KR102186244B1 - Graphene thermal diffusion sheet and method for manufacturing the same - Google Patents

Abstract

The present invention relates to a heat radiation sheet, and in particular, to a graphene heat radiation sheet and a method of manufacturing the same. In the present invention, in the manufacturing method of the graphene heat dissipation sheet, the steps of preparing graphene oxide; Preparing a surface-modified graphene with improved dispersion of graphene; Preparing a mixed material obtained by mixing the graphene oxide and the surface-modified graphene; And forming a film using the mixed material.

Description

Graphene thermal diffusion sheet and method for manufacturing the same}

The present invention relates to a heat radiation sheet, and in particular, to a graphene heat radiation sheet and a method of manufacturing the same.

Materials composed of carbon atoms include fullerene, carbon nanotubes, graphene, and graphite. Among them, graphene is a structure in which carbon atoms are formed in a single layer on a two-dimensional plane.

In particular, graphene is not only very stable and excellent in electrical, mechanical, and chemical properties, but also as an excellent conductive material, it can move electrons much faster than silicon and allow a much larger current to flow than copper. As the method of separating was discovered, it was proved through experiments, and many studies are being conducted to date.

Such graphene can be formed in a large area, has electrical, mechanical, and chemical stability, as well as excellent conductivity properties, and thus is attracting attention as a basic material for electronic circuits.

In addition, since the electrical properties of graphene can generally change according to the crystal orientation of graphene of a given thickness, a user can express electrical properties in a selected direction, and accordingly, a device can be easily designed. Therefore, graphene can be effectively used in carbon-based electric or electromagnetic devices.

As described above, since graphene has excellent heat conduction properties, it can be applied to a heat dissipating material that emits heat.

However, since defects may occur in graphene during the manufacturing process, there is a need for a method to improve thermal conduction characteristics by minimizing such defects or by minimizing the effect of defects.

The technical problem to be achieved by the present invention is to provide a graphene heat dissipation sheet and a method for manufacturing the same, which can effectively transmit and release heat generated from a heat source by manufacturing graphene with fewer defects.

As a first point of view for achieving the above technical problem, in a method of manufacturing a graphene heat dissipation sheet, the method comprising: preparing graphene oxide; Preparing a surface-modified graphene with improved dispersion of graphene; Preparing a mixed material obtained by mixing the graphene oxide and the surface-modified graphene; And forming a film using the mixed material.

Here, the surface-modified graphene may be prepared by pulverizing expanded graphite.

Here, the process of preparing the surface-modified graphene may include acid treatment of graphene.

In this case, the acid treatment may include at least one of hydrochloric acid treatment, nitric acid reflux, piranha solution treatment, and treatment using aqueous ammonia and hydrogen peroxide.

Here, the content of the surface-modified graphene may be 50 to 80 wt% compared to the graphene oxide.

Here, the step of preparing the mixed material may be performed by mixing graphene oxide dispersed in a solvent and surface-modified graphene dispersed in a solvent.

Here, the step of heat-treating the film; And it may further include the step of rolling the film.

The heat dissipation sheet manufactured through the process described above can be obtained.

As a second point of view for achieving the above technical problem, in the graphene heat dissipation sheet, graphene oxide; And a surface-modified graphene mixed with the graphene oxide in an amount of 50 to 80 wt%.

The present invention has the following effects.

First, the heat dissipation sheet of the present invention is attached to a heat source so that heat generated from the heat source can be efficiently discharged.

Specifically, the heat dissipation layer included in the heat dissipation sheet is attached to a heat source by an adhesive layer to release heat generated from the heat source, and at this time, the adhesive layer is attached to the heat source so that heat generated from the heat source is transferred to the heat dissipation layer I can.

The heat dissipation layer can dissipate heat particularly in the lateral direction, and thus more effectively dissipate heat generated from the heat source.

In addition, by mixing graphene oxide and surface-modified graphene together to prepare a heat dissipating sheet, overall thermal conductivity may be improved by graphene having relatively small defects.

That is, in manufacturing the graphene heat dissipation sheet, it is possible to form high quality with suppressed occurrence of defects, thereby further improving the heat dissipation characteristics of the heat dissipation sheet.

1 is a flowchart showing an example of a method of manufacturing a graphene heat dissipating sheet of the present invention.
2 is a schematic diagram showing an example of graphene oxide.
3 is a schematic diagram showing an example of surface-modified graphene.
4 is a schematic diagram showing an example of a graphene heat dissipation sheet.

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

While the present invention allows various modifications and variations, specific embodiments thereof are illustrated and shown in the drawings, and will be described in detail below. However, it is not intended to limit the present invention to the particular form disclosed, but rather the present invention encompasses all modifications, equivalents and substitutions consistent with the spirit of the present invention as defined by the claims.

When an element such as a layer, region or substrate is referred to as being “on” another component, it will be understood that it may exist directly on another element or there may be intermediate elements between them. .

Although terms such as first, second, etc. may be used to describe various elements, components, regions, layers and/or regions, these elements, components, regions, layers and/or regions It will be understood that it should not be limited by these terms.

In addition, the processes described in the present invention are not necessarily meant to be applied in order. For example, when the first step and the second step are described, it can be understood that the first step is not necessarily performed before the second step.

1 is a flow chart showing an example of a method of manufacturing a graphene heat dissipation sheet of the present invention.

As shown in Fig. 1, the process of manufacturing a graphene heat dissipation sheet includes the steps of manufacturing graphene oxide (S10), manufacturing surface-modified graphene (S20), and manufacturing a mixed material (S30). ) And forming a film (S40).

Graphene 11 is a material consisting of a single layer of a hexagonal structure of carbon atoms, and is a material having excellent thermal conductivity and electrical conductivity due to abundant pi electrons on the plane side.

Graphene oxide refers to a state in which carbon particles are oxidized by an acid. Graphene oxide can be prepared by oxidizing graphite with a strong acid such as sulfuric acid. In some cases, a substance in which sulfuric acid and hydrogen peroxide water are mixed may be used for oxidation.

Graphite has a plate-like structure, and is oxidized when a strong acid is added to such graphite, and graphene oxide is a state in which such graphite is chemically manufactured in a small particle state.

Since graphene oxide has a nonconducting property and a thermal conductivity of several tens of W/mK, it can effectively transfer heat generated from a heat source.

The graphene oxide may exist in a state in which an oxygen functional group (eg, an epoxy group, a carbonyl group, a carboxyl group, etc.) and/or an oxidizing agent or a strong acid are adsorbed during the manufacturing process. That is, as shown in FIG. 2, oxygen functional groups 11 may exist on the surface of the graphene oxide 10.

In addition, these oxygen functional groups 11 may also be adsorbed on both sides and ends of each layer of graphene oxide 10. Therefore, when the graphene oxide 10 is formed as a heat dissipating layer by forming a multilayer, such oxygen functional groups 11 may exist between each layer and the layer.

The graphene oxide 10 is excellent in hydrophilicity, so it is easy to disperse in water, and thus it can be easily manufactured in a layered structure. That is, it may be easy to prepare a film by coating the hydrophilic graphene oxide 10 in a dispersed state in water.

3 is a schematic diagram showing an example of surface-modified graphene.

Separately from the step (S10) of preparing the graphene oxide described above, the step (S20) of preparing the surface-modified graphene 20 may be performed. That is, unlike FIG. 1, the step (S20) of preparing the surface-modified graphene 20 may be performed prior to or simultaneously with the step (S10) of preparing the graphene oxide.

Surface-modified graphene 20 refers to graphene having improved dispersibility by oxidizing graphene.

In general, graphene (not oxide graphene) has low hydrophilicity, so dispersion in a solvent such as water may be difficult. However, if such graphene is treated with an acid, hydrophilicity is improved, and dispersibility can be improved.

The surface-modified graphene 20 may be manufactured by pulverizing expanded graphite.

In addition, as described above, the pulverized expanded graphite may be treated with acid to produce surface-modified graphene 20.

An example of a method of surface modification by treating the pulverized expanded graphite with an acid is as follows. Any one of these methods may be used, and at least two or more of these methods may be used. At this time, it goes without saying that conditions such as time and temperature below may be changed.

1. Stirring for 2 hours using hydrochloric acid

2. Reflux for 48 hours using nitric acid

3. Stir for 5 hours using a piranha solution (a solution in which sulfuric acid and hydrogen peroxide are mixed at 7:3)

4. Stir for 5 hours at 80 ℃ in a mixed solution of ammonia water and hydrogen peroxide at 5:5

Through this process, it is possible to manufacture the surface-modified graphene 20 as shown in FIG. 3. As shown, the surface-modified graphene 20 may have a multilayer structure, and at this time, the oxygen functional group 21 may not be located between each layer and the layer.

The heat dissipation sheet using graphene may also be manufactured using only the graphene oxide (10). That is, it can be produced by coating a solution in which the graphene oxide 10 is dispersed on a substrate.

However, in the case of fabricating a heat dissipation sheet using only the graphene oxide 10 as described above, as described above, a large amount of oxygen functional groups may be distributed, thereby reducing thermal conductivity. In addition, defects may occur in the graphene oxide 10 due to chemicals such as oxidizing agents or chemicals that terminate the reaction.

That is, when only the graphene oxide 10 is used, the thermal conductivity may be lowered due to defects that may occur on the end or surface of the graphene oxide 10.

Therefore, when a heat dissipation sheet is manufactured by mixing the surface-modified graphene 20 described above together with the graphene oxide 10, the overall thermal conductivity can be improved by the graphene 20 having relatively small defects. .

At this time, the content of the surface-modified graphene 20 may be 50 to 80 wt% compared to the graphene oxide 10.

In this way, in order to prepare a heat dissipation sheet by mixing the graphene oxide 10 and the surface-modified graphene 20, a mixed material may be prepared (S30). That is, a material in which the graphene oxide 10 and the surface-modified graphene 20 are mixed may be prepared first.

The process of manufacturing such a mixed material (S30) may be performed by adding the surface-modified graphene 20 dispersed in water or other solvent to the graphene oxide 10.

In addition, it may be performed by mixing the graphene oxide 10 and the surface-modified graphene 20 each dispersed in a solvent with each other.

A film can be formed by coating a substrate using such a mixed material (S40). Various coating methods may be used for coating the substrate.

Thereafter, a process of drying such a film may be performed.

In addition, the film may be heat-treated to improve the crystallinity of graphene, and finally, a graphene heat-radiating sheet may be manufactured by rolling.

Thereafter, a process of cutting the graphene heat dissipation sheet manufactured in this way into a product size so that it can be applied to a product may be performed.

In addition, a protective layer may be formed or attached to one side of the graphene film, or an adhesive layer may be formed or attached on the other side of the heat dissipating sheet to be directly attached to a product to prepare a heat dissipating sheet.

Such an adhesive layer may play a role of effectively transferring heat generated from the heat source to the heat dissipating layer while minimizing the distance between the heat source and the heat source as well as the adhesion property to the heat source.

In addition, the protective layer may be formed by coating on the graphene film in order to prevent the material forming the graphene film from falling off. However, in addition to such drop-out prevention properties, it is possible to improve radiation properties. In addition, in some cases, insulating properties can be improved.

4 is a schematic diagram showing an example of a graphene heat dissipation sheet.

As shown, in the heat dissipation sheet 100, a surface-modified graphene 20 may be positioned between the graphene oxide 10 and the graphene oxide 10 to be configured.

Alternatively, it may be configured such that the graphene oxide 10 is very well between the surface-modified graphene 20.

At this time, as described above, since the surface-modified graphene 20 may not have an oxygen functional group or the like between the layer and the layer, the heat dissipation sheet 100 including the surface-modified graphene 20 has a thermal conductivity characteristic. Dispersibility during manufacturing can be improved without affecting.

In addition, the heat dissipation sheet 100 including the surface-modified graphene 20 may have improved thermal conductivity compared to a heat dissipation sheet made of only graphene oxide 10.

At this time, the content of the surface-modified graphene 20 may be 50 to 80 wt% compared to the graphene oxide 10, as mentioned above.

Graphene is a material consisting of a single layer of a hexagonal structure, and is a material having excellent thermal conductivity and electrical conductivity due to the abundance of pi electrons on the plane side. Such graphene has a very high thermal conductivity of 3000 to 5000 W/mK. Since it is high, it is possible to effectively dissipate heat transferred from a heat source through the graphene oxide 10 and the surface-modified graphene 20.

In addition, as described above, in manufacturing such a graphene heat dissipation sheet, it is possible to form high quality with suppressed occurrence of defects, thereby further improving the heat dissipation characteristics of the heat dissipation sheet 100.

On the other hand, the embodiments of the present invention disclosed in the specification and drawings are only presented specific examples to aid understanding, and are not intended to limit the scope of the present invention. In addition to the embodiments disclosed herein, it is apparent to those of ordinary skill in the art that other modified examples based on the technical idea of the present invention may be implemented.

10: graphene oxide 11: oxygen functional group
20: surface modified graphene 21: oxygen functional group
100: graphene heat dissipation sheet

Claims (9)

In the manufacturing method of the graphene heat radiation sheet,
Preparing graphene oxide;
Preparing a surface-modified graphene with improved dispersion of graphene;
Preparing a mixed material obtained by mixing the graphene oxide and the surface-modified graphene; And
Consisting of including the step of forming a film using the mixed material,
The surface-modified graphene is produced by pulverizing expanded graphite and treating the pulverized expanded graphite with acid,
The graphene oxide forms a multilayer structure, and such oxygen functional groups are located between each layer and the layer,
The surface-modified graphene is a method of manufacturing a graphene heat dissipation sheet, characterized in that it forms a multi-layer structure in which oxygen functional groups are not located between each layer of the multi-layer structure. delete delete The method of claim 1, wherein the acid treatment includes at least one of hydrochloric acid treatment, nitric acid reflux, pyranha solution treatment, and treatment using aqueous ammonia and hydrogen peroxide. The method of claim 1, wherein the content of the surface-modified graphene is 50 to 80 wt% compared to the graphene oxide. The method of claim 1, wherein the preparing of the mixed material comprises mixing graphene oxide dispersed in a solvent and surface-modified graphene dispersed in a solvent with each other. The method of claim 5, further comprising: heat-treating the film; And
Graphene heat dissipation sheet manufacturing method, characterized in that it further comprises the step of rolling the film. delete In the graphene heat dissipation sheet,
Graphene oxide; And
Consisting of the graphene oxide and the surface-modified graphene mixed in 50 to 80 wt%,
The graphene oxide forms a multilayer structure, and such oxygen functional groups are located between each layer and the layer,
The surface-modified graphene is a graphene heat dissipation sheet, characterized in that it forms a multi-layered structure in which oxygen functional groups are not located between each layer and the layer of the multi-layered structure.

Images