KR20150031165A - Electric wave absorption sheet for near-field - Google Patents

Abstract

The present invention relates to an electric wave absorption sheet for near-field to start the distribution of imaginary number permeability from a GHz band. The electric wave absorption sheet for near-filed of the present invention includes: at least class one and resin to be selected from composites to be Fe100-xCox having FeCo alloy powder of 0.1<=x<=40, composites to be Fe100-yNiy having FeNi alloy powder of 0.1<=y<=40, and composites to be Fe100-z(CoNi)z having FeCoNi alloy of 1<=z<=40.

Description

[0001] The present invention relates to an electric wave absorption sheet for a near-

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a radio wave absorbing sheet for a near field system used for suppressing extra radiation radio waves in an electronic apparatus or a communication apparatus.

2. Description of the Related Art In recent years, mounting density of components mounted on electronic circuits has increased along with miniaturization and weight reduction of electronic apparatuses and communication apparatuses. For this reason, a malfunction of an electronic device or the like due to radio wave interference between electronic components or electronic circuits due to radio waves radiated from the electronic components becomes a problem.

In order to prevent this problem, a radio wave absorbing sheet for a nearby system for converting extra radiating radio waves into heat is mounted on electronic equipment or the like. Since the electromagnetic wave absorptive sheet has a thickness of 0.1 to 2 mm, it can be inserted in the vicinity of electronic parts and electronic circuits, and is easy to process and has high degree of freedom in shape. Therefore, the radio wave absorbing sheet can be adapted to miniaturization and weight reduction of electronic devices and the like, and is widely used as a noise countermeasure component for electronic devices and the like.

A typical electromagnetic wave absorbing sheet is composed of soft magnetic metal powder and resin processed in a flat shape and is a structure that converts radio waves into heat by magnetic loss of the soft magnetic metal powder. Therefore, the radio wave absorption performance of the radio wave absorbing sheet depends on the permeability of the soft magnetic metal powder. In general, the permeability is represented by the complex permeability μ = μ ' j · μ " using the real magnetic permeability μ' and the imaginary magnetic permeability μ" , but when the magnetic loss such as the radio wave absorbing sheet is used, the imaginary magnetic permeability μ " It becomes important. That is, it is important that the imaginary part magnetic permeability 占 is distributed over the frequency band of the propagation noise to be absorbed. Hereinafter, the distribution of the imaginary part magnetic permeability 占 with respect to the frequency is referred to as 占 占 dispersion.

Patent Document 1 describes an electromagnetic wave absorbing sheet composed of a resin and a resin made of a three-element alloy of FeCoMo alloy, FeCoNb alloy, or FeCoV alloy. Patent Document 2 discloses an electromagnetic wave absorbing sheet composed of a Fe-50Ni alloy and a resin as an example using a binary element-based alloy.

[Patent Document 0001] Japanese Unexamined Patent Application Publication No. 10-106814 [Patent document 0002] Japanese Unexamined Patent Application Publication No. 2002-134309

[0002] In recent years, high performance of electronic devices and the like is rapidly advancing, and the frequency of use tends to increase. For example, in personal computers, a higher speed is required, and the driving frequency of the CPU is set to reach GHz. Further, in a communication device such as a wireless LAN, the capacity of digital contents to be processed is increasing, and the communication frequency is also centering on the GHz band. In addition, satellite communication such as digital TV broadcast and road traffic information system is rapidly expanded, and the age of ubiquitous network is realized. While the multifunctional or convergence of such information communication devices is progressing, the frequency of extra radio waves radiated from the electronic device or the communication device is also increased, and the function interference or malfunction caused by the radiation radio waves is also increased. Therefore, development of a radio wave absorbing sheet capable of effectively absorbing radio waves in the GHz band is required.

However, the phenomenon μ "was not dispersion is obtained is spread-absorbing sheet that begins to appear from the GHz band. Also in the technique described in Patent Document 1 and Patent Document 2, μ" dispersion MHz band, spanning the GHz band.

Therefore, in view of the above problem, the present invention aims to provide a near-field radio wave absorbing sheet in which the distribution of the imaginary part magnetic permeability 占 from the GHz band begins to appear.

In order to achieve the above object, the present inventors have made extensive studies and obtained the following findings. For the soft magnetic metal powder used in the radio wave absorbing sheet, the saturation magnetization is high that μ "dispersion The start also tends to shift to the high frequency side. Therefore, the inventors of the present invention have studied using Fe, which exhibits the highest saturation magnetization, as a soft magnetic metal powder in the case of a single metal. However, if more forward examination, if substituted to a part of Fe with the low Co and / or Ni than the saturation magnetization of Fe, less than the prior rate (specifically, 40% or less), or injury so far μ "dispersion of I have found that the start shifts to the high frequency side.

That is, the electromagnetic wave absorbing sheet for a near field system according to the present invention comprises a flat FeCo alloy powder and a resin, wherein the composition of the FeCo alloy powder is 0.1? _{X? 40} in Fe _{100 - x} Co _x .

Another radio wave absorbing sheet of the present invention includes a flat FeNi alloy powder and a resin, and the composition of the FeNi alloy powder is 0.1? _{Y? 40} in Fe _{100 - y} Ni _y .

Another electromagnetic wave absorbing sheet of the present invention comprises a flat FeCoNi alloy powder and a resin, and the composition of the FeNiCo alloy powder is 0.1? _Z? 40 in Fe _{100- z} (CoNi) _z .

Another radio wave absorbing sheet for a near field system of the present invention is characterized by comprising a mixed powder comprising at least two kinds of FeCo alloy powder, FeNi alloy powder, FeCoNi alloy powder, and flat Fe powder, and a resin do.

The absorptive sheet for a neighborhood system of the present invention has an absorption coefficient of " Distribution begins.

DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a radio wave absorbing sheet for a near field system of the present invention will be described below.

According to one embodiment of the present invention, a radio wave absorbing sheet for a nearby system (hereinafter simply referred to as &quot; radio wave absorbing sheet &quot;) includes a flat soft magnetic metal powder and a resin. As the soft magnetic metal powder, FeCo alloy powder, FeNi alloy powder, or FeCoNi alloy powder is used. Alternatively, as the soft magnetic metal powder, a mixed powder obtained by mixing at least two kinds or more of the total of four types of powders of the three alloy powders and the Fe single powder may be used.

Here, the composition of the FeCo alloy powder is 0.1? _{X? 40} in Fe _{100 - x} Co _x , the composition of the FeNi alloy powder is 0.1? _{Y? 40} in Fe _{100 - y} Ni _y , It is important in the present invention that the composition is 0.1? _Z? 40 in Fe _{100- z} (CoNi) _z . By substituting a part of Fe by Ni and Co, the saturation magnetization is lower than Fe, μ "dispersion of The start can be in GHz band. Here, when a replacement ratio x, y, z (all atomic ratio) to 40, greater than the characteristics of the Co or Ni is dominant, resulting in a re-μ "the beginning of the dispersion MHz band. Therefore, in the present invention x, y, z are in the range of 0.1 ~ 40. μ "to the start of distributed more GHz band, it is preferable that the x, y, z of 10 to 35, more preferably to 20 to 30. Further, if not specifically described, the description of z in the FeCoNi alloy is Co: Ni = 1: 1.

Rate of 4 kinds of powder in the case where a mixed powder is not particularly limited, μ "to the total of the three types of alloy powder with 50 mass% or more is preferred in order to the start of distributed more GHz band.

Hereinafter, an example of a method of manufacturing the radio wave absorbing sheet of the present embodiment will be described.

In the method of manufacturing the radio wave absorbing sheet of the present embodiment, a flat soft magnetic metal powder, a resin, and an organic solvent are mixed to prepare a slurry.

The flat powder can be produced by mechanically processing raw powder close to spherical shape. The raw material powder is preferably spherical, and can be obtained by gas atomization or water atomization, which is a general powder synthesis method. The average particle size of the raw material powder is preferably 10 to 70 mu m. The aspect ratio of the flat powder is preferably 10 or more so that the effect of the semi-magnetic field in the flat powder surface can be ignored. When the average particle diameter of the raw powder is less than 10 mu m, a flat powder having a large aspect ratio is obtained If the average grain size of the raw material powder exceeds 70 탆, it takes a long time to perform flat machining, which is inefficient. The aspect ratio of the flat powder is preferably as large as possible, but when it is 10 or more, the effect of reducing the demagnetizing factor in the powder surface is saturated. The flattening can be performed by machining such as a ball mill, an attritor, a stamp mill, or the like.

In this specification, 'average particle size' means a particle size (50% cumulative particle size: D50) at an integrated value of 50% in a particle size distribution obtained by a laser diffraction / scattering method. The 'aspect ratio' means a value obtained by averaging the ratio of the length / thickness ratio of the flat soft magnetic metal powder to the ten powders in the field of view when observed with an SEM.

In the present embodiment, the average length of the ten flat soft magnetic metal powders observed in the SEM is about 30 to 70 mu m, and the average thickness is about 1 to 2 mu m. Since the soft magnetic metal powder has a low electrical resistance, it is preferable that the thickness of the soft magnetic metal powder is 2 mu m or less in consideration of the skin depth (penetration depth of radio wave) in the GHz band. In addition, since the residual stress is generated in the powder by the flattening, it is preferable to anneal the soft magnetic metal powder in an inert atmosphere after the flattening process in order to prevent the permeability from decreasing. Annealing conditions may be, for example, 300 to 700 ° C for 1 to 5 hours.

It is also preferable to form a magnetic oxidation coating or an external treatment coating on the surface of the flattened powder for the purpose of insulating treatment. The means for forming the film and the material are not limited as long as the insulating property can be maintained. Further, the oxide film is 20 ~ 100nm in thickness because suitable and, the volume of, the magnetic phase (磁性相) that described the case of forming an oxide film than necessary by the self-oxidation reduced, to obtain a sufficient μ "value As a method for forming a film by magnetic oxidation, a typical method is a heat treatment in the atmosphere or a heating treatment in a hydrocarbon-based organic solvent. As a film forming method by an external treatment, a vapor phase method such as dip coating or CVD can be mentioned .

The resin functions as a binder, imparting plasticity, and insulating insulation between soft magnetic powders. Examples of the resin include any of resins having high dispersibility of soft magnetic metal powder such as epoxy resin, phenol resin, cellulose resin, polyethylene resin, polyester resin, polyvinyl chloride resin and polybutyral resin. The enemy may be selected according to the purpose. However, a resin having a low dispersibility of a soft magnetic metal powder such as a silicone resin is not preferable. If the soft magnetic metal powder in the slurry is not uniformly distributed, by a doctor blade method which will be described later, the soft difficult to magnetic metal powder is oriented horizontally, sufficient μ "can not be obtained a dispersion value, μ" of the start of the dispersion, high frequency This is not possible.

The mixing ratio of the soft magnetic metal powder and the resin is preferably 8 to 15 parts by mass when the soft magnetic metal powder is 100 parts by mass. If the resin content is 8 parts by mass or more, the plasticity of the electromagnetic wave absorptive sheet is not lost. When the amount of the resin is 15 parts by mass or less, a flat soft magnetic metal powder is liable to align horizontally at the time of forming a sheet, so that a sufficient μ " value can be obtained.

The organic solvent is not particularly limited, and toluene, butyl acetate, ethyl acetate and the like can be used. The organic solvent evaporates in a subsequent process, and is not contained in the radio wave absorbing sheet.

Next, the slurry is molded into a sheet form by a doctor blade method and dried to produce a molded article. The shear stress at this time can provide a structure in which the flat soft magnetic metal powders are aligned in the horizontal direction with each other.

Since the sheet-shaped formed article enhances the orientation of the flat soft magnetic metal powder, it is preferable to perform the pressing in a state of being heated to a temperature not lower than the softening point of the resin (for example, about 50 to 100 DEG C). The thickness of the resulting radio wave absorbing sheet may be about 0.05 to 2 mm.

Example

(Experimental Example 1)

An alloy powder having the composition shown in Table 1 was obtained by gas atomization. The average particle diameter was 40 to 50 탆. Each of the alloy powders was flattened in an attritor to obtain an average thickness of 0.5 탆 and an aspect ratio of 20. Thereafter, annealing treatment was performed at 550 캜 for 5 hours in an Ar atmosphere in order to remove residual stress. Next, in order to form a magnetic oxidation film on the surface of the powder, oxidation treatment was carried out at 60 ° C for 8 hours in the air. The ratio of Co to Ni of the FeCoNi alloy in Table 1 is 1: 1.

100 parts by mass of each alloy powder processed into a flat surface, 15 parts by mass of a polybutyral resin (softening point: about 70 ° C), and 90 parts by mass of butyl acetate were mixed to prepare a slurry. This slurry was processed into a sheet-shaped article by the doctor blade method and pressed at 85 캜 to produce a radio wave absorbing sheet having a thickness of 1 mm.

The magnetic permeability characteristics of the radio wave absorbing sheet produced in each of the Examples and Comparative Examples were measured by an S-parameter method using a network analyzer. The frequency at which the imaginary part permeability μ " distribution is first started is shown in Table 1.

As is apparent from Table 1, in Comparative Examples 1 to 3, the starting frequency of the dispersion of mu " was a low frequency of less than 1 GHz, whereas in Examples 1 to 15, it was 1 GHz or more.

(Experimental Example 2)

Experiments were carried out in the same manner as in Experimental Example 1, using mixed powders of powders of plural compositions as soft magnetic metal powders. First, the FeCo alloy powder, the FeNi alloy powder, and the FeCoNi alloy powder were produced, flattened, annealed, and oxidized in the same manner as in Example 1. Further, after an Fe powder having an average particle size of 65 占 퐉 was obtained by gas atomization, flattening, annealing and oxidation treatment were carried out in the same manner as in Example 1. [ The four types of kneading powders thus obtained were mixed at the mixing ratio shown in Table 2 to obtain a mixed powder.

100 parts by mass of each of the mixed powders processed into a flat surface, 15 parts by mass of a polybutyral resin (softening point: about 70 占 폚), and 90 parts by mass of butyl acetate were mixed to prepare a slurry. This slurry was processed into a sheet-form molded body by a doctor blade method and pressed at 85 캜 to produce a radio wave absorbing sheet having a thickness of 1 mm. Table 2 shows the frequency at which the imaginary part permeability μ " distribution starts when measured by the same method as in Experimental Example 1. [

In Example 16 to 20 with, mixed powder As is clear from Table 2, μ "was possible to start the distributed frequencies above 1GHz.

According to the present invention, it is possible to provide a radio wave absorbing sheet for a near-field system corresponding to a microwave device of GHz band or more, starting from the GHz band to the imaginary part permeability 占 distribution.

Claims (4)

A flat FeCo alloy powder and a resin,
Characterized in that the composition of the FeCo alloy powder is 0.1? _{X? 40 in} Fe _{100 - x} Co _x .
A flat FeNi alloy powder and a resin,
Wherein the composition of the FeNi alloy powder is 0.1? _{Y? 40 in} Fe _{100 - y} Ni _y .
A flat FeCoNi alloy powder and a resin,
Wherein the composition of said FeNiCo alloy powder is 0.1? _Z? 40 in Fe _{100- z} (CoNi) _z .
A FeCo alloy powder according to claim 1, the FeNi alloy powder according to claim 2, the FeCoNi alloy powder according to claim 3, and a flat Fe powder, and a resin Wherein the electromagnetic wave absorbing sheet is made of a thermoplastic resin.