JP2021034678A - Radio wave absorber - Google Patents

Abstract

To provide a radio wave absorber that can handle a wide frequency band.SOLUTION: A radio wave absorber 10 includes an aluminum sheet that is a reflective layer 11 that reflects radio waves, a radio wave absorbing layer 15 that has radio wave absorbing performance, and a calcium carbonate foam material with a dielectric constant of about 1 that is a spacer layer 13 disposed between the reflective layer 11 and the radio wave absorbing layer 15. The radio wave absorbing layer 15 is a resistive body in which carbon black, a radio wave absorbing material, is dispersed.SELECTED DRAWING: Figure 1

Description

The present invention relates to a radio wave absorber.

Patent Document 1 discloses a conventional radio wave absorber. This radio wave absorber includes a radio wave reflector, a dielectric layer, and a resistance layer, and is laminated in this order. When this radio wave absorber is arranged in a state of absorbing radio waves, the resistance layer is positioned on the radio wave arrival side. Radio reflectors reflect radio waves. This radio wave reflector is composed of a metal plate such as a steel plate or a plate-shaped substrate mainly made of an inorganic material, and a conductive film arranged on the surface of the substrate on the radio wave arrival side. .. The dielectric layer is arranged on the radio wave arrival side of the radio wave reflector. This dielectric layer is mainly composed of an inorganic material. The resistance layer is arranged on the radio wave arrival side of the dielectric layer. This resistance layer is composed of a plate-shaped or sheet-shaped substrate mainly made of an inorganic material, and a resistance film formed on the substrate. The thickness of the dielectric layer, the thickness of the substrate of the resistance layer, and the surface resistance value of the resistance film of the resistance layer are predetermined values so that the radio wave absorber can exhibit desired radio wave absorption characteristics in a predetermined frequency region. Is set to. This radio wave absorber has a resistance film having a surface resistance value of 377 Ω / □ arranged at a position separated by λ / 4 (λ is the wavelength of the radio wave) from the radio wave reflector, and has the same principle as the λ / 4 type radio wave absorber. Absorbs radio waves. That is, this radio wave absorber has a radio wave absorption characteristic in which a peak of the attenuation amount exists at a periodic predetermined frequency.

Japanese Unexamined Patent Publication No. 2004-270143

However, in the radio wave absorber of Patent Document 1, the attenuation amount sharply decreases in the frequency band between the peaks of the attenuation amount. Therefore, this radio wave absorber can only support a narrow frequency band.

The present invention has been made in view of the above-mentioned conventional circumstances, and it is an object to be solved to provide a radio wave absorber capable of corresponding to a wide frequency band.

The radio wave absorber of the first invention is
A reflective layer that reflects radio waves,
A radio wave absorption layer with radio wave absorption performance and
A spacer layer arranged between the reflective layer and the radio wave absorbing layer,
Is equipped with
The radio wave absorbing layer is a resistor in which a radio wave absorbing material is dispersed.

The radio wave absorber of the second invention is
A reflective layer that reflects radio waves,
A radio wave absorbing layer having at least two layers of radio wave absorbing performance,
A spacer layer arranged on the reflection layer side for each radio wave absorption layer,
Is equipped with
At least one layer of each of the radio wave absorbing layers is a resistor in which a radio wave absorbing material is dispersed.

Since the radio wave absorbers of the first invention and the second invention are resistors in which the radio wave absorbing layer is dispersed with the radio wave absorbing material, they absorb radio waves by a principle different from that of the λ / 4 radio wave absorber. Therefore, in this radio wave absorber, the periodic peak of the attenuation amount does not appear clearly and the periodic drop does not appear clearly in a wide frequency band. That is, this radio wave absorber can correspond to a wide frequency band because there is no remarkable periodicity of the attenuation amount in a wide frequency band and there is no clear drop.

Further, the radio wave absorber of the second invention does not have a remarkable periodicity of the attenuation amount in a wide frequency band, can correspond to this wide frequency band, and increases the attenuation amount in the 1 GHz band (low frequency band). be able to.

The "reflective layer that reflects radio waves" in the first and second inventions refers to a layer having higher reflection performance than a layer other than the reflective layer. Further, the "radio wave absorption layer having radio wave absorption performance" in the first invention and the second invention means a layer having higher radio wave absorption performance than a layer other than the radio wave absorption layer.

It is a perspective view which cut out a part of the radio wave absorber of Example 1. FIG. It is a side view of the radio wave absorber of Example 1. FIG. It is a side view of the radio wave absorber of Example 2. It is a side view of the radio wave absorber of Example 3. It is a perspective view which cut out a part of the radio wave absorber of Example 4. It is a side view of the radio wave absorber of Example 4. FIG. It is a side view of the radio wave absorber of Example 5. It is a side view of the radio wave absorber of Example 6. It is a graph which shows the frequency characteristic of the attenuation amount of the radio wave absorber of Example 1. It is a graph which shows the frequency characteristic of the attenuation amount of the radio wave absorber of Example 2. It is a graph which shows the frequency characteristic of the attenuation amount of the radio wave absorber of Example 3. It is a graph which shows the frequency characteristic of the attenuation amount of the radio wave absorber of Example 4. It is a graph which shows the frequency characteristic of the attenuation amount of the radio wave absorber of Example 5. It is a graph which shows the frequency characteristic of the attenuation amount of the radio wave absorber of Example 6. It is a frequency characteristic graph which compared the attenuation amount of the λ / 4 type radio wave absorber with the attenuation amount of the radio wave absorber of Example 3 and Example 4. It is a frequency characteristic graph which compared the attenuation amount of each radio wave absorber of Example 2, Example 3, and Example 4. FIG.

Preferred embodiments of the present invention will be described.

In the radio wave absorber of the second invention, at least one layer of each radio wave absorbing layer may be a resistance film. In this case, the radio wave absorber can be reduced in thickness.

In the radio wave absorber of the second invention, the radio wave absorbing layer arranged at the position farthest from the reflecting layer on the radio wave arrival side may be the resistor. In this case, even if the radio wave absorber is irradiated with strong radio waves, the heat generation of the resistor is suppressed to a low level. Therefore, the temperature rise on the surface of the radio wave absorber on the radio wave arrival side is suppressed, and there is no risk of burns even if the surface of the radio wave absorber on the radio wave arrival side is touched. Further, even if the surface of the resistor on the radio wave arrival side is scratched, the influence of the radio wave absorption performance is small because the resistor is a resistor in which the radio wave absorbing material is dispersed. Further, since the surface of the radio wave absorber on the side where the radio wave arrives is a resistor in which the radio wave absorbing material is dispersed, this resistor is hard to oxidize and can stably absorb the radio wave for a long period of time.

Next, Examples 1 to 6 embodying the radio wave absorber of the present invention will be described with reference to the drawings.

<Example 1>
As shown in FIGS. 1 and 2, the radio wave absorber 10 of the first embodiment is a square flat plate having a side of 600 mm and a thickness of about 16 mm. The radio wave absorber 10 includes a reflection layer 11, a spacer layer 13, a radio wave absorption layer 15, and a finishing layer 17, and are laminated in this order. When the radio wave absorber 10 is arranged in a state of absorbing radio waves, the finishing layer 17 is positioned on the radio wave arrival side. In FIGS. 2 to 4, the direction of radio wave traveling is indicated by an arrow 1.

The reflective layer 11 is a square aluminum sheet having a side of 600 mm. The reflective layer 11 has higher reflective performance than the spacer layer 13, the radio wave absorbing layer 15, and the finishing layer 17. The spacer layer 13 is a square flat plate having a side of 600 mm and a thickness X1 of about 5 mm. The spacer layer 13 is a calcium carbonate foam material, and has a dielectric constant of about 1 which is substantially equal to that of air. The spacer layer 13 is adhesively fixed to the surface of the reflective layer 11 on the radio wave arrival side with a synthetic rubber adhesive. The spacer layer 13 is arranged between the reflection layer 11 and the radio wave absorption layer 15, and the distance between the reflection layer 11 and the radio wave absorption layer 15 is set to about 5 mm.

The radio wave absorbing layer 15 is a square flat plate having a side of 600 mm and a thickness X2 of about 10 mm. This resistor is made by dispersing carbon black (acetylene black, Ketjen black, etc.) which is a radio wave absorbing material in urethane material which is a base material. This resistor is obtained by immersing a urethane material in a solution in which carbon black is dispersed, allowing the solution to be sufficiently absorbed, and then squeezing and drying the resistor. This resistor is adhesively fixed to the surface of the spacer layer 13 on the radio wave arrival side with a synthetic rubber adhesive. This resistor absorbs radio waves by exchanging heat with the energy of the electromagnetic waves. The radio wave absorbing layer 15 has higher radio wave absorbing performance than the reflecting layer 11, the spacer layer 13, and the finishing layer 17.

The finishing layer 17 is a woven fabric made of glass fiber and has excellent heat resistance. The finishing layer 17 is adhesively fixed to the surface of the resistor which is the radio wave absorbing layer 15 on the radio wave arrival side with a synthetic rubber adhesive. As described above, the surface of the radio wave absorber 10 on the side where the radio wave arrives is covered with a woven fabric made of glass fiber which is the finishing layer 17.

<Example 2>
As shown in FIG. 3, the radio wave absorber 20 of the second embodiment is different from the radio wave absorber of the first embodiment in that the thickness X1 of the spacer layer 23 is about 10 mm. Therefore, the radio wave absorber 20 is a square flat plate having a side of 600 mm and a thickness of about 21 mm. Other points are the same as those of the radio wave absorber 10 of the first embodiment, and the same configurations are designated by the same reference numerals and detailed description thereof will be omitted.

The spacer layer 23 of the radio wave absorber 20 is also a calcium carbonate foam material, and has a dielectric constant of about 1 which is substantially equal to that of air. The spacer layer 23 is adhesively fixed to the surface of the reflective layer 11 on the radio wave arrival side with a synthetic rubber adhesive. The spacer layer 23 is arranged between the reflection layer 11 and the radio wave absorption layer 15, and the distance between the reflection layer 11 and the radio wave absorption layer 15 is set to about 10 mm. The reflective layer 11 has higher reflective performance than the spacer layer 23, the radio wave absorbing layer 15, and the finishing layer 17. Further, the radio wave absorbing layer 15 has higher radio wave absorbing performance than the reflecting layer 11, the spacer layer 23, and the finishing layer 17.

<Example 3>
As shown in FIG. 4, the radio wave absorber 30 of the third embodiment is different from the radio wave absorber 20 of the second embodiment in that the thickness of the radio wave absorbing layer 35 is about 20 mm. Therefore, the radio wave absorber 30 is a square flat plate having a side of 600 mm and a thickness of about 31 mm. Other points are the same as those of the radio wave absorber 20 of the second embodiment, and the same configurations are designated by the same reference numerals and detailed description thereof will be omitted.

The radio wave absorbing layer 35 of the radio wave absorber 30 is also a resistor in which carbon black, which is a radio wave absorbing material, is dispersed in urethane, which is a base material. This resistor is also obtained by immersing urethane in a solution in which carbon black is dispersed, allowing the solution to be sufficiently absorbed, and then squeezing and drying the resistor. This resistor is adhesively fixed to the surface of the spacer layer 23 on the radio wave arrival side with a synthetic rubber adhesive. This resistor absorbs radio waves by exchanging heat with the energy of the electromagnetic waves. The radio wave absorbing layer 35 has higher radio wave absorbing performance than the reflecting layer 11, the spacer layer 23, and the finishing layer 17. Further, the reflective layer 11 has higher reflective performance than the spacer layer 23, the radio wave absorbing layer 35, and the finishing layer 17.

<Example 4>
As shown in FIGS. 5 and 6, the radio wave absorber 40 of the fourth embodiment is a square flat plate having a side of 600 mm and a thickness of about 26 mm. The radio wave absorber 40 includes a reflection layer 41, a first spacer layer 43A, a first radio wave absorption layer 45A, a second spacer layer 43B, a second radio wave absorption layer 45B, and a finishing layer 47, and is laminated in this order. ing. When the radio wave absorber 40 is arranged in a state of absorbing radio waves, the finishing layer 47 is positioned on the radio wave arrival side. In FIGS. 6 to 8, the radio wave traveling direction is indicated by an arrow 1.

The reflective layer 41 is a square aluminum sheet having a side of 600 mm. The reflective layer 41 has higher reflective performance than the first spacer layer 43A, the first radio wave absorbing layer 45A, the second spacer layer 43B, the second radio wave absorbing layer 45B, and the finishing layer 47. The first spacer layer 43A is a square flat plate having a side of 600 mm and a thickness X1 of about 5 mm. The first spacer layer 43A is a calcium carbonate foam material, and has a dielectric constant of about 1 which is substantially equal to that of air. The first spacer layer 43A is adhesively fixed to the surface of the reflective layer 41 on the radio wave arrival side with a synthetic rubber adhesive. The first spacer layer 43A is arranged between the reflection layer 41 and the first radio wave absorption layer 45A, and the distance between the reflection layer 41 and the first radio wave absorption layer 45A is set to about 5 mm.

The first radio wave absorbing layer 45A is a resistance film having a side of 600 mm. This resistance film is formed by applying a resistance material in ink to the surface of a film-like polyethylene terephthalate material having a thickness of 1 mm or less, which is a base material, to form a resistance film layer. The surface resistance value of this resistance film is set to 190Ω / □. This resistance film absorbs radio waves by exchanging heat with the energy of electromagnetic waves. The first radio wave absorbing layer 45A has higher radio wave absorbing performance than the reflective layer 41, the first spacer layer 43A, the second spacer layer 43B, and the finishing layer 47.

The second spacer layer 43B is a square flat plate having a side of 600 mm and a thickness X3 of about 10 mm. The second spacer layer 43B is also a calcium carbonate foam material, and has a dielectric constant of about 1 which is substantially equal to that of air. The second spacer layer 43B is adhesively fixed to the surface of the first radio wave absorbing layer 45A on the radio wave arrival side with a synthetic rubber adhesive. The second spacer layer 43B is arranged between the resistance film which is the first radio wave absorbing layer 45A and the resistor which is the second radio wave absorbing layer 45B, and the distance between the first radio wave absorbing layer 45A and the radio wave absorbing layer is increased. It is set to about 10 mm.

The second radio wave absorbing layer 45B is a square flat plate having a side of 600 mm and a thickness X4 of about 10 mm. This resistor is made by dispersing carbon black, which is a radio wave absorbing material, in urethane material, which is a base material. This resistor is obtained by immersing a urethane material in a solution in which carbon black is dispersed, allowing the solution to be sufficiently absorbed, and then squeezing and drying the resistor. This resistor is adhesively fixed to the surface of the second spacer layer 43B on the radio wave arrival side with a synthetic rubber adhesive. This resistor absorbs radio waves by exchanging heat with the energy of the electromagnetic waves. The second radio wave absorbing layer 45B has higher radio wave absorbing performance than the reflective layer 41, the first spacer layer 43A, the second spacer layer 43B, and the finishing layer 47.

The finishing layer 47 is a woven fabric made of glass fiber and has excellent heat resistance. The finishing layer 47 is adhesively fixed to the surface of the resistor which is the second radio wave absorbing layer 45B on the radio wave arrival side with a synthetic rubber adhesive. In this way, the surface of the radio wave absorber 40 on the side where the radio wave arrives is covered with a woven fabric made of glass fiber which is the finishing layer 47.

<Example 5>
As shown in FIG. 7, the radio wave absorber 50 of the fifth embodiment is different from the radio wave absorber 40 of the fourth embodiment in that the first radio wave absorbing layer 55A is a resistor. The first radio wave absorbing layer 55A is a square flat plate having a side of 600 mm and a thickness X2 of about 10 mm. Therefore, the radio wave absorber 50 is a square flat plate having a side of 600 mm and a thickness of about 36 mm. Other points are the same as those of the radio wave absorber 40 of the fourth embodiment, and the same configurations are designated by the same reference numerals and detailed description thereof will be omitted.

The resistor which is the first radio wave absorbing layer 55A of the radio wave absorber 50 is also made by dispersing carbon black, which is a radio wave absorbing material, in a urethane material which is a base material. This resistor is also obtained by immersing a urethane material in a solution in which carbon black is dispersed, allowing the solution to be sufficiently absorbed, and then squeezing and drying the resistor. This resistor is adhesively fixed to the surface of the first spacer layer 43A on the radio wave arrival side with a synthetic rubber adhesive. This resistor absorbs radio waves by exchanging heat with the energy of the electromagnetic waves. The first radio wave absorbing layer 55A has higher radio wave absorbing performance than the reflecting layer 41, the first spacer layer 43A, the second spacer layer 43B, and the finishing layer 47. Further, the reflective layer 41 has higher reflective performance than the first spacer layer 43A, the first radio wave absorbing layer 55A, the second spacer layer 43B, the second radio wave absorbing layer 45B, and the finishing layer 47.

<Example 6>
As shown in FIG. 8, the radio wave absorber of the sixth embodiment has a point where the thickness X1 of the first spacer layer 63A is 10 mm, a point where the thickness X3 of the second spacer layer 63B is 5 mm, and a second radio wave. It differs from the radio wave absorber 50 of Example 5 in that the absorption layer 65B is a resistance film. Therefore, the radio wave absorber 60 is a square flat plate having a side of 600 mm and a thickness of about 26 mm. Other points are the same as those of the radio wave absorber 50 of the fifth embodiment, and the same configurations are designated by the same reference numerals and detailed description thereof will be omitted.

The first spacer layer 63A and the second spacer layer 63B of the radio wave absorber 60 are also calcium carbonate foam materials, and are formed to have a dielectric constant of about 1 which is substantially equal to that of air. The first spacer layer 63A is adhesively fixed to the surface of the reflective layer 41 on the radio wave arrival side with a synthetic rubber adhesive. The first spacer layer 63A is arranged between the reflection layer 41 and the first radio wave absorption layer 55A, and the distance between the reflection layer 41 and the resistor which is the first radio wave absorption layer 55A is set to about 10 mm. The reflective layer 41 has higher reflective performance than the first spacer layer 63A, the first radio wave absorbing layer 55A, the second spacer layer 63B, the second radio wave absorbing layer 65B, and the finishing layer 47. The first radio wave absorbing layer 55A has higher radio wave absorbing performance than the reflecting layer 41, the first spacer layer 63A, the second spacer layer 63B, and the finishing layer 47.

The second spacer layer 63B is adhesively fixed to the surface of the resistor which is the first radio wave absorbing layer 55A on the radio wave arrival side with a synthetic rubber adhesive. The second spacer layer 63B is arranged between the resistor which is the first radio wave absorbing layer 55A and the resistance film which is the second radio wave absorbing layer 65B, and the first radio wave absorbing layer 55A and the second radio wave absorbing layer 65B The distance is set to about 5 mm.

The resistance film, which is the second radio wave absorbing layer 65B of the radio wave absorber 60, is formed by inking and applying a resistance material to the surface of a film-like polyethylene terephthalate material having a thickness of 1 mm or less, which is a base material. It is a thing. The surface resistance value of this resistance film is set to 190Ω / □. This resistance film absorbs radio waves by exchanging heat with the energy of electromagnetic waves. The second radio wave absorbing layer 65B has higher radio wave absorbing performance than the reflective layer 41, the first spacer layer 63A, the second spacer layer 63B, and the finishing layer 47.

Next, the frequency characteristic graphs of the attenuation amounts of the radio wave absorbers 10, 20, 30, 40, 50, and 60 of Examples 1 to 6 are shown in FIGS. 9 to 14. Further, FIG. 15 shows a frequency characteristic graph comparing the attenuation of the λ / 4 type radio wave absorber with the attenuation of the radio wave absorbers 30 and 40 of Examples 3 and 4.

From these graphs, each of the radio wave absorbers 10, 20, 30, 40, 50, 60 of Examples 1 to 6 does not clearly show a periodic peak of the attenuation amount at a frequency of 1 GHz to 40 GHz, and is periodic. It can be seen that the depression does not appear clearly. This means that, as shown in FIG. 15, from 1.2 GHz to 11.2 GHz, the attenuation of the λ / 4 type radio wave absorber has two peaks periodically, whereas in Examples 3 and 11. It is clear that the attenuation of the radio wave absorbers 30 and 40 of No. 4 does not clearly show a periodic peak. In this λ / 4 type radio wave absorber, a resistance film having a surface resistance value of 377 Ω / □ is arranged at a position 25 mm away from the radio wave reflector.

As described above, each of the radio wave absorbers 10, 20, 30, 40, 50, 60 of Examples 1 to 6 does not have a remarkable periodicity of the attenuation amount in a wide frequency band, and therefore there is no clear drop. It can support a wide frequency band.

Next, FIG. 16 shows a frequency characteristic graph of the attenuation of each of the radio wave absorbers 20, 30, and 40 of Example 2, Example 3, and Example 4. In FIG. 16, the graph showing the frequency characteristic of the attenuation of the radio wave absorber 20 is G1, and the graph showing the frequency characteristic of the attenuation of the radio wave absorber 30 is G2, and the frequency characteristic of the attenuation of the radio wave absorber 40. The graph showing is G3. From these graphs, it can be seen that the radio wave absorber 40 has a larger amount of attenuation in the 1 GHz band (low frequency band) near 1.2 GHz to 1.5 GHz than the radio wave absorbers 20 and 30. That is, compared to the radio wave absorbers 20 and 30 in which the radio wave absorbing layers 15 and 35 and the spacer layer 23 are laminated one by one, two layers of the radio wave absorbing layers 45A and 45B and the spacer layers 43A and 43B are alternately laminated. It is considered that the radio wave absorber 40 is attenuated in a larger amount in the low frequency band.

The radio wave absorbers 10, 20, 30, 40, 50, 60 of Examples 1 to 6 are attached to an indoor wall surface, a ceiling surface, or the like. At this time, in these radio wave absorbers 10, 20, 30, 40, 50, 60, the reflective layers 11 and 41 are arranged on the indoor wall surface side and the ceiling surface side. Since these radio wave absorbers 10, 20, 30, 40, 50, 60 are provided with the reflective layers 11, 41, the indoor wall surface, ceiling surface, or the like to be attached does not need to be a metal body. That is, these radio wave absorbers 10, 20, 30, 40, 50, 60 can be used as a retrofitting interior material, and a shield room can be formed.

Further, since these radio wave absorbers 10, 20, 30, 40, 50, 60 are 600 mm square flat plates, the number of mountings can be adjusted according to the size of the indoor wall surface or ceiling, or the shape of the indoor wall surface or ceiling. By setting the mounting position according to the above, it is possible to correspond to any wide shape.

Further, the following methods can be considered as the method of attaching these radio wave absorbers 10, 20, 30, 40, 50, 60 to the indoor wall surface, ceiling, or the like.
-Install using adhesive.
-It can be attached and detached using magnetic force.
-Attachable to be attached and detached using a hook-and-loop fastener.
-It can be attached and detached using a suction cup.
-Hang it using a hook, etc. and attach it detachably.
・ Make it a tsuitate so that it can stand on its own and leave it movable.
-Install using joiner material.
・ Install by the glass cloth post-pasting method.

Further, these radio wave absorbers 10, 20, 30, 40, 50, 60 can be used in the following places.
-Interior parts such as indoor walls and ceilings (In addition to the purpose of improving the existing indoor radio wave environment, improve the basic performance of the shield room and make it a simple anechoic chamber)
・ Mobile radio wave absorption propulsion ・ Inside of electronic and electrical equipment storage racks ・ Radio communication equipment ・ Radio laboratory equipment ・ Medical electronic and electrical equipment

As described above, the radio wave absorbers 10, 20, 30, 40, 50, 60 of Examples 1 to 6 have a radio wave absorption performance and an aluminum sheet which is a reflection layer 11, 41 that reflects radio waves. The dielectric constants of the spacer layers 13, 23, 43A, 43B, 63A arranged between the radio wave absorbing layers 15, 35, 45B, 55A, the reflecting layers 11, 41, and the radio wave absorbing layers 15, 35, 45B, 55A. The radio wave absorbing layer 15, 35, 45B, 55A is a resistor in which carbon black, which is a radio wave absorbing material, is dispersed.

Further, the radio wave absorbers 40, 50, 60 of Examples 4 to 6 are an aluminum sheet which is a reflection layer 41 for reflecting radio waves, and first radio wave absorption layers 45A, 55A and second radio waves having radio wave absorption performance. Absorption layers 45B, 65B, first spacer layers 43A, 63A arranged on the reflection layer 41 side of the first radio wave absorption layers 45A, 55A, and second radio wave absorption layers 45B, 65B arranged on the reflection layer 41 side. The two spacer layers 43B and 63B are provided with a calcium carbonate foam material having a dielectric constant of about 1, and the first radio wave absorbing layer 55A and the second radio wave absorbing layer 45B are dispersed with carbon black, which is a radio wave absorbing material. It is a resistor.

The radio wave absorbers 10, 20, 30, 40, 50, and 60 of Examples 1 to 6 are λ / 4 radio waves because the radio wave absorbing layers 15, 35, 45B, and 55A are resistors in which carbon black is dispersed. It absorbs radio waves on a principle different from that of an absorber. Therefore, in these radio wave absorbers 10, 20, 30, 40, 50, 60, the periodic peak of the attenuation amount does not appear clearly and the periodic drop does not appear clearly in the wide frequency band. That is, these radio wave absorbers 10, 20, 30, 40, 50, 60 can correspond to a wide frequency band because there is no remarkable periodicity of the attenuation amount in the wide frequency band and there is no clear drop.

Further, the radio wave absorbers 40, 50, and 60 of Examples 4 to 6 do not have periodicity of attenuation in a wide frequency band, can correspond to this wide frequency band, and can handle the 1 GHz band (low frequency band). ) Can be increased.

Further, in the radio wave absorber 40 of the fourth embodiment, the first radio wave absorbing layer 45A is a resistance film, and in the radio wave absorber 60 of the sixth embodiment, the second radio wave absorbing layer 65B is a resistance film. These resistance films are formed by applying a resistance material in ink to the surface of a film-like polyethylene terephthalate material having a thickness of 1 mm or less, which is a base material, to form a resistance film layer. As a result, the thickness of these radio wave absorbers 40 and 60 can be reduced.

Further, in the radio wave absorbers 40 and 50 of Examples 4 and 5, carbon black, which is a radio wave absorbing material, is dispersed in the second radio wave absorbing layer 45B arranged at the position farthest from the aluminum sheet which is the reflecting layer 41. It is a resistor that has been made. Therefore, even if the radio wave absorbers 40 and 50 are irradiated with strong radio waves, the heat generation of the resistor which is the second radio wave absorbing layer 45B can be suppressed to a low level. Therefore, the temperature rise on the surface of the radio wave absorbers 40 and 50 on the radio wave arrival side is suppressed, and there is no risk of burns even if the surface of these radio wave absorbers 40 and 50 is touched on the radio wave arrival side. Further, even if the surface of the second radio wave absorption layer 45B on the radio wave arrival side is scratched, the influence of the radio wave absorption performance is small because it is a resistor in which carbon black is dispersed. Further, since the surface of these radio wave absorbers 40 and 50 on the radio wave arrival side is a resistor in which carbon black is dispersed, it is difficult to oxidize and can stably absorb radio waves for a long period of time. Further, a resistor formed by coating a second radio wave absorbing layer located on the surface on the radio wave arrival side on the surface of a film-like polyethylene terephthalate material having a thickness of 1 mm or less, which is a base material, by inking a resistance material into ink. When trying to make a film, it is necessary to increase the resistance, but it is difficult to manufacture the resistance film by increasing the resistance value so as not to exhibit the reflection characteristics.

The present invention is not limited to Examples 1 to 6 described with reference to the above description and drawings, and for example, the following examples are also included in the technical scope of the present invention.
(1) In Examples 1 to 6, the spacer layer was a calcium carbonate foaming agent, but if the dielectric constant is about 1, even a styrene material, a urethane material, a glass fiber material, a resin material, or the like can be used. Good. Further, when the spacer layer is thinned, a material having a high dielectric constant may be used to form the spacer layer.
(2) In Examples 1 to 6, the resistor of the radio wave absorbing layer was made by dispersing carbon black, which is a radio wave absorbing material, in urethane material, which is a base material, but the base material is other than urethane material. It may be a foamed resin material such as foamed styrol, concrete / mortar material, gypsum material, or the like. Further, the radio wave absorbing material may be a ferrite type such as spinel ferrite, hexagonal ferrite, and garnet ferrite.
(3) In Examples 4 and 6, the resistance film was formed by applying an ink-based resistance material to the surface of a polyethylene terephthalate material as a base material to form a resistance film layer. Any material may be used as long as it has a smooth surface and does not have conductivity, and may be an acrylic material, a polycarbonate material, or the like. Further, the resistance film layer may be formed by depositing gold, silver, aluminum, stainless steel, titanium, chromium, indium tin oxide or the like, or may be formed by applying metal powder, carbon, ferrite or the like.
(4) In Examples 4 and 6, the surface resistance value of the resistance film is set to 190Ω / □, but the surface resistance value of the resistance film may be appropriately set in the range of about 50Ω / □ to 400Ω / □.
(5) The thickness of the spacer layer of the radio wave absorbers of Examples 1 to 6 and the thickness of the resistor of the radio wave absorption layer may be appropriately changed.
(6) The radio wave reflectors of Examples 1 to 6 were square flat plates having a side of 600 mm, but the size of one side is not limited to 600 mm. Further, the radio wave reflector is not limited to a square shape, and may be a flat plate having an arbitrary shape such as a rectangular shape.
(7) The radio wave reflectors of Examples 1 to 6 could be made into a square flat plate having a side of 600 mm and used as an interior material for retrofitting. A spacer layer and a radio wave absorbing layer may be laminated on the surface side to form a radio wave absorber of Examples 1 to 6 and the like.
(8) In Examples 1 to 6, the finishing layer is provided, but the finishing layer may not be provided.
(9) In Examples 1 to 3, the radio wave absorbing layer and the spacer layer are laminated one layer at a time, and in Examples 4 to 5, the radio wave absorbing layer and the spacer layer are alternately two layers each. However, three or more layers of the radio wave absorbing layer and the spacer layer may be alternately laminated. In this case, at least one of the plurality of radio wave absorbing layers is a resistor.

10, 20, 30, 40, 50, 60 ... Radio wave absorber 11, 41 ... Reflective layer 15, 35, 45A, 45B, 55A, 65B ... Radio wave absorbing layer (15, 35, 45B, 55A ... Resistor, 45A, 65B ... Resistive film)
… Spacer layer

Claims (4)

A reflective layer that reflects radio waves,
A radio wave absorption layer with radio wave absorption performance and
A spacer layer arranged between the reflective layer and the radio wave absorbing layer,
Is equipped with
The radio wave absorbing layer is a radio wave absorber which is a resistor in which a radio wave absorbing material is dispersed. A reflective layer that reflects radio waves,
A radio wave absorbing layer having at least two layers of radio wave absorbing performance,
A spacer layer arranged on the reflection layer side for each radio wave absorption layer,
Is equipped with
At least one layer of each of the radio wave absorbing layers is a radio wave absorber which is a resistor in which a radio wave absorbing material is dispersed. The radio wave absorber according to claim 2, wherein at least one layer of each radio wave absorbing layer is a resistance film. The radio wave absorber according to claim 2 or 3, wherein the radio wave absorption layer arranged at a position farthest from the reflection layer on the radio wave arrival side is the resistor.