JP2660647B2 - Radio wave absorber - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio wave absorber used for anti-reflection of radio waves, high-frequency cutoff, anechoic chamber, and the like.

[0002]

2. Description of the Related Art In general, radio wave absorbers are used for matching loads (dummy loads) such as waveguides, anechoic chambers, for improving the directivity of antennas, or for reducing radio noise from electronic devices.
It is used for TV ghost countermeasures and radar counterfeit image countermeasures. As a radio wave absorber used for these, a conductive radio wave absorber, a dielectric radio wave absorber, a magnetic radio wave absorber and the like are known.

[0003] The conductive radio wave absorber is a so-called λ / 4 type radio wave absorber, and a surface of a spacer (lossless dielectric) lined with a metal plate has a surface of 377Ω (radio wave characteristic impedance in free space). It is composed of a resistance coating having resistance. This radio wave absorber has a simple structure, and an extremely lightweight type of radio wave absorber can be realized by selecting a material. However, it has the drawbacks that it is used at a relatively high frequency, has a narrow absorption band, and has a reduced radio wave absorption characteristic due to the sheet resistance value of the resistive coating and the susceptance of the spacer.

The dielectric electromagnetic wave absorber is composed of carbon rubber, carbon-containing urethane foam, and carbon-containing styrofoam lined with a metal plate, and is well known in a quadrangular pyramid shape called a mountain shape or a pyramid shape. Therefore, a broadband characteristic can be obtained by using a multilayer structure. In this radio wave absorber, the cross-sectional area gradually increases toward the metal plate, and the impedance inversely proportional to the cross-sectional area gradually increases toward the measurement space, and matching with the impedance of the measurement space is achieved. It absorbs radio waves while suppressing reflected waves. The magnetic wave absorber has a simple structure composed of a ferrite plate lined with a metal plate, but absorbs radio waves well over a relatively wide band.

[0005] In addition, there is a combined electromagnetic wave absorber having a multilayer structure, which makes use of the characteristics of the above-mentioned dielectric electromagnetic wave absorber and magnetic electromagnetic wave absorber. This type of radio wave absorber is composed of a ferrite plate lined with a metal plate and styrene foam. The radio wave absorbers are arranged such that the radio wave absorbers increase the amount of radio wave attenuation toward the metal plate so that the impedance approaches the measurement space toward the measurement space. As a result, the reflected wave is suppressed at the tip, and the attenuation gradually increases as the radio wave travels inside toward the metal plate, so that the reflected wave can be efficiently absorbed and the ultra wide band radio wave can be absorbed. Because of its absorption characteristics, it is used in anechoic chambers and the like. However, such radio wave absorbers
In addition to being expensive, it is heavy and installation work is not easy. In addition, the height of the radio wave absorber increases in order to increase the amount of radio wave attenuation in each layer, and there has been a space problem such as a narrow measurement space in a radio wave anechoic chamber.

[0006]

SUMMARY OF THE INVENTION The present invention has been made to solve such problems, and provides a radio wave absorber having a radio wave absorber which is lightweight, inexpensive, and has a wide measurement space. It is in.

[0007]

According to the present invention, there is provided a radio wave absorber formed of a conductive resistive film, wherein the resistive film is formed in a direction perpendicular to a metal plate .
It is composed of a grid type radio wave absorber or a honeycomb type radio wave absorber.
And a multilayer core type by laminating the grid type radio wave absorbing parts
Or a radio wave absorber formed by laminating honeycomb type radio wave absorbers .

The radio wave absorber according to the present invention may be a radio wave absorber formed by laminating lattice type radio wave absorbers to form a multilayer core type, or a radio wave absorber formed by stacking honeycomb type radio wave absorbers. May be.

[0009]

The radio wave absorber according to the present invention is arranged in a grid pattern at a constant interval and a constant thickness with the sheet resistance of the resistive coating being 377 Ω, which is the radio wave characteristic impedance of free space. The reflection of radio waves incident on the body surface can be suppressed, and the radio waves that have entered the inside of the resistive coating are attenuated by being absorbed by the radio waves along with the radio waves traveling straight ahead, and the impedance near the metal plate surface is reduced. Are designed to approach the spatial impedance and perform efficient radio wave absorption. In addition, the sheet resistance value 37
By using a resistive coating provided with a gradient resistance that is intermittent or continuously low with 7Ω as a base point, the impedance gradually decreases as it goes inside the absorber,
Even if the frequency slightly changes, matching is achieved, and the amount of absorption is increased, so that a stable radio wave absorber can be obtained.

[0010]

BRIEF DESCRIPTION electrodeposition wave absorber by the drawings.
FIG. 1 is a perspective view of a single-layer type radio wave absorber (lattice type radio wave absorber). The lattice-type radio wave absorber 1 includes a lattice-type radio wave absorber 2
And the metal plate 3. The grid-type radio wave absorbing section 2 is formed by cutting a strip-shaped resistive coating having conductivity at a predetermined interval P in each strip in the thickness D direction, applying an adhesive to the cut extension, and combining the strips. It was formed. Here, in the case of a resistance coating having a gradient resistance, the lower surface resistance value of each strip is cut at regular intervals P in the thickness D direction, and formed in a lattice shape.

The metal plate 3 is made of a metal such as aluminum or an iron plate as in the conventional radio wave absorber. The bonding between the grid type radio wave absorbing unit 2 and the metal plate 3 is performed by applying an adhesive to the end surface of the resistive film and bonding the metal plate 3 to the end surface. Here, in the case of a resistive coating having a gradient resistance, an adhesive is applied to the lower surface resistance value and bonded to the metal plate 3. The constituent material of the resistance coating is a flexible web or the like in which a carbon-containing paint is applied on a support such as paper or a film. The support of the resistive film material is applied what is hardness for maintaining the lattice shape, other paper, polyester film, plastic film polypropylene film and the like. Of these,
It is preferable to use a polyester film in terms of impact resistance, workability, and resistance stability. Paint containing carbon is
It is obtained by mixing and dispersing a conductive filler such as carbon black in a general coating resin. Examples of the coating resin used in this case include water-soluble resins such as polyvinyl alcohol and carboxymethyl cellulose in addition to solvent-based synthetic resins such as polyester resin, epoxy resin, and urethane resin. Among them, it is preferable to use a solvent-based synthetic resin of a polyester resin in terms of adhesiveness, water resistance, and coating film strength.

Here, the resistive coating is classified into those having a sheet resistance of 377Ω and those having a gradient resistance so that the sheet resistance gradually decreases based on the sheet resistance of 377Ω. FIG. 2 is a cross-sectional view of a resistive coating comprising a support and a coating film. FIG. 2A shows that the thickness of the carbon-containing coating film 35a on the surface of the support 31 is constant and the sheet resistance is 377Ω. It is a resistance film body that has been manufactured. FIG. 2B shows that the surface resistance of the thinnest carbon-containing coating film 35 b on the surface of the support 31 is 377 Ω.
Then, a resistance coating body having a gradient resistance in which the thickness of the coating film is inclined so as to obtain the intermediate coating film 36b and the thickest coating film 37b. In the present invention, the pitch of each coating film is 10
mm, the sheet resistance value of the intermediate coating film 36b was 170Ω, and the sheet resistance value of the thickest coating film 37b was 110Ω. These can be appropriately set depending on the frequency of the radio wave to be absorbed. The number of pitches (thickness D) and the slope resistance value are not limited. FIG. 2 (c)
As shown in FIG. 2B, the surface of the support 31 is coated such that the thinnest portion of the coating film 35c has a sheet resistance of 377 Ω and the thickest portion of the coating film 35c has a constant angle of 37c. It is a resistance coating having a gradient resistance with a gradient in thickness. Also for this reason, the thickness D and the gradient resistance value are not limited for the same reason as described above. In addition, these were obtained by the coating method. When the thus-obtained resistive coating is used as a radio wave absorbing member, one having the support side bonded with an adhesive or the like is used.

[0013] illustrating the effect of the configured rated child wave absorber as described above. Belt-shaped sheet resistance 37
Since the 7 Ω resistive coatings are arranged in a grid pattern at a fixed interval P and a thickness D, the surface reflection of radio waves incident on the grid type radio wave absorber 2 can be suppressed, and the grid type radio wave absorption The radio wave incident on the inside of the part 2 is attenuated by being absorbed by the surface of the resistive coating body as the radio wave progresses, and the radio wave is absorbed.
In order to efficiently absorb radio waves, a sheet resistance value of 377Ω is used.
By having a gradient resistance so that the resistance decreases intermittently or continuously from the base point, the width of matching with the spatial impedance is widened, the amount of absorption is increased in the area where the sheet resistance is reduced, and the absorption band is also Become wider.

FIG . 3 (a) shows a multi-layer core type in which a lattice type radio wave absorbing portion 20 is laminated, which is an embodiment of the present invention. In this case, radio waves in a lower low frequency region are efficiently absorbed. FIG. 3 (b) shows a multilayer core type which is laterally moved and stacked at an intermediate point of the interval P between the sides of the lattice type radio wave absorbing unit 20, and is also an embodiment of the present invention. . FIG. 4A shows a multi-layer core type in which the lattice type radio wave absorbing portions 20 are stacked with a shift of 45 degrees, which is also an embodiment of the present invention. FIG. 4B shows a honeycomb type in which honeycomb-shaped radio wave absorbing portions 20a are stacked, and this is also an embodiment of the present invention. Further, by embedding a substance having a high dielectric constant, for example, styrene, urethane, etc. partially in the lattice-type and honeycomb-type radio wave absorbers described above, without impairing the absorption characteristics, a high-strength, thin, wide-band absorber. Become. This is also one embodiment of the invention.

[0015]

[0016]

[0017]

[0018]

[0019]

The radio wave absorber of the present invention has the following effects. Since a conventional spacer is unnecessary or only required in a part of the radio wave absorbing portion, it is extremely lightweight and inexpensive. Since the sheet resistance of the resistive coatings is 377 Ω, which is the radio wave characteristic impedance of free space, and is arranged in a grid pattern at a constant interval and a constant thickness, a radio wave absorber with little surface reflection can be obtained. By using a resistive coating provided with a gradient resistance that is intermittent or continuously reduced based on a sheet resistance value of 377Ω, the matching width with the spatial impedance and the absorption amount are increased, and the radio wave absorption band is widened. Compared to conventional radio wave absorbers formed in a cone shape or radio wave absorbers laminated with radio wave absorbers, the height of the absorber required to match the impedance to the spatial impedance can be greatly reduced. , A radio wave absorber advantageous in space. Since the lattice type radio wave absorber and the honeycomb type radio wave absorber have a considerable strength due to their structures, they have excellent shock absorption. By laminating the lattice type radio wave absorber and the honeycomb type radio wave absorber to form a multi-layer structure, radio waves in a low frequency region can be absorbed and provided to an anechoic chamber.

[Brief description of the drawings]

FIG. 1 is a perspective view of a single-layer type radio wave absorber.

FIG. 2 is a sectional view of a resistive coating.

FIG. 3 is a perspective view of a laminated electromagnetic wave absorber.

FIG. 4 is a perspective view of a laminated type radio wave absorber.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 grid-type radio wave absorber 2 grid-type radio wave absorber 3 metal plate 20 grid-type radio wave absorber 20 a honeycomb-shaped radio wave absorber 31 support 35 a coating film with constant thickness 35 b, 35 c coating thin portions 37 b, 37 c Thick part of film P Spacing of one side of lattice D Thickness of lattice

Continuation of the front page (56) References JP-A-2-239700 (JP, A) JP-A-1-251698 (JP, A) JP-A-64-24896 (JP, U) JP-A-61-207098 (JP, A) , U)

Claims (1)

(57) [Claims] 1. A radio wave absorber formed of a conductive resistive coating, wherein the resistive coating is formed as a lattice type radio wave absorbing portion or a honeycomb type radio wave absorbing portion formed in a direction perpendicular to a metal plate. And a grid-type radio wave absorber
Laminated to form a multilayer core mold or honeycomb mold
A radio wave absorber characterized by being formed by laminating radio wave absorbers.