KR100827377B1 - Heat radiating sheet and method for manufacturing the same, and backlight unit with the same - Google Patents

Abstract

The present invention discloses a method of manufacturing a heat dissipation sheet that can be attached to a reflective sheet without damage and can continuously perform an endothermic function. The method for manufacturing a heat dissipation sheet according to the present invention includes the steps of forming an nano-composite by adding an acrylic resin to nano-sized fine graphite powder particles; And compressing the nanocomposite formed by the fine graphite powder particles and the acrylic resin, and in this method, adding a resin having excellent thermal conductivity to the nanocomposite formed by the fine graphite powder particles and the acrylic resin before the pressing step. It may further include.

Backlight device, heat dissipation sheet, nanocomposite

Description

Heat radiating sheet and method for manufacturing the same, and backlight unit with the same}

1 is a cross-sectional view showing a relationship between a light source and a reflecting plate constituting a general backlight device.

Figure 2 schematically shows a direct type backlight device comprising a heat dissipation sheet according to the present invention.

3 is a perspective view showing a relationship between the reflector and the heat dissipation sheet shown in FIG.

The present invention relates to a heat dissipation sheet and a method for manufacturing the same, and more particularly to a method for producing a heat dissipation sheet having excellent ductility and strength.

In general, a liquid crystal display device (hereinafter, referred to as an LCD device) is an electronic device that changes and transmits electrical information generated by various devices to visual information by using a change in liquid crystal transmittance according to an applied voltage. to be.

Such LCD elements do not have their own light sources as display elements for various information as described above, and therefore, a separate device is required to illuminate the entire screen of the LCD elements by installing a light source at the rear thereof. As a device that satisfies such a condition, a back light unit that provides light to a screen of an LCD element is used.

The backlight device has a direct light method where the lamp is located under the liquid crystal panel and an edge-light method where the lamp is located on the side of the light guide plate, depending on the location where the cold cathode fluorescent lamp is installed. Separated by.

1 is a cross-sectional view schematically showing a backlight device of a conventional liquid crystal display device.

1 illustrates an edge-light backlight device 100, which includes a light source unit 110, a light guide plate 120, a reflective sheet 130, and an optical film 140.

The light source unit 110 includes one or more cold cathode fluorescent lamps 112 and a mounting unit 114 for generating light of a predetermined wavelength. Light generated by the cold cathode fluorescent lamp 112 is reflected by the mounting unit 114 and the reflective sheet 130 formed of a reflector, and then the reflected light is reflected on the entire light guide plate 120 as shown in FIG. 1. It spreads uniformly over.

The optical film 140 includes a diffuser plate 142, a prism sheet 144, a protective sheet 146, and a reflective polarizing film 148, and the reflective polarizing film 148 is optionally used.

The function of each component constituting the optical film 140 will be described briefly as follows.

Light uniformly diffused in the light guide plate 120 passes through the diffuser plate 142, and the diffuser plate 142 diffuses or condenses the light that has passed through the light guide plate 120 to make the luminance uniform and widen the viewing angle. .

The light passing through the diffusion plate 142 is sharply lowered in brightness, the prism sheet 144 is used to prevent this. The prism sheet 144 refracts the light emitted from the diffuser plate 142 so that the light incident at a low angle is concentrated toward the front, thereby increasing the luminance in the effective viewing angle range.

The protective sheet 146 is positioned on the prism sheet 144 to prevent scratches of the prism sheet 144 and to widen the viewing angle narrowed by the prism sheet 144.

On the other hand, the LCD device (not shown) positioned on the optical film 140 has a property of transmitting only a part of the light emitted from the optical film 140. For example, longitudinal waves (P waves) are transmitted and transverse waves (S waves) are absorbed. Therefore, the reflective polarizing film 148 is used to utilize the absorbed shear wave.

The reflective polarizing film 148 reflects a horizontal wave (S wave) of light diffused by the protective sheet 146 in the direction of the light guide plate 120, and the vertical wave (P wave) is provided to the LCD device (not shown).

The reflected shear wave is reflected back by the light guide plate 120 or the reflective sheet 130. In this case, the reflected shear wave is changed back to light including the longitudinal wave and the shear wave by re-reflection. The changed light passes through the diffuser plate 142, the prism sheet 144, and the protective sheet 146 and is reincident to the reflective polarizing film 148. In the backlight device 100, light efficiency may be improved through the above process.

On the other hand, unlike the edge-lighting backlight device, in the direct type backlight device, the reflective sheet is positioned under the light source unit, and in this structure, most of the heat generated from the light source unit is transferred to the reflective sheet. Since the reflective sheet is overheated by the transferred heat, there is a concern that deformation of the reflective sheet may occur.

An object of the present invention is to solve the above problems occurring in the backlight device, and to provide a heat dissipation sheet and a method of manufacturing the same that can effectively absorb the heat transferred to the reflective sheet.

Another object of the present invention is to provide a backlight device including a heat radiation sheet.

In general, a heat dissipation sheet for dissipating generated heat is used in a plasma display device and a computer, and in the present invention, the concept of a heat dissipation sheet that performs this function is applied to a backlight device.

The method for manufacturing a heat dissipation sheet according to the present invention includes the steps of forming an nano-composite by adding an acrylic resin to nano-sized fine graphite powder particles; And compressing the nanocomposite formed by the fine graphite powder particles and the acrylic resin, and further comprising adding a resin having excellent thermal conductivity to the nanocomposite formed by the fine graphite powder particles and the acrylic resin before the pressing step. Can be.

In addition, the heat dissipation sheet according to the present invention is characterized in that the nanocomposite formed by the nano-size fine graphite particles and the acrylic resin is formed by pressing in a high temperature state.

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

FIG. 2 is a view showing a part of the direct type backlight device according to the present invention, and the same reference numerals are assigned to the same members as those constituting the backlight device of FIG. 1.

In the direct type backlight device according to the present invention, a light source unit 110 including a plurality of cold cathode fluorescent lamps 112 installed in the mounting unit 114 is installed under the light guide plate 120, and The reflective sheet 130 is provided below.

The reflective sheet 130 disposed under the light source unit 110 reflects the light leaked from the light guide plate 120 back to the light guide plate 120. On the other hand, heat generated in the light source unit 110 in the process of generating light is transmitted to the reflective sheet 130 located below.

The biggest feature of the backlight device according to the present invention is that the heat dissipation sheet 150 is installed below the reflective sheet 130 to dissipate heat transferred to the reflective sheet 130.

3 is a perspective view illustrating the relationship between the reflective sheet and the heat dissipation sheet shown in FIG. 2. In the present invention, as shown in FIG. 3, the heat dissipation sheet 150 may be attached to the bottom of the reflective sheet 130 through the adhesive 160. Alternatively, the heat dissipation sheet layer may be formed on the bottom surface of the reflective sheet 130.

The heat radiation sheet 150, which absorbs heat transferred to the reflective sheet 130 and releases it to the outside of the device, is made of graphite having excellent thermal conductivity. The heat radiation sheet 150 having the shape shown in FIG. 3 is manufactured by pressing graphite under high temperature conditions.

The heat dissipation sheet 150 may effectively absorb heat transferred to the reflective sheet 130 because of excellent thermal conductivity, but has a disadvantage in that the heat dissipation sheet 150 is easily broken due to the physical properties of the material (graphite) and the processing process of high temperature compression.

As shown in FIG. 3, when the heat dissipation sheet 150 is broken (broken) in the state where the heat dissipation sheet 150 is attached to the reflective sheet 130 through the adhesive 160, the heat dissipation sheet 150 is peeled off from the reflective sheet 130. As a result, many effects may be caused on the heat absorption and heat dissipation function of the reflective sheet 130.

As described above, the heat dissipation sheet 150 is easily broken because the heat dissipation sheet is manufactured using graphite powder as a main component. Since the graphite powder is press-molded, the bonding force (adhesive force) between the powder particles is small, so that its shape is easily deformed and broken by external impact.

The heat radiation sheet and the manufacturing method for preventing the above phenomenon by the material constituting the heat radiation sheet will be described in detail.

The main components constituting the heat dissipation sheet according to the first embodiment of the present invention are graphite powder and a binder. That is, graphite powder is mixed with a viscous binder, and the mixture is applied to the bottom surface of the reflective sheet (130 in FIG. 2).

The binder used in the present invention is polyurethane, and the physical and chemical properties of the polyurethane are as follows.

Polyurethane is a rubber-like elastic body of a polymer compound having a urethane bond -OCONH- in a molecule, and its use range has recently been expanded such as urethane rubber, synthetic fiber, adhesive, paint, urethane foam, and automobile bumper. Generally, it manufactures by addition polymerization of diol (1, 4- butanediol etc.) and diisocyanate (diphenylmethane diisocyanate etc.). As a rubber use, aliphatic polyester of polyetherdiol, such as polyethyleneglycol and polypropylene glycol, or terminal diol, is used as a diol. As a use of a urethane foam, it adds triisocyanate and makes it thermosetting in many cases.

After the graphite powder is mixed with the polyurethane in the form of a paste, the mixture is coated on the bottom of the reflective sheet, whereby a heat dissipation sheet having a predetermined thickness is formed on the bottom of the reflective sheet.

Graphite, which is a main component of the heat dissipation sheet, absorbs heat from the reflection sheet, and polyurethane integrates graphite powder particles. Therefore, even if an external impact is applied to the heat radiation sheet, the bonding of the graphite powder particles is not released by the polyurethane, that is, the heat radiation sheet is not broken.

Meanwhile, copper (Cu) or silver (Ag) may be added to improve the ductility of the mixture of graphite powder and polyurethane.

Before describing the heat dissipation sheet and the method of manufacturing the same according to the second embodiment of the present invention, the nanocomposite material is briefly described.

Nano composite is a mixture of two or more constituents, with the chemical, physical, and chemical properties of each constituent being combined while maintaining chemically distinct constituents. It is a material that is artificially constructed to complement each other to obtain better properties than when the individual components are separated.

In general, the constituent materials of the composite material for structural materials can be divided into two types: matrix and reinforcement. The base has the function of bonding the reinforcement to each other, protecting the reinforcement from the outside and maintaining the shape of the composite material, and has a continuous structure in the composite material. The reinforcement, on the other hand, supports external stresses so that the composite material exhibits better mechanical properties than the matrix and is a constituent material in the form of particles, whiskers or fibers dispersed within the matrix.

There are three types of composite materials, depending on the type of matrix: polymer matrix composites based on polymer materials such as epoxy, metal matrix composites based on metals and alloys, and It is classified as a ceramic matrix composite with a ceramic matrix.

In composite materials based on metals or ceramics, carbon fibers, silicon carbide fibers, and alumina fibers are used as reinforcing fibers for the purpose of lightening and increasing the strength of the materials. These materials are used for high temperature special applications where polymer composite materials can be applied. Used.

On the other hand, nano composite material refers to a composite material using nano particles, such as carbon nanofibers, carbon nanotubes, silicon carbide (SiC) as a reinforcing material, such a reinforcing material is mechanical, thermal, electrical Since the characteristics are excellent, there are advantages that various functions can be implemented.

The second embodiment of the present invention uses the characteristics of the nanocomposite material as described above, and will be described in detail as follows.

First, the graphite powder is processed into nano-sized fine particles, and an acrylic resin is added to the fine graphite particles to form a nano-composite.

As such, the nanocomposite formed by uniformly dispersing the acrylic resin in the fine graphite powder particles has excellent thermal stability, mechanical properties (ductility and tensile strength), heat deformation temperature, and dimension resistance.

 Thereafter, the nano-composite formed by the fine graphite powder particles and the acrylic resin is compressed in a high temperature state to form a final heat dissipation sheet.

On the other hand, the resin excellent in thermal conductivity can be added to a mixture before performing a high temperature crimping process.

The heat dissipation sheet manufactured according to the second embodiment as described above is excellent in thermal stability, mechanical properties (ductility and tensile strength) as well as thermal conductivity, so that the heat of the reflective sheet can be effectively absorbed and released.

The heat dissipation sheet manufactured according to the present invention as described above can effectively perform the basic function of absorbing heat and dissipating heat of the reflective sheet, and can prevent damage such as breakage, thereby maintaining the shape of the heat dissipation sheet continuously. .

Preferred embodiments of the invention described above have been disclosed for purposes of illustration. Therefore, those skilled in the art having ordinary knowledge of the present invention will be capable of various modifications, changes, and additions within the spirit and scope of the present invention, and such modifications, changes and additions should be regarded as belonging to the following claims.

Claims (4)

In the manufacturing method of a heat radiation sheet, Forming a nano-composite by adding an acrylic resin to nano-sized fine graphite particles; And And pressing the nanocomposite formed by the fine graphite particles and the acrylic resin. delete A backlight device manufactured by the method of claim 1 and including a heat dissipation sheet disposed below the reflective sheet. A heat dissipating sheet, characterized by pressing and forming a nanocomposite formed by nano-sized fine graphite particles and an acrylic resin.

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