JPH0662072U - Electromagnetic wave absorbing wall structure and metal base material therefor - Google Patents

Abstract

(57) [Summary] (Modified) [Purpose] Regarding the wall structure in which tiles are locked to the metal base material attached to the surface of the structure of the structure to finish the outer wall surface, the radio waves reflected from this structure Provided is an electromagnetic wave absorbing wall structure capable of preventing a radio wave interference such as a ghost caused by. Further, a metal base material for forming such an electromagnetic wave absorbing wall structure is provided. [Structure] In a wall structure in which a metal base material 5 is attached to the surface of a skeleton 4 of a construction, and the tile 1 is locked to an engaging portion formed on the metal base material 5 to finish the surface of the skeleton,
Between the metal base material 5 and the tile 1, there is an electromagnetic wave absorbing wall structure in which an electromagnetic wave absorbing layer 10 having an electromagnetic wave absorbing performance is laminated on the front surface side of the metal base material 5 and / or the back surface side of the tile. Further, it is a metal base material for forming an electromagnetic wave absorbing wall, which has an electromagnetic wave absorbing layer having an electromagnetic wave absorbing property laminated on the surface.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a wall structure in which the surfaces of various structures such as buildings and highways and bridges are tiled, and more specifically, electromagnetic wave absorption that can prevent the reflection of radio waves from these structures as much as possible. The present invention relates to a wall structure and a metal base material therefor.

[0002]

[Prior art]

 In recent years, as many large structures such as skyscrapers and highways are built, radio waves reflected from these structures are becoming more and more popular as a so-called “ghost” television interference. Therefore, in the past, in order to eliminate such a TV reception trouble, an electromagnetic wave absorption panel (Japanese Utility Model Publication No. 63-55,494) in which a ferrite layer is integrally formed on the surface of a plate-shaped tile base material, , A first ferrite-based molded body that absorbs radio waves in the VHF frequency band, a metal mesh-shaped first reflector that reflects radio waves in the VHF frequency band and passes radio waves in the UHF frequency band, and a UHF frequency band. Wave absorbing wall body formed by stacking a second ferrite-based molded body that absorbs radio waves of the above and a second reflecting plate that reflects radio waves in the UHF frequency band (Japanese Patent Laid-Open No. 2-16,038). ) Is proposed.

By the way, in recent years, with regard to the wall structure of these structures, since the appearance has come to be emphasized, the outer wall surface has been favored to be tiled. In order to facilitate the construction at this time, a metal base material is attached to the surface of the skeleton, and the tiles are locked to the engaging parts formed on this metal base material to finish the skeleton surface. ing. However, in the case of the wall structure in which the tile is locked to the metal base material attached to the surface of the skeleton in this way to finish the surface of the outer wall, the device described in Japanese Utility Model Laid-Open No. 63-55,494 is disclosed. In addition, if the ferromagnetic ferrite layer is integrally formed on the surface of the tile, the ferromagnetic ferrite layer on the tile surface may be damaged during the mounting work of this tile.Therefore, it is necessary to pay close attention to the mounting work. In addition to problems in installation workability, there is a problem that even after installation work is always exposed to wind and rain, damage due to flying objects and deterioration due to rain and snow are likely to occur, and durability (weather resistance) is poor. Since the ferromagnetic ferrite layer is the outermost layer, the appearance is also restricted. Further, in such a wall structure, the tile is locked to the metal base material attached to the surface of the frame to finish the surface of the outer wall, and therefore, JP-A-2-16,038. It is difficult to adopt a laminated structure in which the first ferrite-based compact, the first reflector, the second ferrite-based compact, and the second reflector are laminated on each other, as in the invention described above.

[0004]

[Problems to be solved by the device]

 Therefore, the inventor of the present invention imparts electromagnetic wave absorbing performance to the wall structure in which the tile is locked to the metal base material attached to the surface of the frame of the structure as described above to finish the outer wall surface. As a result of intensive studies, an electromagnetic wave absorbing layer having an electromagnetic wave absorbing performance is laminated on the front surface side of the metal base material and / or the back surface side of the tile, so that there is no hindrance to the workability of this wall structure. The inventors have completed the present invention by finding that an electromagnetic wave absorbing wall structure can be formed that has excellent durability (weather resistance), and that the appearance of the formed wall structure is not restricted. Therefore, the object of the present invention is to prevent a ghost, etc. due to the radio waves reflected from this structure in a wall structure in which a tile is locked to a metal base material attached to the surface of the structure of the structure to finish the outer wall surface. It is to provide an electromagnetic wave absorbing wall structure capable of preventing radio wave interference. Another object of the present invention is a wall structure in which tiles are locked to a metal base material attached to the surface of the structure of the structure to finish the surface of the outer wall, and ghosts due to radio waves reflected from the structure An object of the present invention is to provide a metal base material used for forming an electromagnetic wave absorbing wall structure capable of preventing radio wave interference.

[0005]

[Means for Solving the Problems]

 That is, the present invention relates to a wall structure in which a metal base material is attached to the surface of the structure of the structure, and the tile is locked to the engaging portion formed on the metal base material to finish the surface of the structure. An electromagnetic wave absorbing wall structure in which an electromagnetic wave absorbing layer having electromagnetic wave absorbing performance is laminated on the front surface side of the metal base material and / or the back surface side of the tile between the base material and the tile. In addition, the present invention is a metal base material that is attached to lock a tile to a building frame when finishing the surface of the building structure, and an electromagnetic wave absorbing coating agent containing a resin and ferrite powder on the surface of the metal base material. Alternatively, a metal base for forming an electromagnetic wave absorbing wall is formed by laminating an electromagnetic wave absorbing layer having an electromagnetic wave absorbing performance, which is formed of an electromagnetic wave absorbing sheet material obtained by molding a resin composition including a resin and ferrite powder. It is a material.

In the wall structure to which the present invention is applied, a metal base material is attached to the surface of the structure of the building, and the tiles are locked to the engaging portions formed on the metal base material to finish the outer wall surface of the structure of the structure. It is a wall structure that does. Here, as the metal base material to be attached to the surface of the frame, for example, one formed of an extruded aluminum alloy material and having a plurality of engaging ridges as an engaging portion for tile locking, An example is one that is formed by press forming of an excellent steel steel plate and has a punching stop piece as an engaging portion for locking a tile. In addition, as a tile that is locked to the engaging portion formed on such a metal base material, for example, it is formed so as to be engageable with the metal base material by extrusion molding, embossing molding, cutting work, or the like. There are various types of tiles such as ceramic, lightweight concrete, stone, glass, etc.

Further, in the present invention, the electromagnetic wave absorbing layer laminated on the front surface side of the metal base material and / or the back surface side of the tile is an electromagnetic wave composed of a resin as a binder and a ferrite powder as a radio wave absorber. It is formed by applying an absorption coating agent or fixing an electromagnetic wave absorbing sheet material obtained by molding a ferrite powder / resin composition comprising these resins and ferrite powder. Here, examples of the resin used as the binder include resins such as epoxy resin, urethane, polyethylene, acrylic resin, and nylon, and rubber such as neoprene. Examples of the ferrite powder used as the radio wave absorber include ferrite containing nickel or cobalt, ferrite containing metal fibers, and the like, and the particle size thereof is usually 0.1 μm to 1. It is 0 mm, preferably 0.5 to 200 μm. The mixing ratio of these resins and the ferrite powder is not particularly limited, but is usually 60 to 90% by weight of ferrite powder and 40 to 10% by weight of resin content, preferably 80% by weight of ferrite powder. The resin content is about 20% by weight. If the mixing ratio of the ferrite powder is too small, the electromagnetic wave absorption efficiency will be insufficient, and if it is too large, the strength will be decreased.

The method of applying the electromagnetic wave absorbing coating agent on the front surface side of the metal base material and / or the back surface side of the tile is not particularly limited, and generally, an electromagnetic wave absorbing coating agent is suitable. It can be dissolved / dispersed in a solvent and applied by means such as spraying, brushing, or roller coating. As a method of molding the electromagnetic wave absorbing sheet, for example, a ferrite powder / resin composition is uniformly kneaded into a paste or pellet, which is extruded with an extruder to form a metal base material. There is a method such as forming a compatible molded product, or by spreading a paste-like ferrite powder / resin composition in a plate shape, and the electromagnetic wave absorbing sheet-shaped product molded in this way is made of metal. Regarding the method of fixing to the front surface side of the base material and / or the back surface side of the tile, for example, a method of forming engaging portions on the electromagnetic wave absorbing sheet material and the metal base material, respectively, and attaching the both to each other, Examples include a method of sticking with an appropriate adhesive and a method of screw fixing. In this way, the thickness of the electromagnetic wave absorbing layer laminated on the front surface side of the metal base material and / or the back surface side of the tile is required to be the proportion of ferrite powder contained in the laminated electromagnetic wave absorbing layer or required. Although it depends on the performance and the like, it is usually 1 to 5 mm, preferably 1. It is 5 to 3 mm. If the electromagnetic wave absorbing layer is too thin, the electromagnetic wave absorbing performance will be deteriorated, and if it is too thick, the weight will be excessive.

When the electromagnetic wave absorbing layer is laminated on the surface side of the metal base material, after the metal base material is attached to the surface of the frame of the building, before the tile is locked to the metal base material. May also be formed by applying an electromagnetic wave absorbing coating agent by means such as spraying or brushing. Also, a method for attaching an electromagnetic wave absorbing sheet material, a method for attaching the same, a method for fixing a screw, etc. They may be fixedly formed by the above means. Furthermore, when laminating an electromagnetic wave absorbing layer on the back side of the tile, before attaching this tile by locking it to the engaging part of the metal base material attached to the surface of the structure of the construction, It is formed by applying an electromagnetic wave absorbing coating agent on the side by means such as spraying or brushing, or by fixing it by means such as a method of adhering an electromagnetic wave absorbing sheet material.

[0010]

【Example】

 Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings.

Embodiment 1 FIG. 1 is a front explanatory view of a wall structure formed according to an embodiment of the present invention, in which a vertical joint 2 and a horizontal joint 3 are formed around a tile 1 so that the appearance is like masonry. It constitutes a wall structure. Then, as shown in FIG. 2, which is a sectional view taken along the line II-II of FIG. 1, the wall structure of this embodiment is directly attached to the surface of the skeleton 4 of the construct with an anchor bolt or via a furring strip. A large number of metal base materials 5 are attached, and the tiles 1 are locked to these metal base materials 5 by engaging portions 6, 7, 8 formed on the metal base materials 5. In this embodiment, an electromagnetic wave absorption layer 10 is laminated on the entire surface of each of the metallic base materials 5 as shown in FIG. The electromagnetic wave absorption layer 10 was prepared by adding 80 parts by weight of ferrite powder (particle size: 0.3 mmφ or less, manufactured by NEC Corporation) to 20 parts by weight of an epoxy resin (trade name: DE482 manufactured by Nogawa Chemical Co., Ltd.), and % Of methanol was added and kneaded with a blade type kneader to prepare a pasty electromagnetic wave absorbing coating agent, and the electromagnetic wave absorbing coating agent was brushed on the surface of the metal base material 5 to a thickness of about 1.5 mm. The composition was applied to, and dried and cured at 60 ° C. for 3 hours using a drier, and then cured. The performance of the electromagnetic wave absorbing wall structure of Example 1 thus formed was measured using an electromagnetic wave absorptivity measuring device. As a result, the electromagnetic wave absorption performance was 10 to 15 (dB).

Example 2 On the back side of the tile 1 used in Example 1, the same electromagnetic wave absorption coating agent as used in Example 1 was applied by brush coating to a thickness of about 1 mm, and dried with a drier. The electromagnetic wave absorption layer 10 was laminated by drying, curing and curing under conditions of 3 ° C. for 3 hours. The tile 1 having the electromagnetic wave absorbing layer 10 laminated on the back side thus obtained is used as the engaging portion 6 of the metal base material 5 having the electromagnetic wave absorbing layer 10 laminated on the front side as in Example 1 above. , 7 and 8 were engaged and attached to form the electromagnetic wave absorbing wall structure of Example 2. The electromagnetic wave absorbing performance of the electromagnetic wave absorbing wall structure of Example 2 was measured in the same manner as in Example 1. As a result, the electromagnetic wave absorption performance was 15 to 20 (dB).

Example 3 80 parts by weight of ferrite powder (particle size: 0.3 mmφ or less, manufactured by NEC Corporation) was added to 20 parts by weight of a urethane resin (trade name: DU-37 manufactured by Nogawa Chemical Co., Ltd.) and kneaded. Then, the paste-like product was spread on a flat plate into a sheet-like form, and allowed to stand for 6 hours to be cured to obtain a slightly elastic electromagnetic wave-absorbing sheet-like product having a thickness of 3 mm. Further, as shown in FIG. 5, a tile base 11 is formed on a stainless steel flat plate by a punching method to form a metal base material 5, and the tile base 11 formed on the metal base material 5 is formed. The electromagnetic wave absorbing sheet material formed above according to the size and the pitch is provided with a notch, and as shown in FIG. 6, the electromagnetic wave absorbing sheet material is formed by utilizing the notch in the tile engaging portion 11 of the metal base material 5. The electromagnetic wave absorption layer 10 is formed by attaching the tiles 1 to each other, and the tile 1 similar to that of the example 1 is attached to the tile locking portion 11, and the vertical joint 2 (3) is formed between the tiles 1. The electromagnetic wave absorption wall structure of Example 3 was constructed. The electromagnetic wave absorbing performance of the electromagnetic wave absorbing wall structure of Example 3 was measured in the same manner as in Example 1. As a result, the electromagnetic wave absorption performance was 15 to 20 (dB).

[0014]

EFFECTS OF THE INVENTION According to the electromagnetic wave absorbing wall structure of the present invention, the tile structure is locked to the metal base material attached to the surface of the frame of the structure to finish the outer wall surface. In addition, it is possible to add electromagnetic wave absorption performance to prevent electromagnetic interference such as ghosts as much as possible. Moreover, there is no hindrance to the workability of this wall structure, and also in terms of durability (weather resistance). It is excellent and has the advantage that there is no restriction on the appearance of the wall structure to be formed. Further, according to the metal base material having the electromagnetic wave absorbing layer of the present invention, by using this, the tile is locked to the metal base material attached to the surface of the structure of the construction to finish the outer wall surface. It is possible to impart an electromagnetic wave absorbing performance capable of easily preventing a radio wave interference such as a ghost to the wall structure for performing the above.

[Brief description of drawings]

FIG. 1 is an explanatory plan view showing an electromagnetic wave absorbing wall structure according to a first embodiment of the present invention.

FIG. 2 is a sectional view taken along line II-II of FIG.

FIG. 3 is an enlarged sectional view showing the metal base material shown in FIG.

FIG. 4 is a cross-sectional view of a tile used in Example 2 of the present invention.

FIG. 5 is a perspective explanatory view of a metal base material used in Example 3 of the present invention.

FIG. 6 is an explanatory sectional view showing an electromagnetic wave absorbing wall structure according to a third embodiment of the present invention.

[Explanation of symbols]

1 ... tile, 2 ... longitudinal joint, 3 ... horizontal joint, 4 ... frame, 5 ...
Metal base material, 6, 7, 8 ... Engaging portion, 10 ... Electromagnetic wave absorbing layer, 11 ... Tile locking portion.

Claims (6)

[Scope of utility model registration request] 1. A wall structure in which a metal base material is attached to the surface of a skeleton of a structure, and a tile is locked to an engaging portion formed on the metal base material to finish the surface of the skeleton body. An electromagnetic wave absorbing wall structure, in which an electromagnetic wave absorbing layer having electromagnetic wave absorbing performance is laminated between the material and the tile on the front surface side of the metal base material and / or the back surface side of the tile. 2. The electromagnetic wave according to claim 1, wherein the electromagnetic wave absorbing layer is formed by applying an electromagnetic wave absorbing coating agent made of resin and ferrite powder on the front surface side of the metal base material and / or the back surface side of the tile. Absorption wall structure. 3. An electromagnetic wave absorbing layer, wherein an electromagnetic wave absorbing sheet material obtained by molding a resin composition comprising a resin and ferrite powder is fixed to the front surface side of a metal base material and / or the back surface side of a tile. The electromagnetic wave absorbing wall structure according to claim 1, which is formed as follows. 4. The electromagnetic wave absorbing layer is formed by attaching an electromagnetic wave absorbing coating agent or an electromagnetic wave absorbing sheet-like material after attaching a metallic undercoating material to the surface of the skeleton and before locking the tile to the metallic undercoating material. The electromagnetic wave absorbing wall structure according to claim 1, which is formed on the front surface side of the material. 5. The electromagnetic wave absorbing layer is preliminarily attached before the surface side of the metal base material and / or the tile is attached to the body side.
The electromagnetic wave absorbing wall structure according to claim 1, wherein the electromagnetic wave absorbing coating material or the electromagnetic wave absorbing sheet material is formed on the front surface side of the metal base material and / or the back surface side of the tile. 6. An electromagnetic wave absorbing coating agent or resin comprising a resin and a ferrite powder on the surface of which is a metal base material which is attached to lock a tile to a building frame when finishing the surface of the structure. A metal for forming an electromagnetic wave absorbing wall, characterized in that an electromagnetic wave absorbing layer formed of an electromagnetic wave absorbing sheet material obtained by molding a resin composition comprising Base material.