 129SS1 may be connected to the first long side 129LS1 of the transparent board 128 adjacent to the PCB receiving portions 122 and 123.

The cable receiving portion 124L may have a longitudinal direction. The cable accommodating portion 124L may have a longitudinal direction parallel to the longitudinal direction of the first long side 129LS1 of the transparent board 129 adjacent to the PCB accommodating portions 122 and 123. The cable receiving portion 124L may have a longitudinal direction parallel to the direction from the first short side 129SS1 to the second short side 129SS2 of the transparent board 129.

Referring to the cross section cut along B-B' parallel to the longitudinal direction of the cable receiving portion (124L) and passing through the cable receiving portion (124L), the cable receiving portion (124L) extends to one inner side of the transparent flange (126). It may be extended. The transparent board 129 may form a step at the border of the cable receiving portion 124L.

Referring to FIG. 22, the cable receiving portion 124L can be observed from the front of the transparent plate 128. The cable accommodating portion 124L may accommodate at least a portion of the cable connected to the PCB. The cable receiving portion 124L is formed at the center of the transparent plate 128 and may extend to one side of the inner side of the transparent frame 127.

One side inside the transparent frame 127 connected to the cable accommodating portion 124L may be connected to the other side inside the transparent frame 127 adjacent to the PCB accommodating portions 122 and 123. For example, the first short side 127SS1 inside the transparent frame 127 may be connected to the cable receiving portion 124L. For example, the first short side 127SS1 may be connected to the first long side 127LS1 adjacent to the PCB receiving portions 122 and 123.

The cable receiving portion 124L may have a longitudinal direction. The cable accommodating portion 124L may have a longitudinal direction parallel to the longitudinal direction of the first long side 127LS1 inside the transparent frame 127 adjacent to the PCB accommodating portions 122 and 123. The cable receiving portion 124L may have a longitudinal direction parallel to the direction from the first short side 127SS1 to the second short side 127SS2 inside the transparent frame 127.

Referring to the cross section cut along B-B', which is parallel to the longitudinal direction of the cable accommodating part 124L and passes through the cable accommodating part 124L, the cable accommodating part 124L extends to one side of the inner side of the transparent frame 127. It can be. The transparent plate 128 may form a step at the boundary of the cable receiving portion 124L.

Referring to FIG. 23, the cable receiving portion 124 can be observed from the front of the transparent board 129. The cable receiving portion 124 may be in the shape of a hole formed on one side of the transparent board 129. The cable accommodating portion 124 may accommodate at least a portion of the cable connected to the PCB. The cable receiving portion 124 may be located adjacent to the center of the transparent board 129. The cable receiving portion 124 may be spaced apart from the PCB receiving portions 122 and 123.

The PCB accommodating portions 122 and 123 may be located between the cable accommodating portion 124 and one side of the transparent board 129. For example, the PCB accommodating portions 122 and 123 may be located between the cable accommodating portion 124 and the first long side 129LS1 of the transparent board 129.

Referring to the cross section cut along B-B' passing through the cable receiving portion 124, the transparent board 129 can communicate with the front and rear of the transparent board 129 in the area where the cable receiving portion 124 is formed. there is.

Referring to FIG. 24, the cable receiving portion 124 can be observed from the front of the transparent plate 128. The cable receiving portion 124 may be in the shape of a hole formed on one side of the transparent plate 128. The cable accommodating portion 124 may accommodate at least a portion of the cable connected to the PCB. The cable receiving portion 124 may be located at the center of the transparent plate 128. The cable receiving portion 124 may be spaced apart from the PCB receiving portions 122 and 123.

The PCB accommodating portions 122 and 123 may be located between the cable accommodating portion 124 and one side inside the transparent frame 127. For example, the PCB accommodating portions 122 and 123 may be located between the cable accommodating portion 124 and the first long side 127LS1 inside the transparent frame 127.

Referring to the cross section cut along B-B' passing through the cable receiving portion 124, the transparent plate 128 can communicate with the front and rear of the transparent plate 128 in the area where the cable receiving portion 124 is formed. there is.

Referring to FIG. 25, the slot 125 can be observed at least in part in front of the transparent board 129. The slot 125 may have the shape of a hole. The slot 125 may be formed in the transparent body 120 at one point on one side of the transparent board 129. For example, the slot 125 may be formed at one point of the first short side 129SS1 of the transparent board 129. The slot 125 may provide a space for a cable to pass through.

One side of the transparent board 129 on which the slot 125 is formed may be connected to the other side adjacent to the PCB receiving portions 122 and 123. For example, the first short side (129SS1) may be connected to the first long side (129LS1).

The slot 125 may be formed by removing a portion of the transparent flange 126. Alternatively, the slot 125 may be formed by removing a portion of the transparent board 129. Alternatively, the slot 125 may be formed by removing a portion of the transparent flange 126 and a portion of the transparent board 129. For example, the slot 125 may be formed by removing a portion of the transparent flange 126 and a portion of the transparent board 129.

Slot 125 may be open in both directions. For example, one end of the slot 125 may be open toward the cable receiving portion 124. For example, the other end of the slot 125 may be open toward the side wall (SW) of the transparent body 120. The side wall (SW) may be adjacent to the first short side (129SS1) where the slot 125 is located.

The direction in which the slot 125 is opened may correspond to the shape of the slot 125. The path of the cable passing through the slot 125 may correspond to the open direction of the slot 125. For example, when one end of the slot 125 is open toward the cable receiving portion 124 and the other end of the slot 125 is open toward the side wall (SW) adjacent to the first short side 129SS1, the cable receives the cable. It may extend from the portion 124, enter one end of the slot 125, pass through the other end of the slot 125, and head to the outside of the side wall (SW).

Referring to FIG. 26 , the slot 125 may be observed from at least a portion of the front of the transparent board 129. The slot 125 has the shape of a hole and may be formed at one point of the first short side 129SS1 of the transparent board 129. Slot 125 can pass a cable.

Slot 125 may be open in both directions. For example, one end of the slot 125 may be open toward the cable receiving portion 124 and/or toward the front of the transparent board 129. For example, the other end of the slot 125 may be open toward the rear of the transparent body 120.

The direction in which the slot 125 is opened may correspond to the shape of the slot. The path of the cable passing through the slot 125 may correspond to the open direction of the slot 125. For example, one end of the slot 125 is open toward the cable receiving portion 124 and/or toward the front of the transparent board 129, and the other end of the slot 125 is toward the rear of the transparent body 120. When opened, the cable may extend from the cable receiving portion 124, enter one end of the slot 125, pass through the other end of the slot 125, and head toward the rear of the transparent body 120.

Referring to FIG. 27 , the slot 125 may be observed from at least a portion of the front of the transparent board 129. The slot 125 has the shape of a hole and may be formed at one point of the first short side 129SS1 of the transparent board 129. Slot 125 can pass a cable.

Slot 125 may be open in both directions. For example, one end of the slot 125 may be open toward the cable receiving portion 124 and/or toward the front of the transparent board 129. For example, the other end of the slot 125 may be open toward the rear and side wall (SW) of the transparent body 120. When the other end of the slot 125 is open toward the rear and side wall (SW) of the transparent body 120, the slot 125 may be easily formed.

The direction in which the slot 125 is opened may correspond to the shape of the slot. The path of the cable passing through the slot 125 may correspond to the open direction of the slot 125. For example, one end of the slot 125 is open toward the cable receiving portion 124 and/or toward the front of the transparent board 129, and the other end of the slot 125 is opened toward the rear and side walls of the transparent body 120. When opened toward (SW), the cable extends from the cable receiving portion 124, enters one end of the slot 125, passes through the other end of the slot 125, and reaches the rear and side wall (SW) of the transparent body 120. can be directed to the outside of.

Referring to FIG. 28, the slot 125 may be observed at least in part in front of the transparent plate 128. The slot 125 may have the shape of a hole. The slot 125 may be formed in the transparent body 120 at a point on one inner side of the transparent frame 127. For example, the slot 125 may be formed at one point of the first short side 127SS1 inside the transparent frame 127. The slot 125 may provide a space for a cable to pass through.

One side inside the transparent frame 127 where the slot 125 is formed may be connected to the other side adjacent to the PCB receiving portions 122 and 123. For example, the first short side (127SS1) may be connected to the first long side (127LS1).

The slot 125 may be formed by removing a portion of the transparent plate 128. Alternatively, the slot 125 may be formed by removing a portion of the transparent frame 127. Alternatively, the slot 125 may be formed by removing part of the transparent frame 127 and part of the transparent plate 128.

The slot 125 may be formed by bonding the transparent frame 127 to the transparent plate 128 on which a groove or hole is formed. Alternatively, the slot 125 may be formed by bonding the transparent plate 128 to the transparent frame 127 in which a groove is formed. Alternatively, the slot 125 may be formed by bonding the transparent frame 127 to the transparent plate 128 on which a bay-shaped curved portion is formed. Here, the curved portion may have a concave shape toward the side wall (SW) of the transparent body 120. For example, the slot 125 may be formed by joining a transparent plate 128 with a groove and a transparent frame 127 with a groove. Here, the groove formed in the transparent plate 128 or/and the groove formed in the transparent frame 127 may be adjacent to a point of the first short side 127SS1.

Slot 125 may be open in both directions. For example, one end of the slot 125 may be open toward the cable receiving portion 124. For example, the other end of the slot 125 may be open toward the side wall (SW) of the transparent body 120. The side wall (SW) may be adjacent to the first short side (127SS1) where the slot 125 is located.

The direction in which the slot 125 is opened may correspond to the shape of the slot 125. The path of the cable passing through the slot 125 may correspond to the open direction of the slot 125. For example, when one end of the slot 125 is open toward the cable receiving portion 124 and the other end of the slot 125 is open toward the side wall (SW) adjacent to the first short side 127SS1, the cable receives the cable. It may extend from the portion 124, enter one end of the slot 125, pass through the other end of the slot 125, and head to the outside of the side wall (SW).

Referring to FIG. 29, the slot 125 may be observed at least in part in front of the transparent plate 128. The slot 125 may be formed at one point of the first short side 127SS1 inside the transparent frame 127. The slot 125 may provide a space for a cable to pass through. The first short side 127SS1 inside the transparent frame 127 on which the slot 125 is formed may be connected to the first long side 127LS1.

The slot 125 may be formed by removing a portion of the transparent plate 128. Alternatively, the slot 125 may be formed by removing a portion of the transparent frame 127. Alternatively, the slot 125 may be formed by removing part of the transparent frame 127 and part of the transparent plate 128.

The slot 125 may be formed by bonding the transparent frame 127 to the transparent plate 128 on which a groove or hole is formed. Alternatively, the slot 125 may be formed by bonding the transparent plate 128 to the transparent frame 127 in which a groove is formed. Alternatively, the slot 125 may be formed by bonding the transparent frame 127 to the transparent plate 128 on which a bay-shaped curved portion is formed. For example, the slot 125 may be formed by bonding the transparent plate 128 to the transparent frame 127 in which the groove is formed. Here, the groove formed in the transparent plate 128 and/or the groove formed in the transparent frame 127 may be formed adjacent to a point of the first short side 127SS1.

Slot 125 may be open in both directions. For example, one end of the slot 125 may be open toward the cable receiving portion 124. For example, the other end of the slot 125 may be open toward the side wall (SW) of the transparent body 120. The side wall (SW) may be adjacent to the first short side (127SS1) where the slot 125 is located.

The direction in which the slot 125 is opened may correspond to the shape of the slot 125. The path of the cable passing through the slot 125 may correspond to the open direction of the slot 125. For example, when one end of the slot 125 is open toward the cable receiving portion 124 and the other end of the slot 125 is open toward the side wall (SW) adjacent to the first short side 127SS1, the cable receives the cable. It may extend from the portion 124, enter one end of the slot 125, pass through the other end of the slot 125, and head to the outside of the side wall (SW).

Referring to FIG. 30, the slot 125 may be observed at least in part in front of the transparent plate 128. The slot 125 may be formed at one point of the first short side 127SS1 inside the transparent frame 127. The slot 125 may provide a space for a cable to pass through. The first short side 127SS1 inside the transparent frame 127 on which the slot 125 is formed may be connected to the first long side 127LS1.

The slot 125 may be formed by removing a portion of the transparent plate 128. Alternatively, the slot 125 may be formed by removing a portion of the transparent frame 127. Alternatively, the slot 125 may be formed by removing part of the transparent frame 127 and part of the transparent plate 128.

The slot 125 may be formed by bonding the transparent frame 127 to the transparent plate 128 on which a groove or hole is formed. Alternatively, the slot 125 may be formed by bonding the transparent plate 128 to the transparent frame 127 in which a groove is formed. Alternatively, the slot 125 may be formed by bonding the transparent frame 127 to the transparent plate 125 on which a bay-shaped curved portion is formed. For example, the slot 125 may be formed by bonding the transparent frame 127 to the transparent plate 128 on which a bay-shaped curved portion is formed. Here, the groove formed in the transparent plate 128 and/or the groove or/and the curved portion formed in the transparent frame 127 may be formed adjacent to a point of the first short side 127SS1.

Slot 125 may be open in both directions. For example, one end of the slot 125 may be open toward the cable receiving portion 124. For example, the other end of the slot 125 may be open toward the side wall (SW) and the rear of the transparent body 120. The side wall (SW) may be adjacent to the first short side (127SS1) where the slot 125 is located.

The direction in which the slot 125 is opened may correspond to the shape of the slot 125. The path of the cable passing through the slot 125 may correspond to the open direction of the slot 125. For example, if one end of the slot 125 is open toward the cable receiving portion 124 and the other end of the slot 125 is open toward the side wall (SW) adjacent to the first short side 127SS1 and toward the rear, the cable It may extend from the cable receiving portion 124, enter one end of the slot 125, pass through the other end of the slot 125, and head to the outside and rear of the side wall (SW).

Referring to FIG. 31, auxiliary grooves (AXGU1, AXGU2, AXGU3, AXGU4, AXGU5, AXGU6, AXGD1, AXGD2, AXGD3, AXGD4, AXGD5, AXGD6) can be observed at least in part of the front of the transparent body 120. A plurality of auxiliary grooves (AXGU1, AXGU2, AXGU3, AXGU4, AXGU5, AXGU6, AXGD1, AXGD2, AXGD3, AXGD4, AXGD5, AXGD6) may be provided. The auxiliary grooves (AXGU1, AXGU2, AXGU3, AXGU4, AXGU5, AXGU6, AXGD1, AXGD2, AXGD3, AXGD4, AXGD5, AXGD6) are composed of the upper auxiliary grooves (AXGU1, AXGU2, AXGU3, AXGU4, AXGU5, AXGU6) and the lower auxiliary grooves ( AXGD1, AXGD2, AXGD3, AXGD4, AXGD5, AXGD6).

The cable receiving portion 124 may be located between the auxiliary grooves (AXGU1, AXGU2, AXGU3, AXGU4, AXGU5, AXGU6, AXGD1, AXGD2, AXGD3, AXGD4, AXGD5, AXGD6). At least a portion of the auxiliary grooves (AXGU1, AXGU2, AXGU3, AXGU4, AXGU5, AXGU6, AXGD1, AXGD2, AXGD3, AXGD4, AXGD5, AXGD6) is adjacent to the other side connected to one side adjacent to the PCB receiving portions 122 and 123. It can be formed. For example, the upper auxiliary grooves (AXGU1, AXGU2, AXGU3, AXGU4, AXGU5, AXGU6) are formed adjacent to the second short side (129SS2) connected to the first long side (129LS1) adjacent to the PCB receiving portions (122, 123). You can. For example, the lower auxiliary grooves (AXGD1, AXGD2, AXGD3, AXGD4, AXGD5, AXGD6) are formed adjacent to the first short side (129SS1) connected to the first long side (129LS1) adjacent to the PCB receiving portions (122, 123). You can.

The auxiliary grooves (AXGU1, AXGU2, AXGU3, AXGU4, AXGU5, AXGU6, AXGD1, AXGD2, AXGD3, AXGD4, AXGD5, AXGD6) may provide a space where at least a portion of the components extending from the display panel can be seated. Here, the component extending from the display panel may be a chip mounted on a film.

32 to 35 are diagrams showing examples of display panels according to an embodiment of the present invention.

Referring to FIG. 32, the display panel 110 may provide an image on one side. The display panel 110 can divide an image into a plurality of pixels and output an image with color, brightness, and saturation for each pixel. The display panel 110 may generate light corresponding to a color including at least one of red, green, and blue according to a control signal.

A member layer (MBL) may be connected to one side of the display panel 110. For example, the member layer MBL may be formed extending from the first long side 110LS1 of the display panel 110. The member layer (MBL) may include at least one of chip-on-film (COF), chip-on-glass (COG), FPCB, wire, and tape carrier package (TCP). The membership floor (MBL) can be flexible. A plurality of member layers (MBL) may be provided. The member layer (MBL) may be electrically connected to the display panel 110. The member layer (MBL) may supply power to the display panel 110. The pixels of the display panel 110 may be controlled by current provided to the display panel 110 through the member layer (MBL).

The cable SC may be electrically connected to the display panel 110. The cable SC may supply current to the display panel 110. The cable SC may supply electrical signals that control pixels of the display panel 110 to the display panel 110. The cable (SC) may be electrically connected to the member layer (MBL).

The PCB (SP) may be electrically connected to the member layer (MBL). The PCB (SP) may be electrically connected to the cable (SC). The PCB (SP) may be relatively large compared to the member layer (MBL) and/or cable (SC). The PCB (SP) may occupy a certain volume on one side of the display panel 110. The thickness of the PCB (SP) may vary depending on the type and/or arrangement and/or shape of the electronic devices mounted on the PCB (SP). PCB (SP) may be a source PCB.

Referring to FIG. 33, a cross section of the display panel 110, a cross section of the member layer (MBL), a cross section of the PCB (SP), and a cross section of the cable (SC) are shown.

The display panel 110 may be connected to the member layer (MBL). The member layer (MBL) can connect the PCB (SP) and the display panel 110. The PCB (SP) may have a thickness greater than the display panel 110. The cable (SC) can be connected to the PCB (SP).

The cable (SC) may be electrically connected to the PCB (SP). The PCB (SP) may be electrically connected to the member layer (MBL). The member layer (MBL) may be electrically connected to the display panel 110. When two different elements are electrically connected, it may mean that transmission and reception of electrical signals and/or current is possible between the two different elements.

Referring to FIG. 34, the member layer (MBL) may be bent. Since the member layer (MBL) is flexible, it can be overlapped with the display panel 110. That is, at least a portion of the member layer (MBL) may overlap with the display panel 110. At least a portion of the member layer MBL may be located behind the display panel 110, for example.

The member layer MBL may be formed extending from one side of the display panel 110 and may face the other side facing one side of the display panel 110 . For example, the member layer MBL may extend from the first long side 110LS1 of the display panel 110 and face the second long side 110LS2.

The PCB (SP) connected to the member layer (MBL) may be adjacent to one side of the display panel 110 to be connected to the member layer (MBL). For example, the PCB (SP) may be located adjacent to the first long side 110LS1 of the display panel 110. Alternatively, the PCB (SP) may be located between the first long side 110LS1 and the second long side 110LS2 of the display panel 110. The cable (SC) connected to the PCB (SP) may extend from the member layer (MBL) toward the PCB (SP).

Referring to FIG. 35, the cable (SC) extending from the PCB (SP) may be bent. You can look at the arrangement relationship of the member layer (MBL), PCB (SP), and cable (SC). The member layer MBL may extend from one side of the display panel 110 and face the other side facing the one side. For example, the member layer MBL may extend from the first long side 110LS1 of the display panel 110 and face the second long side 110LS2.

The PCB (SP) is connected to the member layer (MBL) and may be closer to the other side of the display panel 110 than the member layer (MBL). For example, the PCB (SP) may be closer to the second long side (110LS2) than the member layer (MBL).

The cable SC may be bent from the PCB SP toward the other side of the display panel 110 and toward the side connected to the one side. For example, the cable SC may be bent toward the second long side 110LS2 of the display panel 110, but may be bent toward the first short side 110SS1 connected to the first long side 110LS1. A region where the cable SC is bent may be formed. For example, the cable SC may form a bending area BA, which is an area where the cable SC is bent. In the bending area BA, a plurality of cables SC may be bent and stacked. The thickness formed by the laminated cable SC may be greatest in the bending area BA.

Although not shown in the drawing, the bent and extending cable SC may be connected to a controller that does not overlap the display panel 110 in the front-to-back direction. By bending the cable SC, the display panel 110 can have various attitudes.

The arrangement relationship of the member layer (MBL), PCB (SP), and cable (SC) can be examined based on one side of the display panel 110 to which the member layer (MBL) is connected and the other side facing the one side. there is. For example, the member layer (MBL), PCB (SP), and cable (SC) may be sequentially connected in a direction from the first long side (110LS1) to which the member layer (MBL) is connected to the second long side (110LS2). .

36 to 41 are diagrams showing examples of combination relationships between components of a display device according to an embodiment of the present invention.

Referring to FIG. 36, the rear of the display panel 110 may be coupled toward the front of the transparent body 120. For example, the first long side 110LS1, the first short side 110SS1, the second long side 110LS2, and the second short side 110SS2 of the display panel 110 are the first long side 129LS1 of the transparent board 129. ), the first short side (129SS1), the second long side (129LS2), and the second short side (129SS2).

The rear of the touch panel TP may be coupled toward the front of the display panel 110. The touch panel (TP) can obtain touch input. The touch panel (TP) may be transparent. The touch panel TP can pass at least a portion of an image displayed on the display panel 110. The touch panel TP may correspond to the shape of the display panel 110.

The touch panel cable (TPC) may be formed to extend from one side of the touch panel (TP). A touch panel cable (TPC) may be inserted into the slot 125. The touch panel cable (TPC) may cross one side of the display panel 110 between one side of the touch panel TP and the slot 125. For example, the touch panel cable (TPC) may cross the first short side (SS1) of the display panel 110. The touch panel cable (TPC) may be located on the side of the display panel 110. The touch panel cable (TPC) inserted into the slot 125, although not shown in the drawing, may be electrically connected to a controller.

With the display panel 110 coupled to the transparent body 120, the first long side 129LS1, the first short side 129SS1, the second long side 129LS2, and the second short side 129SS2 of the transparent board 129. ) may be referred to as the first long side 110LS1, the first short side 110SS1, the second long side 110LS2, and the second short side 110SS2 of the display panel 110. For example, the PCB receiving portions 122 and 123 may be formed along the longitudinal direction of the first long side 110LS1 of the display panel 110. For example, the slot 125 may be formed adjacent to the first short side 110SS1 connected to the first long side 110LS1 of the display panel 110.

At least a portion of the member layer (MBL), PCB (SP), and cable (SC) may be located on the rear side of the display panel 110. At least a portion of the member layer (MBL), PCB (SP), and cable (SC) will be located between the display panel 110 and the transparent board 129 when the display panel 110 and the transparent body 120 are combined. You can. The cable SC may be inserted into the slot 125.

Coupling members (FM1, FM2, FM3) may be located on the front of the transparent board 129. The coupling members FM1, FM2, and FM3 may have a thickness. For example, the thickness of the coupling members (FM1, FM2, FM3) may be greater than the thickness of the cable (SC). The coupling members FM1, FM2, and FM3 may be adhesive tapes or magnetic materials. The coupling members (FM1, FM2, FM3) may form a layer. For example, the coupling members FM1, FM2, and FM3 may be formed by laminating an adhesive tape and a magnetic material. A plurality of coupling members (FM1, FM2, FM3) may be provided. For example, the coupling members FM1, FM2, and FM3 may include a first coupling member FM1, a second coupling member FM2, and a third coupling member FM3.

The PCB receiving portions 122 and 123 located on the front of the transparent board 129 can accommodate at least a portion of the PCB (SP). Since the PCB (SP) is accommodated in the PCB (SP), the cable (SC) may be bent between the PCB receiving portions (122, 123) and the slot (125). The PCB receiving portions 122 and 123 may have the shape of a groove or a hole.

The cable accommodating portion 124 located on the front of the transparent board 129 may accommodate at least a portion of the cable SC. For example, the cable accommodation unit 124 may accommodate the cable SC forming the bending area BA. The cable receiving portion 124 may have a groove shape or a hole shape.

Referring to FIG. 37, an example of the combination of the display panel 110 and the transparent body 120 is shown in cross section. The member layer (MBL), PCB (SP), and cable (SC) may be located on the rear of the display panel 110. The touch panel TP may be located on the front of the display panel 110.

The PCB (SP) may be positioned to be accommodated in the PCB receiving portions 122 and 123. The bending area BA of the cable may be accommodated in the cable receiving portion 124. The coupling member FM3 may couple the display panel 110 and the transparent board 129.

Referring to FIG. 38, the rear of the display panel 110 may be coupled toward the front of the transparent body 120. For example, the first long side 110LS1, the first short side 110SS1, the second long side 110LS2, and the second short side 110SS2 of the display panel 110 are the first long side inside the transparent frame 127 ( 127LS1), the first short side (127SS1), the second long side (127LS2), and the second short side (127SS2).

The rear of the touch panel TP may be coupled toward the front of the display panel 110. The touch panel (TP) can obtain touch input. The touch panel (TP) may be transparent. The touch panel TP can pass at least a portion of an image displayed on the display panel 110. The touch panel TP may correspond to the shape of the display panel 110.

The touch panel cable (TPC) may be formed to extend from one side of the touch panel (TP). A touch panel cable (TPC) may be inserted into the slot 125. The touch panel cable (TPC) may cross one side of the display panel 110 between one side of the touch panel TP and the slot 125. For example, the touch panel cable (TPC) may cross the first short side (SS1) of the display panel 110. The touch panel cable (TPC) may be located on the side of the display panel 110. The touch panel cable (TPC) inserted into the slot 125, although not shown in the drawing, may be electrically connected to a controller.

In a state where the display panel 110 is coupled to the transparent body 120, the first long side (127LS1), the first short side (127SS1), the second long side (127LS2), and the second short side ( 127SS2) may be referred to as the first long side 110LS1, the first short side 110SS1, the second long side 110LS2, and the second short side 110SS2 of the display panel 110. For example, the PCB receiving portions 122 and 123 may be formed along the longitudinal direction of the first long side 110LS1 of the display panel 110. For example, the slot 125 may be formed adjacent to the first short side 110SS1 connected to the first long side 110LS1 of the display panel 110.

At least a portion of the member layer (MBL), PCB (SP), and cable (SC) may be located on the rear side of the display panel 110. At least a portion of the member layer (MBL), PCB (SP), and cable (SC) will be located between the display panel 110 and the transparent plate 128 when the display panel 110 and the transparent body 120 are combined. You can. The cable SC may be inserted into the slot 125.

Coupling members (FM1, FM2, and FM3) may be located on the front of the transparent plate 128. The coupling members FM1, FM2, and FM3 may have a thickness. For example, the thickness of the coupling members (FM1, FM2, FM3) may be greater than the thickness of the cable (SC). The coupling members FM1, FM2, and FM3 may be adhesive tapes or magnetic materials. The coupling members (FM1, FM2, FM3) may form a layer. For example, the coupling members FM1, FM2, and FM3 may be formed by laminating an adhesive tape and a magnetic material. A plurality of coupling members (FM1, FM2, FM3) may be provided. For example, the coupling members FM1, FM2, and FM3 may include a first coupling member FM1, a second coupling member FM2, and a third coupling member FM3.

The PCB receiving portions 122 and 123 located on the front side of the transparent plate 128 can accommodate at least a portion of the PCB (SP). Since the PCB (SP) is accommodated in the PCB (SP), the cable (SC) may be bent between the PCB receiving portions (122, 123) and the slot (125). The PCB receiving portions 122 and 123 may have the shape of a groove or a hole.

The cable accommodating portion 124 located on the front of the transparent plate 128 may accommodate at least a portion of the cable SC. For example, the cable accommodation unit 124 may accommodate the cable SC forming the bending area BA. The cable receiving portion 124 may have a groove shape or a hole shape.

Referring to FIG. 39, an example of the combination of the display panel 110 and the transparent body 120 is shown in cross section. The member layer (MBL), PCB (SP), and cable (SC) may be located on the rear of the display panel 110. The touch panel TP may be located in the front of the display panel 110.

The PCB (SP) may be positioned to be accommodated in the PCB receiving portions 122 and 123. The bending area BA of the cable may be accommodated in the cable receiving portion 124. The coupling member FM3 may couple the display panel 110 and the transparent plate 128.

Referring to FIG. 40 , the rear cover RC may be located on the rear of the transparent body 120. The rear cover RC may be coupled to the rear of the transparent board 129. The rear cover RC may be fitted into the transparent flange 126. The transparent body 120 may provide a space on the rear of the transparent body 120 where the rear cover RC is seated.

When the rear cover RC is coupled to the rear of the transparent board 129, the transparent flange 126 may face the side of the display panel 110 and the side of the rear cover RC. The rear cover RC may have a thickness thinner than the thickness of the transparent flange 126. The rear cover RC may have an area corresponding to the area of the transparent board 129.

The rear cover (RC) can secure certain rigidity. The rear cover RC can be coupled to the transparent board 129 to improve the rigidity of the transparent body 120. The rear cover (RC) may include at least one of metal, reinforced fiber, reinforced glass, reinforced plastic, reinforced ceramic, and carbon fiber.

Referring to FIG. 41 , the rear cover RC may be located on the rear of the transparent body 120. The rear cover 120 may be coupled to the rear of the transparent plate 128. The rear cover RC may be accommodated on the rear of the transparent plate 128. The transparent plate 128 may provide a space at the rear to accommodate the rear cover RC. In this case, a step may occur at the rear of the transparent plate 128.

When the rear cover RC is coupled to the rear of the transparent plate 129, the transparent plate 128 may face the side of the rear cover RC. The rear cover RC may have an area corresponding to the area of the display panel 110. The rear cover RC may have a thickness thinner than the thickness of the transparent plate 129. The rear cover RC can improve the rigidity of the transparent body 120 by being coupled to the transparent plate 128.

Figures 42 to 48 are diagrams showing several examples of cross sections of a display device according to an embodiment of the present invention.

Referring to FIG. 42, the display panel 110 may be coupled to the transparent board 129 by a coupling member (FM). The display panel 110 may be fitted into the transparent flange 126. The rear cover RC may be coupled to the rear of the transparent body 120. The transparent body 120 can accommodate the rear cover RC by forming a step at the rear. A touch panel (TP) may be located in front of the display panel 110.

The cable SC extending from one side of the display panel 110 may be bent to form a bending area BA at the rear of the display panel 110. The cable SC may be thickest in the bending area BA, and the cable SC in the bending area BA may be accommodated in the cable receiving portion 124 formed on one side of the transparent board 129. The thickness of the cable SC located between the display panel 110 and the transparent board 129 may correspond to the thickness of the coupling member FM.

The cable SC may be bent in the cable receiving portion 124. That is, the cable SC may extend from one side of the display panel 110 to the cable accommodating part 124, be bent in the cable accommodating part 124, and be inserted into the slot 125. The slot 125 may be open toward the outside of the side wall (SW) of the transparent body 120.

The cable SC may be bent as it enters the slot 125. The section where the cable SC is bent as it enters the slot 125 may be short. The cable SC may be subjected to pressure by being positioned between the display panel 110 and the transparent board 129 in the section from the cable receiving portion 124 to the slot 125. As the cable SC enters the slot 125, the pressure received from the transparent board 129 may decrease or disappear. Because of this, the cable SC may be bent toward the rear of the transparent board 129 as it enters the slot 125.

The cable SC may pass through the slot 125 and be directed to the outside of the side wall (SW) of the transparent body 120. For example, the cable SC may pass through the slot 125 and fall under the transparent body 120. The cable SC directed to the outside of the side wall (SW) of the transparent body 120 may be electrically connected to a controller (controller) not shown in the drawing.

The touch panel cable (TPC) may extend from one side of the touch panel (TP) and pass through the slot 125. The touch panel cable (TPC) passing through the slot 125 may be directed to the outside of the side wall (SW) of the transparent body 120. The touch panel cable (TPC) directed to the outside of the side wall (SW) of the transparent body 120 may be electrically connected to a controller (controller) not shown in the drawing.

Referring to FIG. 43, the display panel 110 may be coupled to the transparent board 129 by a coupling member (FM). The display panel 110 may be fitted into the transparent flange 126. A touch panel (TP) may be located in front of the display panel 110.

The cable SC extending from one side of the display panel 110 may be bent to form a bending area BA at the rear of the display panel 110. The cable SC may be bent in the cable receiving portion 124. That is, the cable SC may extend from one side of the display panel 110 to the cable accommodating part 124, be bent in the cable accommodating part 124, and be inserted into the slot 125.

The slot 125 may be open toward the rear of the transparent body 120. The cable SC may pass through the slot 125 and head toward the rear of the transparent body 120. The cable SC toward the rear of the transparent body 120 may be electrically connected to a controller (controller) not shown in the drawing.

The touch panel cable (TPC) may extend from one side of the touch panel (TP) and pass through the slot 125. The touch panel cable (TPC) passing through the slot 125 may be directed toward the rear of the transparent body 120. The touch panel cable (TPC) toward the rear of the transparent body 120 may be electrically connected to a controller (controller) not shown in the drawing.

Referring to FIG. 44, the display panel 110 can be coupled to the transparent board 129 by a coupling member (FM). The display panel 110 may be fitted into the transparent flange 126. A touch panel (TP) may be located in front of the display panel 110.

The cable SC extending from one side of the display panel 110 may be bent to form a bending area BA at the rear of the display panel 110. The cable SC may be bent in the cable receiving portion 124. That is, the cable SC may extend from one side of the display panel 110 to the cable accommodating part 124, be bent in the cable accommodating part 124, and be inserted into the slot 125. The cable SC may be bent toward the rear of the transparent board 129 as it enters the slot 125.

The slot 125 may be open toward the outside of the rear and side wall (SW) of the transparent body 120. The cable SC may pass through the slot 125 and be directed to the rear and outside the side wall (SW) of the transparent body 120. The cable SC directed to the outside of the rear and side walls SW of the transparent body 120 may be electrically connected to a controller not shown in the drawing.

The touch panel cable (TPC) may extend from one side of the touch panel (TP) and pass through the slot 125. The touch panel cable (TPC) passing through the slot 125 may be directed to the rear and outside the side wall (SW) of the transparent body 120. The touch panel cable (TPC) directed to the outside of the rear and side wall (SW) of the transparent body 120 may be electrically connected to a controller (controller) not shown in the drawing.

Referring to FIG. 45, the display panel 110 may be coupled to the transparent plate 128 by a coupling member (FM). The display panel 110 may be fitted into the transparent frame 127. The touch panel TP may be located in the front of the display panel 110. The rear cover RC may be coupled to the rear of the transparent plate 128. The transparent plate 120 can accommodate the rear cover RC by forming a step at the rear.

The cable SC extending from one side of the display panel 110 may be bent to form a bending area BA at the rear of the display panel 110. The cable SC may be thickest in the bending area BA, and the cable SC in the bending area BA may be accommodated in the cable receiving portion 124 formed on one side of the transparent plate 128. The thickness of the cable SC located between the display panel 110 and the transparent plate 128 may correspond to the thickness of the coupling member FM.

The cable SC may be bent in the cable receiving portion 124. That is, the cable SC may extend from one side of the display panel 110 to the cable accommodating part 124, be bent in the cable accommodating part 124, and be inserted into the slot 125. The slot 125 may be open toward the outside of the side wall (SW) of the transparent body 120. The slot 125 may be formed by combining the transparent frame 127 and the transparent plate 128 after each forming a groove.

The cable SC may be bent as it enters the slot 125. The section where the cable SC is bent as it enters the slot 125 may be short. The cable SC may be subjected to pressure by being positioned between the display panel 110 and the transparent plate 128 in the section from the cable receiving portion 124 to the slot 125. As the cable SC enters the slot 125, the pressure received from the transparent plate 128 may decrease or disappear. Because of this, the cable SC may be bent toward the rear of the transparent plate 128 as it enters the slot 125.

The cable SC may pass through the slot 125 and be directed to the outside of the side wall (SW) of the transparent body 120. For example, the cable SC may pass through the slot 125 and fall under the transparent body 120. The cable SC directed to the outside of the side wall (SW) of the transparent body 120 may be electrically connected to a controller (controller) not shown in the drawing.

The touch panel cable (TPC) may extend from one side of the touch panel (TP) and pass through the slot 125. The touch panel cable (TPC) passing through the slot 125 may be directed to the outside of the side wall (SW) of the transparent body 120. The touch panel cable (TPC) directed to the outside of the side wall (SW) of the transparent body 120 may be electrically connected to a controller (controller) not shown in the drawing.

Referring to FIG. 46, the display panel 110 may be coupled to the transparent plate 128 by a coupling member (FM). The display panel 110 may be fitted into the transparent frame 127. The touch panel TP may be located on the front of the display panel 110. The rear cover RC may be coupled to the rear of the transparent plate 128. The transparent plate 120 can accommodate the rear cover RC by forming a step at the rear.

The cable SC extending from one side of the display panel 110 may be bent to form a bending area BA at the rear of the display panel 110. The cable SC in the bending area BA may be accommodated in the cable receiving portion 124 formed on one side of the transparent plate 128. The cable SC may extend from one side of the display panel 110 to the cable receiving portion 124 and may be bent in the cable receiving portion 124 and inserted into the slot 125 . The slot 125 may be open toward the outside of the rear and side wall (SW) of the transparent body 120. The slot 125 may be formed by coupling the transparent frame 127 to the transparent plate 128 on which a bay-shaped curved portion is formed.

The cable SC may be bent as it enters the slot 125. The section where the cable SC is bent as it enters the slot 125 may be short. The cable SC may be subjected to pressure by being positioned between the display panel 110 and the transparent plate 128 in the section from the cable receiving portion 124 to the slot 125. As the cable SC enters the slot 125, the pressure received from the transparent plate 128 may decrease or disappear. Because of this, the cable SC may be bent toward the rear of the transparent plate 128 as it enters the slot 125.

The cable SC may pass through the slot 125 and be directed to the outside and/or rear of the side wall (SW) of the transparent body 120. For example, the cable SC may pass through the slot 125 and fall under the transparent body 120. The cable SC directed to the outside of the transparent body 120 may be electrically connected to a controller (controller) not shown in the drawing.

The touch panel cable (TPC) may extend from one side of the touch panel (TP) and pass through the slot 125. The touch panel cable (TPC) passing through the slot 125 may be directed to the outside and/or rear of the side wall (SW) of the transparent body 120. The touch panel cable (TPC) facing the outside of the transparent body 120 may be electrically connected to a controller (controller) not shown in the drawing.

Referring to FIG. 47, the display panel 110 may be coupled to the transparent plate 128 by a coupling member (FM). The display panel 110 may be fitted into the transparent frame 127. The touch panel TP may be located on the front of the display panel 110. The rear cover RC may be coupled to the rear of the transparent plate 128. The transparent plate 120 can accommodate the rear cover RC by forming a step at the rear.

The cable SC may extend from one side of the display panel 110 to the cable receiving portion 124 and may be bent in the cable receiving portion 124 and inserted into the slot 125 . The slot 125 may be open toward the outside of the side wall (SW) of the transparent body 120. The slot 125 may be formed by coupling the transparent plate 128 to the transparent frame 127 in which a groove is formed.

The cable SC may pass through the slot 125 and be directed to the outside of the side wall (SW) of the transparent body 120. For example, the cable SC may pass through the slot 125 and fall under the transparent body 120. The cable SC directed to the outside of the transparent body 120 may be electrically connected to a controller (controller) not shown in the drawing.

The touch panel cable (TPC) may extend from one side of the touch panel (TP) and pass through the slot 125. The touch panel cable (TPC) passing through the slot 125 may be directed to the outside of the side wall (SW) of the transparent body 120. The touch panel cable (TPC) facing the outside of the transparent body 120 may be electrically connected to a controller (controller) not shown in the drawing.

Referring to FIG. 48, the display panel 110 may be coupled to the transparent plate 128 by a coupling member (FM). The display panel 110 may be fitted into the transparent frame 127. The touch panel TP may be located in the front of the display panel 110. The rear cover RC may be coupled to the rear of the transparent plate 128. The transparent plate 120 can accommodate the rear cover RC by forming a step at the rear.

The cable SC may extend from one side of the display panel 110 to the cable receiving portion 124 and may be bent in the cable receiving portion 124 and inserted into the slot 125 . The cable (SC) may be bent as it enters the slot 125. The slot 125 may be open toward the outside of the side wall (SW) of the transparent body 120. The slot 125 may be formed by coupling the transparent frame 127 to the transparent plate 128 in which a groove is formed.

The cable SC may pass through the slot 125 and be directed to the outside of the side wall (SW) of the transparent body 120. For example, the cable SC may pass through the slot 125 and fall under the transparent body 120. The cable SC directed to the outside of the transparent body 120 may be electrically connected to a controller (controller) not shown in the drawing.

The touch panel cable (TPC) may extend from one side of the touch panel (TP) and pass through the slot 125. The touch panel cable (TPC) passing through the slot 125 may be directed to the outside of the side wall (SW) of the transparent body 120. The touch panel cable (TPC) facing the outside of the transparent body 120 may be electrically connected to a controller (controller) not shown in the drawing.

Figures 49 and 50 are diagrams showing examples of display devices according to an embodiment of the present invention.

Referring to FIG. 49, the first display panel 110 can be observed in front of the display device 100. The first display panel 110 may provide an image toward the front of the display device 100. The transparent body 120 may be located behind the first display panel 110.

The second display panel 130 can be observed from the rear of the display device 100. The second display panel 130 may provide an image toward the rear of the display device 100. The second display panel 130 may be located behind the transparent body 120.

The display device 100 may have a plurality of display panels on the front and rear sides. The display device 100 can display the same image on both sides simultaneously. In contrast, the display device 100 may display the front image differently from the rear image. The display panels 110 and 130 may refer to at least one of the first display panel 110 and the second display panel 130.

The transparent body 120 can accommodate the display panels 110 and 130. The transparent body 120 may face the side surfaces of the display panels 110 and 130. The transparent body 120 can fix the display panels 110 and 130. The transparent body 120 may be connected to or fixed to the outside. For example, the transparent body 120 may be suspended or mounted on the ceiling. For example, the transparent body 120 may be connected to or fixed to the top of an external structure. For example, the transparent body 120 may be connected to or fixed to the side of an external structure. For example, the transparent body 120 may be located between external structures.

The portion of the transparent body 120 facing the side of the display panel 110 and 130 may extend from the portion of the transparent body 120 facing the rear of the display panel 110 and 130. The direction in which the rear of the first display panel 110 faces may be opposite to the direction in which the rear of the second display panel 130 faces. That is, the direction in which the rear of the first display panel 110 faces may be the direction in which the front of the second display panel 130 faces. In this way, 'front' and 'rear' may not indicate absolute directions and may vary depending on the type of display panel 110 and 130. For example, the direction in which the front of the first display panel 110 faces may be the direction in which the front of the display device 100 faces. For example, the direction in which the front of the second display panel 130 faces may be the direction in which the rear of the display device 100 faces.

The portion of the transparent body 120 that faces the side of the display panel (110, 130) and the portion that faces the rear of the display panel (110, 130) may be formed integrally, for example, as shown in FIG. 1. there is. The portion of the transparent body 120 facing the side of the display panel 110 and 130 and the portion facing the rear of the display panel 110 and 130 may be distinguished, for example, as shown in FIG. 2. .

Referring to FIG. 50 , the first transparent frame 127a may face the side of the first display panel 110. The transparent plate 128 may be coupled to the first transparent frame 127a. The first transparent frame 127a may have a shape extending from one side of the transparent plate 128. Here, one side of the transparent plate 128 may face the rear of the first display panel 110. A first boundary line LB1 may be formed between the first transparent frame 127a and the transparent plate 128.

The second transparent frame 127b may face the side of the second display panel 130. The transparent plate 128 may be coupled to the second transparent frame 127b. The second transparent frame 127b may have a shape extending from the other side of the transparent plate 128. Here, the other side of the transparent plate 128 may face the rear of the second display panel 130. A second boundary line LB2 may be formed between the second transparent frame 127b and the transparent plate 128.

The boundary line LB may mean at least one of the first boundary line LB1 and the second boundary line LB2. The frame 127 may refer to at least one of the first transparent frame 127a and the second transparent frame 127b.

Figures 51 and 52 are diagrams showing examples of the configuration of a display device according to an embodiment of the present invention.

Referring to FIG. 51, one side of the first display panel 110 can be observed from the front of the display device 100. One side or the front of the first display panel 110 may display an image. One side of the second display panel 130 can be observed from the rear of the display device 100. One side or the front of the second display panel 130 may display an image.

The display panels 110 and 130 may be divided into an active area (AA) that displays images, and an inactive area (IA) that does not display images.

The first display panel 110 may be located on the front of the transparent body 120. The second display panel 130 may be located on the rear of the transparent body 130. That is, the transparent body 120 may be located between the first display panel 110 and the second display panel 130. The sides of the display panels 110 and 130 may be surrounded by the transparent body 120. The display panels 110 and 130 may be coupled to the transparent body 120. The display panels 110 and 130 may be attached and detached from the transparent body 120. The display panels 110 and 130 may be flexible. The display panels 110 and 130 may receive certain rigidity from the transparent body 120.

The first display panel 110 may form a first long side 110LS1, a second long side 110LS2, a first short side 110SS1, and a second short side 110SS2. The second display panel 130 may form a first long side 130LS1, a second long side 130LS2, a first short side 130SS1, and a second short side 130SS2.

The first long side 130LS1, the second long side 130LS2, the first short side 130SS1, and the second short side 130SS2 of the second display panel 130 are the first long side of the first display panel 110 ( 110LS1), the second long side (110LS2), the first short side (110SS1), and the second short side (110SS2) may be adjacent to or parallel to each other.

The transparent body 120 may be divided into a transparent flange 126 facing the side of the display panels 110 and 130, and a transparent board 129 facing the rear of the display panels 110 and 130. The transparent flange 126 and the transparent board 129 may be formed integrally. The transparent board 129 may be positioned between the first display panel 110 and the second display panel 130.

The transparent board 129 may face the rear of the display panels 110 and 130. One side of the transparent board 129 facing the rear of the first display panel 110 may be referred to as the front of the transparent board 129. The other side of the transparent board 129 facing the rear of the second display panel 130 may be referred to as the rear of the transparent board 129.

The transparent board 129 may correspond to the shape of the display panels 110 and 130. For example, the first long side 129aLS1, the second long side 129aLS2, the first short side 129aSS1, and the second short side 129aSS2 on the front of the transparent board 129 are the first long side 129aSS1 of the first display panel 110. It may be formed to correspond to a long side (110LS1), a second long side (110LS2), a first short side (110SS1), and a second short side (110SS2). For example, each side of the rear of the transparent board 129 may be formed to correspond to each side of the second display panel 130.

The side of the transparent board 129 may be surrounded by the transparent flange 126. For example, the first long side (129aLS1), the second long side (129aLS2), the first short side (129aSS1), and the second short side (129aSS2) on the front of the transparent board 129 are located inside the transparent body 120. You can.

The transparent flange 126 may be shaped to surround the display panels 110 and 130. The transparent flange 126 may form sides corresponding to each side of the transparent board 129. For example, the first long side 126LS1, the second long side 126LS2, the first short side 126SS1, and the second short side 126SS2 of the transparent flange 126 are the first long side of the front of the transparent board 129 ( It may be formed adjacent to or parallel to 129aLS1), the second long side 129aLS2, the first short side 129aSS1, and the second short side 129aSS2, respectively.

The transparent body 120 may form a side wall (SW). The side wall (SW) may be located on the first long side (126LS1), the second long side (126LS2), the first short side (126SS1), and the second short side (126SS2) of the transparent flange 126.

The length of the first long side 110LS1 of the first display panel 110 may be slightly shorter than the length of the first long side 129aLS1 on the front of the transparent board 129. The length of the first short side 110aSS1 of the first display panel 110 may be slightly shorter than the length of the first short side 129aSS1 on the front of the transparent board 129. The relationship between the length of each side of the second display panel 130 and the length of each side of the rear of the transparent board 129 is the relationship between the length of each side of the first display 110 and the length of each side of the front of the transparent board 129. may be the same.

The display panels 110 and 130 may be fixed to the transparent board 129. The display panels 110 and 130 may be coupled to the transparent board 129 by magnetic force. The display panels 110 and 130 may be fitted into the transparent flange 126.

Referring to FIG. 52, the first transparent frame 127a may be shaped to surround the first display panel 110. The inside of the first transparent frame 127a may form a space to accommodate the first display panel 110. The second transparent frame 127b may be shaped to surround the second display panel 130. The inside of the second transparent frame 127b may form a space to accommodate the second display panel 130. The transparent frames 127a and 127b may refer to at least one of the first transparent frame 127a and the second transparent frame 127b.

The inside of the first transparent frame 127a may have a shape corresponding to the shape of the first display panel 110. For example, the first long side 127aLS1, the second long side 127aLS2, the first short side 127aSS1, and the second short side 127aSS2 inside the first transparent frame 127a are of the first display panel 110. It may be formed to correspond to a first long side (110LS1), a second long side (110LS2), a first short side (110SS1), and a second short side (110SS2). Likewise, the inside of the second transparent frame 127b may have a shape corresponding to the shape of the second display panel 130.

The transparent plate 128 may be located on the rear side of the display panels 110 and 130. That is, the transparent plate 128 may be located between the first display panel 110 and the second display panel 130.

The transparent plate 128 may be located on the rear side of the transparent frames 127a and 127b. That is, the transparent plate 128 may be located between the first transparent frame 127a and the second transparent frame 127b. The transparent plate 128 may be coupled to the transparent frames 127a and 127b.

The sides formed on the outside of the transparent plate 128 may be formed to correspond to the sides formed on the inside of the transparent frames 127a and 127b. For example, the first long side 128LS1, the second long side 128LS2, the first short side 128SS1, and the second short side 128SS2 of the transparent plate 128 are the first long side 128LS1 inside the first transparent frame 127a. It may be formed adjacent to the long side 127aLS1, the second long side 127aLS2, the first short side 127aSS1, and the second short side 127aSS2, respectively.

The transparent body 120 may form a side wall (SW). The side wall SW may be located on the first long side 128LS1, the second long side 128LS2, the first short side 128SS1, and the second short side 128SS2 of the transparent plate 128.

The length of the first long side 110LS1 of the first display panel 110 may be slightly shorter than the length of the first long side 127aLS1 inside the first transparent frame 127a. The length of the first short side 110SS1 of the first display panel 110 may be slightly shorter than the length of the first short side 127aSS1 inside the first transparent frame 127a. The relationship between the length of each side of the second display panel 130 and each side inside the second transparent frame 127b is the relationship between the length of each side of the first display panel 110 and each side inside the first transparent frame 127a. may be the same as

The display panels 110 and 130 may be fixed to the transparent plate 128. The display panels 110 and 130 may be coupled to the transparent plate 128 by magnetic force. The display panels 110 and 130 may be fitted into the transparent frames 127a and 127b.

53 and 54 are diagrams illustrating an example of a process for forming a transparent body of a display device according to an embodiment of the present invention.

Referring to FIG. 53, a flat transparent body 120 in the shape of a slab may be provided. The transparent body 120 may be made of a transparent material. For example, the transparent body 120 may include glass. For example, the transparent body 120 may contain silicon dioxide. For example, the transparent body 120 may include plastic.

The transparent body 120 may be made of a translucent material. For example, the transparent body 120 may include translucent glass. Alternatively, the transparent body 120 may include a transparent material and a translucent material. The transparent body 120 may be made of, for example, a transparent material containing an opaque/translucent material. For example, the transparent body 120 may form both a transparent area and a translucent area.

The transparent body 120 may, for example, pass, diffract, refract, or reflect at least a portion of the incident light. The transparent body 120 may have a color, for example.

A mask (MSK) may be placed on the slab-shaped transparent body 120. The mask MSK may have a height and be located on one side of the transparent body 120 . The mask MSK may be positioned on the transparent body 120 along the edge of one side of the transparent body 120. The mask MSK may be placed on the transparent body 120 to form a partially open space.

The etching solution (ESL) may be contained in the space formed by the mask (MSK) and the transparent body 120. The etching solution (ESL) may chemically etch a region of the transparent body 120 exposed to the etching solution (ESL). The etching solution (ESL) may contain, for example, hydrofluoric acid. The mask MSK may have resistance to the etching solution ESL and thus protect the transparent body 120 from the etching solution ESL.

Although not shown in the drawing, the transparent body 120 may be etched, for example, by plasma etching. When plasma is applied to one side of the transparent body 120 with a mask (MSK) mounted on the transparent body 120, the area exposed to the plasma among the areas of the transparent body 120 is Can be etched. The mask MSK may have resistance to plasma and thus protect the transparent body 120 from plasma. Plasma may be, for example, atmospheric plasma.

After etching is performed, the mask MSK may be separated from the transparent body 120. The slab-shaped transparent body 120 may have a shape in which steps are formed after etching. The area facing the mask MSK may be a transparent flange 126. The area that has undergone an etching process by being exposed to an etching solution (ESL) may form one side 129a of the transparent board 129. For example, one side 129a of the transparent board 129 may be the front surface 129a of the transparent board 129. Due to etching, the thickness of the transparent flange 126 may be greater than the thickness of the transparent board 129.

The mask MSK may be placed on the other side of the transparent body 120. The other side of the transparent body 120 may refer to the rear side of the transparent body 120. The mask MSK may be placed on the back of the transparent body 120 to form a partially open space. The etching solution (ESL) may be contained in the space formed by the mask (MSK) and the transparent body 120 to etch a portion of the rear surface of the transparent body 120.

After etching is performed, the mask MSK may be separated from the transparent body 120. The rear surface of the transparent body 120 may have a step shape formed after etching. That is, the back side 129b of the transparent board 129 can be formed.

Referring to FIG. 54, a cross section of a flat transparent body 120 in the shape of a slab may appear. The thickness of the slab-shaped transparent body 120 may be T1. A portion of one surface of the slab-shaped transparent body 120 may be exposed to an etching solution, etc.

Among the areas of the transparent body 120, the area exposed to the etching solution may be a transparent board 129 having a thickness T2. Among the areas of the transparent body 120, the area protected from etching may be the transparent flange 126 having a thickness T1. Thickness T2 may be smaller than thickness T1.

The step formed between the transparent flange 126 and the transparent board 129 may have a thickness T3. Thickness T3 may correspond to the thickness of the display panel. For example, the thickness T3 may be slightly larger than the thickness of the display panel.

A portion of the other surface of the transparent body 120 may be exposed to an etching solution, etc. A portion of the other surface of the transparent body 120 may be etched to a thickness of T6 by the etching solution. Thickness T6 may be the same as or different from thickness T3. The transparent board 129 may have a thickness T7.

Figures 55 and 56 are diagrams showing another example of a process for forming a transparent body of a display device according to an embodiment of the present invention.

Referring to FIG. 55, a flat transparent plate 128 in the shape of a slab may be provided. The transparent plate 128 may be made of a transparent material. For example, the transparent plate 128 may allow at least a portion of the incident light to pass through. For example, the transparent plate 128 may have a color. For example, the transparent plate 128 may contain at least one of glass, plastic, crystal, and quartz. The transparent plate 128 may be made of a translucent material. For example, the transparent plate 128 may have a rough outer surface, causing light to be diffusely reflected.

The transparent plate 128 may include fibers to reinforce rigidity. For example, the transparent plate 128 may include at least one of glass fiber, carbon fiber, metal wire, and metal fiber. The transparent plate 128 may include micro fibers.

A first transparent frame 127a may be attached to one side of the transparent plate 128. A second transparent frame 127b may be attached to the other side of the transparent plate 128. The transparent frames 127a and 127b may be made of a transparent material. The transparent frames 127a and 127b may be made of the same material as the transparent plate 128.

For example, the transparent frames 127a and 127b may be made of a different material from the transparent plate 128. For example, the transparent frames 127a and 127b may have a different color, transparency, reflectivity, or refractive index than the transparent plate 128. For example, the transparent frames 127a and 127b may have a different rigidity than the transparent plate 128. For example, the transparent frames 127a and 127b may have outlines different from the transparent plate 128.

The transparent frames 127a and 127b may be combined with the transparent plate 128 to form a boundary line LB. The boundary line LB may be formed along the outer side of the transparent body 120. The boundary line LB may mean a boundary between the transparent plate 128 and the transparent frames 127a and 127b.

Referring to FIG. 56, a cross section of a flat transparent plate 128 in the shape of a slab can be seen. The thickness of the slab-shaped transparent plate 128 may be T7.

A first transparent frame 127a may be attached to one side of the transparent plate 128. For example, the first transparent frame 127a may be coupled to the transparent plate 128 with an adhesive. For example, the first transparent frame 127a may be coupled to the transparent plate 128 by heat. For example, the first transparent frame 127a may be coupled to the transparent plate 128 by pressure. For example, the first transparent frame 127a may be coupled to the transparent plate 128 using frit glass or frit glaze.

A second transparent frame 127b may be attached to the other side of the transparent plate 128. The method by which the second transparent frame 127b is coupled to the transparent plate 128 may include at least one of a plurality of methods by which the first transparent frame 127a is coupled to the transparent plate 128 listed above.

The first transparent frame 127a may have a thickness T3. The first transparent frame 127a may be surface treated to facilitate attachment to the transparent plate 128. Alternatively, at least a portion of one surface of the transparent plate 128 may be surface treated to facilitate attachment to the first transparent frame 127a.

The second transparent frame 127b may have a thickness T6. At least one of the second transparent frame 127b and the transparent plate 128 may be surface treated to facilitate attachment.

When the first transparent frame 127a and the transparent plate 128 are combined, a step may be formed on one side of the transparent body 120. The step formed on one side of the transparent body 120 may have a thickness T3. Thickness T3 may correspond to the thickness of the first display panel. For example, the thickness T3 may be slightly larger than the thickness of the first display panel.

When the second transparent frame 127b is combined with the transparent plate 128, a step may be formed on the other side of the transparent body 120. The step formed on the other side of the transparent body 120 may have a thickness T6. Thickness T6 may correspond to the thickness of the second display panel. For example, the thickness T6 may be slightly larger than the thickness of the second display panel. The transparent body 120 may have a thickness T1 at one point. Thickness T1 may be the thickest among the thicknesses at various points of the transparent body 120.

Figures 57 to 70 are diagrams showing examples of transparent bodies according to an embodiment of the present invention. Hereinafter, 'PCB accommodating part' may mean at least one of 'front PCB accommodating part' and 'rear PCB accommodating part'. Hereinafter, the 'cable accommodating part' may mean at least one of the 'front cable accommodating part' and the rear 'cable accommodating part'. Hereinafter, 'first accommodating part' may mean at least one of 'front first accommodating part' and 'rear first accommodating part'. Hereinafter, 'second accommodating part' may mean at least one of 'front second accommodating part' and 'rear second accommodating part'. Hereinafter, 'slot' may mean at least one of 'front slot' and 'rear slot'.

Hereinafter, the 'PCB accommodating part' may be referred to as a 'first accommodating part'. Hereinafter, the 'cable accommodating part' may be referred to as a 'second accommodating part'. Hereinafter, the 'front PCB accommodating part' may be referred to as the 'front first accommodating part'. Hereinafter, the 'rear PCB accommodating part' may be referred to as the 'rear first accommodating part'. The 'rear PCB accommodating part' can be referred to as the 'third accommodating part'.

Referring to FIG. 57 , the front PCB receiving portion 122a may be formed on one side of the transparent body 120. For example, the front PCB receiving portion 122a may be formed on one side of the transparent board 129. That is, the front PCB receiving portion 122a may be formed on the front of the transparent board 129. The front PCB receiving portion 122a can be observed from the front of the transparent body 120. The front PCB receiving portion 122a may be formed along a direction from the first short side 129SS1 to the second short side 129SS2 of the transparent board 129. The front PCB receiving portion 122a may be formed adjacent to one of the first long side 129aLS1 and the second long side 129aLS2 on the front of the transparent board 129. For example, the front PCB receiving portion 122a may be formed adjacent to the first long side 129aLS1 on the front of the transparent board 129.

The rear PCB receiving portion 122b may be formed on the other side of the transparent body 120. For example, the rear PCB receiving portion 122b may be formed on the other side of the transparent board 129. That is, the rear PCB receiving portion 122b may be formed on the rear of the transparent board 129. The rear PCB receiving portion 122b can be observed from the rear of the transparent body 120. The rear PCB receiving portion 122b may be formed parallel to the front PCB receiving portion 122a. The rear PCB receiving portion 122b may be formed adjacent to the second long side (not shown) of the rear of the transparent board 129. The rear PCB receiving portion 122b may be formed adjacent to the second long side 129aLS2 on the front of the transparent board 129.

The PCB receiving portions 122a and 122b may be formed by physical action. For example, the PCB receiving portions 122a and 122b may be formed by cutting using a mechanism having a rigidity greater than that of the transparent board 129. The PCB receiving portions 122a and 122b may be formed by chemical action. For example, the PCB receiving portions 122a and 122b may be formed by reacting with chemicals that act on the transparent board 129.

The PCB receiving portions 122a and 122b may accommodate at least a portion of the PCB connected to the display panels 110 and 130. For example, the front PCB accommodating portion 122a may accommodate at least a portion of the PCB connected to the first display panel 110. For example, the rear PCB accommodating portion 122b may accommodate at least a portion of the PCB connected to the second display panel 130.

The PCB receiving portions 122a and 122b may be formed to correspond to the shape of the PCB connected to the display panels 110 and 130. The PCB receiving portions 122a and 122b may have the shape of a groove.

Referring to a cross section cut along A-A' parallel to the longitudinal direction of the front PCB receiving portion 122a, the transparent flange 126 may have a thickness T1. The transparent board 129 may have a thickness T7. T7 may be smaller than T1. Thickness T1 may be the thickness of the outer side of the transparent body 120.

In the area where the front PCB receiving portion 122a is formed, the transparent board 129 may have a thickness T8a. The front of the transparent board 129 may be divided into an area where the front PCB receiving portion 122a is formed and a surrounding area. The area where the front PCB receiving portion 122a is formed may have a thinner thickness than the surrounding area. T8a may be smaller than T7.

Referring to a cross section cut along C-C' parallel to the longitudinal direction of the rear PCB accommodating portion 122b, the transparent board 129 may have a thickness T8b in the area where the rear PCB accommodating portion 122b is formed. The rear of the transparent board 129 may be divided into an area where the rear PCB receiving portion 122b is formed and a surrounding area. The area where the rear PCB receiving portion 122b is formed may have a thinner thickness than the surrounding area. T8b may be smaller than T7.

Referring to FIG. 58 , the front PCB receiving portion 122a may be formed on one side of the transparent body 120. The front PCB receiving portion 122a can be observed from the front of the transparent body 120. The front PCB receiving portion 122a may be formed on one side of the transparent plate 128. For example, the front PCB receiving portion 122a may be formed on the front of the transparent plate 128. The front PCB receiving portion 122a may be formed adjacent to one of the first long side 127aLS1 and the second long side 127aLS2 inside the first transparent frame 127a. For example, the front PCB receiving portion 122a may be formed adjacent to the first long side 127aLS1 inside the first transparent frame 127a. The front PCB receiving portion 122a may be formed along a direction from the first short side 127aSS1 inside the first transparent frame 127a toward the second short side 127aSS2.

The rear PCB receiving portion 122b may be formed on the rear of the transparent plate 128. The rear PCB receiving portion 122b may be formed adjacent to one of the first long side (not shown) and the second long side (not shown) inside the second transparent frame 127b. For example, the rear PCB receiving portion 122b may be formed adjacent to the second long side (not shown) inside the second transparent frame 127b. The rear PCB receiving portion 122b may be formed parallel to the front PCB receiving portion 122a.

The PCB receiving portions 122a and 122b may be located inside an area defined by edges formed inside the transparent frame 127. For example, the front PCB receiving portion 122a is located on the first long side 127aLS1, the first short side 127aSS1, the second long side 127aLS2, and the second short side 127aSS2 inside the first transparent frame 127a. It can be formed inside an area demarcated by For example, the rear PCB receiving portion 122b may be formed inside an area defined by each side inside the second transparent frame 127b.

The PCB receiving portions 122a and 122b may be formed by physical action. For example, the PCB receiving portions 122a and 122b may be formed by cutting using a mechanism having a rigidity greater than that of the transparent plate 128. The PCB receiving portions 122a and 122b may be formed through chemical action. For example, the PCB receiving portions 122a and 122b may be formed by reacting with chemicals acting on the transparent plate 128.

The front PCB receiving portion 122a may face the front of the transparent body 120. The rear PCB receiving portion 122b may face the rear of the transparent body 120. The PCB receiving portions 122a and 122b may accommodate at least a portion of the PCB connected to the display panels 110 and 130. The PCB receiving portions 122a and 122b may have the shape of a groove.

Referring to the cross section cut along A-A' parallel to the longitudinal direction of the front PCB receiving portion 122a, the thickness of the transparent plate 128 at one point in the area where the front PCB receiving portion 122a is formed may be T8a. . The thickness of the transparent plate 128 at a point around the front PCB receiving portion 122a may be T7. The outer side of the transparent body 120 may have a thickness T1.

Referring to a cross section cut along C-C' parallel to the longitudinal direction of the rear PCB receiving portion 122b, the thickness of the transparent plate 128 at one point in the area where the rear PCB receiving portion 122b is formed may be T8b. . The thickness of the transparent plate 128 at a point around the rear PCB receiving portion 122b may be T7.

Referring to FIG. 59 , the grinder GRD may form a groove on one side of the transparent body 120. For example, the PCB receiving portion 122 may be formed using a grinder (GRD). Although not shown in the drawing, the grinder (GRD) may form a hole on one side of the transparent body 120.

The grinder (GRD) may include a blade (BLD). The rigidity of the blade (BLD) may be greater than the rigidity of the transparent body 120. The blade (BLD) can rotate. The blade (BLD) can be connected to the motor (MTR) to receive rotational force. The blade (BLD) contacts one side of the transparent plate 128 and rotates to cut or grind the transparent plate 128. Although not shown in the drawing, the blade (BLD) may form a groove by applying rotational force to one side of the transparent board 129.

Referring to the cross section cut along A-A' parallel to the longitudinal direction of the front PCB receiving portion 122a, the blade BLD can reduce the thickness of the transparent plate 128. The thickness of the transparent board 129 in the area where the blade BLD is not applied may be T7. The thickness of the transparent board 129 in the area where the blade BLD is applied may be T8a. T8a may be smaller than T7.

Referring to FIG. 60, the front PCB accommodating portion 122a and the rear PCB accommodating portion 122b may be formed on the front and rear sides of the transparent plate 128, respectively. Referring to the cross section cut along A-A' parallel to the longitudinal direction of the front PCB accommodating part 122a and passing through the front PCB accommodating part 122a, the rear PCB accommodating part 122b is the front PCB accommodating part 122a. It can be formed at the location of . That is, the rear PCB accommodating part 122b may overlap the front PCB accommodating part 122a in the front and rear direction. Although not shown in the drawing, the front PCB accommodating part 122a may overlap the rear PCB accommodating part 122b on the transparent board 129 in the front-to-back direction.

The PCB receiving portions 122a and 122b have the shape of grooves or holes and may weaken the rigidity or support of the transparent body 120. The areas of the PCB receiving portions 122a and 122b may affect the rigidity or support capacity of the transparent body 120.

When the front PCB accommodating portion 122a overlaps the rear PCB accommodating portion 122b in the front and rear direction, an area in the transparent plate 128 where no groove or hole is formed can be easily secured.

Referring to FIG. 61, the PCB receiving portion 122 may be observed from the front or/and rear of the transparent body 120. The PCB receiving portion 122 may be observed from the front or/and rear of the transparent plate 122. The PCB receiving portion 122 may be a hole formed on one side of the transparent plate 128. Although not shown in the drawing, the PCB receiving portion 122 may be a hole formed on one side of the transparent board 129.

The PCB receiving portion 122 may be formed adjacent to the first long side 127aLS1 inside the first transparent frame 127a. The PCB receiving portion 122 may be formed along a direction from the first short side 127aSS1 inside the first transparent frame 127a toward the second short side 127aSS2. The PCB accommodating part 122 can be understood as a structure in which the front PCB accommodating part and the rear PCB accommodating part are in communication.

The PCB receiving portion 122 may be formed through physical processing. For example, the PCB receiving portion 122 may be formed using a grinder. For example, the PCB receiving portion 122 may be formed through NC processing.

The PCB receiving portion 122 may be formed through chemical processing. For example, the PCB receiving portion 122 may be formed by applying an etching solution to the transparent plate 128. For example, the PCB receiving portion 122 may be formed by applying plasma to the transparent plate 128.

Referring to the cross section cut along A-A' parallel to the longitudinal direction of the PCB receiving portion 122, the area where the PCB receiving portion 122 is formed may be a passage communicating between the front and rear of the transparent plate 128. .

Referring to FIG. 62, the front PCB receiving portions 122a and 123a can be observed from the front of the transparent plate 128. The front PCB receiving portions 122a and 123a may have the shape of a groove formed in the transparent plate 128. A plurality of front PCB receiving portions 122a and 123a may be provided. For example, the front PCB receiving portions 122a and 123a may include a lower front PCB receiving portion 122a and an upper front PCB receiving portion 123a.

The rear PCB receiving portions 122b and 123b can be observed from the rear of the transparent plate 128. The rear PCB receiving portions 122b and 123b may have the shape of a groove formed in the transparent plate 128. A plurality of rear PCB receiving portions 122b and 123b may be provided. For example, the rear PCB accommodating portions 122b and 123b may include a lower rear PCB accommodating portion 122b and an upper rear PCB accommodating portion 123b.

The lower front PCB accommodating part 122a and the upper front PCB accommodating part 123b may be arranged in series. The lower front PCB receiving portion 122a may be arranged in a long line with the upper front PCB receiving portion 123a. The lower front PCB receiving portion 122a and the upper front PCB receiving portion 123a may be formed adjacent to the first long side 127aLS1 inside the first transparent frame 127a. The lower front PCB accommodating portion 122a and the upper front PCB accommodating portion 123a may be sequentially arranged along a direction from the first short side 127aSS1 to the second short side 127aSS2 of the first transparent frame 127a. there is.

The lower rear PCB accommodating part 122b and the upper rear PCB accommodating part 123b may be arranged in series. The lower rear PCB accommodating portion 122b may be arranged in a long line with the upper rear PCB accommodating portion 123b. The lower rear PCB receiving portion 122b and the upper rear PCB receiving portion 123b may be formed adjacent to the second long side (not shown) inside the second transparent frame 127b. The lower rear PCB accommodating portion 122b and the upper rear PCB accommodating portion 123b are sequentially arranged along the direction from the first short side (not shown) to the second short side (not shown) of the second transparent frame 127b. It can be.

Referring to the cross section cut along A-A' passing through the front PCB accommodation portions 122a and 123a in the longitudinal direction of the front PCB accommodation portions 122a and 123a, the area where the front PCB accommodation portions 122a and 123a are formed is At one point transparent plate 128 may have a thickness T8a. The thickness of the transparent plate 128 at a point in the area where the lower front PCB accommodating part 122a is formed is the same as or different from the thickness of the transparent plate 128 at a point in the area where the upper front PCB accommodating part 123a is formed. You can.

Referring to a cross section cut along C-C' passing through the rear PCB accommodation portions 122b and 123b in the longitudinal direction of the rear PCB accommodation portions 122b and 123b, the area where the rear PCB accommodation portions 122b and 123b are formed is At one point transparent plate 128 may have a thickness T8b. The thickness of the transparent plate 128 at a point in the area where the lower rear PCB accommodating part 122b is formed is the same as or different from the thickness of the transparent plate 128 at a point in the area where the upper rear PCB accommodating part 123b is formed. You can.

The PCB receiving portions 122a, 122b, 123a, and 123b may be formed on one side of the transparent plate 128 by physical or/and chemical methods. For example, the PCB receiving portions 122a, 122b, 123a, and 123b may be formed by a laser.

Referring to FIG. 63, the PCB receiving portions 122 and 123 can be observed from the front and rear of the transparent plate 128. The PCB receiving portions 122 and 123 may be in the shape of holes formed in the transparent plate 128. A plurality of PCB receiving portions 122 and 123 may be provided. For example, the PCB accommodating parts 122 and 123 may include a lower PCB accommodating part 122 and an upper PCB accommodating part 123.

The lower PCB accommodating part 122 and the upper PCB accommodating part 123 may be arranged in series. The lower PCB accommodating part 122 may be arranged in a long line with the upper PCB accommodating part 123. The lower PCB accommodating part 122 and the upper PCB accommodating part 123 may be formed adjacent to the first long side 127aLS1 inside the first transparent frame 127a. The lower PCB accommodating portion 122 and the upper PCB accommodating portion 123 may be sequentially arranged along a direction from the first short side 127aSS1 inside the first transparent frame 127a toward the second short side 127aSS2. .

Referring to a cross section cut along A-A' passing through the PCB receiving portions 122 and 123 in the longitudinal direction of the PCB receiving portions 122 and 123, at one point of the area where the PCB receiving portions 122 and 123 are formed. The transparent plate 128 may communicate with the front and rear sides of the transparent plate 128 .

The PCB receiving portions 122 and 123 may be formed on one side of the transparent plate 128 by an optical method. For example, the PCB receiving portions 122 and 123 may be formed using a carbon dioxide laser.

Referring to FIG. 64, the front cable receiving portion 124a can be observed from the front of the transparent plate 128. The front cable receiving portion 124a may be in the shape of a groove formed on one side or the front of the transparent plate 128. The front cable receiving portion 124a may accommodate at least a portion of the cable connected to the PCB. The front cable receiving portion 124a may be located on one side of the transparent plate 128 or at the center of the front. The front cable receiving portion 124a may be spaced apart from the front PCB receiving portions 122a and 123a.

The rear cable receiving portion 124b can be observed from the rear of the transparent plate 128. The rear cable receiving portion 124b may be in the shape of a groove formed on the other side or rear of the transparent plate 128. The rear cable receiving portion 124b can accommodate at least a portion of the cable connected to the PCB. The rear cable receiving portion 124b may be located at the center of the other side or rear of the transparent plate 128. The rear cable accommodating portion 124b may be spaced apart from the rear PCB accommodating portion (not shown). The cable accommodating part 124 may refer to at least one of the rear cable accommodating part 124b and the front cable accommodating part 124a.

The front PCB accommodating portions 122a and 123a may be located between the front cable accommodating portion 124a and one side inside the first transparent frame 127a. For example, the front PCB accommodating portions 122a and 123a may be located between the front cable accommodating portion 124a and the first long side 127aLS1 inside the first transparent frame 127a.

The rear PCB accommodating part (not shown) may be located between the rear cable accommodating part 124b and one side inside the second transparent frame 127b. For example, the rear PCB accommodating part (not shown) may be located between the rear cable accommodating part 124b and the second long side (not shown) inside the second transparent frame 127b.

The front cable accommodating portion 124a may overlap with the rear cable accommodating portion 124b in the front-to-back direction. Through this configuration, the area of the transparent plate 128 that has a thin thickness due to the formation of grooves or holes can be minimized.

Referring to the cross section cut along B-B' passing through the cable receiving portion 124, the transparent plate 128 may have a thickness T10 at one point in the area where the cable receiving portion 124 is formed. The transparent plate 128 may form a step at the border of the cable receiving portion 124.

Referring to FIG. 65, the cable receiving portion 124 can be observed from the front of the transparent plate 128. The cable receiving portion 124 may be in the shape of a hole formed on one side of the transparent plate 128. The cable accommodating portion 124 may be understood as being formed by the front cable accommodating portion and the rear cable accommodating portion being in communication with each other. Although not shown in the drawing, the hole-shaped cable receiving portion 124 may be formed on the transparent board 129.

The cable accommodating portion 124 may accommodate at least a portion of the cable connected to the PCB. In particular, the cable accommodating portion 124 may accommodate at least a portion of the cable connected to the first display panel and at least a portion of the cable connected to the second display panel. The cable receiving portion 124 may be located at the center of the transparent plate 128. The cable receiving portion 124 may be spaced apart from the front PCB receiving portions 122a and 123a. Although not shown in the drawing, the cable receiving portion 124 may be spaced apart from the rear PCB receiving portion.

The front PCB accommodating portions 122a and 123a may be located between the cable accommodating portion 124 and one side inside the first transparent frame 127a. For example, the front PCB receiving portions 122a and 123a may be located between the cable receiving portion 124 and the first long side 127LS1 inside the first transparent frame 127a. The arrangement relationship of the rear PCB accommodating parts (122b, 123b), the cable accommodating part 124, and the second transparent frame (127b) is that of the front PCB accommodating parts (122a, 123a), the cable accommodating parts 124, and the first transparent frame. It may be the same as the placement trick in (127a).

Referring to the cross section cut along B-B' passing through the cable receiving portion 124, the transparent plate 128 can communicate with the front and rear of the transparent plate 128 in the area where the cable receiving portion 124 is formed. there is.

Since the hole-shaped cable receiving portion 124 may be formed in the center of the plate 128, the processing method may be problematic. A method may be devised to minimize the impact on the overall quality of the plate 128. For example, a hole may be formed in the center of the plate 128 using a high-power laser. The high-power laser may be, for example, a carbon dioxide laser or a Nd-YAG laser.

Referring to FIG. 66, the front slot 125a can be observed from at least a portion of the front of the transparent plate 128. The rear slot 125b can be observed at least in part behind the transparent plate 128. The slots 125a and 125b may refer to at least one of the front slot 125a and the rear slot 125b. Although not shown in the drawing, the slots 125a and 125b may be formed in the transparent board 129 or the transparent flange 126.

The slots 125a and 125b may have the shape of a hole. The slots 125a and 125b may be formed in the transparent body 120 at one point on one inner side of the transparent frames 127a and 127b. For example, the slots 125a and 125b may be formed at one point of the first short sides 127aSS1 and 127bSS1 inside the transparent frames 127a and 127b. The slots 125a and 125b may provide a space for the cable to pass through.

One side inside the transparent frame (127a, 127b) where the slots (125a, 125b) are formed may be connected to the other side adjacent to the PCB receiving portion (122a, 123a, 122b, 123b). For example, the first short side 127aSS1 inside the first transparent frame 127a may be connected to the first long side 127aLS1. For example, the first short side 127bSS1 inside the second transparent frame 127b may be connected to the second long side 127bLS1.

The front slot 125a may overlap with the rear slot 125b in the front-to-back direction. The overlap of the front slot 125a and the rear slot 125b may be related to the overlap of the front cable accommodating portion 124a and the rear cable accommodating portion 124b. Alternatively, the overlap of the front slot 125a and the rear slot 125b may be related to a structure in which the front cable accommodating portion 124a is formed integrally with the rear cable accommodating portion 124b to form the cable accommodating portion 124. there is.

The slots 125a and 125b may be formed by removing a portion of the transparent plate 128. Alternatively, the slots 125a and 125b may be formed by removing a portion of the transparent frame 127. Alternatively, the slots 125a and 125b may be formed by removing part of the transparent frame 127 and part of the transparent plate 128.

The slots 125a and 125b may be formed by bonding the transparent frames 127a and 127b to the transparent plate 128 on which a groove or hole is formed. Alternatively, the slots 125a and 125b may be formed by bonding the transparent plate 128 to the transparent frames 127a and 127b in which grooves are formed. Alternatively, the slots 125a and 127b may be formed by bonding the transparent frames 127a and 127b to the transparent plate 128 on which a bay-shaped curved portion is formed. In this case, the front slot 125a may be formed integrally with the rear slot 125b.

For example, the slots 125a and 125b may be formed by joining a transparent plate 128 in which a groove is formed and a transparent frame 127a and 127b. Here, the groove formed in the transparent plate 128 may be adjacent to a point on the first short side (127aSS1, 127bSS1).

Slots 125a and 125b may be open in both directions. For example, one end of the slots 125a and 125b may be open toward the cable receiving portion 124. For example, the other ends of the slots 125a and 125b may be open toward the side wall SW of the transparent body 120. The side wall (SW) may be a side wall (SW) adjacent to the first short side (127aSS1, 127bSS1) where the slots (125a, 125b) are located.

The direction in which the slots 125a and 125b are opened may correspond to the shape of the slots 125a and 125b. The path of the cable passing through the slots 125a and 125b may correspond to the open direction of the slot 125. For example, one end of the slots (125a, 125b) is open toward the cable receiving portion 124, and the other end of the slots (125a, 125b) is open toward the side wall (SW) adjacent to the first short side (127aSS1, 127bSS1). Then, the cable may extend from the cable receiving portion 124, enter one end of the slots 125a and 125b, pass through the other end of the slot 125, and head to the outside of the side wall (SW).

Referring to FIG. 67, the slot 125 may be observed at least in part in front and/or behind the transparent plate 128. The slot 125 may communicate with the front and side of the transparent plate 128. Additionally, the slot 125 may communicate with the rear and side of the transparent plate 128.

The slot 125 may be formed by joining the transparent frames 127a and 127b to the transparent plate 128 on which a bay-shaped curved portion is formed. Here, the curved portion may have a concave shape toward the side wall (SW) of the transparent body 120.

Referring to FIG. 68, the front slot 125a can be observed at least in part of the front of the transparent plate 128. The rear slot 125b can be observed at least in part of the rear of the transparent plate 128. The front slot 125a may communicate with the front of the transparent plate 128 and the side of the transparent body 120. The rear slot 125b may communicate with the rear of the transparent plate 128 and the side of the transparent body 120.

The slots 125a and 125b may be formed by joining transparent plates 128 to transparent frames 127a and 127b in which grooves are formed. The groove formed on the transparent frames 127a and 127b may have a shape that crosses the side of the point where the groove is formed. Grooves located in the transparent frames 127a and 127b may be formed using a grinder or chemical vision.

Referring to FIG. 69, the front slot 125a can be observed at least in part of the front of the transparent plate 128. The rear slot 125b can be observed at least in part of the rear of the transparent plate 128. The front slot 125a may communicate with the front of the transparent plate 128 and the side of the transparent body 120. The rear slot 125b may communicate with the rear of the transparent plate 128 and the side of the transparent body 120.

The slots 125a and 125b may be formed by joining transparent plates 128 with grooves to transparent frames 127a and 127b with grooves. The groove formed in the transparent frames 127a and 127b and/or the transparent plate 128 may have a shape that crosses the side of the point where the groove is formed. Grooves located in the transparent frames 127a and 127b and/or the transparent plate 128 may be formed using a grinder or chemical vision.

Referring to FIG. 70, auxiliary grooves (AXGU1, AXGU2, AXGU3, AXGU4, AXGU5, AXGU6, AXGD1, AXGD2, AXGD3, AXGD4, AXGD5, AXGD6) can be observed at least in part of the front of the transparent body 120. A plurality of auxiliary grooves (AXGU1, AXGU2, AXGU3, AXGU4, AXGU5, AXGU6, AXGD1, AXGD2, AXGD3, AXGD4, AXGD5, AXGD6) may be provided. The auxiliary grooves (AXGU1, AXGU2, AXGU3, AXGU4, AXGU5, AXGU6, AXGD1, AXGD2, AXGD3, AXGD4, AXGD5, AXGD6) are composed of the upper auxiliary grooves (AXGU1, AXGU2, AXGU3, AXGU4, AXGU5, AXGU6) and the lower auxiliary grooves ( AXGD1, AXGD2, AXGD3, AXGD4, AXGD5, AXGD6). Although not shown in the drawing, an auxiliary groove may be disposed at the rear of the transparent body 120.

The cable receiving portion 124 may be located between the auxiliary grooves (AXGU1, AXGU2, AXGU3, AXGU4, AXGU5, AXGU6, AXGD1, AXGD2, AXGD3, AXGD4, AXGD5, AXGD6). At least a portion of the auxiliary grooves (AXGU1, AXGU2, AXGU3, AXGU4, AXGU5, AXGU6, AXGD1, AXGD2, AXGD3, AXGD4, AXGD5, AXGD6) is on the other side connected to one side adjacent to the front PCB receiving portions 122a and 123a. Can be formed adjacent to each other. For example, the upper auxiliary grooves (AXGU1, AXGU2, AXGU3, AXGU4, AXGU5, AXGU6) are formed adjacent to the second short side (129SS2) connected to the first long side (129LS1) adjacent to the front PCB receiving portions (122a, 123a). It can be. For example, the lower auxiliary grooves (AXGD1, AXGD2, AXGD3, AXGD4, AXGD5, AXGD6) are formed adjacent to the first short side (129SS1) connected to the first long side (129LS1) adjacent to the front PCB receiving portions (122a, 123a). It can be.

The auxiliary grooves (AXGU1, AXGU2, AXGU3, AXGU4, AXGU5, AXGU6, AXGD1, AXGD2, AXGD3, AXGD4, AXGD5, AXGD6) may provide a space where at least a portion of the components extending from the display panel can be seated. Here, the component extending from the display panel may be a chip mounted on a film.

71 to 74 are diagrams showing examples of display panels according to an embodiment of the present invention.

Referring to FIG. 71, the display panels 110 and 130 may provide an image on one side. The display panels 110 and 130 may divide an image into a plurality of pixels and output an image with color, brightness, and saturation for each pixel. The display panels 110 and 130 may generate light corresponding to a color including at least one of red, green, and blue according to a control signal.

A member layer (MBL) may be connected to one side of the display panels 110 and 130. For example, the member layer MBL may be formed extending from the first long side 110LS1 of the first display panel 110. For example, the member layer MBL may be formed extending from the second long side 130LS2 of the second display panel 130.

The member layer (MBL) may include at least one of chip-on-film (COF), chip-on-glass (COG), FPCB, wire, and tape carrier package (TCP). The membership floor (MBL) can be flexible. A plurality of member layers (MBL) may be provided. The member layer MBL may be electrically connected to the display panels 110 and 130. The member layer (MBL) may supply power to the display panels 110 and 130. The pixels of the display panels 110 and 130 may be controlled by current provided to the display panels 110 and 130 through the member layer (MBL).

The cable SC may be electrically connected to the display panels 110 and 130. The cable SC may supply current to the display panels 110 and 130. The cable SC may supply electrical signals that control the pixels of the display panels 110 and 130 to the display panels 110 and 130. The cable (SC) may be electrically connected to the member layer (MBL).

The PCB (SP) may be electrically connected to the member layer (MBL). The PCB (SP) may be electrically connected to the cable (SC). The PCB (SP) may be relatively large compared to the member layer (MBL) and/or cable (SC). The PCB (SP) may occupy a certain volume on one side of the display panels 110 and 130. The thickness of the PCB (SP) may vary depending on the type and/or arrangement and/or shape of the electronic devices mounted on the PCB (SP). PCB (SP) may be a source PCB.

The member layer (MBL), PCB (SP), and cables may be classified according to the display panels 110 and 130 to which they are connected. For example, the member layer (MBL) connected to the first display panel 110 may be referred to as 'first member layer'. For example, the member layer (MBL) connected to the second display panel 130 may be referred to as a ‘second member layer.’ For example, the PCB (SP) connected to the first member layer may be referred to as the 'first PCB'. For example, the PCB (SP) connected to the second member layer may be referred to as 'second PCB'. For example, the cable (SC) connected to the first PCB may be referred to as the 'first cable'. For example, the cable (SC) connected to the second PCB may be referred to as a 'second cable'. Hereinafter, the member layer (MBL) may mean at least one of the first member layer and the second member layer. Hereinafter, PCB (SP) may mean at least one of the first PCB and the second PCB. Hereinafter, the cable SC may refer to at least one of the first cable and the second cable.

Referring to FIG. 72, a cross section of the display panels 110 and 130, a cross section of the member layer (MBL), a cross section of the PCB (SP), and a cross section of the cable (SC) are shown.

The display panels 110 and 130 may be connected to the member layer (MBL). The member layer (MBL) can connect the PCB (SP) and the display panel 110. The PCB (SP) may have a thickness greater than that of the display panels 110 and 130. The cable (SC) can be connected to the PCB (SP).

The cable (SC) may be electrically connected to the PCB (SP). The PCB (SP) may be electrically connected to the member layer (MBL). The member layer (MBL) may be electrically connected to the display panels 110 and 130. When two different elements are electrically connected, it may mean that transmission and reception of electrical signals and/or current is possible between the two different elements.

Referring to FIG. 73, the member layer (MBL) may be bent. Since the member layer (MBL) is flexible, it can be overlapped with the display panels 110 and 130. That is, at least a portion of the member layer (MBL) may overlap with the display panels 110 and 130. At least a portion of the member layer MBL may be located behind the display panels 110 and 130, for example.

The member layer MBL may extend from one side of the display panels 110 and 130 and may face the other side facing one side of the display panel 110 . For example, the member layer MBL may extend from the first long side 110LS1 of the first display panel 110 and face the second long side 110LS2. For example, the member layer MBL may be formed to extend from the second long side 130LS2 of the second display panel 130 and face the first long side 130LS1.

The PCB (SP) connected to the member layer (MBL) may be adjacent to one side of the display panels (110, 130) to be connected to the member layer (MBL). For example, the PCB (SP) may be located adjacent to the first long side 110LS1 of the first display panel 110. For example, the PCB (SP) may be located adjacent to the second long side 130LS2 of the second display panel 130.

The PCB (SP) may be located between the first long side 110LS1 and the second long side 110LS2 of the first display panel 110. Additionally, the PCB (SP) may be located between the second long side 130LS2 and the first long side 130LS1 of the second display panel 130. The cable (SC) connected to the PCB (SP) may extend from the member layer (MBL) toward the PCB (SP).

Referring to FIG. 74, the cable (SC) extending from the PCB (SP) may be bent. You can look at the arrangement relationship of the member layer (MBL), PCB (SP), and cable (SC). The member layer MBL may extend from one side of the display panels 110 and 130 and face the other side facing the one side. For example, the member layer MBL may extend from the first long side 110LS1 of the first display panel 110 and face the second long side 110LS2. For example, the member layer MBL may extend from the second long side 130LS2 of the second display panel 130 and face the first long side 130LS1.

The PCB (SP) is connected to the member layer (MBL) and may be closer to the other side of the display panel (110, 130) than the member layer (MBL). For example, the PCB (SP) may be closer to the second long side (110LS2) of the first display panel (110) than the member layer (MBL). For example, the PCB (SP) may be closer to the first long side (130LS1) of the second display panel (130) than the member layer (MBL).

The cable (SC) may be bent from the PCB (SP) toward the other side of the display panel (110, 130) and toward the side connected to the one side. For example, the cable SC may be bent toward the second long side 110LS2 of the first display panel 110 and toward the first short side 110SS1 connected to the first long side 110LS1. For example, the cable SC may be bent toward the first long side 130LS1 of the second display panel 130 and toward the first short side 130SS1 connected to the second long side 130LS2.

A region where the cable SC is bent may be formed. For example, the cable SC may form a bending area BA, which is an area where the cable SC is bent. In the bending area BA, a plurality of cables SC may be bent and stacked. The thickness formed by the laminated cable SC may be greatest in the bending area BA.

Although not shown in the drawing, the bent and extending cable SC may be connected to a controller that does not overlap the display panel 110 in the front-to-back direction. By bending the cable SC, the display panels 110 and 130 can have various attitudes.

The member layer (MBL), PCB (SP), and cable (SC) have an arrangement relationship based on one side of the display panel (110, 130) to which the member layer (MBL) is connected and the other side facing the one side. You can take a look. For example, the member layer (MBL), PCB (SP), and cable (SC) are connected from the first long side (110LS1) to the second long side (110LS2) of the first display panel 110 to which the member layer (MBL) is connected. They can be connected sequentially in the facing direction. For example, the member layer (MBL), PCB (SP), and cable (SC) connect the first long side (130LS1) to the second long side (130LS2) of the second display panel 130 to which the member layer (MBL) is connected. They can be connected sequentially in the facing direction.

Figures 75 to 77 are diagrams showing examples of combination relationships between components of a display device according to an embodiment of the present invention.

Referring to FIG. 75, the rear of the first display panel 110 may be coupled toward the front of the transparent body 120. For example, the first long side 110LS1, the first short side 110SS1, the second long side 110LS2, and the second short side 110SS2 of the first display panel 110 are inside the first transparent frame 127a. It can face the first long side (127aLS1), the first short side (127aSS1), the second long side (127aLS2), and the second short side (127aSS2).

The rear of the first touch panel TP1 may be coupled toward the front of the first display panel 110 . The first touch panel TP1 can obtain touch input. The first touch panel TP1 may be transparent. The first touch panel TP1 can pass at least a portion of the image displayed on the first display panel 110 . The first touch panel TP1 may correspond to the shape of the first display panel 110 .

The first touch panel cable (TPC1) may be formed to extend from one side of the first touch panel (TP1). The first touch panel cable TPC1 may be inserted into the front slot 125a. The first touch panel cable TPC1 may cross one side of the first display panel 110 between one side of the first touch panel TP1 and the front slot 125. For example, the first touch panel cable TPC1 may cross the first short side 110SS1 of the first display panel 110. The first touch panel cable (TPC1) may be located on the side of the first display panel 110. The first touch panel cable (TPC) inserted into the front slot 125a, although not shown in the drawing, may be electrically connected to a controller.

When the first display panel 110 is coupled to the transparent body 120, the first long side 127aLS1, the first short side 127aSS1, the second long side 127aLS2 inside the first transparent frame 127a, and The second short side 127aSS2 may be referred to as the first long side 110LS1, the first short side 110SS1, the second long side 110LS2, and the second short side 110SS2 of the first display panel 110. For example, the front PCB receiving portions 122a and 123a may be formed along the longitudinal direction of the first long side 110LS1 of the first display panel 110. For example, the front slot 125a may be formed adjacent to the first short side 110SS1 connected to the first long side 110LS1 of the first display panel 110.

At least a portion of the member layer (MBL), PCB (SP), and cable (SC) may be located on the rear side of the first display panel 110. At least a portion of the member layer (MBL), PCB (SP), and cable (SC) is connected to the first display panel 110 and the transparent plate 128 when the first display panel 110 and the transparent body 120 are combined. It can be located in between. The cable SC may be inserted into the front slot 125a.

Coupling members (FM1, FM2, and FM3) may be located on the front of the transparent plate 128. The coupling members FM1, FM2, and FM3 may have a thickness. For example, the thickness of the coupling members (FM1, FM2, FM3) may be greater than the thickness of the cable (SC). The coupling members FM1, FM2, and FM3 may be adhesive tapes or magnetic materials. The coupling members (FM1, FM2, FM3) may form a layer. For example, the coupling members FM1, FM2, and FM3 may be formed by laminating an adhesive tape and a magnetic material. A plurality of coupling members (FM1, FM2, FM3) may be provided. For example, the coupling members FM1, FM2, and FM3 may include a first coupling member FM1, a second coupling member FM2, and a third coupling member FM3.

The front PCB receiving portions 122a and 123a located on the front of the transparent plate 128 can accommodate at least a portion of the PCB (SP). Since the PCB (SP) is accommodated in the PCB (SP), the cable (SC) may be bent between the front PCB accommodating portion (122a) and the front slot (125a). The front PCB receiving portions 122a and 123a may have the shape of a groove or a hole.

The cable accommodating portion 124 located on the front of the transparent plate 128 may accommodate at least a portion of the cable SC. For example, the cable accommodation unit 124 may accommodate the cable SC forming the bending area BA. The cable receiving portion 124 may have a groove shape or a hole shape.

Referring to FIG. 76, the rear of the second display panel 130 may be coupled toward the rear of the transparent body 120. For example, the first long side 130LS1, the first short side 130SS1, the second long side 130LS2, and the second short side 130SS2 of the second display panel 130 are inside the second transparent frame 127b. It can face the first long side (127bLS1), the first short side (127bSS1), the second long side (127bLS2), and the second short side (127bSS2).

The rear of the second touch panel TP2 may be coupled toward the front of the second display panel 130 . The second touch panel TP2 can obtain touch input. The second touch panel TP2 may be transparent. The second touch panel TP2 can pass at least a portion of the image displayed on the second display panel 130. The second touch panel TP2 may correspond to the shape of the second display panel 130. The touch panel may refer to at least one of a first touch panel and a second touch panel.

The second touch panel cable (TPC2) may be formed to extend from one side of the second touch panel (TP2). The second touch panel cable TPC2 may be inserted into the front slot 125a. The second touch panel cable TPC2 may cross one side of the second display panel 130 between one side of the second touch panel TP2 and the front slot 125. For example, the second touch panel cable TPC2 may cross the first short side 130SS1 of the second display panel 130. The second touch panel cable (TPC2) may be located on the side of the second display panel 130. The second touch panel cable (TPC) inserted into the front slot 125a, although not shown in the drawing, may be electrically connected to a controller. The touch panel cable may refer to at least one of a first touch panel cable and a second touch cable.

When the second display panel 110 is coupled to the transparent body 120, the first long side 127bLS1, the first short side 127bSS1, the second long side 127bLS2 inside the second transparent frame 127b, and The second short side 127bSS2 may be referred to as the first long side 130LS1, the first short side 130SS1, the second long side 130LS2, and the second short side 130SS2 of the second display panel 130. For example, the rear PCB receiving portions 122b and 123b may be formed along the longitudinal direction of the second long side 130LS2 of the second display panel 130. For example, the rear slot 125b may be formed adjacent to the first short side 130SS1 connected to the second long side 130LS2 of the second display panel 130.

At least a portion of the member layer (MBL), PCB (SP), and cable (SC) may be located on the rear side of the second display panel 130. At least a portion of the member layer (MBL), PCB (SP), and cable (SC) is connected to the second display panel 130 and the transparent plate 128 when the second display panel 130 and the transparent body 120 are combined. It can be located in between. The cable SC may be inserted into the rear slot 125b.

Coupling members (FM4, FM5, FM6) may be located on the rear of the transparent plate 128. The coupling members (FM4, FM5, FM6) may have a thickness. For example, the thickness of the coupling members (FM4, FM5, and FM6) may be greater than the thickness of the cable (SC). The coupling members FM4, FM5, and FM6 may be adhesive tapes or magnetic materials. The bonding members (FM4, FM5, FM6) can form a layer. For example, the coupling members FM4, FM5, and FM6 may be formed by laminating an adhesive tape and a magnetic material. A plurality of coupling members (FM4, FM5, FM6) may be provided. For example, the coupling members FM4, FM5, and FM6 may include a fourth coupling member FM4, a fifth coupling member FM5, and a sixth coupling member FM6.

The rear PCB receiving portions 122b and 123b located on the rear of the transparent plate 128 can accommodate at least a portion of the PCB (SP). Since the PCB (SP) is accommodated in the PCB (SP), the cable (SC) can be bent between the rear PCB receiving portions (122b, 123b) and the rear slot (125b). The rear PCB receiving portions 122b and 123b may have the shape of a groove or a hole.

The cable accommodating portion 124 located at the rear of the transparent plate 128 may accommodate at least a portion of the cable SC. For example, the cable accommodation unit 124 may accommodate the cable SC forming the bending area BA. The cable receiving portion 124 may have a groove shape or a hole shape.

Referring to FIG. 77, an example of the combination of the display panels 110 and 130 and the transparent body 120 is shown in cross section. The member layer (MBL), PCB (SP), and cable (SC) may be located on the rear side of the display panels 110 and 130. The first touch panel TP1 may be located on the front of the first display panel 110 . The second touch panel TP2 may be located in the front of the second display panel 130.

The PCB (SP) may be positioned to be accommodated in the PCB receiving portions 122a and 122b. The bending area BA of the cable may be accommodated in the cable receiving portion 124. The coupling members FM3 and FM6 may couple the display panels 110 and 130 and the transparent plate 128.

Figures 78 to 81 are diagrams showing several examples of cross sections of a display device according to an embodiment of the present invention.

Referring to FIG. 78, the display panels 110 and 130 may be coupled to the transparent plate 128 by coupling members FM1 and FM4. The display panels 110 and 130 may be fitted into the transparent frames 127a and 127b. The first touch panel TP1 may be located on the front of the first display panel 110 . The second touch panel TP2 may be located in front of the second display panel 130.

The cable SC extends from one side of the first display panel 110 to the cable receiving portion 124, is bent in the cable receiving portion 124, and may be inserted into the front slot 125a. The cable SC may be bent while being inserted into the front slot 125a.

The front slot 125a may be open toward the outside of the side wall (SW) of the transparent body 120. The front slot 125a may be formed by coupling the first transparent frame 127a to the transparent plate 128 on which a groove is formed.

The cable SC extends from one side of the second display panel 130 to the cable receiving portion 124, is bent in the cable receiving portion 124, and may be inserted into the rear slot 125b.

The rear slot 125b may be open toward the outside of the side wall (SW) of the transparent body 120. The rear slot 125b may be formed by coupling the second transparent frame 127b to the transparent plate 128 on which a groove is formed.

The cable SC may pass through the slots 125a and 125b and be directed to the outside of the side wall SW of the transparent body 120. For example, the cable SC may pass through the slots 125a and 125b and fall under the transparent body 120. The cable SC directed to the outside of the transparent body 120 may be electrically connected to a controller (controller) not shown in the drawing.

The first touch panel cable TPC1 may extend from one side of the first touch panel TP1 and pass through the front slot 125a. The second touch panel cable TPC2 may extend from one side of the second touch panel TP2 and pass through the rear slot 125b. The touch panel cables TPC1 and TPC2 passing through the slots 125a and 125b may be directed to the outside of the side wall SW of the transparent body 120. The touch panel cables TPC1 and TPC2 facing outside the side wall SW of the transparent body 120 may be electrically connected to a controller not shown in the drawing.

Referring to FIG. 79, the display panels 110 and 130 may be coupled to the transparent plate 128 by coupling members FM1 and FM4. The display panels 110 and 130 may be fitted into the transparent frames 127a and 127b. The first touch panel TP1 may be located on the front of the first display panel 110 . The second touch panel TP2 may be located in front of the second display panel 130.

The cable SC extending from one side of the display panels 110 and 130 may be bent to form a bending area BA at the rear of the display panels 110 and 130. The cable SC in the bending area BA may be accommodated in the cable receiving portion 124 formed on one side of the transparent plate 128. The cable SC may extend from one side of the display panels 110 and 130 to the cable receiving portion 124 and may be bent in the cable receiving portion 124 and inserted into the slot 125 .

The slot 125 may be open toward the outside of the side wall (SW) of the transparent body 120. The slot 125 may be formed by combining the transparent frames 127a and 127b with the transparent plate 128 on which a bay-shaped curved portion is formed. The curved portion formed in the transparent plate 128 may have a concave shape with respect to the outside of the side wall (SW). The slot 125 may be understood as being formed by connecting the front slot and the rear slot.

The cable SC may be bent as it enters the slot 125. The section where the cable SC is bent as it enters the slot 125 may be short. The cable SC may be subjected to pressure by being positioned between the display panels 110 and 130 and the transparent plate 128 in the section from the cable receiving portion 124 to the slot 125. As the cable SC enters the slot 125, the pressure received from the transparent plate 128 may decrease or disappear. Because of this, the cable SC may be bent toward the rear of the display panels 110 and 130 as it enters the slot 125.

The cable SC may pass through the slot 125 and be directed to the outside and/or rear of the side wall SW of the transparent body 120. For example, the cable SC may pass through the slot 125 and fall under the transparent body 120. The cable SC directed to the outside of the transparent body 120 may be electrically connected to a controller (controller) not shown in the drawing.

The first touch panel cable (TPC1) may extend from one side of the first touch panel (TP1) and pass through the slot 125. The second touch panel cable (TPC2) may extend from one side of the second touch panel (TP2) and pass through the slot 125. The touch panel cables TPC1 and TPC2 that pass through the slot 125 may face the outside of the transparent body 120. The touch panel cables TPC1 and TPC2 facing outside of the transparent body 120 may be electrically connected to a controller not shown in the drawing.

Referring to FIG. 80, the display panels 110 and 130 may be coupled to the transparent plate 128 by coupling members FM1 and FM4. The display panels 110 and 130 may be fitted into the transparent frame 127. The first touch panel TP1 may be located on the front of the first display panel 110 . The second touch panel TP2 may be located in front of the second display panel 130.

The cable SC extends from one side of the first display panel 110 to the cable receiving portion 124, is bent in the cable receiving portion 124, and may be inserted into the front slot 125a. The front slot 125a may be open toward the outside of the side wall (SW) of the transparent body 120. The front slot 125a may be formed by coupling the transparent plate 128 to the first transparent frame 127a in which a groove is formed.

The cable SC extends from one side of the second display panel 130 to the cable receiving portion 124, is bent in the cable receiving portion 124, and may be inserted into the rear slot 125b. The rear slot 125b may be open toward the outside of the side wall (SW) of the transparent body 120. The rear slot 125b may be formed by coupling the transparent plate 128 to the second transparent frame 127b in which a groove is formed.

The cable SC may pass through the slots 125a and 125b and be directed to the outside of the side wall SW of the transparent body 120. For example, the cable SC may pass through the slots 125a and 125b and fall under the transparent body 120. The cable SC directed to the outside of the transparent body 120 may be electrically connected to a controller (controller) not shown in the drawing.

The first touch panel cable TPC1 may extend from one side of the first touch panel TP1 and pass through the front slot 125a. The second touch panel cable TPC2 may extend from one side of the second touch panel TP2 and pass through the rear slot 125b. The touch panel cables TPC1 and TPC2 passing through the slots 125a and 125b may be directed to the outside of the side wall SW of the transparent body 120. The touch panel cables TPC1 and TPC2 facing outside the side wall SW of the transparent body 120 may be electrically connected to a controller not shown in the drawing.

Referring to FIG. 81, the display panels 110 and 130 may be coupled to the transparent plate 128 by coupling members FM1 and FM4. The display panels 110 and 130 may be fitted into the transparent frames 127a and 127b. The first touch panel TP1 may be located on the front of the first display panel 110 . The second touch panel TP2 may be located in front of the second display panel 130.

The cable SC extends from one side of the first display panel 110 to the cable receiving portion 124, is bent in the cable receiving portion 124, and may be inserted into the front slot 125a. The cable (SC) may be bent while being inserted into the front slot (125a). The front slot 125a may be open toward the outside of the side wall (SW) of the transparent body 120. The front slot 125a may be formed by combining the first transparent frame 127a and the transparent plate 128 after each forming a groove.

The cable SC extends from one side of the second display panel 110 to the cable receiving portion 124, is bent in the cable receiving portion 124, and may be inserted into the rear slot 125b. The cable (SC) may be bent while being inserted into the rear slot (125b). The rear slot 125b may be open toward the outside of the side wall (SW) of the transparent body 120. The rear slot 125b may be formed by forming grooves in the second transparent frame 127b and the transparent plate 128 and then joining them.

The cable SC may pass through the slots 125a and 125b and be directed to the outside of the side wall SW of the transparent body 120. For example, the cable SC may pass through the slots 125a and 125b and fall under the transparent body 120. The cable SC directed to the outside of the side wall (SW) of the transparent body 120 may be electrically connected to a controller (controller) not shown in the drawing.

The first touch panel cable TPC1 may extend from one side of the first touch panel TP1 and pass through the front slot 125a. The second touch panel cable TPC2 may extend from one side of the second touch panel TP2 and pass through the rear slot 125b. The touch panel cables TPC1 and TPC2 passing through the slots 125a and 125b may be directed to the outside of the side wall SW of the transparent body 120. The touch panel cables TPC1 and TPC2 facing outside the side wall SW of the transparent body 120 may be electrically connected to a controller not shown in the drawing.

Any or other embodiments of the present invention described above are not exclusive or distinct from each other. In certain embodiments or other embodiments of the present invention described above, each configuration or function may be used in combination or combined.

The above detailed description should not be construed as restrictive in any respect and should be considered illustrative. The scope of the present invention should be determined by reasonable interpretation of the appended claims, and all changes within the equivalent scope of the present invention are included in the scope of the present invention.

100: display device 110: first display panel
120: transparent body 130: second display panel
122: PCB accommodating part 124: Cable accommodating part
125: slot 126: transparent flange
127: transparent frame 128: transparent plate
129: transparent board

Claims (15)

transparent plate;
a first display panel located on one side of the transparent plate;
a second display panel located on the other side of the transparent plate;
a first transparent frame located on one side of the transparent plate and adjacent to a side of the first display panel;
a second transparent frame located on the other side of the transparent plate and adjacent to a side of the second display panel;
a first receiving portion provided on the transparent plate and formed in the shape of a groove located on one surface of the transparent plate or in the shape of a hole penetrating the transparent plate;
a third receiving portion provided on the transparent plate and formed in the shape of a groove located on the other side of the transparent plate or in the shape of a hole penetrating the transparent plate;
a slot provided in the transparent plate, the first transparent frame, or the second transparent frame, and formed in a groove shape or a hole shape;
a first member layer connected to one side of the first display panel;
a second member layer connected to one side of the second display panel;
a first PCB connected to the first member layer and accommodated in the first accommodating portion;
a second PCB connected to the second member layer and accommodated in the third accommodating part;
a first cable extending from the first PCB and inserted into the slot; and,
A display device including a second cable extending from the second PCB and inserted into the slot. According to claim 1,
The first receiving part,
It is adjacent to one side of the first display panel and is formed along the longitudinal direction of one side of the first display panel,
The third receiving part,
It is adjacent to one side of the second display panel and is formed along the longitudinal direction of one side of the second display panel,
A display device wherein the first accommodating part faces the third accommodating part. According to claim 1,
The slot is,
A display device adjacent to other sides of the first and second display panels that meet one side of the first and second display panels. According to claim 1,
The slot is,
A display device connected to the outer surface of the transparent plate, the first transparent frame, or the second transparent frame. According to claim 1,
The slots are:
a first slot formed on one side of the transparent plate or the first transparent frame; and,
Further comprising a second slot formed on the other side of the transparent plate or the second transparent frame,
The first cable is inserted into the first slot,
The second cable is a display device inserted into the second slot. According to claim 5,
The first slot and the second slot are integrated into one and connected to an outer surface of the transparent plate, the first transparent frame, or the second transparent frame. According to claim 1,
The display device further includes a second accommodating part located between the first accommodating part and the third accommodating part and formed through the transparent plate. According to claim 7,
The first cable is a display device that faces each other through the second cable and the second accommodating part. According to claim 7,
The first cable and the second cable are each bent or folded in the second receiving portion. According to claim 7,
The first cable includes a first plurality of cables,
The second cable includes a second plurality of cables,
The first and second plurality of cables overlap while being bent or folded, respectively,
Overlapping portions of the first and second plurality of cables are located in the second receiving portion. According to claim 1,
A display device wherein the transparent plate and the first and second transparent frames are integrally formed. According to claim 1,
A display device in which a boundary line is formed between the transparent plate and the first transparent frame and between the transparent plate and the second transparent frame. According to claim 1,
a first touch panel located on an outer surface of the first display; and,
A display device further comprising a second touch panel located on an outer surface of the second display. According to claim 13,
a first touch panel cable connected to the first touch panel; and
Further comprising a second touch panel cable connected to the second touch panel,
The first and second touch panel cables are inserted into the slot. According to claim 14,
The first touch panel cable is inserted into the slot through a gap between a side of the first display panel and the first transparent frame,
The second touch panel cable is inserted into the slot through a side of the second display panel and the second transparent frame.

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