JP2005086022A - Electromagnetic-wave absorber - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electromagnetic-wave absorber having a transparency, an excellent electromagnetic-wave absorbing characteristic, an abundant weather resistance, and a durability. <P>SOLUTION: The electromagnetic-wave absorber has a first transparent resin layer 1, a resistance film layer 2, a second transparent resin film layer 3, and a conductive film layer 4 in this order from a front-surface side A of an electromagnetic-wave incident surface side. Further, the absorber has a third transparent resin layer 5 having a different thickness T<SB>3</SB>from a thickness T<SB>1</SB>of the first transparent resin layer 1 on the rear-surface side of the conductive film layer 4. Also, a front surface 1a of the first transparent resin layer 1 and a rear surface 5b of the third transparent resin layer 5 are subjected respectively to weather-resistant treatments. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a radio wave absorber.

In an automatic toll collection system (ETC system) on toll roads such as expressways that are being introduced in recent years, radio waves for absorbing unwanted radio waves in the vicinity of toll booths to eliminate equipment malfunctions due to unnecessary radio waves An absorber (radio wave absorption panel) is installed.
Until now, the electromagnetic wave absorbers used in the ETC system have been developed and installed on the back of the toll booth and the underpass of the elevated road.
In addition, there is often only one lane (gate) dedicated to ETC at one toll gate, but recently, with the spread of the ETC system, there are multiple ETC dedicated lanes at one toll gate. The need to provide lanes has emerged. As the number of ETC-dedicated lanes increases, it has become necessary to absorb radio waves between lanes for the purpose of preventing malfunctions caused by unnecessary radio waves between adjacent lanes.
However, in addition to the absorption characteristics of obliquely incident radio waves, the characteristics required of the radio wave absorber laid between the lanes need to be transparent in order not to give the driver a feeling of pressure and to ensure visibility. It is said that.
A conventionally known transparent wave absorber is a λ / 4 type wave absorber (see, for example, Patent Document 1). λ is the wavelength of the radio wave to be absorbed, and in an environment in the ETC system, for example, λ = 51.7 mm. This λ / 4 type wave absorber is formed of a resistance film, a dielectric, and a radio wave reflection film from the incident surface side of the radio wave.
Japanese Patent Laid-Open No. 6-120688

However, this λ / 4 type wave absorber has a limit in radio wave absorption characteristics, and in particular, the radio wave absorption characteristics for radio waves having a large incident angle with respect to the panel-shaped radio wave absorber are insufficient.
In addition, the electromagnetic wave absorber used in the ETC system is installed outdoors, but this electromagnetic wave absorber is poor in environmental resistance (weather resistance) such as deterioration due to temperature change and deterioration due to exhaust gas. There is a problem that it cannot be applied.

  Accordingly, an object of the present invention is to provide a radio wave absorber that is transparent, excellent in radio wave absorption characteristics, rich in weather resistance, and durable.

In order to achieve the above-described object, the radio wave absorber according to the present invention includes a first transparent resin layer, a resistance film layer, a second transparent resin layer, and a conductive layer from the front surface side, which is the radio wave incident surface side. And a third transparent resin layer having a thickness different from the thickness of the first transparent resin layer on the back side of the conductive film layer.
Moreover, the weather resistance process was given to the surface of the said 1st transparent resin layer, and / or the back surface of the said 3rd transparent resin layer.
Further, a frame material is attached to the side peripheral surface of the laminated panel body composed of the first transparent resin layer to the third transparent resin layer.
The laminated panel body to which the frame material is attached is erected between the lanes at the toll gate of the toll road standing upright.

A first transparent resin layer having a laminated structure composed of a resistive film layer, a conductive film layer and three transparent resin layers, but having different thicknesses on the front surface side which is the radio wave incident surface side and on the back surface side on the opposite surface side And the third transparent resin layer, the expansion of the radio wave absorber due to temperature change (thermal expansion, thermal contraction) is unidirectional, that is, the surface distortion is prevented, the undulation is suppressed, and the bonding interface It is possible to provide durability without causing separation between the layers. In other words, it can be installed outdoors even in direct sunlight.
Furthermore, since the first transparent resin layer and the third transparent resin layer function as protective layers, a highly durable transparent radio wave absorber can be obtained.
In addition, the first transparent resin layer can improve the oblique incidence characteristics of radio waves, and can effectively absorb radio waves from a wide range.

  Hereinafter, the present invention will be described in detail based on the illustrated embodiment.

  FIG. 1 is an enlarged side view showing an embodiment of a radio wave absorber according to the present invention. This radio wave absorber (radio wave absorption panel) is optically transparent—visible light transmittance of 60% or more. For example, it is used in an ETC system on a toll road such as a highway. And this transparent electromagnetic wave absorber can be arrange | positioned between the lanes (between gates) in a toll booth. In the case of this ETC system, it is set as a thing with respect to the electromagnetic wave of a frequency band of 5.8 GHz.

  As shown in FIG. 1, the radio wave absorber according to the present invention includes a first transparent resin layer 1 and a resistive film layer from the front surface side A which is the radio wave incident surface side (the surface side where radio waves are intended to be incident). 2, a second transparent resin layer 3, a conductive film layer (reflection film layer) 4, and a third transparent resin layer 5. And the laminated panel body 6 which consists of these 1st transparent resin layers 1 to the 3rd transparent resin layer 5 is installed orient | assigned to the direction in which the 1st transparent resin layer 1 injects an electromagnetic wave. That is, as the whole laminated panel body 6, the first transparent resin layer 1 appears and becomes the surface side A, and the third transparent resin layer 5 becomes the back surface side B.

Further, the thickness T ₁ of the first transparent resin layer 1 and the thickness T ₃ of the third transparent resin layer 5, and the different thicknesses (value). Thereby (as will be described later), the laminated panel body 6 has a laminated structure in which the thermal expansion coefficients of the three transparent resin layers sandwiching the resistive film layer 2 and the conductive film layer 4 are different in each layer. With the first and third transparent resin layers 1 and 5 having different temperatures, the expansion of the entire radio wave absorber due to the temperature change is made in one direction, the undulation is suppressed, and peeling between the respective layers at the bonding interface is not caused. .

Next, each layer will be described. First, the first transparent resin layer 1 is made of a transparent resin plate, and the thickness of the resin plate is the layer thickness T ₁ .
The thickness T ₁ of the first transparent resin layer 1 (transparent resin plate) is set to 2.5 mm to 7.8 mm, and particularly preferably 3 mm to 6 mm.

The second transparent resin layer 3 and the third transparent resin layer 5 will be described. The second and third transparent resin layers 3 and 5 are also made of a transparent resin plate. The plate thickness is the layer thickness T ₂ , and the plate thickness of the resin plate of the third transparent resin layer 5 is the layer thickness T ₃ .
The thickness T ₂ of the second transparent resin layer 3 (transparent resin plate) is set to 2.5 mm to 7.8 mm, and the thickness T ₂ is particularly preferably 3 mm to 6 mm.
Although the thickness T ₃ of the third transparent resin layer 5 (transparent resin plate) is different from the thickness T _{1 of} the first transparent resin layer 1, in particular, from the thickness T _{1 of} the first transparent resin layer 1. It is preferable to reduce the thickness. By reducing the total thickness T of the radio wave absorber, the manufacturing cost can be reduced and the laying space can be reduced. In particular, a thinner one is preferable between lanes of toll booths where the installation space is determined (limited).
Therefore, the thickness T ₃ of the third transparent resin layer 5 is set to 1 mm to 4 mm, and the thickness T ₃ is particularly preferably 2 mm to ₃ mm.

These transparent resin plates of the first, second, and third transparent resin layers 1, 3, and 5 are optically transparent—visible light transmittance of 60% or more—and are made of the same material. However, the material and production method thereof are not particularly limited, and the material and the production method may be those produced by a known production method using a known resin material.
However, in the present invention, these three layers of transparent resin plates are preferably made of dielectric materials having suitable dielectric constants. Specifically, polycarbonate resin (PC), acrylic resin (AC), polyester resin ( PE), vinyl chloride resin (PVC), polymethyl methacrylate resin (PMMA) and the like are preferable. In particular, polycarbonate resin is preferable from the viewpoint of weather resistance and impact resistance.

Next, the resistance film layer 2 will be described. Although the material is not limited, a thin metal oxide or metal mesh is used so that the radio wave absorber to be manufactured is transparent (translucent) to visible light as a whole. Etc. are used.
In the case of a metal oxide, it can be produced by a known production method such as sputtering or vapor deposition. Examples of the thin metal oxide include indium tin oxide (ITO) and tin oxide.

As a specific method for producing the resistance film layer 2, as shown in FIG. 1, a metal oxide thin film 10 is formed on a film 9 made of polyethylene terephthalate resin (PET) by sputtering. That is, in this case, the resistive film layer 2 is composed of the film 9 and the thin film 10, and the film 9 is on the second transparent resin layer 3 side. The film 9 may have a thickness and a material that do not affect the radio wave absorption characteristics. For example, in the case of a polyethylene terephthalate resin, the film 9 may have a thickness of about 20 μm to 150 μm (preferably 20 μm to 125 μm). In addition, a resin other than polyethylene terephthalate resin may be used as long as the thickness and material do not affect the radio wave absorption characteristics.
Alternatively, although not shown, a thin film of metal oxide is formed by direct sputtering on the back surface side of the first transparent resin layer 1 and / or the front surface side of the second transparent resin layer 3, and the resistance film layer 2 is formed into this thin film. It is good only as well.

Further, the surface resistance value (surface resistivity) in the resistive film layer 2 is set to 160Ω / □ to 350Ω / □. When the surface resistance value is less than 160Ω / □ or exceeds 350Ω / □, preferable oblique incident wave absorption characteristics cannot be obtained with respect to 5.8 GHz radio waves. That is, as shown in FIG. 1, when the incident angle θ is an angle formed with a straight line perpendicular to the incident surface of the radio wave absorber, the surface resistance value is less than 160Ω / □ or more than 350Ω / □. When the incident angle θ is in the range of 0 ° to 47.5 ° in a radio wave of .8 GHz, it is not possible to obtain an absorption characteristic with a return loss of 20 dB or more.
The surface resistance value (rate) is a resistance per unit area defined in JIS K 7194 (unit: Ω / □).

Next, the conductive film layer 4 will be described. The conductive film layer 4 functions as a reflective layer, and the material is not limited. However, the radio wave absorber to be manufactured is transparent (translucent) to visible light as a whole. A thin metal film, a metal oxide film, a metal mesh, or the like is used.
In the case of a metal film, it can be produced by a known production method such as sputtering or vapor deposition. Examples of the metal of the thin film include silver (Ag).
In the case of a metal mesh, it can be manufactured by knitting resin fibers plated with metal on the outer periphery, metal plating on a knitted resin fiber, or punching a metal foil by punching. Among these, a metal mesh with a wire mesh with a wire diameter of 0.2 mm or less and a mesh of 50 or less (that is, a coarse mesh = does not reduce light transmission) is preferable. Specifically, commercially available products such as Seiren 4X series and 4F series can be used.
In the case of a metal oxide, it can be produced by a known production method such as sputtering or vapor deposition. Examples of the thin metal oxide include indium tin oxide (ITO) and tin oxide.

As a specific method for producing the conductive film layer 4, as shown in FIG. 1, a metal oxide or metal thin film 12 is formed on a film 11 made of polyethylene terephthalate resin (PET) by sputtering. That is, in this case, the conductive film layer 4 includes the film 11 and the thin film 12, and the film 11 is on the second transparent resin layer 3 side. The film 11 may have a thickness and a material that do not affect the radio wave absorption characteristics. For example, in the case of a polyethylene terephthalate resin, the film 11 may have a thickness of about 20 μm to 150 μm (preferably 20 μm to 125 μm).
In addition, a resin other than polyethylene terephthalate resin may be used as long as the thickness and material do not affect the radio wave absorption characteristics.
Alternatively, although not shown in the drawings, a thin film of metal oxide is formed by direct sputtering on the back surface side of the second transparent resin layer 3 and / or the front surface side of the third transparent resin layer 5, and the conductive film layer 4 is formed into this thin film. It is good only as well.

  Further, the surface resistance value in the conductive film layer 4 is set to 0.01Ω / □ to 40Ω / □. In particular, it is preferably 0.14Ω / □ to 10Ω / □. When the surface resistance value exceeds 40Ω / □, the transmission attenuation amount is less than 15 dB, and unnecessary radio waves incident from the first transparent resin layer 1 are transmitted to the third transparent resin layer 5 (back surface side B). Moreover, it is difficult to produce a surface resistance value of less than 0.01 Ω / □, which tends to increase the product cost and decrease the visible light transmittance.

The surface resistance values of the resistance film layer 2 and the conductive film layer 4 can be controlled by the following method. For example, when these are formed by sputtering of indium tin oxide, a desired surface resistance value can be easily obtained by adjusting the film thickness according to the sputtering time, atmosphere, and the like.
Further, when the resistance film layer 2 and the conductive film layer 4 are metal meshes, the surface resistance value can be controlled by adjusting the plating thickness according to the current density, time, etc. when metal plating is performed on the resin fiber. Furthermore, when a resistance film is formed by weaving a fine wire of wire mesh, stainless steel, or brass, the surface resistance value can be controlled by the density of the weave and the material of the fine wire.

  The first transparent resin layer 1 and the third transparent resin layer 5 will be further described. The first transparent resin layer 1 becomes a radio wave incident surface and can improve oblique incidence characteristics, greatly affecting radio wave absorption characteristics, It becomes a protective material for the resistive film layer 2. On the other hand, the third transparent resin layer 5 is on the back side opposite to the radio wave incident surface side and does not affect the radio wave absorption characteristics. However, the third transparent resin layer 5 serves as a protective material for the conductive film layer 4 and is not bent by the second transparent resin layer 3 due to temperature change. ) Can be absorbed (corrected).

In particular, the third transparent resin layer 5 and the first transparent resin layer 1 have the same thermal expansion by making the thickness T _{3 of} the third transparent resin layer 5 different from the thickness T ₁ of the first transparent resin layer 1. Even with a coefficient (same linear expansion coefficient), peeling at the center of the panel can be avoided by flexing to one of the panels bonded together when expanding and contracting due to the difference in thickness.

  In addition, weathering treatment is performed on the front surface 1 a of the first transparent resin layer 1 and / or the back surface 5 b of the third transparent resin layer 5. Specifically, the weather resistance treatment is performed by covering the surface 1a of the first transparent resin layer 1 and the back surface 5b of the third transparent resin layer 5 with the weather resistant films 13 and 14 to protect the radio wave absorber. Yes. The material of the weather resistant films 13 and 14 may be any material that can absorb ultraviolet rays. For example, it may be a transparent (translucent) paint containing a light stabilizer, an ultraviolet absorber, etc. It is processed by applying. Note that the thickness of the weather resistant films 13 and 14 may be set to a thickness that does not deteriorate the radio wave absorption characteristics and transparency.

Further, the cross section of FIG. 5 is formed on the side peripheral surface 6a of the laminated panel body 6 composed of the first transparent resin layer 1, the resistance film layer 2, the second transparent resin layer 3, the conductive film layer 4, and the third transparent resin layer 5. As shown in the side view, a frame material 7 is attached. The frame material 7 is attached to the laminated panel body 6 via a sealant 8 such as silicon sealant (Cemedine 8050, manufactured by Cemedine Co., Ltd.), and prevents foreign substances such as rainwater from entering (invading). That is, the side peripheral surface 6 a perpendicular to the bonding surface of the laminated panel body 6 is protected by the sealing agent 8 and the frame material 7.
The shape of the frame material 7 is a U-shaped cross section that sandwiches the edge of the laminated panel body 6 from both sides, and the frame material 7 has four linear members that surround the rectangular laminated panel body 6 from four sides, and absorbs radio waves. Increases body rigidity. Further, the material of the frame member 7 is made of aluminum, aluminum alloy, or the like to reduce the weight.

The laminated panel body 6 to which the frame material 7 is attached is erected in an upright shape and is laid between adjacent lanes in the vicinity of the toll gate on the toll road.
As a result, the radio wave absorber can separate adjacent driving lanes and is transparent. Therefore, the radio wave absorber is safe because it does not give a feeling of pressure to a driver of a traveling vehicle and can ensure visibility.

  Next, the manufacturing method of the radio wave absorber according to the present invention will be described with reference to perspective views shown in FIGS. 2, 3 and 4. In FIG. 2 (a), reference numeral 15 denotes a resistance subjected to a conductive treatment. The resistance film 16 is a roll in which a film 16 is wound, and is formed by forming an indium tin oxide film as a conductive surface on a thin film made of, for example, polyethylene terephthalate resin. This is cut to form a resistive film 16 having a predetermined length. Moreover, in FIG.2 (b), 17 is a 1st transparent resin board which has a weathering processing surface (weathering film | membrane 13) on one surface (lower surface), and sticks the adhesive sheet 18 on the other surface. Then, the cut resistive film 16 is bonded to the transparent resin plate 17 so that the pressure-sensitive adhesive sheet 18 and the conductive treatment surface overlap each other, thereby producing a first intermediate product 31 (c).

  Further, as shown in FIG. 3 (d), 19 is a roll around which a conductive film 20 subjected to a conductive treatment is wound, and the conductive film 20 is, for example, a thin film made of polyethylene terephthalate resin. A silver film is formed as a conductive treatment surface. This is cut to obtain a conductive film 20 having a predetermined length. Moreover, in FIG.3 (e), 21 is a 3rd transparent resin board which has a weathering processing surface (weathering film | membrane 14) on one surface (lower surface), and sticks the adhesive sheet 22 on the other surface. Then, the cut conductive film 20 is bonded to the transparent resin plate 21 so that the adhesive sheet 22 and a thin film made of resin are overlapped to produce a second intermediate product 32 (f).

  Moreover, in FIG.3 (g), 23 is a 2nd transparent resin board, and the adhesive sheet 24 is stuck on the one surface. Then, the transparent resin plate 23 and the second intermediate product 32 are bonded together so that the adhesive sheet 24 and the conductive film 20 are overlapped to produce a third intermediate product 33 (h). And the adhesive sheet 25 is affixed on the 2nd transparent resin board 23 side of the 3rd intermediate product 33, and the 4th intermediate product 34 is produced (i).

Then, as shown in FIG. 4 (j), the first intermediate product 31 and the fourth intermediate product 34 are bonded so that the resistive film 16 and the second transparent resin plate 23 overlap with the adhesive sheet 25 interposed therebetween. Then, the laminated panel body 6 is produced, and the frame material 7 is attached to the side peripheral surface 6a of the laminated panel body 6 as shown in FIG.
The pressure-sensitive adhesive sheets 18, 22, 24, 25 may be of a thickness and material that do not affect the radio wave absorption characteristics. For example, in the case of an acrylic pressure-sensitive adhesive material, 20 μm to 75 μm (preferably, 20 μm to 50 μm).

Next, a specific configuration of the radio wave absorber according to the present invention will be described with reference to Table 1 as Examples 1 to 4. As comparative examples, Comparative Examples 1 to 5 are shown in Table 1.
Table 2 shows the results of the performance tests of Examples 1 to 4 and Comparative Examples 1 to 5. The performance test includes an oblique incidence characteristic test for the purpose of confirming radio wave absorption characteristics, and durability ( A heat cycle test and a high temperature and high humidity test were conducted for the purpose of confirming the weather resistance.

The oblique incidence characteristic test is a measurement of the return loss with respect to a circularly polarized wave of 5.8 GHz incident in the range of 0 to 70 ° by the arch method, and the upper limit value of the oblique incidence angle indicating a return loss of 20 dB or more. The angle of oblique incidence angle of 60 ° or more is the best (◎), the case of 50 ° or more and less than 60 ° is good (◯), and the case of less than 50 ° is bad (x).
In the heat cycle test, −30 ° C. (humidity 50%) → 60 ° C. (humidity 50%) → −30 ° C. (humidity 50%), 1 cycle: 100 hours of temperature rise and fall for 8 hours, and visually checked for interface peeling As a result, it was evaluated as good (◯) that there was no interfacial peeling. In addition, after this heat cycle test, the return loss with respect to the 5.8 GHz circularly polarized light incident in the range of 0 to 70 ° is measured, and the return loss is equal to the result obtained before the heat cycle test. The thing was evaluated as good (◯), and the deteriorated one was evaluated as defective (×).
In the high-temperature and high-humidity test, exposure was performed for 2000 hours in an environment of a temperature of 60 ° C. and a humidity of 85%, and the presence or absence of interfacial delamination was visually confirmed, and those without interfacial delamination were evaluated as good (◯). In addition, after this high-temperature and high-humidity test, the return loss with respect to 5.8 GHz incident in the range of 0 to 70 ° is measured, and the return loss equivalent to the result obtained before the high-temperature and high-humidity test is measured. It was evaluated as good (◯), and the deteriorated one was evaluated as defective (×).
In addition, as a comprehensive evaluation, ◎ indicates that a particularly favorable result is obtained comprehensively, and × indicates that any one of these tests is regarded as defective.
Moreover, the graph which shows the relationship between the incident angle (theta) of an electromagnetic wave by Example 1-4 and the comparative example 1 and a return loss is shown in FIG.

The structure of Example 1 will be described with reference to FIG. 1. From the surface side A, the first transparent resin layer 1 is a polycarbonate resin plate (product name, manufactured by Asahi Glass Matex Co., Ltd.) subjected to weathering treatment on the surface 1a. : LEXAN), and the thickness T ₁ is 6 mm. The first pressure-sensitive adhesive layer 26 is made of an acrylic pressure-sensitive adhesive (manufactured by Nichiei Kako Co., Ltd., NE-tak pressure-sensitive adhesive P-406) and has a thickness t ₁ of 24 μm. Resistive layer 2 is for indium tin oxide film is formed on the PET film, the surface resistance value is 180 ohms / □, and the thickness thereof T _a and 125 [mu] m. The second pressure-sensitive adhesive layer 27 is made of an acrylic pressure-sensitive adhesive (manufactured by Nichiei Kako Co., Ltd., NE-tak pressure-sensitive adhesive P-406) and has a thickness t ₂ of 24 μm. The second transparent resin layer 3 is a polycarbonate resin plate (trade name: LEXAN, manufactured by Asahi Glass Matex Co., Ltd.), and has a thickness T ₂ of 6 mm. The third pressure-sensitive adhesive layer 28 is made of an acrylic pressure-sensitive adhesive (manufactured by Nichiei Chemical Co., Ltd., NE-tak pressure-sensitive adhesive P-406), and has a thickness t ₃ of 24 μm. Conductive layer 4, which silver film is formed on the PET film, surface resistance is 10 [Omega / □, and the thickness thereof T _b and 50 [mu] m. The fourth pressure-sensitive adhesive layer 29 is made of an acrylic pressure-sensitive adhesive (NE-tak pressure-sensitive adhesive P-406, manufactured by Nichiei Kako Co., Ltd.), and has a thickness t ₄ of 24 μm. Then, the third transparent resin layer 5, a polycarbonate resin plate which is weathering process on the rear surface 5b (Asahi Glass Matex Co., Ltd., trade name: LEXAN) is a, and the thickness T ₃ and 2 mm.

Next, Example 2 has the same configuration as Example 1 except that the thickness T ₁ of the first transparent resin layer 1 is 4 mm and the surface resistance value of the resistive film layer 2 is 260 Ω / □.
Example 3 has the same configuration as Example 1 except that the thickness T ₁ of the first transparent resin layer 1 is 3 mm and the surface resistance value of the resistive film layer 2 is 320Ω / □.
Example 4 has the same configuration as Example 1 except that the surface resistance value of the resistive film layer 2 is 185 Ω / □ and the thickness T ₂ of the second transparent resin layer 3 is 5 mm.

On the other hand, Comparative Example 1 is a conventional λ / 4 type wave absorber, which is composed of a resistive film layer, a transparent resin layer, and a conductive film layer from the radio wave incident surface side. The resistance film layer is formed by forming an indium tin oxide film on a PET film and has a surface resistance value of 377 Ω / □. The transparent resin layer is a polycarbonate resin plate having a thickness of 7.82 mm, the conductive film layer is a PET film in which a silver film is formed, and the surface resistance value is 10Ω / □.
Further, Comparative Example 2, Comparative Example 3, Comparative Example 4, and Comparative Example 5 are in the form in which the third transparent resin layer 5 is excluded from Example 1, Example 2, Example 3, and Example 4, respectively. is there.

  As can be seen from the results in Table 2, the first transparent resin layer 1 is omitted in the comparative example 1 compared to the example, so that the oblique incidence characteristics are poor, and the comparative example in which the third transparent resin layer 5 is omitted. In Nos. 2 to 5, the interface peeling occurred due to the heat cycle, and the radio wave absorption characteristics deteriorated. On the other hand, in all of Examples 1 to 4, no peeling or deterioration of radio wave absorption characteristics occurred. Furthermore, in Example 1 and Example 2, the oblique incidence characteristics were particularly excellent, and favorable results were obtained in terms of radio wave absorption characteristics and durability (weather resistance).

As described above, according to the present invention, the first transparent resin layer 1, the resistance film layer 2, the second transparent resin layer 3, and the conductive film layer 4 from the front surface side A that is the radio wave incident surface side. And a third transparent resin layer 5 having a thickness T ₃ different from the thickness T _{1 of} the first transparent resin layer 1 on the back side of the conductive film layer 4. The laminated structure is composed of the conductive film layer 4 and the three transparent resin layers 1, 3, and 5, but the thickness is different between the front surface side A on the radio wave incident surface side and the back surface side B on the opposite surface side. Since the first transparent resin layer 1 and the third transparent resin layer 5 are provided, the wave absorber is stretched in one direction due to temperature change (thermal expansion, thermal contraction), that is, the surface distortion is prevented and the undulation is performed. It is possible to suppress and prevent peeling between the respective layers at the bonding interface, and to have durability. In other words, it can be installed outdoors even in direct sunlight.

Furthermore, since the 1st transparent resin layer 1 and the 3rd transparent resin layer 5 function as a protective layer, a highly durable transparent electromagnetic wave absorber can be obtained.
Further, the first transparent resin layer 1 can improve the oblique incidence characteristics of radio waves, and can effectively absorb radio waves from a wide range.

  Since weather resistance treatment is applied to the front surface 1a of the first transparent resin layer 1 and / or the back surface 5b of the third transparent resin layer 5, for example, deterioration due to ultraviolet rays can be prevented, and durability and weather resistance can be prevented. The property can be further improved. That is, it can be used outdoors and can maintain radio wave absorption characteristics over a long period of time.

  Since the frame material 7 is attached to the side peripheral surface 6a of the laminated panel body 6 composed of the first transparent resin layer 1 to the third transparent resin layer 5, a highly rigid radio wave absorber can be obtained, A panel can be used. Peeling of each layer at the edge portion can be prevented, and foreign matter can be prevented from entering between the layers.

  The laminated panel body 6 to which the frame material 7 is attached is erected between the lanes of the toll road on the toll road at the toll gate on the toll road so that the radio wave is absorbed between the adjacent traveling lanes. By installing the body, the driving lanes can be separated and transparent, so that it does not give a feeling of pressure to the driver of the driving car and it is safe to ensure visibility.

It is an enlarged side view which shows one Embodiment of the electromagnetic wave absorber of this invention. It is explanatory drawing explaining manufacture of an electromagnetic wave absorber. It is explanatory drawing explaining manufacture of an electromagnetic wave absorber. It is explanatory drawing explaining manufacture of an electromagnetic wave absorber. It is a cross-sectional side view of a radio wave absorber. It is a graph which shows the relationship between the incident angle of a radio wave, and a return loss.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 1st transparent resin layer 1a Front surface 2 Resistance film layer 3 2nd transparent resin layer 4 Conductive film layer 5 3rd transparent resin layer 5b Back surface 6 Laminated panel body 6a Side peripheral surface 7 Frame material A Front side T ₁ Thickness T ₃ thickness

Claims (4)

From the front surface side (A) that is the radio wave incident surface side, the first transparent resin layer (1), the resistance film layer (2), the second transparent resin layer (3), and the conductive film layer (4) And a third transparent resin layer (5) having a thickness (T ₃ ) different from the thickness (T ₁ ) of the first transparent resin layer (1) on the back side of the conductive film layer (4). ), An electromagnetic wave absorber.   The radio wave absorber according to claim 1, wherein a weather resistance treatment is applied to the front surface (1a) of the first transparent resin layer (1) and / or the back surface (5b) of the third transparent resin layer (5).   The frame material (7) is attached to the side peripheral surface (6a) of the laminated panel body (6) composed of the first transparent resin layer (1) to the third transparent resin layer (5). 2. The radio wave absorber according to 2.   The radio wave absorber according to claim 3, wherein the laminated panel body (6) to which the frame material (7) is attached is erected on an upright surface and is laid between lanes at a toll gate on a toll road.

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