JP4361189B2 - Manufacturing method of electromagnetic wave absorbing building materials for interior - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present inventionFor interiorMore specifically, the present invention relates to a method for manufacturing a plate-shaped building material used for inner and outer walls, floors, ceilings, and the like having uniform radio wave absorption performance.
[0002]
[Prior art]
In order to solve problems such as radio disturbance such as TV ghost and malfunction due to radio waves, conventionally, as shown in, for example, Japanese Patent Publication Nos. 55-13600 and 55-49798, buildings such as concrete ( In general, a large number of tiles made of a sintered ferrite body having good radio wave absorption characteristics in the VHF band and the UHF band are adhered to the outer wall surface of a high-rise building.
[0003]
However, in the case of using the above-mentioned conventional ferrite sintered body tile, the ferrite sintered body itself is very heavy, which causes problems in workability and safety of attaching the tile made of the ferrite sintered body. . Moreover, since the planar shape of such a tile is only about 100 mm square and is very small, the above-described pasting operation becomes very complicated.
[0004]
Furthermore, since the tile made of a ferrite sintered body is heavy, it has a strength to hold it and needs to exhibit a fireproof function, so that the thickness of the concrete also increases, and the weight on the concrete side increases accordingly. For example, even if a standard size of 4 m × 3.2 m is made using lightweight concrete (specific gravity 1.2), the weight of the concrete alone is 300 kg.
[0005]
As a result, the entire building becomes very heavy, and the foundation work and the steel frame work that support the weight of the building must be carried out, so that the processing is complicated and the work is prolonged and the cost is increased.
[0006]
Further, the radio wave absorption characteristics slightly change depending on the composition and dimensions of the ferrite constituting the tile. Thus, the tiles need to be dimensioned with high accuracy. However, it is difficult to accurately dimension the tiles due to shrinkage during sintering. In addition, there is a possibility that cracks and chips may occur after manufacturing, and a tile in which such a situation has occurred becomes a defective product. Therefore, due to the difficulty in dimensioning and the cracking, the yield when manufacturing tiles having desired characteristics is poor, resulting in higher costs. Further, in actuality, determination of a dimension and shape having desired characteristics is a complicated process because trial and error are repeated and the shrinkage rate fluctuates.
[0007]
Therefore, recently, in order to solve the above-described problem, a resistive film type electromagnetic wave absorber has been developed to reduce the thickness and weight. In the basic structure of such a radio wave absorber, a resistive film layer is provided on one surface of a dielectric layer, and a radio wave reflector layer is provided on the back side of the dielectric layer.
[0008]
In order to use the resistance film type electromagnetic wave absorber as a building material as it is, it is necessary to have a certain level of strength and fire resistance in a fire. Accordingly, the dielectric layer is preferably made of an inorganic dielectric such as concrete, cement mortar, gypsum, calcium silicate (Japanese Patent Laid-Open Nos. 9-260886, 9-283972, and 10-215097). (See publications).
[0009]
In the case of the resistive film type electromagnetic wave absorber disclosed in such a gazette, the resistive film layer has a carbon fiber bundle arranged in parallel on the surface of the dielectric layer (Japanese Patent Laid-Open Nos. 9-260886 and 9--9). No. 283972). As the installation method, an adhesive was used, or an integral molding was performed by placing concrete or the like in a state where the material constituting the resistive film layer was placed in the bottom of the formwork. .
[0010]
[Problems to be solved by the invention]
However, the above-described conventional radio wave absorber has the following problems. In other words, in order to obtain the desired radio wave absorption characteristics, the improvement of how to make the material and dimensions of the dielectric layer and the resistive film layer has been actively made, but the set radio wave absorption characteristics, There has been little research on how to make the entire radio wave absorber uniformly exhibited. In other words, although it can be understood that the material and thickness of the dielectric layer and the resistive film layer should be formed accurately and precisely as designed, and evenly on the whole, how do they actually become uniform? The development of was not made.
[0011]
Furthermore, although the required degree of accuracy is required to be very high as compared with the dimensional tolerance required for building materials, conventionally, no improvement has been made focusing on such accuracy. Moreover, no specific technique for obtaining uniform radio wave absorption performance has been disclosed for relatively large plates (standard dimensions: 910 mm × 1820 mm) such as building materials.
[0012]
Therefore, as a result of researches by the present inventors, it has been found that it is difficult to make a uniform thickness over the entire radio wave absorber (building material) in the resistance film layer using the conventional carbon fiber bundle. Furthermore, the dielectric layer and the resistive film layer need to be in close contact with each other, but in the conventional manufacturing method using adhesion or integral molding, there is a problem in long-term durability and the like because it cannot be in complete contact. . And if there is a part with poor adhesion, there will be an air layer between them, the dielectric constant will change at that part, and the overall thickness considering the dielectric constant is different from other parts, This is a cause of variation in characteristics.
[0013]
When the dielectric layer is an organic material such as a resin, the resistive film layer can be uniformly formed by sputtering or the like, but it is difficult to sputter on the surface of concrete or the like. Moreover, the fact that the object has a large size and shape such as a building material also contributes to difficulty in forming a film by sputtering or the like.
[0014]
  The present invention has been made in view of the above-described background, and the object of the present invention is to solve the above-described problems and to have uniform radio wave absorption performance even if it has a large size and shape.For interiorThe object is to provide a method of manufacturing a radio wave absorbing building material.
[0015]
[Means for Solving the Problems]
  In order to achieve the above-described object, at least a method for manufacturing a radio wave absorbing building material according to the present invention includes:The film thickness is in the range of 10 μm to 200 μmResistive film layer,Calcium silicate plate with equilibrium moisture contentA method for producing a radio wave absorbing building material, in which a dielectric layer and a radio wave reflecting material layer are laminated in this order, comprising a raw material for forming the resistive film layer on the surface of the dielectric layer As a paint, urethane resin, acrylic resin, acrylic urethane resin, polyester resin, unsaturated polyester resin, urethane acrylate resin, polyester acrylate resin as a binder, carbon powder is dispersed in the binder, A paint having a viscosity of 10 sec or more and 90 sec or less (measurement method: NK-2 cup method) is applied by a flow coater method, and then includes a resistance film layer manufacturing step of curing the paint.
[0020]
  More preferably, before carrying out the resistance film manufacturing step, a step of applying a sealing treatment paint to at least a surface of the dielectric layer in contact with the resistance film layer is performed.(Claim 2).
[0021]
  More preferably, a step of applying a sanding sealer thereon after applying the sealing treatment paint, a step of polishing and applying a surface treatment after curing the applied sealing treatment paint and the sanding sealer And applying a paint containing a raw material for forming the resistance film layer on the surface-treated surface.(Claim 3). Further, the viscosity is preferably 15 sec or more and 60 sec or less.
[0023]
DETAILED DESCRIPTION OF THE INVENTION
  FIG. 1 (a) relates to the present invention.For interior1 shows an embodiment of a radio wave absorbing building material manufactured by a method of manufacturing a radio wave absorbing building material. As shown in the figure, a resistive film layer 2 is provided on the surface (radio wave incident surface) of the inorganic ceramic building material layer 1 to be a dielectric layer, and a radio wave reflecting material layer 3 is provided on the back side of the inorganic ceramic building material layer 1. A three-layer structure is provided. Such a basic structure is the same as the conventional one.
[0024]
Here, the inorganic ceramics building material layer 1 is composed of inorganic ceramics building materials, and more specifically, calcium silicate board, fiber reinforced cement board, gypsum board, slag gypsum board, lightweight concrete board, precast concrete board, etc. Non-combustible building materials should be used. In addition, semi-incombustible building materials such as semi-incombustible gypsum board and wood-cement cement board can be used, but when semi-incombustible inorganic ceramic building materials are used as a dielectric layer, naturally the obtained radio wave absorbing building material Will not be incombustible.
[0025]
Further, the inorganic ceramic building material used in this embodiment is porous for weight reduction. Moreover, you may make it mix conductive materials, such as a ferrite powder, a metal powder, and a carbon fiber, as needed.
[0026]
When the thickness of the inorganic ceramic building material layer 1 is set to be ¼ wavelength within the layer with respect to the incoming radio wave, the radio wave reflector layer 3 exists behind it, so the input of the surface for that wavelength. The impedance becomes infinite. Furthermore, the input impedance of the surface of the resistive film layer 2 is set to be the same as the impedance of the space (details will be described later). Then, it becomes a non-reflective state and absorbs the radio wave of the said wavelength (a big radio wave absorption is obtained).
[0027]
That is, when the wavelength of the incoming radio wave to be absorbed is λ and the dielectric constant of the inorganic ceramic building material layer 1 (dielectric) is εr, the thickness of the inorganic ceramic building material layer 1 is λ / 4 (εr)^1/2Set to be. Here, the wavelength λ represents the speed of light of 2.998 × 10.¹¹In the case of mm / second and frequency f (GHz), λ (mm) = 2.998 × 10¹¹/ F × 10⁹It becomes.
Therefore, the relationship between the frequency f (GHz) of the radio wave to be absorbed and the thickness t (mm) of the inorganic ceramic building material layer 1 is
f = 299.8 / (4t (εr)^1/2)
It becomes.
[0028]
On the other hand, the volume resistivity of the resistive film layer 2 is set to 0.3 Ω · cm or more and 10.0 Ω · cm or less.
[0029]
In order to draw out the radio wave absorption characteristics of the resistive film type wave absorber, the surface resistance value of the resistive film is theoretically set to 377Ω which is the impedance of the space. However, when a dielectric such as an actual building material is used, it has a slight dielectric loss. Therefore, in consideration of the dielectric loss, when the surface resistance value of the resistive film layer 2 is set to 400Ω, The characteristics are the best. And even if the surface resistance value becomes larger than 400 ohms or becomes smaller, the radio wave absorption characteristics deteriorate. In order to verify this, when the radio wave absorption characteristics with respect to the frequency when the surface resistance value was changed were examined, the results shown in FIG. 2 were obtained.
[0030]
In addition, the radio wave absorption characteristics that are practically required may be at least 10 dB or more, for example, in order to suppress communication troubles in a private wireless LAN. In consideration of fluctuations in the thickness of the dielectric layer and the dielectric constant, it is preferable to obtain a radio wave absorption characteristic of 15 dB or more in an ideal state. Therefore, from the experimental results shown in FIG. 2, the allowable range of the surface resistance value is set to a range of 300 to 500Ω.
The surface resistance is determined by the film thickness and volume resistivity of the resistance film layer 2, and the film thickness range of the resistance film layer 2 needs to be in the range of 10 μm to 200 μm.
[0031]
The volume resistivity is defined by the following formula.
Volume resistivity (Ω · cm) = Surface resistance (Ω) × Thickness (cm)
Therefore, in order for the surface resistance to be 300 to 500Ω, the volume resistivity of the resistive film layer should be set to be 0.3Ω · cm or more and 10.0Ω · cm or less in consideration of the film thickness range. .
[0032]
The radio wave reflecting material layer 3 may be configured to cover the entire surface (no opening), such as a metal plate or metal foil, or may be a perforated metal plate, a metal mesh, or a metal coating. A mesh or the like (with an opening) can also be used. However, when a material having these openings is used as a radio wave reflecting material, the size of the openings needs to be 1/60 or less of the wavelength of the radio waves.
[0033]
The inorganic ceramic building material layer 1 and the radio wave reflecting material 3 are joined with an adhesive. Needless to say, the inorganic ceramic building material layer 1 can be integrally formed at the time of manufacture. That is, the manufacturing method of inorganic ceramics building materials is generally mixed with raw materials and water and molded by known techniques such as paper making, extrusion molding, molding, vacuum dehydration press, etc., and curing and curing after molding. For example, when a paper making method is used as a molding method, the obtained uncured molded product and the radio wave reflecting material are laminated and pressed to be integrated, and then cured and cured. .
[0034]
In addition, when using a molding method or a vacuum dehydration press method as a molding method, when an inorganic ceramic material mixed with water is put into a mold, a radio wave reflector is inserted at a desired position and molded. good. When the radio wave reflecting material 3 is also provided by integral molding when manufacturing an inorganic ceramic building material as in these methods, a material having an opening such as a perforated metal plate or a metal mesh may be used.
[0035]
Here, in the present invention, the resistive film layer 2 is formed using a paint. That is, the resistance film layer 2 is formed by converting the raw material for forming the resistance film into a paint and applying the paint uniformly to the surface of the inorganic ceramic building material layer 1. Thus, since the coating material is used, even if the application area is large, the film thickness can be applied uniformly over the entire application surface with high accuracy. And since it is a coating material, adhesiveness with the inorganic ceramics type building material layer 1 is also favorable, and it can be made to closely_contact | adhere and integrate over the whole surface. Therefore, the radio wave absorption performance can be made uniform throughout.
[0036]
Next, a method for manufacturing the above-described radio wave absorber will be described. For example, a metal plate or the like constituting the radio wave reflecting material layer is installed in a mold for producing a building material having a predetermined size and shape, such as a precast concrete plate. In this state, an inorganic ceramic building material layer 1 with the radio wave reflecting material layer 3 is manufactured by placing and curing the material constituting the inorganic ceramic building material layer such as concrete in the mold. In addition, you may affix the electromagnetic wave reflection material layer 3 using an adhesive agent separately. In that case, you may affix after manufacturing the resistance film layer 2 shown below.
[0037]
The coating material for forming the resistance film layer 2 is formed by kneading a resistance film material and a binder and mixing a diluent solvent and additives as necessary. First, the material for the resistance film is not particularly limited as long as the above-described desired surface resistance can be obtained.
[0038]
As a preferable combination, a non-conductive resin is used as a binder, and a conductive material such as graphite powder, carbon powder, or metal powder is dispersed therein as a resistance film material. Among these, a material in which carbon powder is dispersed as a conductive substance in a binder is particularly preferable. In this case, the mixing mass ratio of the resin and the carbon powder and the fineness (particle size) of the carbon powder depend on the resistance film layer thickness and the surface resistance value required for the resistance film layer to be formed. It will be set appropriately.
[0039]
Non-conductive binder is suitable for coating, easy to cure after coating, and the degree of shrinkage (curing shrinkage) in the curing process and the performance of the resistance film (hardness, Young's modulus) Etc.), urethane resins, acrylic resins, acrylic urethane resins, epoxy resins, polyester resins, unsaturated polyester resins, epoxy acrylate resins, urethane acrylate resins, polyester acrylate resins, and the like are suitable.
[0040]
Furthermore, as a solvent for dilution, an alcohol solvent, a polyhydric alcohol derivative solvent, a ketone solvent, an ether solvent, an aromatic hydrocarbon solvent, or the like is selected according to the type of resin. Additives that can be added to the paint include a dispersant for uniformly dispersing carbon in the resin, a leveling agent for obtaining a smooth coating surface when applied, and a foam in the paint. An antifoaming agent, a curing accelerator that accelerates the curing reaction of the resin, and the like can be added as necessary. Moreover, the said additive may be one type of addition, or may combine two or more types of additives.
[0041]
Coating materials prepared using the above materials can be applied to inorganic ceramics building materials using known coating methods such as spraying, roll coater, flow coater, transfer, and gravure offset printing. Apply to the surface. The use of the flow coater method is particularly preferable in the context of the present invention because a uniform coating can be formed efficiently.
[0042]
The conditions for applying the paint on the surface of the inorganic ceramic building material by the above method are as follows. First, the thickness of the resistance film is adjusted to be 10 μm or more and 200 μm or less. Of course, it is applied to the entire surface of the building material so as to maintain a predetermined thickness within this range. That is, when a resistance film having a desired surface resistance value is formed with a film thickness of less than 10 μm, it is difficult to uniformly coat the entire surface of the inorganic ceramic building material, and there is a variation in the surface resistance value of the resistance film layer 2. Since it becomes large, it is not preferable. In addition, since the resin and carbon powder, which are main resistance film materials constituting the resistance film layer 2, are both combustible materials, if the thickness of the resistance film layer 2 exceeds 200 μm, the non-combustible performance as a building material decreases. That is not preferable.
[0043]
In the case of building materials, a decorative layer may be further formed on the surface of the resistive film layer 2. At this time, when a decorative layer made of a non-conductor is provided, and this decorative layer is made of a combustible material such as a resin-based paint, the thickness of the resistive film layer is considered in consideration of the non-flammability as a building material. It is preferable that the total thickness of the decorative layers does not exceed 200 μm.
[0044]
Moreover, it is preferable that the viscosity of the coating material for resistance films shall be 10 sec or more and 90 sec or less (measurement method: NK-2 cup method). In particular, the viscosity of the paint when using the flow coater method, which is preferable as a coating method, is preferably 15 sec or more and 60 sec or less. If the viscosity of the paint is outside the above range, it is not only difficult to paint, but also the variation of the surface resistance value of the formed resistive film layer is not preferable. In other words, in a flow coater, if the viscosity is low, the paint curtain (coating film) that is formed becomes unstable, causing problems such as curtain breakage, and not only the coating itself becomes difficult, but also solids in the paint Since the fraction is reduced, an effective resistance film cannot be obtained. On the other hand, when the viscosity is high, dispersion of the solid content including the resistance film material in the coating is deteriorated, and the coated coating becomes difficult to level, which causes variations in film thickness.
[0045]
As described above, if the conductive paint having a predetermined film thickness is applied to the surface of the building material (inorganic ceramic industry building material layer), the applied paint is then cured. By curing in this way, the resistance film layer 2 that is firmly adhered to the surface of the inorganic ceramic building material layer 1 is formed.
[0046]
The specific curing method varies depending on the type of resin used as the binder, but thermal curing or electron beam curing is suitable. An electron beam curable coating material can be sufficiently and uniformly crosslinked and polymerized by irradiation with an electron beam, even if it is a coating material to which a pigment having high concealability such as carbon is added. In addition, the paint (resin) cured by this method has the advantage that, unlike the ultraviolet curable paint, there is little discoloration deterioration due to ultraviolet rays and it can be used outdoors.
[0047]
In the above-described embodiment, when the coating material constituting the resistive film layer is applied, it is applied directly to the surface of the inorganic ceramic building material layer 1, but preferably, as shown in FIG. In order to form the resistance film layer 2 on the surface of the sealing treatment layer 5 obtained by performing a ground treatment called a sealing treatment on the surface (application surface) of the ceramic building material layer 1 and then treating the surface. It is better to apply the paint.
[0048]
That is, the ground treatment is performed to smooth the painted surface of the inorganic ceramic building material and to improve the adhesion to the paint. Also in the present invention, the smoothness of the painted surface of the inorganic ceramic industry building material that is a dielectric layer and the adhesion between the surface of the building material and the paint are important requirements, and further, this alone is insufficient as a radio wave absorbing building material, It is necessary to prevent variation in the surface resistance value of the formed resistive film layer by preventing the uneven coating when the coating is applied and the uneven suction of the inorganic ceramic building material.
[0049]
Therefore, a coating for sealing treatment was applied to the surface of inorganic ceramic building materials. Here, the coating for the sealing treatment is a high-viscosity material containing a pigment, which is generated when an inorganic ceramic building material is manufactured and cannot be completely removed, such as pinholes, dents, and objects to be coated. It refers to the one that plays a role of filling delicate irregularities and the like generated by surface polishing or the like, which is the final process in production, until smooth. Moreover, what consists of nonconductors is preferable. Specifically, an ultraviolet curable paint composed of components such as a pigment, a photopolymerizable prepolymer, a photopolymerizable oligomer, a photopolymerizable monomer, a photopolymerization initiator, an additive, and a modifying resin, and A thermosetting paint composed of components such as a pigment, a binder, an additive, and a solvent can be used. In addition, since the sealing coating is highly viscous, the reverse roll coater and the natural roll coater are available as coating methods for effectively filling the surface of the inorganic ceramics building materials, such as dents and pinholes. And a reverse roll coater are suitable. A natural roll coater has a mechanism in which the rotation of a feed roll that transports inorganic ceramic building materials and a coating roll that applies paint is in the forward direction, and a reverse roll coater has a rotation of a feed roll and a coating roll. It has a mechanism that is in the reverse direction.
[0050]
Furthermore, the coating amount of the sealing coating is 10 g / m.²50 g / m²Within the following range. That is, the coating amount is 10 g / m²If it is less than this, the required performance (hole filling, surface smoothness, adhesion) cannot be obtained sufficiently (of course, better than nothing). As the coating amount increases, the performance improves, but the coating amount is 50 g / m.²The upper limit is 50 g / m because the cost is increased and performance is not improved.²It is practical to set the degree. In addition, the coating amount described in this specification means the weight of the coating material per unit area immediately after coating (not at the time of hardening) to the inorganic ceramic industry building material.
[0051]
Further, in this embodiment, in order to more reliably perform the ground treatment, the sanding sealer is applied after the coating material for the sealing treatment is applied. The applied sealing paint and sanding sealer are cured and polished to further increase the flatness of the coated surface.
[0052]
Further, the sanding sealer is applied on the sealing treatment paint, is for forming a polishing treatment layer on the surface of the object to be coated, and is preferably made of a nonconductor. Specifically, an ultraviolet curable paint composed of components such as a pigment, a photopolymerizable prepolymer, a photopolymerizable oligomer, a photopolymerizable monomer, a photopolymerization initiator, an additive, and a modifying resin, and A thermosetting paint composed of components such as a pigment, a binder, an additive, and a solvent can be used.
[0053]
The application amount of sanding sealer is 30g / m²Above, more preferably 50 g / m²100 g / m or more²The following is recommended. That is, the coating amount is 30 g / m²If it is less than 1, the thickness of the obtained sanding sealer layer is thin, and depending on the polishing conditions, the thickness of the sanding sealer layer may be significantly reduced, and the required performance (surface smoothness, adhesion, prevention of suction unevenness) This is because the variation of the surface resistance value of the resistance film formed by coating on the surface becomes large. On the other hand, the coating amount is 100 g / m, similar to the coating material for the sealing treatment.²The upper limit is only 100 g / m because the cost is increased even if the value is exceeded, and the performance is not improved.²It is practical to set the degree.
[0054]
Furthermore, the sanding sealer is applied and cured, and after the polishing process, the obtained polishing layer is smooth (the center line average roughness Ra measured at a cutoff value of 0.8 mm is 5.0 μm or less), Further, polishing is performed so that suction unevenness does not occur. In addition, the above-mentioned coating material for sealing treatment and sanding sealer are preferably ultraviolet curable from the viewpoint of production efficiency when performing surface treatment. By this treatment, the surface smoothness of the building material surface and the adhesion to the paint can be obtained, and variations in the surface resistance value of the formed resistance film layer can be prevented. Of course, it is not limited to ultraviolet irradiation, and heating or other curing methods may be used.
[0055]
Next, after the sanding sealer is cured, the surface of the inorganic ceramic building material is polished. When polishing with abrasive paper, the count of the abrasive paper is not particularly limited as long as it can be uniformly polished, but preferably # 80 or more and # 400 or less, more preferably # 180 or more and # 240 or less. . If it is less than # 80, the surface of the cured sanding sealer is not suitable because it becomes rough when polishing, and the polishing eyes or polishing streaks remain and impairs the surface smoothness. Since it is extremely low, it is not suitable. Further, the polishing machine used in the polishing process may be one head, or may have a structure in which the number of polishing paper is gradually increased by a plurality of heads.
In addition, as a prior art of the ground treatment in a general paint, there is, for example, Japanese Patent Publication No. 55-18680.
[0056]
By the way, the inorganic ceramics building materials are porous, and when the humidity in the air changes or when water is applied directly, the moisture content changes and the dielectric constant also changes, so that the radio wave absorption performance becomes unstable. Therefore, it is preferable to perform a treatment so that the moisture content does not change. In this embodiment, since the resistance film layer 2 covers the entire surface of the inorganic ceramic building material layer 1 which is a dielectric layer, it also serves as a waterproof layer. Further, when the radio wave reflecting material layer 3 is formed of a metal plate, a metal foil, or the like that does not have an opening, it functions as a waterproof layer for the other surface of the inorganic ceramic building material layer 1. That is, in this embodiment, there is also an effect that the waterproof function is exhibited without performing a special treatment that does not change the moisture content. Further, when a material having an opening such as a perforated metal plate, a metal mesh, or a metal-coated mesh is used as the radio wave reflector layer, the surface of the radio wave reflector layer 3 or the inorganic ceramic building material layer 1 and A predetermined waterproof layer may be provided between the radio wave reflecting material layers 3. Furthermore, it is more preferable to seal the edge of the inorganic ceramic building material layer (providing a waterproof layer).
[0057]
It is also effective to adjust the moisture content of the inorganic ceramic building materials to an equilibrium moisture content in order to stabilize the radio wave absorption performance. The equilibrium moisture content means the moisture content when the inorganic ceramic building materials are left for a long time in a well-ventilated room to stabilize the moisture content. For example, the measured value of the equilibrium moisture content of a calcium silicate plate having a bulk density of 0.8 at 20 ° C. is 3.2% to 6.2%, and the measured value of the equilibrium moisture content of a calcium silicate plate having a bulk density of 0.5. Is 4.9% to 7.2%, bulk specific gravity l. The measured value of the equilibrium moisture content of the fiber reinforced cement board No. 6 was 4.1% to 6.6%.
[0058]
FIG. 3 shows another embodiment of the present invention. In this embodiment, the embodiment shown in FIG. 1 is used as a basis, and a decorative layer 4 made of a nonconductor is formed on the surface of the resistive film layer 2. The decorative layer made of a non-conductor here is not particularly limited as long as it is a decorative layer made of a paint that does not contain a conductive substance. Acrylic resin, urethane resin, acrylic urethane resin, epoxy resin Examples thereof include paints composed of polyester resins, unsaturated polyester resins, epoxy acrylate resins, urethane acrylate resins, polyester acrylate resins, and the like. The decorative layer 4 may be formed by applying a paint, or a separately prepared decorative panel may be attached.
[0059]
If the decorative layer 4 is also formed integrally, it is not necessary to separately install a decorative panel or the like at the site, and the construction becomes easy. Further, when the material constituting the decorative layer 4 affects the radio wave absorption performance, it is preferable to incorporate the decorative layer 4 so that various designs can be made in consideration of the decorative layer 4.
[0060]
FIG. 4 shows still another embodiment of the present invention. In this embodiment, the inorganic ceramic building material layer 1 as a dielectric layer is provided on both sides of the radio wave reflecting material layer 3, and the surface of each inorganic ceramic building material layer 1 (surface to be joined with the radio wave reflecting material layer 3). The resistive film layer 2 is provided. As a result, radio waves incident from both sides can be absorbed, and convenience is improved. In order to manufacture a radio wave absorbing building material having such a structure, for example, a radio wave reflecting material is inserted and integrated between two uncured molded articles (inorganic ceramic building materials), and then a predetermined paint is applied to the surface. It can form by apply | coating. Of course, the radio wave reflecting material and one or both of the inorganic ceramic building material layers 1 may be joined in a post-process using an adhesive (separate from the production of the inorganic ceramic building material layer).
**Experimental result
In order to demonstrate the effect of the present invention, resistance film type radio wave absorption building materials with different manufacturing conditions were manufactured, and the characteristics were obtained.
[0061]
* Example 1
As the inorganic ceramic building material, a 0.8 FK calcium silicate plate (Celstone F, manufactured by Ask Co., Ltd., width 910 mm, length 1820 mm, thickness 8 mm) of type 2 defined in JIS-A-5430 was used. As a calcium silicate plate, an impregnation sealer (U-60 manufactured by Nippon Paint Co., Ltd.) is 70 g / m for the purpose of reinforcing the surface.²A pre-painted one was used. On the surface of this calcium silicate plate, 40 g / m of Ubicoat 60 sanding sealer seal made by Nippon Paint Co., Ltd. is used as a seal-treating coating.²Apply it and apply U-60 sanding sealer made by Nippon Paint Co., Ltd. as a sanding sealer at 80g / m²Coating (both coatings are performed with a roll coater), UV light is applied to two 80 W high-pressure mercury lamps, line speed is 6 m / min (integrated UV irradiation amount: 350 mJ / cm)²) Was cured by irradiation under the condition (2), and then a surface treatment (primary treatment) was performed by polishing with a wide belt sander (using abrasive paper: # 240).
[0062]
Moreover, the coating material which forms a resistance film layer uniformly disperse | distributed 15 mass% of carbon powders adjusted to the average particle diameter of 0.5 micrometer in the binder which made urethane resin 5 mass%. In addition, toluene was used as a solvent and the ratio of the solid content raw material of a coating material and a solvent was 20:80 by mass ratio. Furthermore, in order to uniformly disperse the carbon powder in the urethane resin, a dispersant was used as an additive. And the viscosity of the manufactured coating material was 83 sec (measured with NK-2 cup). Therefore, the paint diluted with toluene until the viscosity of the paint reached 40 sec was used for painting.
[0063]
This coating is performed by using a flow coater on the surface-treated surface of an inorganic ceramics building material (inorganic ceramics building material layer), 90 g / m of the diluted paint.²Applied. Thereafter, a resistance film layer was formed by heating and curing at 100 ° C. for 20 minutes.
[0064]
Furthermore, as the radio wave reflecting material, an aluminum foil having a thickness of 0.05 mm was used and bonded to the surface of the calcium silicate plate opposite to the surface on which the resistance film layer was formed via an adhesive. The moisture content of the calcium silicate plate at the time of joining was 5.2%.
[0065]
For the formed resistive film layer, the thickness and surface resistance value were measured at 28 locations. The thickness was 56 ± 4 μm, the surface resistance value was about 400 ± 30Ω (specifically, 372 to 430Ω), and it was confirmed that the variation in the surface resistance value was extremely small.
[0066]
In addition, the radio wave absorption performance is intended to absorb 5.2 GHz band radio waves. Radio wave absorption performance was measured at six locations of this radio wave absorbing building material. The measurement was performed by the horn antenna method. Then, the minimum value of the absorption peak was 25 dB, and the absorption range of 15 dB or more was 1.5 ± 0.1 GHz, and the radio wave absorption performance was practically sufficient. Furthermore, when the same measurement was performed after leaving the room indoors for two months, no difference was observed in the radio wave absorption performance from that immediately after production.
* Example 2
It was based on the one of Example 1 and was manufactured without the surface treatment. That is, using a flow coater, a coating for directly forming a resistance film layer on the surface of the same calcium silicate plate is 90 g / m.²After coating, a resistance film layer was formed by heating and curing at 100 ° C. for 20 minutes. Furthermore, an aluminum foil was adhered to the back surface of the calcium silicate plate with an adhesive to form a radio wave reflecting material layer.
[0067]
The surface resistance value is increased by the amount not subjected to the ground treatment, becomes 280-548Ω, and the radio wave absorption value of the radio wave absorption characteristic at 5.2 GHz is 16 dB. .
* Comparative Example 1
The materials used and the manufacturing process were basically the same as in Example 1 (the ground treatment was also performed), and the film thickness of the coating material constituting the resistance film layer was reduced (9 μm). As a result, the surface resistance value varied from 204 to 720Ω. Furthermore, the radio wave absorption value of the radio wave absorption characteristics at 5.2 GHz was 10 dB, and sufficient radio wave absorption characteristics were not obtained.
[0068]
* Example 3
Based on Example 1, the radio wave reflecting material was composed of a metal mesh, and the metal mesh was formed integrally when the calcium silicate plate was formed. Other configurations are the same as those of the first embodiment. Even with such a configuration, since there is no influence on the resistance film layer side, the variation of the film thickness and the surface resistance value was the same as in Example 1, and the same result was obtained for the radio wave absorption characteristics.
[0070]
A calcium silicate board is a building material mainly used for interior use. That is, it is preferably used for suppressing communication failure when a local wireless LAN or the like is constructed. On the other hand, the fiber reinforced cement board is mainly used for exterior. Therefore, the present invention can be used for both interior and exterior use, and when used for exterior use as in the present embodiment, it can be used, for example, for countermeasures against television ghosts.
[0071]
【The invention's effect】
  As aboveIn the lightSince the resistive film layer is formed of a paint, the thickness of the resistive film layer can be made uniform over the entire surface even if the size and shape of the radio wave absorbing building material is large. Moreover, even if an inorganic ceramic building material is used for the dielectric layer, the paint, that is, the resistance film layer can be reliably adhered. Therefore, even if it is a thing of a big dimension shape, uniform electromagnetic wave absorption performance can be obtained.
[Brief description of the drawings]
FIG. 1 manufactured by the present inventionFor interiorIt is a figure which shows one form of a radio wave absorption building material.
FIG. 2 is a diagram showing radio wave absorption characteristics.
FIG. 3 produced by the present inventionFor interiorIt is a figure which shows another suitable one form of a radio wave absorption building material.
FIG. 4 produced by the present inventionFor interiorIt is a figure which shows the form of another suitable form of a radio wave absorption building material.
[Explanation of symbols]
  1 Dielectric layer (inorganic ceramics building material layer)
  2 Resistance film layer
  3 Radio wave reflector layer
  4 Makeup layer
  5 Sealing treatment layer

Claims (4)

This is a method of manufacturing a radio wave absorbing building material in which at least a resistive film layer having a film thickness in the range of 10 μm to 200 μm, a dielectric layer made of a calcium silicate plate having an equilibrium water content , and a radio wave reflecting material layer are laminated in this order. And
As a paint containing a raw material for forming the resistive film layer on the surface of the dielectric layer, urethane resin, acrylic resin, acrylic urethane resin, polyester resin, unsaturated polyester resin, urethane acrylate resin, polyester acrylate A resin selected from a series resin is used as a binder, carbon powder is dispersed in the binder, and a viscosity of 10 sec to 90 sec (measurement method: NK-2 cup method) is applied by a flow coater method,
Then, the manufacturing method of the electromagnetic wave absorption building material for interiors characterized by including the resistance film layer manufacturing process which hardens the said coating material. 2. The interior according to claim 1, wherein a step of applying a sealing paint is applied to at least a surface of the dielectric layer in contact with the resistance film layer before the resistance film manufacturing step is performed. Manufacturing method for electromagnetic wave absorbing building materials. A step of applying a sanding sealer thereon after applying the coating for sealing treatment;
After curing the applied coating for sealing treatment and the sanding sealer, carrying out a step of polishing and surface treatment,
3. The production of an interior radio wave absorbing building material according to claim 2 , wherein a step of applying a paint containing a raw material for forming the resistance film layer on the surface-treated surface is performed. Method. The said viscosity is 15 sec or more and 60 sec or less, The manufacturing method of the electromagnetic wave absorption building material for interiors of any one of Claim 1 to 3 characterized by the above-mentioned.

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