KR20240050035A - Vapor chamber and display device having the same - Google Patents

Abstract

This invention relates to a vapor chamber that dissipates heat using the phase change principle of a heat transfer medium in a vacuum state, wherein the vapor chamber has a size corresponding to the size of a large display panel and is composed of a multi-part or multi-compartment structure, and the large display panel It is attached in a form that covers the entire surface of one side, enabling efficient and uniform heat dissipation over the entire surface of the large display panel.

Description

Vapor chamber and display device having the same {Vapor chamber and display device having the same}

This invention relates to a vapor chamber that dissipates heat using the phase change principle of a heat transfer medium in a vacuum state. More specifically, it has a size corresponding to the size of a large display panel, but is composed of a multi-part or multi-compartment structure and is one of the large display panels. This relates to a vapor chamber that can be attached in a form that covers the entire surface of a large display panel, enabling efficient and uniform heat dissipation over the entire surface of a large display panel. Additionally, this invention also relates to a display device in which the vapor chamber as described above is attached and integrated to cover one entire surface of a large display panel.

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 these, display devices using organic light emitting diodes (OLED) have the advantage of having superior brightness and viewing angles compared to liquid crystal display devices and can be implemented in an ultra-thin form because they do not require a backlight unit.

Additionally, much research is being conducted on structures that can effectively remove heat generated when displaying high-definition images in large-screen, ultra-thin display devices. For example, as a heat dissipation structure, the vapor chamber can cool a heating element that generates high temperature heat.

Meanwhile, in recent years, display devices have tended to become larger, so when using the vapor chamber of the concept disclosed in Patent Registration No. 2304816, thermal damage to elements adjacent to the heating element can be prevented, but the display panel Heat dissipation on one entire surface is impossible. Therefore, a new concept vapor chamber is required.

Patent Registration No. 2304816

Therefore, this invention was developed to solve the problems of the prior art as described above, and has a size corresponding to the size of a large display panel, but is composed of a multi-segment or multi-compartment structure and covers the entire surface of one side of the large display panel. The purpose is to provide a vapor chamber that can be attached in a form that allows efficient and uniform heat dissipation over the entire surface of a large display panel.

Another object of the present invention is to provide a display device in which the vapor chamber described above is integrated so as to cover the entire surface of one side of a large display panel.

This invention to achieve the above object is a vapor chamber that dissipates heat using the phase change principle of a heat transfer medium in a vacuum state, wherein the vapor chamber has a size corresponding to the size of a large display panel and has a multi-divided or multi-compartment structure. It is composed of and is attached in a form that covers the entire surface of one side of the large display panel, enabling efficient and uniform heat dissipation over the entire surface of the large display panel.

Additionally, according to this invention, the vapor chamber may be divided into four or two divisions.

Additionally, according to this invention, the vapor chamber may be composed of four or two compartments.

Additionally, according to this invention, the vapor chamber includes an adhesive layer for attaching to the large display panel, and the adhesive layer may include a thermally conductive adhesive and a gap pad.

In addition, according to this invention, the vapor chamber has a stepped edge, and may further include an adhesive layer on the edge for close contact with the surface of the display panel.

Additionally, according to this invention, the adhesion layer may include a thermally conductive gap pad and graphite.

In order to achieve the above object, the display device of this invention has the vapor chamber attached in a form that covers the entire surface of one side of the large display panel, thereby efficiently and uniformly dissipating heat from the entire surface of the large display panel. It is characterized by this possibility.

The vapor chamber of this invention has a size corresponding to the size of a large display panel, but is composed of a multi-segment or multi-compartment structure and can be attached in a form that covers the entire surface of one side of the large display panel, making it efficient on the entire surface of the large display panel. However, uniform heat dissipation is possible.

Figure 1 is a conceptual diagram of the structural relationship of a general vapor chamber,
2 to 4 are conceptual diagrams of applying the vapor chamber according to the first embodiment of the present invention to the display panel of the display device;
5 to 7 are conceptual diagrams of applying the vapor chamber according to the second embodiment of the present invention to the display panel of the display device;
Figure 8 is a conceptual diagram of applying the vapor chamber according to the third embodiment of the present invention to the display panel of a display device.

Hereinafter, preferred embodiments of a vapor chamber and a display device equipped therewith according to the present invention will be described in detail with reference to the attached drawings. This invention is not limited to the embodiments disclosed below and may be implemented in various different forms, but these embodiments only serve to make the disclosure of this invention complete and to fully convey the scope of the invention to those skilled in the art. It is provided for information purposes only.

The vapor chamber of this invention, like a typical vapor chamber, serves to dissipate heat generated from the display panel of a display device using the phase change principle of the heat transfer medium in a vacuum state.

However, in recent years, there has been a trend to enlarge display devices, and heat dissipation for one entire surface of a large display panel is required. That is, in order to dissipate heat generated from a large display device (eg, large LED, OLED TV, etc.), it is necessary to attach and arrange a vapor chamber to cover one entire surface of the display panel. Meanwhile, as shown in FIG. 1, the vapor chamber requires a wick (including a sheet) capable of evaporation on one entire surface to enable efficient and rapid heat diffusion even when irregular local heat is generated from the display panel (heating element). However, the capillary force of the wick has a limit (approximately 300 to 400 mm) in its rising height due to gravity, causing problems in operation when heat is generated at the upper part of the large display panel.

Therefore, in this invention, the vapor chamber is configured to have a size corresponding to the size of the large display panel, but is configured in a multi-segment or multi-compartment structure to be closely fixed to the display panel.

2 to 4 are conceptual diagrams of applying the vapor chamber according to the first embodiment of the present invention to a display panel of a display device. As shown in FIGS. 2 to 4, the vapor chamber of this embodiment is divided into four parts to have a size corresponding to the size of the large display panel 200. Here, it is preferable that each of the four divided vapor chambers 100 be configured in a configuration relationship that will be described later. Meanwhile, each of the four divided vapor chambers 100 is attached to cover a corresponding portion of the display panel 200, ultimately covering one entire surface of the display panel 200. Here, each vapor chamber 100 is attached so as to cover a corresponding portion of the display panel 200, so that the display panel 200 and the vapor chamber 100 are connected using a thermally conductive adhesive, gap pad, etc. It is desirable to form an adhesive layer 120 that minimizes the air layer and contact heat resistance between the surfaces (see Figure 3). That is, each vapor chamber 100 has the adhesive layer 120 as described above on its back, and may be configured in the form of, for example, a double-sided adhesive tape.

Meanwhile, as will be described later, the vapor chamber 100 must be sealed in a vacuum state with an internal space (sheet, built-in heat transfer medium), so the edge portion (welded portion) has a stepped shape. Therefore, in order to solve the problem of the edge portion of the vapor chamber 100 not being in close contact with the surface of the display panel 200, the empty space is configured to have an additional adhesive layer 130 such as a thermally conductive gap pad and graphite. It is desirable to do so (see Figure 4). It is preferable that the adhesive layer 130 is applied in advance to the corresponding area of the display panel 200 where the edge of the vapor chamber 100 will be located (see FIG. 2).

Alternatively, the four divided vapor chambers 100 are welded to each other to form a shape corresponding to the size of the display panel 200, and the adhesive layer 130 as described above is applied to the step portion formed at the welded portion between each other. It can also be composed by applying it. Here, when the adhesive layer 130 is placed on the surface of the display panel 200, it is desirable to have a height that can be placed on the same or substantially similar surface as the adhesive layer 120.

The vapor chamber 100 of this embodiment is sealed to form an internal space in a vacuum state, and includes an external means 110 that can be adhered to the display panel 200, and an adhesive layer formed on one entire surface of the external means 110. (120), a heat transfer medium (not shown) filled in a part of the internal space of the external means 110, and one surface is in close contact with one inner surface of the external means 110 to drag the heat transfer medium in the opposite direction of gravity. It consists of a sheet (not shown) that is raised to enable condensation and evaporation. In addition, if necessary, it may further include a mesh member (not shown) in close contact with the other surface of the sheet and the other inner surface of the outer shape means 110.

The external means 110 uses two external members 111 and 112 to weld and seal each other to have an internal space in a vacuum state, so that the edge portion (welded portion) has a stepped shape. In addition, an adhesive layer 120 is formed on the entire surface of one of the two external members 111 and 112, and the adhesive layer 120 is used to bond the adhesive layer 120 to the surface of the display panel 200 through the adhesive layer 120. It is configured to be glued. Here, the adhesive layer 120 preferably uses a thermally conductive adhesive, a gap pad, etc. as described above to minimize the air layer and contact heat resistance between the display panel 200 and the vapor chamber.

In addition, the external means 110 is preferably configured to have an embossing portion inside the two external members 111 and 112 to prevent collapse during vacuum, and considering the characteristics of the vapor chamber 100, stainless steel is used as the basic material. It is desirable to use

The sheet has one surface in close contact with one inner surface of the external means 110 to pull the heat transfer medium in the opposite direction of gravity to enable condensation and evaporation, and can cover the entire inner surface of the vapor chamber 100. It is desirable to have a certain width. Such a sheet must have high absorption of the heat transfer medium, chemical resistance that does not react with the heat transfer medium, and a capillary force that lifts the heat transfer medium in the opposite direction of gravity.

Additionally, the sheet preferably has a large number of pores to have more efficient capillary force. Meanwhile, in this embodiment, the sheet may be an inorganic material, an organic material, or a mixed sheet of inorganic and organic materials that has been confirmed to have excellent absorbency and capillary force for heat transfer media.

The mesh member is in close contact with the other surface of the sheet and the other inner surface of the external shape means 110 to fix the sheet, and as heat is released to the outside, the condensed heat transfer medium flows smoothly along the sheet toward the evaporation part of the heat source. It plays the role of providing a passageway for easy movement. Therefore, it is desirable to configure the mesh member to have the same width as the sheet. It is preferable to use STS 304, 316, and 430 materials that have a mesh structure and have high strength and excellent corrosion resistance for these mesh members.

The heat transfer medium is inserted into a portion of the internal space of the external means 110, absorbs heat generated in the evaporation part of the heat source, evaporates, and exchanges heat with the atmosphere in the condensation part of the external member in contact with the external air, thereby generating heat. is released, and condenses from the vapor state back to the liquid state and moves to the evaporation unit. Therefore, it is desirable to use a heat transfer medium that satisfies the above conditions. For example, water can be used as a heat transfer medium.

On the other hand, when inserting a heat transfer medium into a part of the internal space of the external means 110, a hole is drilled on one side of the external member, and a copper tube through which the heat transfer medium can be injected is welded (brazed) into the drilled hole, Simply inject the heat transfer medium through the connected copper pipe. Then, when the heat transfer medium is injected in this way, the heat transfer medium is cooled, and forced exhaust is applied through the copper tube with a vacuum pump, and then the copper tube is sealed and air cooled at room temperature, so that the inside has a certain degree of vacuum.

As shown in FIGS. 2 to 4, the display device of this embodiment includes a display panel 200 that displays a screen. The display panel 200 applicable to this embodiment can be applied to all products that generate heat from the display panel itself, such as advertising panels, including various large TVs (OLED, QLED, LED, etc.).

5 to 7 are conceptual diagrams of applying a vapor chamber according to a second embodiment of the present invention to a display panel of a display device. As shown in FIGS. 5 to 7, the vapor chamber 300 of this embodiment has a size corresponding to the size of the large display panel 200 and is composed of four compartments, each of which functions as a vapor chamber. Since it is the same or similar to the first embodiment except for what is configured to have it, detailed description thereof will be omitted. That is, each compartment of the vapor chamber 300 of this embodiment is configured the same as the vapor chamber 100 of the first embodiment and performs the same function.

On the other hand, the vapor chamber 300 of this embodiment has a welded portion dividing the compartment as shown in FIG. 6 in the same vertical direction as the vapor chamber 100 of the first embodiment, so that the first embodiment Likewise, it must be constructed to have an adhesive layer on the stepped area. However, as shown in FIG. 7, when the area where the display panel 200 is in close contact is not stepped and has a structure in which a compartment is formed by welding in a stepped shape only on the opposite side, it is necessary to provide a separate adhesive layer. In addition, it is possible to configure the entire surface of the vapor chamber 300 to which the display panel 200 is in close contact with an adhesive layer (one adhesive layer).

Meanwhile, the vapor chamber of this embodiment can also be composed of two compartments with the same concept as above.

Figure 8 is a conceptual diagram of applying the vapor chamber according to the third embodiment of the present invention to the display panel of a display device. As shown in FIG. 8, the vapor chamber 400 of this embodiment is divided into two to have a size corresponding to the size of the large display panel 200. Since the concept is the same as the first embodiment, The detailed explanation is omitted.

In the previously described embodiments, examples in which the vapor chamber is composed of 4 divisions, 2 divisions, or 4 or 2 compartments were described, but the vapor chamber is divided into 2 divisions (3, 5, 6, 8 divisions, etc.) or 2 compartments ( It can be configured with 3, 5, 6, 8 compartments, etc.). In addition, it is divided into squares or structured into compartments, but it can also be configured in the form of triangles, polygons, etc., if necessary.

As described above, since the internal space of the vapor chamber of this embodiment is in a vacuum state, the heat transfer medium repeats evaporation and condensation at a low temperature, allowing the heat generated in the display panel to be released more efficiently. In addition, the vapor chamber of this embodiment dissipates heat using the phase change principle of the heat transfer medium, and heat diffusion occurs through convection currents generated by the air pressure difference due to the phase change, thereby taking heat generated from the display panel at a faster rate, making it more efficient. Heat dissipation is possible. In addition, the vapor chamber of this embodiment has a size corresponding to the size of the large display panel and is composed of a multi-segment or multi-compartment structure, so that it can be attached in a form that covers the entire surface of one side of the large display panel. Efficient and uniform heat dissipation is possible.

In the above, the technical details of the vapor chamber of this invention and the display device equipped with the same have been described together with the accompanying drawings, but this is an exemplary explanation of the best embodiment of this invention. Therefore, this invention is not limited to the embodiments described above, and it is obvious to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the invention, and such modifications Examples or modifications may also fall within the scope of the claims of this invention.

100: Vapor chamber 110: Appearance means
111, 112: External member 120: Adhesive layer
130: Adhesion layer 200: Display panel

Claims (7)

In a vapor chamber that dissipates heat using the phase change principle of the heat transfer medium in a vacuum state,
The vapor chamber has a size corresponding to the size of the large display panel and is composed of a multi-segment or multi-compartment structure, and is attached in a form to cover one entire surface of the large display panel, so that it covers the entire surface of the large display panel. A vapor chamber characterized by efficient and uniform heat dissipation. In claim 1,
The vapor chamber is characterized in that the vapor chamber is divided into four or two divisions. In claim 1,
The vapor chamber is characterized in that it consists of four or two compartments. In claim 1,
The vapor chamber includes an adhesive layer for attachment to the large display panel,
The vapor chamber is characterized in that the adhesive layer includes a thermally conductive adhesive and a gap pad. In claim 1,
The vapor chamber has a stepped edge, and further includes an adhesive layer on the edge to adhere to the surface of the display panel. In claim 5,
The vapor chamber is characterized in that the adhesion layer includes a thermally conductive gap pad and graphite. The vapor chamber according to any one of claims 1 to 6 is attached in a form that covers the entire surface of one side of the large display panel, enabling efficient and uniform heat dissipation from the entire surface of the large display panel. Display device.