JP2002371138A - Heat-radiating electric wave absorbing material - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a heat-radiating electric wave absorbing material having excellent heat conductivity and an electric wave absorbing property and is lightweight. SOLUTION: The heat-radiating electric wave absorbing material is produced from a mixed composition containing a heat-conductive filler and Mg-Zn ferrite powder as soft magnetic powder in an organic matrix. The true specific gravity of the Mg-Zn ferrite powder is preferably <5.0. The average particle diameter of the Mg-Zn ferrite powder is preferably 1-50 μm. The compounding ratio of the Mg-Zn ferrite powder is preferably 5-60 vol.% and the organic matrix is preferably a silicone gel.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat dissipating radio wave absorber used for electronic equipment such as information equipment, video equipment and mobile communication equipment. More specifically, the present invention relates to a heat dissipating radio wave absorber that attenuates and absorbs electromagnetic field noise generated in various electronic components and dissipates heat generated in various electronic components to the outside.

[0002]

2. Description of the Related Art In recent years, electronic devices using a high frequency band of a quasi-microwave band (100 MHz to 3 GHz) or more, such as digital electronic devices, have been widely used. In such electronic devices, miniaturization and high performance are required, and high-density mounting of various electronic components is performed. In such high-density mounted electronic devices, there is a possibility that problems such as electromagnetic interference and interference due to electromagnetic noise generated in electronic components or deterioration of characteristics due to heat generation may occur. Is an important issue.

Conventionally, in order to avoid such problems, radio wave absorbers have been used to attenuate and absorb electromagnetic wave noise generated in electronic components. A thermally conductive sheet (a thermally conductive molded body) is used as a material that diffuses thermally.

On the other hand, recent high-performance heat-generating electronic components require measures against electromagnetic noise and heat at the same time. In such a case, both of the above-described radio wave absorber and the thermally conductive molded body are used in combination. Then, since a plurality of members are used, costs are increased, and there is a problem that a wide mounting space is required.

For this reason, Japanese Patent Application Laid-Open No. H11-335472 discloses a single member that fulfills both functions of radio wave absorption and heat radiation.
In the publication, an electromagnetic wave absorbing heat conductive silicone gel sheet is proposed. This electromagnetic wave absorbing heat conductive silicone gel sheet is formed from a silicone gel composition containing metal oxide magnetic particles and a heat conductive filler, and contains Mn-Zn based ferrite as metal oxide magnetic particles. Powder or Ni-Zn ferrite powder was used. That is, since these Mn-Zn based ferrite powders and Ni-Zn based ferrite powders are mass-produced and easily available as materials for magnetic cores and magnetic heads of power transformers and the like, they have also been used in radio wave absorbers. .

On the other hand, in recent years, in mobile communication devices and the like typified by mobile phones, weight reduction has become an important challenge in addition to miniaturization and high performance. Have been done.

[0007]

However, the electromagnetic wave absorbing heat conductive silicone gel molded sheet proposed in the above-mentioned Japanese Patent Application Laid-Open No. 11-335472 has a metal oxide magnetic particle having a large specific gravity in an organic matrix. , The weight was large. Specifically, M
The true specific gravity of the n-Zn ferrite powder is about 5.1,
The true specific gravity of the Zn-based ferrite powder is about 5.4.
For this reason, there has been a problem that various inconveniences occur when applied to recent high-performance electronic devices such as mobile communication devices that are reduced in weight in gram units.

For example, in the case where metal oxide magnetic particles are highly filled in order to improve radio wave absorption characteristics and heat radiation characteristics, or when a large-sized electromagnetic wave absorbing heat conductive silicone gel molded sheet is manufactured, etc. In addition, the weight of the electromagnetic-wave-absorbing heat-conductive silicone gel molded sheet increases remarkably, and handling becomes inconvenient. Also, even if such a heavy electromagnetic wave absorbing heat conductive silicone gel molded sheet is mounted on a substrate or the like, the existing substrate frame may not be able to cope with the load of the electromagnetic wave absorbing heat conductive silicone gel molded sheet. In some cases, it is necessary to change the design of the board frame itself. Therefore, in order to avoid these inconveniences, it has been desired to realize a lightweight heat-radiating radio wave absorber.

On the other hand, in recent high-performance electronic devices which have been mounted at high density, for example, the electronic components can be mounted so as to cover the side surfaces of the electronic components or the upper surface, or can be mounted so as to cover a plurality of electronic components. There is a demand for realizing a large sheet-shaped heat-dissipating radio wave absorber. Therefore, in order to meet these demands, there has been a long-awaited desire to realize a heat-radiating radio wave absorber that is further reduced in weight.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide a light-weight heat-dissipating radio wave absorber having excellent heat conductivity and radio wave absorption characteristics. is there.

[0011]

Means for Solving the Problems In order to solve the above-mentioned problems, the invention according to claim 1 is to provide a mixed composition containing a soft magnetic material powder and a thermally conductive filler in an organic matrix by a predetermined method. A heat-dissipating radio wave absorber formed into a shape, wherein the magnetic substance powder is an Mg-Zn-based ferrite powder.

According to a second aspect of the present invention, in the first aspect, the true specific gravity of the Mg—Zn ferrite powder is less than 5.0. The invention according to claim 3 is the invention according to claim 1 or 2, wherein the average particle diameter of the Mg—Zn-based ferrite powder is 1 to 3.
It is characterized by being 50 μm.

According to a fourth aspect of the present invention, there is provided the method according to any one of the first to third aspects, wherein the Mg-Z
The compounding ratio of the n-type ferrite powder is 5 to 60 vol%. According to a fifth aspect of the present invention, in any one of the first to fourth aspects of the present invention, the organic matrix is a silicone gel.

(Function) The present invention relates to a heat-radiating radio wave absorber formed by molding a mixed composition containing a soft magnetic substance powder and a thermally conductive filler in an organic matrix into a predetermined shape. The body powder is a Mg-Zn ferrite powder. By using the Mg-Zn-based ferrite powder as the soft magnetic material powder, it has excellent thermal conductivity and excellent radio wave absorption in a high frequency band above the quasi-microwave band, particularly in a high frequency band above 1 GHz. A light-weight heat-dissipating radio wave absorber having characteristics and light weight can be realized. The shape of the heat-dissipating radio wave absorber of the present invention is not particularly limited.

Hereinafter, the radio wave absorber will be described. The radio wave absorption of the radio wave absorber is generally evaluated by the return loss Γ, and the return loss is represented by the following equation 1. Here, the return loss indicates a ratio of an incident wave to a reflected wave when a plane electromagnetic wave is perpendicularly incident from a free space to a radio wave absorber lined with a conductor, in dB.

[0016]

(Equation 1) From Equation 1, it can be seen that the condition for increasing the return loss is to set the molecular side (reflected wave) to 0 and is determined by variables of complex relative magnetic permeability, complex relative permittivity, material thickness, and frequency.

One of the characteristics required of the radio wave absorber is to reduce the amount of electromagnetic wave reflection. For this purpose, it is preferable to make the characteristic impedance value of the radio wave absorber close to the characteristic impedance value of free space. That is, in order to suppress the reflection and allow the electromagnetic wave to enter the inside of the radio wave absorber, it is desirable to make the ratio of the complex relative permeability and the complex relative permittivity of the radio wave absorber close to 1.

Further, in order to design the radio wave absorber thin, it is necessary to increase the attenuation of the electromagnetic wave inside the radio wave absorber. This involves increasing the real part (attenuation constant) of the propagation constant of the radio wave absorber, as shown in Equation 2.
That is, it is necessary to increase the complex relative magnetic permeability and the complex relative permittivity of the radio wave absorber at a desired frequency.

[0019]

(Equation 2)

The Mg—Zn ferrite powder used in the present invention is known as a magnetic material having high electric resistance, low cost and low specific gravity and high magnetic permeability, and suppresses the occurrence of a ringing phenomenon. Therefore, it is used as a core material of a deflection yoke. Such performances as high electric resistance, low cost, low specific gravity, and high magnetic permeability are required for a soft magnetic material powder dispersed and mixed in an organic matrix. For example, when the electric wave absorber has a low electric resistance, when the electric wave absorber is used in contact with a circuit of an electronic device or the like, an electrical trouble occurs in the circuit. Therefore, it can be said that the Mg-Zn-based ferrite powder having these properties is the most suitable material as the soft magnetic material powder dispersed and mixed in the organic matrix.

Here, ferrite refers to iron oxide (Fe
_TwoO_Three) Is a generic term for composite oxides whose main component is
And iron ions and acids
In addition to elementary ions, magnesium (Mg) ions and zinc
When there are (Zn) ions, Mg-Zn ferrite
being called. From the crystal structure of ferrite,
Crystal magnet plumbite type (MeFe₁₂O₁₉),
Cubic spinel type (MeFe_TwoO_Four), Garnet type
(Me_ThreeFe_FiveO₁₂), Perovskite type (MeFe
O _Three)). Note that Me indicates a metal element.
You. Among these, spinel-type ferrite is
High symmetry and low crystal magnetic anisotropy
The nature is the softest. Where the magnetic properties are soft
Is magnetized when the magnetic material is exposed to a magnetic field,
When removed, magnetization is not maintained and is erased.
Magnetic materials having such properties as soft magnetic materials (soft magnetic materials)
Calling. And the softer the magnetic properties,
The above-mentioned magnetic permeability μ '(the real part of the complex relative magnetic permeability) is large.
No.

Therefore, as a soft magnetic powder to be dispersed and compounded in an organic matrix, Mg—Z having a spinel type crystal structure is used.
By using the n-type ferrite powder, a heat-dissipating radio wave absorber having excellent heat conductivity and radio wave absorption characteristics can be realized. In addition, Mg-Zn-based ferrite powder has an advantage that it is easy to reduce the specific gravity at low cost compared to the above-described Mn-Zn-based ferrite powder and Ni-Zn-based ferrite powder. In addition, a light-weight heat-dissipating radio wave absorber can be realized at low cost.

The true specific gravity of the Mg—Zn ferrite powder is as follows:
Preferably it is less than 5.0. By setting the true specific gravity of the Mg—Zn-based ferrite powder to less than 5.0, it is possible to realize a light-weight heat-dissipating radio wave absorber having excellent heat conductivity and radio wave absorption characteristics. On the other hand, M
When the true specific gravity of the g-Zn-based ferrite powder is 5.0 or more, the weight of the heat-radiating radio wave absorber becomes large and the handling becomes inconvenient. It may not be possible to cope with the above, and it may be necessary to change the design of the board frame itself, which is not preferable.

The mixing ratio of the Mg—Zn ferrite powder is preferably 5 to 60 vol%. Mg-Z
If the mixing ratio of the n-based ferrite powder is less than 5 vol%,
It is difficult to obtain sufficient radio wave absorption characteristics, and it is not preferable to improve the radio wave absorption characteristics by using other soft magnetic powders together, because the weight increases. On the other hand, when the mixing ratio of the Mg-Zn-based ferrite powder exceeds 60 vol%,
It is not preferable because the heat conductive filler cannot be blended in the organic matrix at a high level, and the heat conductivity decreases.

The average particle diameter of the Mg—Zn ferrite powder (the long diameter in the case of an anisotropic shape such as a scale) is preferably 1 to 50 μm in consideration of dispersibility, workability, and the like. When the average particle size is less than 1 μm, the bulk specific gravity increases, and it is difficult to uniformly disperse the particles in the organic matrix, which is not preferable. On the other hand, when the average particle size exceeds 50 μm, the soft magnetic powder not involved in the attenuation of the electromagnetic wave is not affected by the skin portion (approximately several μm) of the soft magnetic powder involved in the attenuation of the electromagnetic wave in the quasi-microwave band or more. The occupation ratio of the portion other than the skin (core portion) becomes large, and even if the Mg-Zn-based ferrite powder is blended in high content, the radio wave absorption characteristics cannot be efficiently improved.

The Mg—Zn ferrite powder has been subjected to a surface treatment with a silane coupling agent, a titanate coupling agent or the like, if necessary, in order to improve the compatibility and dispersibility with the organic matrix. It does not matter. The shape of the Mg-Zn ferrite powder is
The shape is not particularly limited, and for example, a shape such as a sphere, a scale, or a fiber can be suitably used.

[0027]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, a heat-radiating radio wave absorbing sheet (heat-radiating radio wave absorber) embodying the present invention will be described.

The heat-radiating electromagnetic wave absorbing sheet is formed by molding a mixed composition containing a thermally conductive filler and the above-mentioned Mg-Zn ferrite powder as a soft magnetic material powder in an organic matrix into a sheet. Become. That is, in this heat radiation radio wave absorbing sheet, a heat conductive filler and a Mg—Zn ferrite powder are dispersed in an organic matrix.

The organic matrix is appropriately selected from known organic matrices, for example, resins, rubbers, gels, thermoplastic elastomers, etc., according to various use performances such as mechanical strength, heat resistance, electrical characteristics, and durability. There is no particular limitation on the composition, curing form and the like. The organic matrix is preferably a silicone gel in consideration of adhesiveness to an electronic component, followability, and the like. In addition, the organic matrix may be used alone or in combination of two or more by blending, and may be alloyed.

The heat conductive filler is not particularly limited, but is preferably a heat conductive filler such as aluminum oxide, zinc oxide, aluminum nitride, boron nitride, silicon nitride, silicon carbide, quartz, aluminum hydroxide, etc. Metal oxides,
Metal nitride, metal carbide, metal hydroxide, silver, copper,
Metals and alloys such as gold, iron, aluminum, and magnesium can be suitably used. Further, the particle shape, particle diameter, and the like of the thermally conductive filler are not particularly limited. Furthermore, the heat conductive filler may be one that has been surface-treated with a silane coupling agent, a titanate coupling agent, or the like, if necessary, in order to improve compatibility, dispersibility, and the like with the organic matrix. Absent.

The thickness of the heat-radiating electromagnetic wave absorbing sheet is 0.2 to
It is preferably 5 mm. If the thickness is less than 0.2 mm, it becomes difficult to manufacture, and sufficient radio wave absorption characteristics cannot be obtained. On the other hand, when the thickness is more than 5 mm, the thermal conductivity is reduced and the price is high, which is not preferable.

Further, it is preferable that at least one of the heat-radiating radio wave absorbing sheets has an adhesive property. It is possible to sufficiently adhere to the electronic component, to secure more heat transfer area and physically improve thermal conductivity, and to reduce leakage of electromagnetic waves.

Further, the heat-dissipating radio wave absorbing sheet is provided with a sheet-like or fibrous reinforcing layer or a shielding layer on one of the sheet surfaces or in the sheet for the purpose of improving workability, reinforcing and shielding electromagnetic waves. They may be stacked or buried.

It is preferable that the surface of at least one of the heat-radiating electromagnetic wave absorbing sheets has a Asker C hardness of 5 to 50. If the heat-dissipating radio wave absorbing sheet has low hardness, it has shape followability to uneven surfaces and can be used in close contact with electronic components, so more heat transfer area is secured and thermal conductivity is improved. In addition, leakage of electromagnetic waves can be reduced. Here, Asker C hardness is SRIS0
101 (Japan Rubber Standards Association) indicates the hardness measured with an Asker C hardness tester.

The heat-dissipating radio wave absorbing sheet may contain other additives in addition to the soft magnetic powder and the heat conductive filler described above. For example, a plasticizer, an adhesive, a reinforcing agent, etc. , A colorant, a heat resistance improver, and the like. In addition to the above-described Mg-Zn-based ferrite powder, another soft magnetic powder may be used in combination. As other soft magnetic material powder, for example, Fe-Si alloy powder,
Fe-Si-Al alloy (Sendust) powder, Fe-Ni
Alloy (permalloy) powder, Mn-Zn ferrite powder,
Ni-Zn ferrite powder and the like.

As described in detail above, according to the present embodiment, the following effects can be obtained. -Mg-Zn ferrite powder was used as the soft magnetic material powder. By using the Mg-Zn ferrite powder as the soft magnetic material powder as described above, it has excellent radio wave absorption characteristics and excellent thermal conductivity in a high frequency band above the quasi-microwave band, particularly in a high frequency band above 1 GHz. And
In addition, a light-weight heat-dissipating radio wave absorbing sheet can be realized. Therefore, the heat-dissipating radio wave absorbing sheet is subject to interference by various electronic components of an electronic device using a high frequency band higher than the quasi-microwave band, for example, an electronic component that generates an electromagnetic wave, and an electromagnetic wave. It can be suitably used for an electronic component or an electronic component that generates heat.

The soft magnetic powder has a true specific gravity of 5.0.
A Mg—Zn soft ferrite powder having a spinel type crystal structure of less than 10% was used. By using an Mg—Zn ferrite powder having a true specific gravity of less than 5.0, the conventional Mn—
As compared with a heat-dissipating radio wave absorber using Zn-based ferrite powder and Ni-Zn-based ferrite powder, a light-weight heat-dissipating radio wave absorbing sheet can be realized.

The average particle size of the Mg—Zn ferrite powder was set to 1 to 50 μm. As described above, when the average particle size of the Mg-Zn-based ferrite powder is 1 to 50 m,
Since the dispersibility in the organic matrix is good, M
The g-Zn-based ferrite powder can be highly filled in the organic matrix, and a heat-dissipating radio wave absorption sheet excellent in radio wave absorption characteristics and thermal conductivity can be realized.

The mixing ratio of the Mg—Zn ferrite powder was 5 to 60 vol%. Thus, Mg-Zn
By setting the blending ratio of the system ferrite powder to 5 to 60 vol%, a light-weight heat-dissipating radio wave absorbing sheet having excellent radio wave absorbing properties and thermal conductivity can be realized.

A silicone gel was used as the organic matrix. When a silicone gel having excellent adhesiveness and followability is used, the silicone gel can be sufficiently adhered to an electronic component, so that a larger heat transfer area can be secured and leakage of electromagnetic waves can be reduced. Therefore, it is possible to realize a heat-dissipating radio wave absorption sheet having excellent radio wave absorption characteristics and thermal conductivity, which can be suitably used for a recent high-performance electronic component or the like which is mounted at a high density.

A mixed composition containing a thermally conductive filler in an organic matrix and the above-mentioned Mg—Zn ferrite powder as a soft magnetic material powder was formed into a sheet.
By using a sheet-like heat-radiating radio wave absorber as described above, for example, the electronic component can be mounted so as to cover from the side surface to the upper surface, or can be mounted so as to cover a plurality of electronic components. Can be reduced, and the electromagnetic wave noise can be attenuated and the heat radiation of the heat-generating components can be performed with higher efficiency.

[0042]

EXAMPLES Hereinafter, the above embodiments will be described in more detail with reference to Examples and Comparative Examples, but these do not limit the scope of the present invention in any way.

The radio wave absorption characteristics of the heat-radiating radio wave absorbing sheets of the examples and comparative examples were obtained by measuring the reflection coefficient and the transmission coefficient using a network analyzer (8720 made by HP), and calculating the return loss from the measured values. Things. Also,
The thermal conductivity of the heat-dissipating radio wave absorbing sheet of each example and comparative example was measured using a rapid thermal conductivity meter (QTM-
500). Further, the viscosities of the mixed compositions of the respective Examples and Comparative Examples were measured with a rotational viscometer.

(Example 1) Addition type liquid silicone gel (manufactured by Dow Corning Toray Silicone Co., Ltd., specific gravity 1.0, Asker C hardness after curing:
5) The soft magnetic powder has a true specific gravity of 4.
8, 70 parts by weight of a Mg—Zn ferrite powder having a spinel type crystal structure (average particle diameter of 6 μm) and 530 parts by weight of silicon carbide (SiC) powder (true specific gravity 3.1, average particle diameter 60 μm) as a thermally conductive filler Were mixed and stirred until uniform using a stirring defoamer to prepare a mixed composition (silicone gel composition). The mixing ratio of this mixed composition is as follows: organic matrix 35 vol%, silicon carbide powder 60 vol%, Mg—Zn ferrite powder 5 vol%.
It is. Next, this mixed composition was cured by heating at 120 ° C. for 30 minutes to produce a heat-radiating radio wave absorbing sheet having a thickness of 1 mm.

Example 2 The mixing ratio was 35 vol% of organic matrix, 45 vol% of silicon carbide powder, Mg-
Except that the Zn-based ferrite powder was 20 vol%, a mixed composition was prepared in the same manner as in Example 1 to produce a heat-radiating electromagnetic wave absorbing sheet.

Example 3 The mixing ratio was 35 vol% of organic matrix, 25 vol% of silicon carbide powder, Mg-
Except that the Zn-based ferrite powder was 40 vol%, a mixed composition was prepared in the same manner as in Example 1 to produce a heat-radiating radio wave absorbing sheet.

Example 4 The mixing ratio was 35 vol% of organic matrix, 5 vol% of silicon carbide powder, Mg-Z
A mixed composition was prepared in the same manner as in Example 1 except that the n-type ferrite powder was changed to 60 vol%, to produce a heat-radiating electromagnetic wave absorbing sheet.

(Comparative Example 1) As a soft magnetic material powder, a Mn-Zn based ferrite powder having a true specific gravity of 5.1 (average particle diameter of 6 μm) was used.
Except for using m), a mixed composition was prepared in the same manner as in Example 3 to produce a heat-radiating electromagnetic wave absorbing sheet.

Comparative Example 2 As a soft magnetic material powder, a Ni—Zn ferrite powder having a true specific gravity of 5.4 (average particle size of 6 μm) was used.
Except for using m), a mixed composition was prepared in the same manner as in Example 3 to produce a heat-radiating electromagnetic wave absorbing sheet.

Each of the mixed compositions of Examples and Comparative Examples 2
Table 1 shows the measurement results of the viscosity at 5 ° C., the specific gravity of the heat-radiating radio wave absorbing sheet, and the thermal conductivity. 1 and 2 show the measurement results of the return loss of the heat-radiating radio wave absorbing sheets of the above Examples and Comparative Examples.

[0051]

[Table 1]

(Consideration) In the first to fourth embodiments, Mg-Zn
Comparative Example 1 is a conventional heat-radiating radio wave absorbing sheet using a Mn-Zn-based ferrite powder, and Comparative Example 2 is N-type.
It is a conventional heat dissipation radio wave absorption sheet using an i-Zn ferrite powder.

It has been confirmed that the heat-radiating radio wave absorbing sheets of the above Examples and Comparative Examples all have excellent radio wave absorbing characteristics in a high frequency band above the quasi-microwave band, especially in a high frequency band above 1 GHz. It was confirmed that it was a heat-radiating radio wave absorption sheet matched to a high frequency band above the quasi-microwave band. Further, each of the heat-radiating radio wave absorbing sheets of Examples and Comparative Examples has a thermal conductivity of 1.5 (W /
(M · K)), indicating that the composition had excellent thermal conductivity. Furthermore, each of the heat-radiating radio wave absorbing sheets of each of the examples and the comparative examples was rich in flexibility and had good followability. In addition, each of the mixed compositions of Examples and Comparative Examples had low viscosity and good processability.

On the other hand, when comparing Example 3, Comparative Example 1 and Comparative Example 2 in which the mixing ratio of each component was the same, the heat radiation electromagnetic wave absorbing sheet of Example 3 was found to have the heat radiation property of Comparative Example 1 and Comparative Example 2. Compared to the radio wave absorbing sheet, the specific gravity is clearly smaller, though the radio wave absorbing property and the thermal conductivity are equivalent.
Therefore, it was confirmed that the use of the Mg-Zn-based ferrite powder can realize a lightweight heat-radiating radio wave absorbing sheet. Further, from Examples 1 to 4, Mg-Zn
It has been confirmed that when the blending ratio of the system ferrite powder is in the range of 5 to 60 wt%, a light-weight heat-dissipating radio-wave-absorbing sheet having excellent radio-wave absorption properties and thermal conductivity can be realized.

Next, technical ideas grasped from the above-described embodiment, examples and comparative examples will be described. (A) The heat-dissipating radio wave absorber according to any one of claims 1 to 5, wherein the thermal conductivity is 1.5 (W / (m · K)) or more.

(B) A mixed composition containing a soft magnetic material powder and a thermally conductive filler in an organic matrix, wherein the soft magnetic material powder is an Mg—Zn ferrite powder. Mixed composition. (C) The soft magnetic material powder contains Mg- having a true specific gravity of less than 5.0.
The mixed composition according to the above (B), which is a Zn-based ferrite powder. (D) The average particle diameter of the Mg—Zn ferrite powder is
The mixed composition according to the above (B) or (C), which has a thickness of 1 to 50 µm. (E) The mixing ratio of the Mg—Zn ferrite powder is 5
The mixed composition according to any one of the above (B) to (D), wherein the content of the mixed composition is from 60 to 60% by volume. (F) The silicone gel composition according to any one of the above (B) to (E), wherein the organic matrix is a silicone gel.

(G) A heat-radiating radio wave absorber obtained by molding the mixed composition according to any one of (B) to (F) into a predetermined shape. (H) A heat-radiating electromagnetic wave absorbing sheet obtained by molding the mixed composition according to any one of (B) to (F) into a sheet.

[0058]

As described in detail above, according to the present invention, the use of the Mg-Zn ferrite powder as the soft magnetic powder has excellent thermal conductivity,
It is possible to realize a light-weight heat-dissipating radio wave absorber having excellent radio wave absorption characteristics in a high frequency band higher than the quasi-microwave band, particularly in a high frequency band higher than 1 GHz.

The heat dissipating radio wave absorber of the present invention is adapted to a high frequency band equal to or higher than the quasi-microwave band.
Since it is able to attenuate and dissipate electromagnetic wave noise with higher efficiency and is lighter, it is suitable for electronic devices that use high frequency bands higher than the quasi-microwave band, which have been increasingly used in recent years. It is useful as an absorptive electromagnetic wave absorber, and in particular, its weight reduction in gram units is very useful for electronic devices.

[Brief description of the drawings]

FIG. 1 is a graph showing the return loss of the heat-dissipating radio wave absorbing sheets of Examples 1 to 4.

FIG. 2 is a graph showing the return loss of the heat-radiating radio wave absorbing sheets of Example 3, Comparative Examples 1 and 2.

Claims (5)

[Claims] 1. A heat-dissipating radio wave absorber formed by molding a mixed composition containing a soft magnetic powder and a thermally conductive filler in an organic matrix into a predetermined shape, wherein the soft magnetic powder comprises: A heat-dissipating radio wave absorber, which is an Mg-Zn ferrite powder. 2. The heat-dissipating radio wave absorber according to claim 1, wherein the true specific gravity of the Mg—Zn-based ferrite powder is less than 5.0. 3. The heat-radiating radio wave absorber according to claim 1, wherein the average particle diameter of the Mg—Zn ferrite powder is 1 to 50 μm. 4. The method according to claim 1, wherein the mixing ratio of the Mg—Zn ferrite powder is 5 to 60 vol%.
The heat-dissipating radio wave absorber according to any one of claims 1 to 3. 5. The heat-dissipating radio wave absorber according to claim 1, wherein the organic matrix is a silicone gel.