JP2007335781A - Electromagnetic wave shielding material - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To shield only the electromagnetic waves of a specified frequency band while transmitting the electromagnetic waves of the other frequencies, and to save the time and labor of a construction when shielding the electromagnetic waves inside and outside a building. <P>SOLUTION: On one surface of a noncombustible facing 1, a frequency selection layer 2 is provided for selectively shielding the electromagnetic waves of at least one frequency band by a plurality of conductive parts 4. Thus, the electromagnetic wave shielding material is constituted for an electromagnetic wave shielding construction. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an electromagnetic wave shielding material, and more particularly to incombustibility and facilitation of electromagnetic wave shielding work.

  In recent years, along with the development of communication systems such as mobile phones and wireless LANs, it has become necessary to enhance information security and prevent communication crosstalk. As a specific measure for that purpose, in order to suppress the inadvertent intrusion and leakage of electromagnetic waves, the interior wall surface of the building is surrounded by a grounded conductive material to shield the electromagnetic waves.

For example, Patent Document 1 discloses that a building body is constructed using concrete mixed with an electromagnetic shielding material such as a metal mesh or ferrite.
Japanese Examined Patent Publication No. 6-99972 (Page 2, FIGS. 2 and 3)

  However, in the above conventional case, since electromagnetic waves of almost all frequencies are shielded, there is a drawback that a device such as a mobile phone that transmits and receives electromagnetic waves to the outside cannot be used.

  In addition, there is a problem that it takes time for the construction because the electromagnetic wave shields need to be connected to each other.

  The present invention has been made in view of such points, and its main purpose is to shield only electromagnetic waves in a specific frequency band and shield electromagnetic waves of other frequencies when shielding electromagnetic waves between inside and outside buildings. In addition, it is possible to pass through the work, and it is possible to use it at a place where non-combustibility is required while not requiring labor.

  In order to achieve the above object, in the present invention, as an electromagnetic shielding material, a frequency selective surface (FSS “Frequency Selective Surface”) is formed on an incombustible surface material used as an interior / exterior material of a building, and this is shielded against electromagnetic waves. It can now be used on indoor and outdoor wall surfaces.

  Specifically, in the present invention, as the electromagnetic wave shielding material, the nonflammable surface material is provided on at least one surface of the nonflammable surface material, and each selectively shields electromagnetic waves in a specific frequency band. And a frequency selection layer in which a plurality of conductive portions formed as described above are arranged. Here, “non-combustible” refers to what is evaluated as “non-combustible” by the non-combustible, semi-incombustible, and flame-retardant tests specified by the Building Standards Law.

  In the above configuration, when a plurality of incombustible face materials are used, a frequency selection layer can be arranged between at least some of the adjacent incombustible face materials. In addition, when the frequency selection layer is disposed between two or more sets of nonflammable face materials, that is, when there are a plurality of frequency selection layers, the conductive portion of each frequency selection layer is connected to a frequency other than the frequency selection layer It can be formed so as to selectively shield electromagnetic waves in a frequency band different from the conductive portion of the selective layer.

  As an example of the nonflammable face material as described above, a foamed calcium carbonate board can be exemplified. Moreover, in order to form a frequency selective layer on a noncombustible face material, it may be formed directly by printing or the like, or a frequency selective layer is formed on a film and the film is laminated on the noncombustible face material. You may make it do. Furthermore, when laminating the film on the non-combustible face material, the frequency selection layer may be arranged on the non-combustible face material side of the film, or on the opposite side of the film from the non-combustible face material. Also good.

  In addition, as each conductive portion of the frequency selection layer, three first element portions extending radially from one point, and each extending in a direction intersecting the corresponding first element portion and in a part of the length direction The first element portion may include three second element portions coupled to the tip of the first element portion.

  According to the present invention, electrical grounding is performed when construction is performed to prevent leakage by shielding radio waves without deteriorating the radio wave environment of equipment using radio waves other than a specific frequency band. Since it is not necessary, labor is not required, and the face material itself has nonflammability, so that it can also be used in places where nonflammability is required.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Embodiment 1)
FIG. 1 is a cross-sectional view schematically showing the overall configuration of an electromagnetic wave shielding board according to Embodiment 1 of the present invention. This electromagnetic wave shielding board is a single board that is a lightweight plate-like foam having noncombustibility. The main body 1 and the board main body 1 are provided on one surface, and selectively shield electromagnetic waves in a specific frequency band with a plurality of regularly arranged antennas 4, 4,. And a frequency selection layer 2.

The board body 1 is a lightweight foamed calcium carbonate board obtained by heating and foaming a composition comprising calcium carbonate and talc (magnesium hydrated silicate), a binder resin, and a foaming agent as inorganic base materials. as the thickness, about 5 to 20 mm, the density, 0.05 to 0.2 g / cm ³ order (more preferably, 0.15 g / cm ³ or less) is preferably.

  Here, an example of the manufacturing method of the board body 1 will be briefly described. An inorganic base material, a binder resin, a foaming agent, etc. are put into a kneader and mixed for 5 minutes, and then 40 parts by weight of calcium carbonate. 50 parts by weight of organic solvent (such as toluene) is gradually added and kneaded for 1 hour. Then, the composition obtained is filled in the mold without any gaps while being pressurized by kneading, sealed with a lid, and pressed with a press. In this state, the binder resin is heated to 170 ° C. to gel, and at the same time, the foaming agent is decomposed. After sufficiently gelling and decomposing, the mold is cooled to room temperature in a pressurized state, the foam is taken out, and heated to 150 ° C. at normal pressure to expand to a predetermined size. Thereafter, the organic solvent is evaporated and completely removed by once cooling to room temperature and then gradually heating to 100 ° C. The board body 1 of this embodiment can be obtained by slicing the foam obtained as described above.

  In addition, it is preferable that it is 50 / 50-95 / 5 as a compounding ratio (calcium carbonate / talc weight ratio) of the said inorganic base material, and it is preferable that it is 50-300 micrometers as an average particle diameter. Examples of the binder resin include vinyl chloride resin, EVA resin, acrylic resin, and the like, and it is preferable to use it in the form of a paste resin having an average particle diameter of 10 to 30 μm. Moreover, as the content, it is preferable that it is 10-100 weight part with respect to 100 weight part inorganic base material. The foaming agent is not particularly limited as long as it is a substance that decomposes by heating to generate gas. Examples of the foaming agent include azodicarbonamide, azobisisobutylnitrile, dinitrosopentatetramine, p, which are organic foaming agents. -Toluenesulfonyl hydrazide, p, p'-oxybis (benzenesulfonyl hydrazide), inorganic bicarbonate sodium bicarbonate, ammonium chloride and the like. Moreover, as the content, it is preferable that it is 10-120 weight part with respect to 100 weight part inorganic base material.

  In the present embodiment, an electromagnetic wave shielding sheet 3 as shown in FIG. 2 is used to provide the frequency selection layer 2 on the board body 1. The electromagnetic wave shielding sheet 3 has a frequency selection layer 2 formed on a film substrate 3a, and an adhesive layer 3b and a release liner 3c are sequentially formed on the surface of the film substrate 3a opposite to the frequency selection layer 2. It is layered and rolled up. And the frequency selection layer 2 can be provided in this board main body 1 by cutting only the required length, peeling the release liner 3c, and sticking it on the board main body 1. The film substrate 3a is preferably a polymer film that can be easily formed into a thin roll and has excellent flexibility. In particular, the thickness is generally 10 to 500 μm, preferably 30 to 150 μm, and more preferably 50 to 120 μm.

  Both of the antennas 4, 4,... Have a frequency selectivity that selectively reflects only radio waves in a specific frequency band. Therefore, the frequency selection layer 2 shields only radio waves in a specific frequency band. On the other hand, radio waves of other frequencies are transmitted. Specifically, each antenna 4 is made of a conductive material and has conductivity, and the radio wave reflectance of the antenna 4 with respect to radio waves in a specific frequency band correlates with the conductivity of the antenna 4. That is, the higher the conductivity of the antenna 4 (the smaller the electric resistance of the antenna 4), the higher the radio wave reflectance of the antenna 4. Therefore, by increasing the conductivity of the antenna 4, it is possible to increase the radio wave reflectance of the antenna 4 with respect to radio waves in a specific frequency band. Examples of such a conductive material include aluminum, silver, copper, gold, platinum, iron, carbon, graphite, indium tin oxide (ITO), indium zinc oxide (IZO), a mixture or an alloy thereof. The antenna 4 preferably includes any one of copper, aluminum, and silver. The reason is that copper, aluminum and silver have a relatively low electric resistance among conductive materials and are inexpensive. Among the above conductive materials, silver is particularly preferable from the viewpoint of realizing higher electromagnetic shielding properties and lower costs.

  Each antenna 4 may include fine particles of a conductive material such as copper, aluminum, and silver. For example, a conductive paste in which a powdery conductive material is contained in a binder is used as a film base. It can be obtained by applying uniformly so that a predetermined pattern is formed on the material 3a, and then drying. Specifically, after forming a predetermined pattern of the conductive paste, the antenna 4 is dried by drying for 10 minutes or more and 5 hours or less in an atmosphere of 100 ° C. or higher and 200 ° C. or lower, for example. Obtainable. As such a conductive paste, a powdery conductive material (for example, silver) may be dispersed and mixed in a polyester resin. In this case, the content of the conductive material is preferably 40% by weight or more and 80% by weight or less, more preferably 50% by weight or more and 70% by weight or less. When the content of the conductive material is less than 40% by weight, the conductivity of the antenna 4 tends to decrease. On the other hand, if the content of the conductive material is more than 80% by weight, it tends to be difficult to uniformly disperse and mix in the resin. The antenna 4 may be composed of a conductive film made of a conductive material and an antioxidant film that covers the conductive film.

  In addition, about the formation method of the antenna 4, it is not limited to said method, You may form by another method. For example, a conductive film (for example, an aluminum film or a silver film) is formed on the board body 1 by a film forming method such as a vapor deposition method, a sputtering method, or a chemical vapor deposition method (CVD method), and then patterned by a patterning method such as photolithography. You may make it pattern into a predetermined shape dimension. In addition, the antenna 4 is formed by, for example, silk printing, pattern pressing, etching, sputtering, vapor deposition (for example, chemical vapor deposition (CVD)), mist coating, or mold fitting. It can also be performed by an embedding method or the like. The thickness T of the antenna 4 is preferably 10 μm or more and 20 μm or less (10 μm ≦ T ≦ 20 μm). That is, when the thickness of the antenna 4 is smaller than 10 μm (T <10 μm), the conductivity of the antenna 4 tends to be lowered. On the other hand, when the thickness of the antenna 4 is larger than 20 μm (T> 20 μm), The formability of 4 tends to decrease.

  In this embodiment, the antennas 4, 4,... Are arranged in a matrix as shown in FIG. These antennas 4, 4,... Are arranged at regular intervals so that adjacent antennas 4, 4 do not contact each other. Each antenna 4 has three first element portions 4a, 4a,... And three second element portions 4b, 4b,. The three first element portions 4a, 4a,... Extend radially from the antenna center C and are formed in a straight line having an angle of 120 ° with each other. Each second element portion 4b extends linearly in a direction orthogonal to the corresponding first element portion 4a, and is coupled to the outer end of the first element portion 4a at the center in the length direction. In the illustrated example, the lengths L1 and L2 of the first and second element portions 4a and 4b are the same (L1 = L2), and the width W1 of the first element portion 4a and the lengths of the second element portions 4b The width W2 is also the same (W1 = W2).

The first element portion length L1 and the second element portion length L2 may be different from each other (L1 ≠ L2). In this case, the relational expression 0 <L2 <2 × 3 ^1/2 × L1 Will be satisfied. That is, when L2 ≧ 2 × 3 ^1/2 × L1, the adjacent second element portions 4b and 4b come into contact with each other, and a desired electromagnetic wave shielding effect cannot be obtained. Furthermore, from the viewpoint of realizing a high shielding rate in the specific frequency band, the second element portion length L2 is not less than 0.5 times and not more than twice the first element portion length L1 (0.5 × L1 ≦ L2). ≦ 2 × L1) is preferable, and 0.75 times or more and 2 times or less (0.75 × L1 ≦ L2 ≦ 2 × L1) is more preferable. Also, the first and second element portion widths W1, W2 may be different from each other (W1 ≠ W2). In the present embodiment, the first and second element portions 4a and 4b are orthogonal to each other, but may be crossed at an angle other than 90 °. Further, the coupling position of the second element part 4b with respect to the first element part 4a may be a position other than the center in the length direction of the second element part 4b.

  By the way, the lengths L1 and L2 of the first and second element portions 4a and 4b of the antenna 4 correlate with the frequency band (specific frequency band) of the radio wave reflected by the antenna 4. For this reason, the length L1 of the first element portion 4a and the length L2 of the second element portion 4b can be appropriately determined according to the frequency band of the radio wave to be shielded by the electromagnetic wave shielding board. For example, when the length L1 of the first element portion 4a and the length L2 of the second element portion 4b are the same (L1 = L2), the total length L of the elements of the antenna 4 (L = 3 × L1 + 3 × L2) Hereinafter, the specific frequency band can be lowered by increasing the element length L). Conversely, the specific frequency band can be increased by shortening the element length L.

  Hereinafter, the electromagnetic wave shielding characteristics of the electromagnetic wave shielding board by the lengths L1 and L2 of the first and second element portions 4a and 4b will be described in detail. Here, the first and second element portion widths W1, W2 are both 0.7 mm (W1 = W2 = 0.7 mm).

  First, when the length L1 of the first element portion 4a and the length L2 of the second element portion 4b are the same (L1 = L2), the first element portion length L1 is set to L1 = 10.6 mm. As shown in the characteristic diagram of FIG. 5, the transmittance of radio waves having a frequency in the vicinity of 2.7 GHz is selectively reduced. That is, about 2.7 GHz radio waves are selectively shielded out of the radio waves incident on the electromagnetic wave shielding board. This is because the antenna 4 in the frequency selection layer 2 of the electromagnetic wave shielding board selectively reflects radio waves having a frequency of approximately 2.7 GHz out of incident radio waves having various frequencies. For measuring the transmission attenuation, a “network analyzer” manufactured by Agilent, USA is used.

  Next, the relationship between the length L1 of the first element part 4a of the antenna 4 and the frequency of the radio wave reflected by the antenna 4 is shown in FIG. As can be seen from this characteristic diagram, the frequency of the radio wave reflected by the antenna 4 becomes lower as the element length L (here, L = 6 × L1) becomes longer. In other words, the longer the element length L, the longer the wavelength of the radio wave reflected by the antenna 4. Therefore, as the element length L becomes shorter, the frequency of the radio wave reflected by the antenna 4 becomes higher (the wavelength becomes shorter). By the way, the frequency of the reflected radio wave is not greatly correlated with the respective widths W1 and W2 of the first and second element portions 4a and 4b. That is, the frequency of the reflected radio wave is mainly determined by the element length L. Therefore, an appropriate element length L can be obtained from the frequency band (specific frequency band) of the radio wave desired to be reflected by the antenna 4 based on the characteristic diagram of FIG. For example, it is understood that the length L1 of the first element portion 4a should be set to L1≈6 mm in order to shield radio waves having a frequency of about 5 GHz.

  On the other hand, when the first and second element portion lengths L1 and L2 are different from each other (L1 ≠ L2), for example, the length L1 of the first element portion 4a is fixed and only the length L2 of the second element portion 4b is fixed. In other words, the specific frequency band can also be adjusted by changing the ratio (L2 / L1) of the second element portion length L2 to the first element portion length L1. Specifically, the specific frequency band can be lowered by increasing the length L2 of the second element portion 4b, while the specific frequency band can be increased by shortening the length L2 of the second element portion 4b. can do.

  That is, for example, in the case of an antenna having a Y shape (see FIG. 12), the specific frequency band can be adjusted only by changing the first element portion length L1. On the other hand, in the electromagnetic wave shielding board according to the present embodiment, as described above, the specific frequency band is also changed by changing both the length L1 of the first element portion 4a and the length L2 of the second element portion 4b. Not only can it be adjusted, but also the specific frequency band can be adjusted by changing the ratio (L2 / L1) of the second element length L2 to the first element length L1, so that the degree of freedom in design is great. An electromagnetic wave shielding board can be realized.

  Therefore, according to the present embodiment, the board body 1 made of lightweight foamed calcium carbonate as the electromagnetic wave shielding board, and the plurality of antennas 4 provided on one surface of the board body 1 and regularly arranged. , 4,... Are provided with the frequency selection layer 2 that selectively shields electromagnetic waves in a specific frequency band, so that the radio wave environment of equipment using radio waves other than the specific frequency band is not deteriorated. There is no need for electrical grounding when performing work to shield radio waves and prevent leakage, and since the board body 1 is lightweight, it does not take time and is nonflammable. It can also be used for parts that require nonflammability.

  In the above embodiment, the board main body 1 is made of lightweight foamed calcium carbonate. However, as the non-combustible face material in the present invention, the non-combustible inner wall material, floor material, and ceiling material are used. , Outer wall materials, roofing materials, etc., as long as it is a planar or phased surface material having a planar or phased two-dimensional expanse, and in addition, it is even better if it is lightweight.

(Embodiment 2)
FIG. 7 shows an antenna arrangement in the frequency selection layer of the electromagnetic wave shielding board according to the second embodiment of the present invention. The same parts as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.

  In this embodiment, each pair of two adjacent antennas 4 and 4 is set so that a pair of second element portions 4b and 4b face each other in parallel as shown in an enlarged view in FIG. An antenna unit 5a is formed in the proximity. Further, the three adjacent antenna units 5a, 5a,... Are formed in a regular hexagonal shape in which the corresponding three sets of second element portions 4b, 4b are arranged close to each other so as to face each other in parallel and are continuously developed in two dimensions. Antenna assembly 5 (array unit). In other words, the antenna assembly 5 is composed of six antennas 4 arranged in a regular hexagonal shape in which six corresponding second element portions 4b and 4b face each other in parallel. Since the antenna assembly 5 has a regular hexagonal shape, it can exhibit a relatively stable electromagnetic wave shielding performance against radio waves incident at various incident angles.

  In addition, the six antennas 4 constituting the antenna assembly 5 have six sets corresponding to the 12 second element parts 4b of the 18 second element parts 4b of the six antennas 4. Since the two element portions 4b and 4b are arranged close to each other, the antennas 4 can be arranged with high density, and as a result, the radio wave reflectivity (electromagnetic wave shielding rate) for radio waves in a specific frequency band can be further increased. The electromagnetic wave shielding board which can be improved and has a high electromagnetic wave shielding rate with respect to radio waves in a specific frequency band can be realized.

  The density of the antennas 4, 4,... Increases as the distance X between the opposing second element portions 4b, 4b decreases. Specifically, the distance X between the second element portions 4b and 4b is preferably 3.0 mm or less (X ≦ 3.0 mm). That is, when the distance X is larger than 3.0 mm (X> 3.0 mm), the electromagnetic wave shielding rate tends to decrease. If the distance X is too small, the second element portions 4b and 4b are likely to contact each other undesirably depending on the method of forming the antenna 4. Therefore, the distance X is limited to 0.05 mm or more (X ≧ 0.05 mm). It is preferable to keep.

  Here, the fact that the electromagnetic wave shielding board configured as described above has a relatively high frequency selectivity will be specifically described with reference to FIGS.

  FIG. 9 is a characteristic diagram showing the electromagnetic wave shielding characteristics of the electromagnetic wave shielding board according to the present embodiment. As can be seen from the figure, in the case of the present embodiment, the ratio of the 10 dB bandwidth to the matching frequency F0 [{(F2-F1) / F0} × 100 (%)] is very small, 10.4%. . That is, the frequency selectivity is very high. On the other hand, for example, in the case of antennas 104, 104,... Having a so-called Jerusalem cross shape as in Modification 1 shown in FIG. The ratio of 10 dB bandwidth to 17.0% (> 10.4%) is larger than in the present embodiment. In addition, in the case of Y-shaped antennas 204, 204,... Arranged in a matrix as in Modification 2 shown in FIG. 12, the electromagnetic wave shielding characteristics are 10 dB band with respect to the matching frequency as shown in FIG. The width ratio is 33.0% (> 10.4%), which is even greater than in the present embodiment. In the above three characteristic diagrams (FIG. 9, FIG. 11, FIG. 13), the matching frequency (F0) is different from each other, but the 10 dB bandwidth is not dependent on the matching frequency. Absent. The arrangement distance (vertical / horizontal distance) of Comparative Example 2 is the same as that of Comparative Example 1.

  Therefore, in the present embodiment, in addition to the same effects as those in the first embodiment, the 10 dB bandwidth is narrow (high frequency selectivity), and therefore the radio wave environment for radio waves other than the specific frequency band is particularly deteriorated. There is a merit that it is difficult.

-Experimental example-
The length L1 of the first element part 4a of each antenna 4 in the frequency selection layer 2 of the electromagnetic wave shielding board is fixed to L1 = 12.24 mm, while the length L2 of the second element part 4b is changed variously. Five types of electromagnetic shielding boards were produced. The width W1 of the first element portion 4a and the width W2 of the second element portion 4b are W1 = W2 = 1.2 mm.

  Specifically, silver paste was applied onto the board body 1 and dried to form five types of antennas of Examples 1 to 4 and Comparative Example, respectively. At that time, in Example 1, the second element portion length L2 was L2 = 24.48 mm (L1: L2 = 1: 2). In Example 2, the second element portion length L2 was set to L2 = 15.30 mm (L1: L2 = 1: 1.25). In Example 3, the second element portion length L2 was set to L2 = 12.24 mm (L1: L2 = 1: 1). In Example 4, the length L2 of the second element portion was L2 = 9.2 mm (L1: L2≈1: 0.75). In Example 5, the second element portion length L2 was set to L2 = 0 mm. That is, “Y-shaped antenna”.

  The relationship between the frequency and the amount of transmission attenuation in Examples 1 to 5 is shown in the characteristic diagram of FIG. Further, the relationship between the ratio (L2 / L1) between the first element portion length L1 and the second element portion length L2 in Examples 1 to 5 and the matching frequency is shown in the characteristic diagram of FIG.

  As can be seen from FIG. 14, in Examples 1 to 4 having the second element portion 4b, the electromagnetic wave shielding rate was higher than that in Example 5. From this result, it can be seen that in Examples 1 to 4, radio waves in a specific frequency band can be shielded with a higher electromagnetic wave shielding rate than in Example 5. Moreover, in the case of Examples 1-4, it has a sharper peak than the case of Example 5. That is, it can also be seen that Examples 1 to 4 have higher frequency selectivity than Example 5 and shield radio waves in a specific frequency band with higher selectivity.

  Further, as can be seen from FIG. 15, the matching frequency tends to decrease as the ratio (L2 / L1) between the first element portion length L1 and the second element portion length L2 increases. From this, it can be seen that the matching frequency can be adjusted by changing the length L2 of the second element portion 4b.

(Embodiment 3)
FIG. 16 shows an array of antennas in the frequency selection layer of the electromagnetic wave shielding board according to Embodiment 3 of the present invention. In this embodiment, the frequency selection layer 2 shields radio waves in two different frequency bands. There are two types of antennas 4 and 6 which are large and small. Since the large antenna 4 has substantially the same size and shape as the antenna 4 of the first embodiment, the same parts as those in the first embodiment are denoted by the same reference numerals and description thereof is omitted.

  In this embodiment, the frequency selection layer 2 includes a plurality of large antennas 4, 4,... And a plurality of small antennas 6, 6,... Arranged in a matrix so as to form a certain pattern. . The large antennas 4, 4,... And the small antennas 6, 6,... Are arranged at regular intervals so as not to interfere with each other.

  The small antenna 6 is similar to the large antenna 4 and differs from the large antenna 4 only in size. Specifically, as shown in an enlarged view in FIG. 17, the small antenna 6 has three first element portions 6a, 6a,... And three second element portions 6b, as in the case of the large antenna 4. , 6b,... The three first element portions 6a, 6a,... Extend radially from the antenna center Cs and form an angle of 120 ° with each other. Each second element portion 6b extends linearly in a direction orthogonal to the corresponding first element portion 6a, and is coupled to the outer end of the first element portion 6a at the center in the length direction. In the illustrated example, the lengths Ls1, Ls2 of the first and second element portions 6a, 6b are the same (Ls1 = Ls2), and the width Ws1 of the first element portion 6a and the length of the second element portion 6b The width Ws2 is also the same (Ws1 = Ws2).

The first element portion length Ls1 and the second element portion length Ls2 may be different from each other (Ls1 ≠ Ls2). In this case, the relationship 0 <Ls2 <2 × 3 ^1/2 × Ls1 Will satisfy the equation. That is, if Ls ≧ 2 × 3 ^1/2 × Ls1, adjacent second element portions 6b and 6b come into contact with each other, and a desired electromagnetic wave shielding effect cannot be obtained. Furthermore, from the viewpoint of realizing a high shielding rate in a specific frequency band, the second element portion length Ls2 is not less than 0.5 times and not more than twice the first element portion length Ls1 (0.5 × Ls1 ≦ Ls2). ≦ 2 × Ls1) is preferable, and 0.75 times or more and 2 times or less (0.75 × Ls1 ≦ Ls2 ≦ 2 × Ls1) is more preferable. Further, the widths Ws1 and W2 of the first and second element portions 6a and 6b may be different from each other (Ws1 ≠ Ws2). In the present embodiment, the first and second element portions 6a and 6b are orthogonal to each other, but may be crossed at an angle other than 90 °. Further, the coupling position of the second element part 6b with respect to the first element part 6a may be a position other than the center in the length direction of the second element part 6b.

  Further, the antennas of the frequency selection layer 2 in this embodiment are only two types, that is, the large antenna 4 and the small antenna 6. Good. For example, in an environment where radio waves of three or more types of frequency bands are used, the frequency selection layer 2 may be configured by three or more types of antennas having different sizes.

  Each of the large antenna 4 and the small antenna 6 has frequency selectivity. Specifically, the large antenna 4 reflects radio waves in the first frequency band, and the small antenna 6 reflects radio waves in the second frequency band (> first frequency band) higher than the first frequency band. For this reason, the electromagnetic wave shielding board according to the present embodiment selectively shields both radio waves in the first frequency band and the second frequency band, and transmits radio waves of other frequencies.

  By the way, for example, in a wireless LAN, radio waves in two frequency bands of 2.45 GHz band and 5.2 GHz band are used. In such an environment, only radio waves in the two frequency bands used are selectively used. It is necessary to have an electromagnetic wave shielding board that transmits information on other frequencies that are not used (for example, radio waves used in mobile phones, TV broadcasts, etc.) while preventing the leakage of information. It is said. On the other hand, as described above, the electromagnetic wave shielding board according to the present embodiment is preferable because it can selectively shield radio waves in two specific frequency bands and transmit radio waves in other frequencies. is there.

  Here, in the electromagnetic wave shielding board configured as described above, the lengths L1 and L2 and the widths W1 and W2 of the first and second element portions 4a and 4b of the large antenna 4 are 11.19 mm (L1 = L2), respectively. = 1.19 mm) and 0.7 mm (W1 = W2 = 0.7 mm), and the lengths Ls1, Ls2 and widths Ws1, Ws2 of the first and second element portions 6a, 6b of the small antenna 6 are 6 respectively. The electromagnetic wave shielding characteristics when 0.05 mm (Ls1 = Ls2 = 6.05 mm) and 0.7 mm (Ws1 = Ws2 = 0.7 mm) will be described.

  FIG. 18 shows the relationship between the frequency of the radio wave incident on the electromagnetic wave shielding board and the transmission attenuation when the radio wave passes through the electromagnetic wave shielding board. As can be seen from the figure, the radio wave incident on the electromagnetic wave shielding board is attenuated by the electromagnetic wave shielding board, specifically, the radio wave of two frequency bands, specifically, the radio wave of 2.45 GHz band and the radio wave of 5.2 GHz band. Is done. In other words, two radio waves in the 2.45 GHz band and the 5.2 GHz band among the radio waves incident on the electromagnetic wave shielding board are selectively shielded by the electromagnetic wave shielding board. This is because radio waves in two specific frequency bands are selectively reflected by the large antenna 4 and the small antenna 6 of the frequency selection layer 2. Specifically, the large antenna 4 reflects radio waves in the low first frequency band (2.45 GHz band), and the small antenna 6 reflects radio waves in the second frequency band (5.2 GHz band).

  By the way, in the case of a Y-shaped antenna, it is difficult to arrange two types of large and small linear antennas corresponding to a wireless LAN efficiently and with high density. That is, as in Modification 1 of the present embodiment shown in FIG. 19, when the six large antennas 204, 204,... Adjacent to each other are arranged close to each other in a state where the element portions 204a, 204a face each other in parallel, As for the small antennas 206, 206,..., It is difficult to place the small antennas 206, 206 close to each other, not to mention that the element portions 206a, 206a face each other in parallel, and the large antennas 204, 204,. Can be arranged at a high density, but the number of small antennas 206, 206,... Must be smaller than that of the large antennas 204, 204,. For this reason, the shielding rate for radio waves targeted by the small antennas 206, 206,... Is considerably lower than the shielding rate for radio waves targeted by the large antennas 204, 204,. That is, in the case of a Y-shaped antenna, it is difficult to arrange both the large and small antennas 204 and 206 at a high density, and accordingly, a plurality of radio waves having different frequency bands are shielded with a high shielding rate at the same level. Is difficult.

  Such a situation is the same even when a Jerusalem cross-type antenna is used. That is, when the large antennas 104, 104,... Are arranged close to each other in a matrix shape in which the second element portions 104b, 104b face each other in parallel as in Modification 2 of the present embodiment shown in FIG. As for the antennas 106, 106,..., It is difficult to place the small antennas 106, 106 close to each other as well as the second element portions 106b, 106b face each other in parallel. .. Can be arranged with high density, but the small antennas 106, 106,... Inevitably have a smaller number per unit area than the large antenna 104, and are difficult to arrange with high density. As in the third modification shown in FIG. 21, if only the small antennas 106, 106,... Arranged in the horizontal direction are arranged close to each other so that the second element portions 106b, 106b face each other in parallel, Although the density of the antennas 106, 106,... Increases slightly, this time, the density of the large antenna 104 decreases in the vertical direction. It is difficult to place. In this case, radio waves having a specific frequency incident along the arrangement direction of the large and small antennas 104 and 106 (left and right direction in FIG. 21) can be well shielded, but the arrangement direction of the large and small antennas 104 and 106 In the direction that intersects (for example, the vertical direction in the figure), the large antennas 104 and 104 and the small antennas 106 and 106 that are adjacent to each other in the same direction are separated from each other. Therefore, the incident angle dependency problem that the electromagnetic wave shielding ratio largely changes depending on the incident direction of the radio wave is caused.

  Therefore, according to the present embodiment, when the two types of large and small antennas 4 and 6 that respectively shield radio waves in two different frequency bands are arranged on the frequency selection layer 2 of the electromagnetic wave shielding board, the large antenna 4 As described above, each of the first element portions 4a, 4a,... Extending radially from the antenna center C extends in a direction perpendicular to the corresponding first element portion 4a. While having three second element portions 4b, 4b,... Coupled to the outer end, each of the small antennas 6 includes three first element portions 6a, 6a extending radially from the antenna center Cs. ,..., Each extending in a direction orthogonal to the corresponding first element portion 6a and connected to the outer end of the first element portion 6a. Therefore, the two types of large and small antennas 4 and 6 can be arranged with high density, and radio waves in the two frequency bands can be shielded with the same level of high electromagnetic wave shielding rate. As a result, for example, in the case of a wireless LAN environment that uses radio waves of two frequency bands of 2.45 MHz band and 5.2 MHz band, the radio wave environment of a device such as a mobile phone that uses radio waves of other frequencies This makes it possible to suppress leakage of radio waves from the wireless LAN.

(Embodiment 4)
22 shows an arrangement of large antennas 4, 4,... And small antennas 6, 6,... In the frequency selection layer 2 of the electromagnetic wave shielding board according to Embodiment 4 of the present invention. Since the configurations of the large antenna 4 and the small antenna 6 are the same as those in the third embodiment, the same portions are denoted by the same reference numerals and description thereof is omitted. Further, the arrangement of the large antennas 4 is the same regular hexagonal shape as in the second embodiment, and the two large antennas 4 and 4 are arranged close to each other so that the second element portions 4b and 4b face each other in parallel. The pair constitutes a large antenna unit 5a, and three large antenna units 5a, 5a,... Arranged close to each other so that the corresponding three sets of second element portions 4b, 4b face each other in parallel are one large. An antenna assembly 5 is formed. The adjacent large antenna assemblies 5 are arranged close to each other so that the corresponding second element portions 4b and 4b face each other in parallel. In this way, a large number of large antenna assemblies 5 and 5 are arranged. , ... are continuously expanded in two dimensions.

  The small antennas 6 of this embodiment are also arranged in the same manner as the large antennas 4, 4,. That is, the pair of the two small antennas 6 and 6 that are arranged close to each other so that the second element portions 6b and 6b face each other in parallel form a small antenna unit 7a, and corresponding three sets of the second sets. Three small antenna units 7a, 7a,... Arranged close to each other so that the element portions 6b, 6b face each other in parallel constitute a small antenna assembly 7. However, the small antenna assemblies 7 are arranged for each large antenna assembly 5 one by one inside the large antenna assembly 5 in a state of being separated from the other small antenna assemblies 7, 7,. Precisely, the small antenna assemblies 7 are arranged one by one on the inner side of each large antenna assembly 5 and in a portion surrounded by three adjacent large antenna assemblies 5, 5,.

  Similar to the case of the large antenna 4, the radio wave reflectance of the small antenna 6 increases as the small antennas 6 are arranged at a high density so that the distance between the opposing second element portions 6b and 6b is reduced. Specifically, as shown in an enlarged view in FIG. 23, the distance Xs between the opposing second element portions 6b and 6b is preferably 3.0 mm or less (Xs ≦ 3.0 mm), and more preferably in a range. Is 1.0 mm or less (Xs ≦ 1.0 mm). That is, when the distance Xs is larger than 3.0 mm (Xs> 3.0 mm), the electromagnetic wave shielding rate tends to decrease. If the distance Xs is too small, the second element portions 6b, 6b are likely to contact each other undesirably depending on the method of forming the small antennas 6, 6,. 4 mm), and more safely, it is preferable to keep it at 0.6 mm or more (Xs ≧ 0.6 mm).

  In order to allow the relatively small antenna 6 to be disposed without shortening the second element portion length L2 of the large antenna 4, the large antenna assembly 5 (first The small antenna assembly 7 (six small antennas 6, 6,... Arranged in a hexagonal shape) in the six large antennas 4, 4,. A relatively small angle θ (for example, θ = 10 °) may be relatively rotated around the center. Also by doing this, it is possible to avoid the second element portion 4b of the large antenna 4 and the second element portion 6b of the small antenna 6 from interfering with each other.

  Therefore, according to the present embodiment, when the frequency selection layer 2 of the electromagnetic wave shielding board has the two types of large and small antennas 4 and 6 that shield two types of radio waves having different frequency bands, the large antennas 4 and 4 Are arranged in a state in which the second element portions 4b, 4b face each other in parallel to form a regular hexagonal large antenna assembly 5, and inside each large antenna assembly 5, there are six small elements. The antennas 6, 6,... Are arranged in a state in which the second element portions 6b, 6b face each other in parallel to form a regular hexagonal small antenna assembly 7. Therefore, the large antennas 4, 4,. And the small antennas 6, 6,... Can be arranged at a high density, so that the electromagnetic wave shielding rate against the two types of radio waves can be further improved.

  In the above embodiment, the large antenna assembly 5 and the small antenna assembly 7 are both closely packed, but depending on the desired electromagnetic wave shielding rate, they are not closely packed. The number of the bodies 5 and 7 can be adjusted as appropriate.

(Embodiment 5)
FIG. 25 schematically shows a cross section of the electromagnetic wave shielding board according to Embodiment 5 of the present invention.

  The present embodiment is the same as the first embodiment in that the frequency selection layer 2 is provided on the board body 1 using the electromagnetic wave shielding sheet 3, but the position of the frequency selection layer 2 with respect to the board body 1 is the same. Along with this, the configuration of the electromagnetic wave shielding sheet 3 used for providing the frequency selection layer 2 is also different.

  That is, in the case of the first embodiment, the frequency selection layer 2 faces the side opposite to the board body 1 (upper side in FIG. 1), whereas in the present embodiment, the frequency selection layer 2 is the board. It faces the side of the main body 1 (the lower side in FIG. 25). That is, in the electromagnetic wave shielding sheet 3 of the present embodiment, unlike the case of the first embodiment, the frequency selection layer 2 is disposed on the same side as the adhesive layer 3b and the release liner 3c in the film substrate 3a. An adhesive layer 3b and a release liner 3c are sequentially laminated on the frequency selection layer 2.

  The frequency selection layer 2 can selectively reflect radio waves in a specific frequency band even when facing the board body 1 side as in the present embodiment. However, compared to the case where the antenna 4 faces the atmosphere as in the first embodiment, the frequency of the radio wave reflected (shielded) by the antenna 4 even if the shape and the material of the antenna 4 are the same. The band (specific frequency band) is different. Here, FIG. 27 shows the relationship between the first element portion length L1 (1/6 of the element length L) of the antenna 4 and the matching frequency in the frequency selection layer 2 of the electromagnetic wave shielding board configured as described above. According to the figure, as can be seen from the case of the first embodiment (see FIG. 6), when the frequency selection layer 2 is covered by the board body 1, the frequency selection layer 2 is in contact with air. The frequency band of the radio wave reflected (shielded) by the frequency selection layer 2 is lower than the case.

(Embodiment 6)
FIG. 28 is a cross-sectional view showing a configuration of an electromagnetic wave shielding board according to Embodiment 6 of the present invention.

  In this embodiment, the electromagnetic wave shielding board includes two board bodies 1 similar to those in the first to fifth embodiments, and one of the two board bodies 1 is provided on one side of the board body 1. The frequency selection layer 2 is provided using an electromagnetic wave shielding sheet (the same electromagnetic shielding sheet as in the first to fourth embodiments). In addition, since the other structure is substantially the same as each case of Embodiment 1-5, description is abbreviate | omitted.

  Therefore, the present embodiment can achieve the same effects as those of the first embodiment.

  In the above-described embodiment, the two board bodies 1 and 1 are superposed so as to be the simplest to produce. However, the board body 1 has three or more boards, as in the modification shown in FIG. The frequency selection layer 2 can be a plurality of layers (in the example shown, two frequency selection layers 2 and 2 for three board bodies 1, 1,...). According to this, when the plurality of frequency selection layers 2, 2,... Shield the radio waves in the same frequency band, the shielding rate for the radio waves can be increased, and the frequency bands different from each other. If the radio wave is shielded, it is possible to easily cope with an increase in the types of frequency bands to be shielded.

(Embodiment 7)
FIG. 30 is a cross-sectional view showing a configuration of an electromagnetic wave shielding board according to Embodiment 7 of the present invention.

  In the present embodiment, unlike the case of the first to sixth embodiments, the electromagnetic wave shielding sheet is not used, and the frequency selection layer 2 (actually one type or a plurality of types of antennas) is directly on the board body 1. Is formed. Since other configurations are the same as those in the first to sixth embodiments, description thereof will be omitted.

  As a specific method for forming the frequency selective layer 2 as described above, as an example, as in the case of the first embodiment, a conductive material in which a powdery conductive material such as copper, aluminum, or silver is contained in a binder is used. For example, a paste may be used. That is, this conductive paste may be applied uniformly on the board body 1 so that a predetermined pattern is formed, and then dried.

  Therefore, according to this embodiment, in providing the frequency selection layer 2 in the board main body 1, although there is no simplicity like the case of Embodiments 1-6, there exists a substantially the same effect in another point. Can do.

It is sectional drawing which shows typically the structure of the electromagnetic wave shielding board which concerns on Embodiment 1 of this invention. It is the whole figure (a) and principal part expanded sectional view (b) which show the roll-shaped frequency selection sheet | seat formed separately from the board main body. It is a top view which shows the pattern of the antenna in the frequency selection layer of an electromagnetic wave shielding board. It is a top view which expands and shows one antenna. It is a characteristic view which shows the relationship between the frequency and the amount of transmission attenuation in the electromagnetic wave shielding board whose first element part length is 10.6 mm. It is a characteristic view which shows the relationship between the 1st element part length and matching frequency in an antenna. FIG. 4 is a view corresponding to FIG. 3 and showing antenna patterns in the frequency selection layer of the electromagnetic wave shielding board according to Embodiment 2 of the present invention. It is a top view which expands and shows two adjacent antennas. FIG. 6 is a diagram corresponding to FIG. 5 and illustrating the relationship between the frequency and transmission attenuation in the antenna. It is a top view which shows the pattern in which the Jerusalem cross-shaped antenna is arranged in the matrix form as the modification 1 of this embodiment. It is a characteristic view which shows the relationship between the frequency and the amount of transparent attenuation in the modification 1. It is a top view which shows the pattern in which the Y-shaped antenna is arranged in the matrix form as the modification 2 of this embodiment. FIG. 12 is a diagram corresponding to FIG. 11 and illustrating a relationship between a frequency and a transparent attenuation amount in Modification 2. It is a characteristic view which shows together each relationship between the frequency in Example 1-5 of an experiment example, and transmission attenuation amount. It is a characteristic view which shows the relationship between (2nd element part length / 1st element part length) and a matching frequency in an experiment example. FIG. 4 is a diagram corresponding to FIG. 3 showing patterns of two types of large and small antennas in the frequency selection layer of the electromagnetic wave shielding board according to Embodiment 3 of the present invention. FIG. 5 is an enlarged view of a small antenna corresponding to FIG. 4. It is a characteristic view which shows the relationship between the frequency when each 1st element part length of two types of large and small antennas is 11.19 mm and 6.05 mm, respectively, and a transmission attenuation amount. It is a top view which shows the pattern in which two types of large and small Y-shaped antennas are arranged as the modification 1 of this embodiment. FIG. 20 is a view corresponding to FIG. 19 showing a pattern in which two types of large and small Jerusalem cross antennas are arranged as a second modification of the present embodiment. FIG. 20 is a view corresponding to FIG. 19 showing another pattern in which two types of large and small Jerusalem cross-shaped antennas are arranged as a third modification of the present embodiment. FIG. 6 is a view corresponding to FIG. 2 showing patterns of two kinds of large and small antennas in the frequency selective film of the electromagnetic wave shielding board according to Embodiment 4 of the present invention. FIG. 11 is an enlarged view corresponding to FIG. 10 showing two small antennas adjacent to each other. FIG. 23 is a view corresponding to FIG. 22 showing a modification of the fourth embodiment. FIG. 6 is a view corresponding to FIG. 1 schematically showing an overall configuration of an electromagnetic wave shielding board according to Embodiment 5 of the present invention. FIG. 3 is a view corresponding to FIG. 2 showing a roll-shaped frequency selection sheet formed separately from the board body. FIG. 5 is a diagram corresponding to FIG. 4 and illustrating a relationship between the first element length and the matching frequency. It is the FIG. 1 equivalent view which shows typically the whole structure of the electromagnetic wave shielding board which concerns on Embodiment 6 of this invention. FIG. 6 is a view corresponding to FIG. 1 showing a modification of the present embodiment. It is the FIG. 1 equivalent view which shows typically the whole structure of the electromagnetic wave shielding board which concerns on Embodiment 7 of this invention.

Explanation of symbols

1 Board body (non-combustible face material)
2 Frequency selection layer 3a Film substrate (film)
4 Antenna, large antenna (conductive part)
4a 1st element part 4b 2nd element part 6 Small antenna (conductive part)
6a 1st element part 6b 2nd element part 104 Y-shaped antenna, Y-shaped large antenna (conductive part)
106 Y-shaped small antenna (conductive part)
204 Jerusalem cross type antenna, Jerusalem cross type large antenna (conducting part)
206 Jerusalem Cross Small Antenna (conductive part)

Claims (10)

  A non-combustible face material and a frequency selection layer that is provided on one surface of the non-combustible face material and selectively shields electromagnetic waves in at least one frequency band with a plurality of conductive portions. An electromagnetic shielding material. The electromagnetic shielding material according to claim 1,
The electromagnetic wave shielding material, wherein the frequency selection layer is provided so as to selectively shield electromagnetic waves in a plurality of frequency bands.   Select electromagnetic waves of at least one frequency band with a plurality of regularly arranged conductive parts provided between a plurality of non-combustible face materials stacked on each other and at least one set of adjacent non-combustible face materials An electromagnetic wave shielding material comprising a frequency selective layer for shielding the electromagnetic wave. In the electromagnetic wave shielding material according to claim 3,
Each of the frequency selective layers is provided between a plurality of adjacent non-combustible face materials,
Each of the frequency selection layers is provided so as to selectively shield electromagnetic waves in a plurality of frequency bands. In the electromagnetic wave shielding material according to claim 1 or 3,
An electromagnetic wave shielding material, wherein the nonflammable face material is a foamed calcium carbonate board. In the electromagnetic wave shielding material according to claim 1 or 3,
The electromagnetic wave shielding material, wherein the frequency selection layer is formed directly on the nonflammable face material. In the electromagnetic wave shielding material according to claim 1 or 3,
Each conductive portion of the frequency selective layer includes three first element portions extending radially from one point, and each of the first elements extends in a direction intersecting with the corresponding first element portion and partially in the length direction. An electromagnetic wave shielding material comprising three second element parts coupled to the tip of each part. In the electromagnetic wave shielding material according to claim 1 or 3,
An electromagnetic wave shielding material, wherein the frequency selective layer is formed on a film, and the film is laminated on the non-combustible face material by being laminated on the non-combustible face material. The electromagnetic wave shielding material according to claim 8,
The electromagnetic wave shielding material, wherein the frequency selection layer is disposed on the non-combustible face material side of the film. The electromagnetic wave shielding material according to claim 8,
The electromagnetic wave shielding material, wherein the frequency selection layer is disposed on a side of the film opposite to the nonflammable face material.

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