JP2013093447A - Heat radiation structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a heat radiation structure which dramatically improves heat radiation performance even when fastening is not conducted between a heating element and a radiator or the fastening pressure is small.SOLUTION: A heat radiation structure includes: a CPU 1; a heat sink 4; and an expanded graphite sheet 2 disposed between the CPU 1 and the heat sink 4. An adhesive layer 3 including graphitized carbon exists between the CPU 1 and the expanded graphite sheet 2.

Description

  The present invention relates to a heat dissipation structure capable of improving the heat conduction between a heating element and a heat dissipation element.

  A heat sink such as a heat sink is used to cool a heat generating element such as a CPU used in a computer. However, when the adhesion between the heat generating element and the heat dissipating element is poor, the thermal conductivity between the two decreases. As a result, the cooling performance of the heating element decreases. In order to prevent such a decrease in cooling performance, a sheet having excellent adhesion between the heat generating element and the heat radiating body and having thermal conductivity is generally disposed between the heat generating element and the heat radiating element.

  Here, a graphite sheet is used as the sheet, and the sheet is pressed and attached in a state of being sandwiched between a heat generator and a heat radiator. With such a structure, the unevenness present on the surface of the heating element and the heat dissipation body bites into the graphite sheet, so that there is no gap between the heating element and the graphite sheet and between the graphite sheet and the heat dissipation element. Therefore, the thermal resistance at the contact portion can be reduced, and the cooling efficiency can be improved.

  Here, the force for sandwiching the graphite sheet between the heat generating element and the heat radiating element depends on the force for attaching the heat radiating element to the heat generating element. However, when a CPU or the like is used as the heat generating element, the internal chip is subjected to a large stress on the CPU or the like. May be damaged. For this reason, it is desirable to regulate so that the force which attaches a heat radiator to a heat generating body may become as low as possible. However, if the force to attach the radiator to the heating element is too low, the unevenness present on the surface of the heating element and the radiator cannot sufficiently penetrate into the graphite sheet. In this state, a large number of voids remain. For this reason, the thermal resistance between a heat generating body and a heat radiator becomes large, and the problem that cooling efficiency falls arises.

  In order to solve such a problem, a proposal has been made to arrange an expanded graphite sheet between a heating element and a radiator (see Patent Document 1 below). In addition, proposals have been made to dispose silicon grease containing expanded graphite between the heat generator and the heat radiator.

JP 2006-286684 A

  If it is a proposal of the said patent document 1, heat dissipation will improve compared with the case where a graphite sheet is arrange | positioned between a heat generating body and a heat radiator. However, even when an expanded graphite sheet is disposed between the heating element and the radiator, it is necessary to apply a certain amount of clamping pressure with the expanded graphite sheet sandwiched between the heating element and the radiator. In addition, a certain degree of strength is required for the heating element and the like, and when the strength of the heating element and the like is insufficient and sufficient tightening pressure cannot be applied, there is a problem in that heat dissipation is reduced. . Moreover, even if it is a proposal which arrange | positions the silicon grease containing expanded graphite between a heat generating body and a heat radiator, it had the same subject.

  In view of the above circumstances, the present invention provides a heat dissipation structure that can dramatically improve heat dissipation even when the heating element and the heat dissipation element are not tightened or when the tightening pressure is small. The purpose is to provide.

  In order to achieve the above object, the present invention is a heat dissipation structure comprising a heating element, a radiator, and an expanded graphite sheet disposed between the heating element and the radiator, An adhesive layer containing graphitized carbon exists between the expanded graphite sheet and / or between the heating element and the expanded graphite sheet.

  If the adhesive layer is present as in the above configuration, the adhesion between the heat radiator and the expanded graphite sheet and / or the adhesion between the heat generator and the expanded graphite sheet is improved, so that Further, it is possible to suppress the presence of an air layer inferior in heat conduction. Therefore, since the heat of the heat generating element can be sufficiently transmitted to the heat radiating element, the temperature rise of the heat generating element is suppressed. Here, the graphitized carbon is included in the adhesive layer because the heat conduction in the adhesive layer is insufficient only in the case where carbonized carbon is included in the adhesive layer. This is because the heat dissipation performance cannot be improved dramatically.

The heat-resistant temperature of the radiator is preferably higher than the graphitization temperature, and the adhesive layer is preferably present between the radiator and the expanded graphite sheet.
In general, since the heat generating element has a low heat-resistant temperature, it is often difficult to provide an adhesive layer between the heat generating element and the expanded graphite sheet. Therefore, it is desirable to provide an adhesive layer between the heat radiator and the expanded graphite sheet. However, if the heat-resistant temperature of the radiator is low, problems such as deformation of the radiator occur, and therefore the heat-resistant temperature of the radiator is restricted to be higher than the graphitization temperature. The graphitization temperature is generally 2000 to 2800 ° C.

It is desirable that the expanded graphite sheet has a bulk density of 1.0 Mg / m ³ or less.
If the bulk density is regulated in this way, it is easily compressed even if the applied pressure is small, so that the adhesion between the expanded graphite sheet and the member in contact therewith becomes high. Therefore, the heat conduction from the heat generating element to the heat radiating element can be improved (the thermal resistance is reduced), and the effect of cooling the heat generating element is enhanced. In particular, when there is an adhesive layer only between the radiator and the expanded graphite sheet, and there is no adhesive layer between the heating element and the expanded graphite sheet, the heat conduction between the heating element and the expanded graphite sheet However, if the bulk density is regulated as described above, it is possible to suppress a decrease in heat conduction between the heating element and the expanded graphite sheet. Similarly, when there is an adhesive layer only between the heating element and the expanded graphite sheet, and there is no adhesive layer between the radiator and the expanded graphite sheet, the heat between the radiator and the expanded graphite sheet Although conduction | electrical_connection falls, if a bulk density is controlled as mentioned above, the fall of the heat conduction between a heat radiator and an expanded graphite sheet can be suppressed. It is more preferable to regulate the bulk density of the expanded graphite sheet to be 0.7 Mg / m ³ or less.

  According to the present invention, it is possible to dramatically improve the heat dissipation in the heat dissipation structure even when the tightening is not performed between the heating element and the heat dissipation body, or even when the tightening pressure is small. Excellent effect.

It is explanatory drawing which showed an example of the thermal radiation structure of this invention. It is explanatory drawing which showed the other example of the thermal radiation structure of this invention.

Embodiments of the present invention will be described below.
The heat dissipating structure of the present invention includes a heat generating body composed of a CPU of a computer, a heat dissipating body such as a heat sink and a fan, an expanded graphite sheet disposed between the heat generating body and the heat dissipating body, and the expanded graphite sheet. And an adhesive layer that adheres the radiator.

The expanded graphite sheet is obtained by immersing natural graphite, cache graphite, or the like in a liquid such as sulfuric acid or nitric acid, and then performing heat treatment at 400 ° C. or higher to form expanded graphite in a sheet shape. The expanded graphite sheet is preferably formed so as to have a thickness of 0.05 to 5.0 mm and a bulk density of 1.0 Mg / m ³ or less.
The expanded graphite is worm-like or fibrous, that is, its axial length is longer than its radial length. For example, its axial length is about 1 mm, and its radial direction is The length is about 300 μm. And in the inside of an expanded graphite sheet, the above expanded graphite exists in the state which was entangled.

  The expanded graphite sheet may be formed only from expanded graphite as described above, but a binder such as a phenol resin or a rubber component may be mixed slightly (for example, about 5% by mass). Moreover, the method of forming an expanded graphite sheet from expanded graphite as described above is not particularly limited.

  Here, in the expanded graphite sheet formed from expanded graphite as described above, the heat conduction improves as the bulk density increases, while the flexibility decreases. For this reason, the bulk density of the expanded graphite sheet is adjusted according to the application. Normally, the heat transfer sheet is configured to increase the bulk density with emphasis on heat conduction, whereas the one used as a heat insulating material such as a wall or an electromagnetic shielding material has a low bulk density. Composed.

  Therefore, when considering the expanded graphite sheet used in the present invention, it is desirable to select in consideration of both flexibility and thermal conductivity. This is because if the thermal conductivity is inferior, the original function of the expanded graphite sheet cannot be fully exerted, so the heat of the heating element such as the CPU cannot be sufficiently transferred to the heat radiating body, while the lack of flexibility, This is because it is impossible to suppress the presence of an air layer inferior in heat conduction in the heat transfer path, so that the heat of the heating element cannot be sufficiently transferred to the heat dissipation element.

In consideration of the above, by limiting the bulk density of the expanded graphite sheet to 1.0 Mg / m ³ or less (preferably 0.7 Mg / m ³ or less), the flexibility of the expanded graphite sheet can be secured. Thus, it is possible to suppress the presence of an air layer in the heat transfer path by providing followability to the unevenness. However, when the bulk density of the expanded graphite sheet is less than 0.3 Mg / m ³ , the flexibility of the expanded graphite sheet is high, but the heat conduction in the surface direction of the expanded graphite sheet decreases, and the cooling efficiency of the heating element decreases. Or the strength of the expanded graphite sheet may decrease, and the workability at the time of mounting the expanded graphite sheet may decrease. Accordingly, the bulk density of the expanded graphite sheet is desirably 0.3 Mg / m ³ or more.

  When an adhesive layer is disposed not only between the heat radiator and the expanded graphite sheet, but also between the heat generator and the expanded graphite sheet, the presence of the adhesive layer causes the heat radiator and the expanded graphite sheet to It is possible to suppress the formation of an air layer not only between the heating element but also between the heating element and the expanded graphite sheet. Therefore, in such a configuration, it is only necessary to place importance on thermal conductivity when selecting an expanded graphite sheet.

Next, considering from the viewpoint of the applied pressure to the expanded graphite sheet, the applied pressure to the expanded graphite sheet is preferably 0.3 MPa or more and 10.0 MPa or less.
This is because if the pressure applied to the expanded graphite sheet is less than 0.3 MPa, the deformation of the expanded graphite sheet becomes insufficient, and the adhesion between the expanded graphite sheet and the heating element cannot be sufficiently improved, As a result of being unable to suppress the presence of an air layer having poor heat conduction in the heat transfer path, the heating element may not be sufficiently cooled. On the other hand, if the pressure applied to the expanded graphite sheet exceeds 10.0 MPa, the heating element may be damaged. However, when an adhesive layer is disposed not only between the heat radiator and the expanded graphite sheet, but also between the heat generator and the expanded graphite sheet, the heat sink and the heat generator expand due to the presence of the adhesive layer. It is possible to suppress the formation of an air layer between the graphite sheet. Therefore, the pressure applied to the expanded graphite sheet may be extremely small.

Furthermore, considering from the viewpoint of the thickness of the expanded graphite sheet, the thickness of the expanded graphite sheet is preferably 0.1 mm or more and 3.0 mm or less.
This is because when the thickness of the expanded graphite sheet exceeds 3.0 mm, the expanded graphite sheet becomes stronger, but the thermal conductivity of the expanded graphite sheet decreases, and the cooling efficiency of the heating element may decrease. On the other hand, if the thickness of the expanded graphite sheet is less than 0.1 mm, the thermal conductivity of the expanded graphite sheet increases, but the strength of the expanded graphite sheet decreases and the workability at the time of mounting the expanded graphite sheet decreases. It is because there are times when it is.

Next, the adhesive layer was formed as follows. First, carbon cement (for example, KC-300 manufactured by SEC Carbon Co., Ltd.) is applied to a radiator or an expanded graphite sheet (coating amount is 0.01 to 0.5 g / cm ² ), and then heat is released through the carbon cement. The body and the expanded graphite sheet were arranged. In this state, the said structure was arrange | positioned in a vacuum furnace, and the said carbon cement was carbonized by hold | maintaining at 800-1000 degreeC for 1 to 10 hours (preferably 3 to 5 hours). Thereafter, the structure is placed in a vacuum furnace or an atcheson furnace, gradually heated, and adjusted to 2000 to 2800 ° C. (preferably 2450 to 2500 ° C.) for 5 to 24 hours (preferably 7 to 15). Time), the carbide (carbonized carbon cement) was graphitized. Here, the carbon cement is mainly composed of carbon black, but a phenol resin or an epoxy resin may be added.

  The heat radiator is preferably made of isotropic graphite or a carbon fiber composite material. Further, the shape is not limited to a structure in which fins are formed, and may be a simple rectangular parallelepiped shape or the like. Further, a metal-impregnated carbon material in which pores existing in the carbon material are impregnated with metal by molten forging or the like may be used.

  Next, the specific structure of the heat dissipation structure will be described below with reference to FIG. The heat dissipation structure of the present invention includes a CPU (heating element) 1, a heat sink (heat dissipation element) 4, an expanded graphite sheet 2 disposed between the CPU 1 and the heat sink 4, the expanded graphite sheet 2 and the above It has an adhesive layer 3 that adheres to the heat sink 4.

  If the adhesive layer 3 is present as in the above configuration, the adhesion between the heat sink 4 and the expanded graphite sheet 2 is improved, and an air layer having a low thermal conductivity is provided between the heat sink 4 and the expanded graphite sheet 2. The presence can be suppressed.

Further, the expanded graphite sheet 2 is pressurized by the weight of the heat sink 4 to reduce its thickness. As a result, the adhesion between the expanded graphite sheet 2 and the CPU 1 is improved. The reason is that since there is a space between the expanded graphites constituting the expanded graphite sheet 2, the expanded graphite located on the surface of the expanded graphite sheet 2 is uneven in the surface of the CPU 1 during the compression process. It is because it invades inside. Such a phenomenon is remarkable when the expanded graphite sheet 2 having a large space between the expanded graphites and a bulk density of 1.0 Mg / m ³ or less is used.

  As described above, the presence of the adhesive layer 3 can suppress the formation of an air layer between the heat sink 4 and the expanded graphite sheet 2, and when the expanded graphite sheet 2 is pressurized, the expanded graphite sheet It is possible to suppress the formation of an air layer between the CPU 2 and the CPU 1. As a result, since the thermal resistance in the heat transfer path is drastically reduced, the cooling efficiency of the CPU 1 is increased, and the temperature rise of the CPU 1 can be drastically reduced.

  In addition, if the thermal conductivity in the surface direction of the expanded graphite sheet 2 is regulated to be 50 to 200 W / (m · K), the thermal conductivity in the thickness direction is extremely larger than the thermal conductivity. The temperature distribution in the surface direction of the graphite sheet 2 can be kept substantially uniform. Therefore, it is possible to prevent heat spots from being formed on the expanded graphite sheet 2, the CPU 1 and the heat sink 4. Further, the expanded graphite sheet 2 and the CPU 1 may be fixed by an adhesive or the like.

(Other matters)
(1) When the weight of the heat sink 4 is small, the pressure applied to the expanded graphite sheet 2 becomes too small, the adhesion between the expanded graphite sheet 2 and the CPU 1 is lowered, and the thermal resistance is sufficiently reduced. It may not be possible. Therefore, in such a case, as shown in FIG. 2, it is preferable to use a clamp 7 that sandwiches the CPU 1, the expanded graphite sheet 2, and the heat sink 4. In FIG. 2, 5 is a fan and 6 is a base.

(2) The arrangement position of the adhesive layer 3 is not limited between the heat sink 4 and the expanded graphite sheet 2, but between the expanded graphite sheet 2 and the CPU 1, or both (the heat sink 4 and the expanded graphite sheet 2). And between the CPU 1 and the expanded graphite sheet 2).

(3) In the expanded graphite sheet 2, the total amount of impurities such as sulfur and iron contained is preferably regulated to 10 ppm or less. In particular, if the treatment is performed so that sulfur is 1 ppm or less, the CPU 1 to which the expanded graphite sheet 2 is attached can be prevented from being deteriorated.

  The heat dissipation structure of the present invention can be suitably used for heat dissipation of LED backlights for liquid crystals, heat dissipation of LED lighting, heat dissipation of solar panels, heat dissipation of CPUs such as computers and mobile phones, and the like.

1 CPU (heating element)
2 Expanded graphite sheet 3 Adhesive layer 4 Heat sink (heat radiator)
5 Fan 6 Base 7 Clamp

Claims (3)

A heat dissipating structure comprising a heat generating element, a heat dissipating element, and an expanded graphite sheet disposed between the heat generating element and the heat dissipating element,
A heat radiating structure characterized in that an adhesive layer containing graphitized carbon exists between the heat radiating body and the expanded graphite sheet and / or between the heat generating body and the expanded graphite sheet. .   The heat-dissipating structure according to claim 1, wherein the heat-resistant temperature of the heat-dissipating body is higher than the graphitization temperature, and the adhesive layer is present between the heat-dissipating body and the expanded graphite sheet. The heat dissipation structure according to claim 1 or 2, wherein a bulk density of the expanded graphite sheet is 1.0 Mg / m ³ or less.

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