JP2008130749A - Nonflammable wave absorber - Google Patents

Abstract

[PROBLEMS] To be excellent in radio wave absorption ability in the vicinity of a frequency of 5.8 GHz band. To provide a nonflammable electromagnetic wave absorbing plate with good characteristics.
A noncombustible wave absorbing plate 1 includes an electric resistance layer 11, a calcium silicate plate 10, and a radio wave reflector 12 in that order from the side on which a radio wave enters.
[Selection] Figure 1

Description

  The present invention relates to a lightweight non-combustible wave absorbing plate capable of preventing malfunction due to multiple reflection of radio waves emitted from communication equipment in an ETC system or a DSRC system.

In recent years, communication of various types of information by communication devices has been activated, and for example, an in-house computer network has been expanded in an office. From the viewpoint of convenience, LAN (Local Area Network) construction is also becoming popular from wired to wireless networks.
In addition, ITS (Intelligent Transport System) has been built on toll roads such as expressways, and as part of this, ETC (Electronic Toll Collection System) and DSRC (Dedicated Short System) Range Communications systems are becoming widespread. Such an automatic toll collection system is a system that can be used for rooftop and underground parking lots, drive-throughs, and gas stations.

  On the other hand, when the above-described wireless system is employed, malfunction may occur due to multiple reflections of radio waves on the ceiling, side walls, and the like. For example, there are many reflectors such as metal furniture in an office, and it is inevitable that a reflected wave of a self radio wave is generated. In the case of an ETC system and a DSRC system, radio waves are reflected multiple times on the ceiling, road surface, wall, and the like. As described above, due to the crossing of radio waves, not only the efficiency of radio wave transmission is deteriorated and communication quality is deteriorated, but also malfunction of information equipment becomes a serious problem.

Therefore, in order to prevent such reflection of radio waves, a method is adopted in which a magnetic material that absorbs radio waves is mixed with a plate or sheet, and this is installed on a reflection surface. For example, as a radio wave absorber, a sheet or plate material in which ferrite is kneaded using a resin material or a rubber material as a matrix has been developed. However, even though such sheets and plates can be used in ETC systems, etc., the resin material and rubber material are matrixes, so deterioration due to ultraviolet rays can be considered outdoors, and there is also a problem with the durability years. was there. In particular, incombustible materials that are inferior in fire resistance are inappropriate for underground and rooftop parking lots where DSRC systems are used, and inner walls of tunnels related to ITS, and it is necessary to provide radio wave absorbers made of noncombustible materials. It was.
As such non-combustible radio wave absorbers, technologies for non-combustible radio wave absorbers compatible with wireless LAN and non-combustible radio wave absorbers compatible with ETC have been disclosed (for example, see Patent Document 1 and Patent Document 2).

JP 2002-364154 A JP 2003-229893 A

  However, the non-combustible wave absorbing plates disclosed in Patent Document 1 and Patent Document 2 are high in weight because they contain high specific gravity ferrite, and the construction on a high place such as a ceiling becomes complicated. Furthermore, since the radio wave absorbing plate is heavy, there is a possibility that it will fall off the ceiling or side wall when used for a long time.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a lightweight non-combustible wave absorbing plate that has the ability to absorb radio waves in the frequency band of ETC systems and DSRC systems.

In order to solve the above-mentioned problems, the non-combustible wave absorbing plate of the present invention includes an electric resistance layer, a calcium silicate plate, and a wave reflector in order from the side on which the radio wave enters.
According to the non-combustible wave absorbing plate of the present invention, the calcium silicate plate has a structure in which an electric resistance layer is formed on one surface and a wave reflector is provided on the other surface. Moreover, since a calcium silicate board is a nonflammable material, it can maintain nonflammability in the excellent state.
Therefore, the non-combustible wave absorbing plate of the present invention is not only non-combustible, but the calcium silicate plate is inherently free of sawing, nailing, etc. like wood and plywood. Rich in nature. And by performing papermaking and molding continuously, it can be provided as a radio wave absorber that is advantageous from the viewpoint of productivity. In addition, it is excellent as a non-combustible wave absorber for preventing malfunction due to multiple reflections of radio waves emitted from communication equipment. In particular, ETC (Electronic Toll Collection System) and DSRC (Dedicated Short Range Communications) : Narrow-area communication) can be suitably used for toll wall materials, ceiling materials, and the like. Furthermore, even when such a system is applied to a parking lot, a drive-through, etc., it can be used advantageously.

In the noncombustible wave absorbing plate of the present invention, the surface resistance value of the electrical resistance layer is preferably 350 to 650 Ω / □.
When the surface resistance value of the electric resistance layer is within the above range, it is possible to exhibit a radio wave absorption characteristic in which a reflection loss is 20 dB or more in a target frequency band of 5.8 GHz.

In the present invention, the electrical resistance layer is preferably a conductive paint applied to the calcium silicate plate.
According to the present invention, since the electric resistance layer can be easily formed simply by applying the conductive paint to the calcium silicate plate, the cost is excellent. In addition, mass production is facilitated. When the conductive material contained in such a conductive paint is carbon black having conductivity, the film thickness for obtaining a predetermined electric resistance value can be reduced, and the acid resistance is higher than that of metal particles. It is preferable because it is excellent in chemical properties and stability over time.

In the present invention, the calcium silicate plate may be a light calcium silicate plate or a hard calcium silicate plate.
Here, the light calcium silicate plate is a JIS A5430 type 2 0.8 calcium silicate plate, and the hard calcium silicate plate is a JIS A5430 type 2 1.0 calcium silicate plate. It is.
A hard calcium silicate plate is preferable because it has a higher dielectric constant than a light calcium silicate plate and can be made thinner in order to set a predetermined frequency.

Moreover, it is preferable that the thickness of a calcium silicate board is 5-9 mm.
Since the calcium silicate plate generally employs a papermaking method, if the thickness is within this range, the molding yield is good and the productivity is excellent.

(Configuration of non-combustible wave absorber)
FIG. 1 is a cross-sectional view showing an embodiment of the configuration of a non-combustible wave absorbing plate (hereinafter also simply referred to as “wave absorbing plate”) of the present invention.
The radio wave absorbing plate 1 has a multilayer structure, and includes an electric resistance layer 11, a calcium silicate plate 10, and a radio wave reflector 12 in this order from the side on which the radio wave enters.

Here, the calcium silicate plate 10 may be a light calcium silicate plate (JIS A5430 type 2 0.8 calcium silicate plate), or a hard calcium silicate plate (JIS A5430 type 2 1.0 calcium silicate plate). ) May be used. Since the hard calcium silicate plate has high bending strength, it is suitable when the ceiling or wall requires strength.
Moreover, it is preferable that the thickness of a calcium silicate board is about 5-9 mm. If the thickness is less than 5 mm, the molding yield is unfavorable. Further, if it exceeds 9 mm, productivity is inferior, which is not preferable.

The electrical resistance layer 11 is a resistance film formed by applying a conductive paint to one surface of the calcium silicate plate 10. Here, examples of the conductive substance contained in the conductive paint include carbon-based carbon black, metal particles such as copper, silver, and nickel. When the composition type and blending ratio of the conductive paint are different, the surface resistance value is different even if the thickness of the electric resistance layer is the same.
It is preferable to apply the conductive paint by adjusting the thickness of the conductive paint so that the surface resistance value of the electric resistance layer is 350 to 650 Ω / □. If the surface resistance value is less than 350Ω / □ or exceeds 650Ω / □, the absorption peak shifts in the intended frequency band of 5.8 GHz, or the amount of absorption decreases to obtain a reflection loss of 20 dB or more. It becomes difficult.

  The radio wave reflector 12 needs to have conductivity and effectively reflect radio waves, and is a layered metal material, specifically, a thin plate or film made of aluminum, copper, nickel, stainless steel, iron, or the like. Sheets, mesh nets, foils and the like can be employed. The thickness of the radio wave reflector 12 is not particularly limited, but may be about 0.1 to 1 mm.

(Manufacture of non-combustible wave absorbers)
An example of the manufacturing method of the nonflammable wave absorber 1 is shown below.
The radio wave reflector 12 is bonded to one surface of the hard calcium silicate plate 10 with an adhesive or a screw (screw). When an adhesive is used, an organic or inorganic adhesive can be employed. As the organic adhesive, α-olefin, acrylic, urethane, and epoxy adhesives can be used, and as the inorganic adhesive, sodium silicate, alumina cement, and the like can be used.
Next, a conductive paint is spray applied to the other surface of the hard calcium silicate plate 10 to form the electric resistance layer 11.

  Thus, as shown in FIG. 1, the noncombustible wave absorbing plate 1 of the present invention employs a three-layer structure including the electric resistance layer 11, the calcium silicate plate 10, and the wave reflector 12. Since the calcium silicate plate is a dielectric, the absorption frequency can be broadened by a two-layer structure with an electric resistance layer.

It should be noted that the present invention is not limited to the above-described embodiments, and modifications and improvements within the scope that can achieve the object of the present invention are included in the present invention. For example, when the non-combustible radio wave absorber 1 is used outdoors, it is preferable that the non-combustible radio wave absorber 1 is waterproofed when installed in a place where it is expected to get wet by rainwater.
Examples of waterproofing treatment include applying a water repellent to form a water repellent layer on the surface, applying a waterproof paint, and covering the non-combustible wave absorbing plate 1 with a waterproof sheet. By performing such waterproofing treatment, it is possible to prevent a decrease in absorption performance due to the incombustible wave absorbing product plate 1 being wet and a dielectric constant being increased, and a reduction in the intended absorption frequency.

  Hereinafter, the present invention will be described more specifically with reference to examples. In addition, this invention is not limited to the content of these Examples.

(Manufacture of non-combustible wave absorbers)
A noncombustible wave absorbing plate 1 as shown in FIG. 1 was produced as follows.
As the hard calcium silicate plate 10, a JIS A5430 type 2 1.0 calcium silicate plate was used. The apparent density of the hard calcium silicate plate 10 is 1.1 g / cm ³ and the thickness is 5.7 mm. The hard calcium silicate plate 10 was spray-coated with a carbon-based conductive paint to form an electric resistance layer (resistance film) 11 having a surface resistance value of 520 Ω / □.
On the other surface of the hard calcium silicate plate 10, an aluminum film having a thickness of 0.1 mm was bonded as an electromagnetic wave reflector 12 with an acrylic adhesive. Then, the surface part of the electrical resistance layer 11 and the side part of the nonflammable wave absorber 1 were finished by fluorine coating.

(Evaluation method and results)
With respect to the noncombustible wave absorbing plate 1 obtained by the above method, a test piece having a predetermined size of 500 mm × 500 mm is prepared, and circular polarization of a predetermined region is irradiated from the direction of the electric resistance layer 11 at incident angles of 15 ° and 50 °. did.
The result of confirming the reflection loss for this radio wave is shown in FIG. In this graph, the frequency (GHz) of a radio wave incident on the horizontal axis is set, and the reflection loss (dB) of the reflected radio wave is set on the vertical axis. As shown in FIG. 2, it was confirmed that the reflection loss was 20 dB or more in the frequency band of 5.8 GHz used for the ETC system and the DSRC system. Therefore, it has been confirmed that the non-combustible wave absorbing plate of the present invention can be sufficiently applied to use for wave absorption in the ETC system and the DSRC system.

  INDUSTRIAL APPLICABILITY The present invention can be suitably used as a non-combustible radio wave absorber suitable for ceiling materials and side walls of a toll booth that employs an ETC system or a DSRC system.

Sectional drawing which shows the one aspect | mode of the nonflammable electromagnetic wave absorber which concerns on embodiment. In an Example, the graph which shows the electromagnetic wave absorption performance of a nonflammable electromagnetic wave absorption board.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Nonflammable electromagnetic wave absorption board 10 ... Calcium silicate board 11 ... Electrical resistance layer (resistance film)
12 ... Radio wave reflector

Claims (7)

  A non-combustible wave absorbing plate comprising an electric resistance layer, a calcium silicate plate, and a wave reflector in order from the side on which a radio wave enters. The noncombustible wave absorbing plate according to claim 1,
A surface resistance value of the electric resistance layer is 350 to 650 Ω / □. In the nonflammable wave absorbing plate according to claim 1 or 2,
The non-combustible wave absorbing plate, wherein the electrical resistance layer is a conductive paint applied to a calcium silicate plate. In the nonflammable electromagnetic wave absorption board in any one of Claims 1-3,
A nonflammable wave absorbing plate, wherein the conductive material contained in the conductive paint is carbon black having conductivity. In the nonflammable electromagnetic wave absorption board in any one of Claims 1-4,
The noncombustible wave absorbing plate, wherein the calcium silicate plate is a light calcium silicate plate or a hard calcium silicate plate. In the nonflammable electromagnetic wave absorption board in any one of Claims 1-5,
A nonflammable wave absorbing plate, wherein the calcium silicate plate has a thickness of 5 to 9 mm. In the nonflammable electromagnetic wave absorption board in any one of Claims 1-6,
A nonflammable wave absorbing plate, wherein the nonflammable wave absorbing plate is used in an ETC system or a DSRC system.

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