JP7479686B2 - Wall panels - Google Patents

Description

The present invention relates to a wall panel suitable for use as a wall material in buildings.

The concrete walls in reinforced concrete structures have excellent fire resistance and sound insulation properties, and exposed concrete finishes in particular have excellent design appeal. However, concrete has a high thermal conductivity and is easily affected by the outside air, making it hot in the summer and cold in the winter. Furthermore, if insulation is not provided, heating and cooling are less effective, resulting in problems such as high utility bills.

On the other hand, gypsum board, particle board, structural plywood, etc. are generally used for the walls of wooden or light steel frame buildings. These are relatively inexpensive and easy to install, but particle board and structural plywood in particular have the problem of sick house syndrome due to formaldehyde.

Therefore, various wall materials that are excellent in fire resistance, heat insulation, and moisture control, and can suppress health damage have been disclosed (see, for example, Patent Documents 1 and 2). One aspect of the architectural lightweight earth wall panel disclosed in Patent Document 1 is characterized in that, in an exterior wall body consisting of structural plywood, a support wooden frame, and a bamboo stopper, an insulation board made by mixing rice husks with adhesive, a preservative, and an anti-termite agent and drying and solidifying it is attached between the support wooden frame and the bamboo stopper of the exterior wall body, the upper surface of the insulation board is covered with a moisture-proof sheet, bamboo that will serve as a wooden balustrade base is attached to the support wooden frame and the bamboo stopper, the wooden balustrade base is coated with an earth wall material mixture composed of soil, rice husks, straw, lime, and water, and the upper surface of the earth wall material mixture is covered with a net for preventing surface cracks and dried.

And according to one embodiment of the architectural lightweight earthen wall panel disclosed in Patent Document 1, the advantages of earthen walls, such as the use of materials that are safe for the human body, cool in summer and warm in winter, excellent fire resistance, and environmental benefits, can be fully utilized, and because the wall material can be manufactured in a factory as panels, the wall work carried out at the construction site is the installation of lightweight earthen wall panels, eliminating the need for plastering work, thus significantly shortening the construction period, and it is also described that the panels can be manufactured or cut into any shape desired to suit architectural designs.

One aspect of the architectural wall material disclosed in Patent Document 2 is characterized in that it has at least a first layer containing a base material and a latent heat storage material on a substrate, and the content of the latent heat storage material in the first layer is 10 to 30 mass %.

According to one embodiment of the architectural wall material disclosed in Patent Document 2, the material has excellent heat storage properties, which allows the temperature inside the house to be kept low, making it possible to live comfortably, and also provides a house with excellent flame retardancy. It is also described that in addition to heat storage and flame retardancy, the material has excellent moisture control properties and suppresses substances that cause sick house syndrome, such as formaldehyde, making it possible to provide a house in which people can live more comfortably.

JP 2003-035007 A JP 2019-112929 A

According to one embodiment of a lightweight clay wall panel for construction disclosed in Patent Document 1 and one embodiment of a wall material for construction disclosed in Patent Document 2, it is believed that a wall material using clay walls that has excellent moisture control, fire resistance, heat insulation, etc. can be provided.

However, although one embodiment of the lightweight architectural clay wall panel disclosed in Patent Document 1 can be manufactured in a factory, the structure of the clay wall panel is relatively complex, and it is desirable to have an clay wall panel that can be manufactured more simply. Also, one embodiment of the architectural wall material disclosed in Patent Document 2 has a simple structure, but the material used is very special, and the process of applying it to the substrate surface is thought to require skill.

In view of the above problems, the inventors of the present application conducted extensive research to provide a wall panel that is fire-resistant, insulating, moisture-regulating, and maintainable, and that is easy to install and low-cost, and as a result, they arrived at the present invention.

That is, the wall panel of the present invention comprises a concrete base, a glass plate attached to the front side of the concrete base, and an earth wall section disposed in a recess formed on the back side of the concrete base, and is characterized in that the earth wall section is formed of one or more wall earth layers.

The wall panel of the present invention is also characterized in that a resin mesh plate is embedded in the wall soil layer.

Furthermore, the wall panel of the present invention is characterized in that a plurality of connecting pipe members are arranged in the lateral direction of the concrete base.

The wall panel of the present invention is also characterized in that one or more resin mesh pipes are embedded in the clay wall section in the vertical direction of the concrete base, the resin mesh pipes are filled with sand, and the upper ends of the resin mesh pipes are exposed on the upper surface of the concrete base.

Furthermore, the wall panel of the present invention is characterized in that the back side of the glass plate facing the front side of the concrete base is colored.

The wall panel of the present invention is made of concrete, yet has excellent fire resistance, heat insulation, moisture control, and maintainability, making construction of buildings easy and reducing costs.

In addition, in the wall panel of the present invention, resin mesh plates are embedded in the wall soil layer, which prevents the soil wall portion from falling off.

Furthermore, in the wall panel of the present invention, multiple connecting pipe members are arranged in the lateral direction of the concrete base, which makes it easy to firmly connect multiple wall panels in the lateral direction, and allows the formation of a large wall surface while suppressing the size and weight of each panel.

In addition, in the wall panel of the present invention, one or more resin mesh pipes are embedded in the earthen wall section in the vertical direction of the concrete base, the resin mesh pipes are filled with sand, and the upper ends of the resin mesh pipes are exposed to the upper surface of the concrete base, so that moisture absorbed in the earthen wall section can be released above the concrete base, further improving the moisture control effect, especially the dehumidification effect.

Furthermore, in the wall panel of the present invention, the back side of the glass plate facing the front side of the concrete base is colored, which allows the creation of a wall surface with excellent design.

FIG. 1 is a schematic perspective view of a wall panel according to an embodiment of the present invention; 2A is a plan view of the wall panel shown in FIG. 1, and FIG. 2B is a cross-sectional view taken along the line AA in FIG. FIG. 2 is a plan view showing a state in which the wall panels shown in FIG. 1 are connected in the horizontal direction. FIG. 2 is a cross-sectional view of another embodiment of the wall panel shown in FIG. FIG. 11 is a schematic perspective view of a wall panel according to another embodiment of the present invention; 6A is a plan view of the wall panel shown in FIG. 5, and FIG. 6B is a cross-sectional view taken along line BB in FIG. FIG. 6 is a cross-sectional view of another embodiment of the wall panel shown in FIG.

The following describes in detail an embodiment of the wall panel of the present invention with reference to the drawings. Fig. 1 is a schematic perspective view of a wall panel 10 according to one embodiment of the present invention, Fig. 2(a) is a plan view of the wall panel 10 shown in Fig. 1, and Fig. 2(b) is a cross-sectional view taken along the line A-A in Fig. 2(a). The wall panel 10 according to one embodiment of the present invention shown in these figures is applied to a wall material for a building, and is characterized by comprising at least a concrete base 12, a glass plate 14 attached to the front side 12a of the concrete base 12, and an earthen wall portion 16 disposed in a recess 15 formed in the back side 12b of the concrete base 12.

The concrete base 12 of the wall panel 10 of this embodiment is rectangular, and as shown in FIG. 2(b), is made of reinforced concrete with reinforcing bars 24 arranged inside, and is appropriately arranged according to the size of the wall panel 10 to ensure strength as a wall material. Note that in FIG. 1 and FIG. 2(a), the reinforcing bars 24 arranged inside the concrete base 12 are omitted in order to show an outline of the wall panel 10 of this embodiment.

A glass plate 14 is attached to the front side 12a of the concrete base 12. When the wall panel 10 of this embodiment is used as a wall material for a building, the surface to which the glass plate 14 is attached becomes the exterior wall surface.

In a typical concrete wall, when cracks appear on the surface due to aging or other reasons, water seeps into the concrete wall through the cracks, causing corrosion of the reinforcing bars arranged inside the concrete wall and leading to deterioration of the concrete wall. However, since the front side of the wall panel 10 of this embodiment, i.e., the front side 12a of the concrete base 12 of this embodiment, is entirely covered with glass plate 14, even if cracks appear on the front side 12a of the concrete base 12, the glass plate 14 can prevent water from seeping into the interior of the concrete base 12, and deterioration of the concrete base 12 can be prevented.

On the other hand, in this embodiment, a recess 15 is formed on the back side 12b of the concrete base 12 for arranging the earth wall portion 16. This recess 15 is formed when the concrete base 12 is poured, and after the concrete base 12 hardens, the recess 15 is filled with wall earth to form the earth wall portion 16.

As described above, the earth wall portion 16 in this embodiment is formed by filling the recess 15 formed on the back side 12b of the concrete base 12 with wall soil. The earth wall portion of the wall panel of the present invention is formed of one or more wall soil layers, but the earth wall portion 16 in this embodiment is formed of one wall soil layer 16a.

The wall clay used for the wall clay layer 16a forming the earthen wall portion 16 is not particularly limited, and can be any common wall clay used in normal earthen walls, such as diatomaceous earth or shirasu. Furthermore, straw, hemp, bamboo charcoal, etc. may be mixed with these wall clays as appropriate. For the wall clay layer 16a according to this embodiment, tataki clay is used as the wall clay. Tataki clay is a mixture of three materials: earth, slaked lime, and natural bittern, and is usually used as a material for flooring. Tataki clay has a very high moisture control performance, absorbing moisture during the humid summer months and releasing an appropriate amount of humidity during the dry winter months, and also has a high insulating effect, making it suitable as a wall material. In addition, straw, hemp, bamboo charcoal, etc. may be mixed with this tataki clay as appropriate.

The wall panel 10 of this embodiment, which has at least the above configuration, can provide a wall material with fire resistance, heat insulation, and moisture control properties while ensuring the strength of the wall material with the concrete base 12.

In addition, the front side 12a of the concrete base 12 is completely covered by the glass plate 14, which prevents water from entering the concrete base 12, prevents deterioration of the concrete base 12, and improves maintainability.

Furthermore, the wall panel 10 of this embodiment can be manufactured in advance in a factory, etc., and the wall of a building can be constructed at the site simply by transporting and assembling the finished wall panel 10. Also, while the construction of a typical mud wall requires a great deal of skill and time, is susceptible to the effects of weather, and is costly, the mud wall section 16 of the wall panel 10 of this embodiment can be manufactured in a factory, etc., and can be formed simply by filling the recess 15 formed on the back side 12b of the concrete base 12 with wall mud, which does not require advanced technology and therefore allows for low costs.

The basic configuration of the wall panel 10 of this embodiment has been described above in detail, but it is preferable that a resin mesh plate 28 is embedded in the wall soil layer 16a that forms the soil wall portion 16 of the wall panel 10 of this embodiment. When embedding the resin mesh plate 28, the reinforcing bars 24 embedded in the concrete base 12 and the resin mesh plate 28 are connected and fixed by the connecting members 26. Then, when filling the recesses 15 of the concrete base 12 with soil to form the wall soil layer 16a, by embedding the resin mesh plate 28 connected to the reinforcing bars 24, the resin mesh plate 28 and the wall soil layer 16a are integrated, and the fall-off of the soil wall portion 16 formed by the wall soil layer 16a can be easily prevented.

Note that a metal mesh plate can be used if the only function required is to prevent the earth wall portion 16 from falling off; however, if the metal mesh plate rusts due to moisture absorbed by the earth wall portion 16, this can cause deterioration of the earth wall portion 16. In particular, when using Japanese clay for the wall soil layer 16a forming the earth wall portion 16, the bittern contained in the Japanese clay can easily cause rust in the metal mesh plate, so it is preferable to bury a resin mesh plate 28 in the wall soil layer 16a.

In addition, in the wall panel 10 of this embodiment, it is preferable that multiple connecting pipe members 20 are arranged in the lateral direction of the concrete base 12. With the wall panel 10 of this embodiment, a building wall can be constructed by simply erecting the wall panel 10, which has been manufactured in advance in a factory or the like, on-site. However, if the wall area is large, it is difficult to construct the entire wall with one wall panel 10. Therefore, by embedding multiple connecting pipe members 20 in the concrete base 12, as shown in Figure 3, multiple wall panels 10 can be arranged side by side, and connecting steel bars 30, such as PC steel bars, can be inserted and fixed through the connected connecting pipe members 20, making it easy to form a large wall surface.

In addition, since a large wall surface can be easily formed by firmly connecting multiple wall panels 10 horizontally, the size of each wall panel 10 can be reduced, and the reduced size also reduces the weight of each wall panel 10.

In the wall panel 10 of this embodiment, multiple connecting pipe members 20 are arranged only in the horizontal direction of the concrete base 12, but multiple connecting pipe members 20 may also be arranged in the vertical direction of the concrete base 12. Since the wall height of a typical house is about 250 cm, the length of the longitudinal direction (vertical direction) of the concrete base 12 of the wall panel 10 of this embodiment can be sufficiently secured, and it is not necessary to connect multiple wall panels 10 vertically when constructing a wall. However, by arranging multiple connecting pipe members 20 in the vertical direction of the concrete base 12, for example, a connecting steel rod 30 is erected in advance on the foundation of a building, and this connecting steel rod 30 is inserted into the connecting pipe member 20 arranged in the vertical direction of the concrete base 12 when erecting the wall panel 10. Then, the upper end of the connecting steel rod 30 is inserted into the beam member and fixed with a bolt or the like, so that the wall panel 10 can be firmly connected to the foundation and the beam member.

The wall panel 10 according to one embodiment of the present invention has been described in detail above, but the wall panel 10 of this embodiment can be easily manufactured by the following procedure. First, a glass plate 14 is placed on the bottom surface of a formwork for manufacturing the concrete base 12. After the glass plate 14 is placed, the spacers 22 are placed at a specified interval. The spacers 22 may be placed directly on the glass plate 14, but it is preferable to apply silicone resin between the glass plate 14 and the spacers 22 to prevent misalignment and ensure adhesion to the glass plate 14.

After placing the spacers 22 on the glass plate 14, the reinforcing bars 24 are placed. If the connecting pipe members 20 are to be embedded in the concrete base 12, they are placed in the prescribed positions at this stage. Also, if a resin mesh plate 28 is to be embedded in the earth wall section 16, the connecting members 26 for connecting the resin mesh plate 28 are placed in advance on the reinforcing bars 24.

Once the above preparations are complete, concrete is poured into the formwork to produce the concrete base 12. After the concrete hardens, the formwork is removed, yielding a concrete base 12 with a glass plate 14 attached to the front side 12a of the concrete base 12 and a recess 15 formed on the back side 12b.

Once the concrete base 12 has been produced, the recesses 15 of the concrete base 12 are filled with wall clay to form the wall clay layer 16a. When embedding the resin mesh plate 28, the wall clay is filled to a predetermined height, the resin mesh plate 28 is then placed, and the resin mesh plate 28 is connected and fixed with the connecting members 26 that have been previously connected to the reinforcing bars 24. The wall clay is then filled up to the upper edge of the recesses 15 of the concrete base 12, and the wall clay hardens to form the clay wall portion 16, resulting in the wall panel 10 of this embodiment.

The resulting wall panel 10 of this embodiment is transported to the construction site and erected on a base to form the wall of the building. The erection method is not particularly limited, and the panel can be erected and fixed using known metal fittings or by fitting the panel into a groove formed in advance on the base.

In the wall panel 10 of this embodiment, a finished surface 18 may be formed on the back side 12b of the concrete base 12 using plaster or the like. If there is no finished surface 18, the earth wall portion 16 will be exposed on the back side 12b of the concrete base 12. The interior wall surface of the building will have the appearance of the earth wall portion 16 arranged within a concrete frame formed by the back side 12b of the concrete base 12, and depending on the type and color of the wall clay that forms the earth wall portion 16, an interior wall surface with excellent design can be formed.

On the other hand, if it is not desired to expose the concrete frame or the earth wall portion 16, a finishing surface 18 can be formed with plaster or plaster on the back side 12b of the concrete base 12 and the exposed surface of the earth wall portion 16 to form an integrated wall surface covering the concrete frame and the earth wall portion 16. When forming the finishing surface 18, it is preferable to use plaster, plaster, diatomaceous earth, etc., in order to ensure the moisture-regulating function of the earth wall portion 16. Also, it is preferable to form the finishing surface 18 on-site after the wall panel 10 is erected, so that the finishing surface 18 is not soiled during transportation of the wall panel 10.

The wall panel 10 according to one embodiment of the present invention has been described in detail above, including the manufacturing method thereof.
The wall panel 10a according to another embodiment of the present invention shown in Figure 4 has a basic structure similar to that of the wall panel 10 according to the above-mentioned embodiment, and comprises a concrete base 12, a glass plate 14 attached to the front side 12a of the concrete base 12, and an earthen wall portion 16 disposed in a recess 15 formed in the back side 12b of the concrete base 12.

The earthen wall section 16 of the wall panel 10a of this embodiment has a two-layer structure of wall soil layers 16a and 16b. By making the earthen wall section 16 of this embodiment have a two-layer structure of wall soil layers 16a and 16b and applying different types of wall soil to each of the wall soil layers 16a and 16b, it is possible to improve moisture control and workability. For example, by applying the same type of clay as the wall soil layer 16a of the wall panel 10 of the above-mentioned embodiment to the wall soil layer 16a and applying diatomaceous earth or shirasu to the wall soil layer 16b, the surface is very strong, while the internal wall soil layer 16b can further improve workability and moisture control.

In addition, it is preferable that resin mesh plates 28 are embedded in the wall soil layers 16a and 16b that form the earth wall portion 16 of the wall panel 10a of this embodiment. By embedding the resin mesh plates 28 connected by the reinforcing bars 24 and the connecting members 26 when forming the wall soil layers 16a and 16b, it is possible to easily prevent the earth wall portion 16 formed by the wall soil layers 16a and 16b from falling off.

The wall panel 10a according to the embodiment of the present invention has been described above, but the wall panel of the present invention is not limited to these embodiments. The wall panel 11 according to the embodiment of the present invention shown in Figures 5 and 6 has a basic configuration similar to that of the wall panel 10 according to the embodiment described above, and includes a concrete base 12, a glass plate 14 attached to the front side 12a of the concrete base 12, and an earth wall portion 16 arranged in a recess 15 formed in the back side 12b of the concrete base 12, and the earth wall portion 16 is formed by a wall earth layer 16a.

Furthermore, in the earth wall portion 16 of the wall panel 11 of this embodiment, multiple resin mesh pipes 32 are embedded in the vertical direction of the concrete base 12. The lower ends 32a of the resin mesh pipes 32 are arranged so as to be located within the recess 15 of the concrete base 12, i.e., within the earth wall portion 16, and the upper ends 32b are arranged so as to be exposed on the upper surface 13 of the concrete base 12. By arranging the resin mesh pipes 32 in this manner, the inside of the earth wall portion 16 and the outside on the upper surface 13 side of the concrete base 12 are electrically connected by the resin mesh pipes 32.

The resin mesh pipe 32 in this embodiment is filled with sand 34. By filling the resin mesh pipe 32 with sand 34, the strength of the resin mesh pipe 32 within the earth wall portion 16 can be ensured, and moisture absorbed in the earth wall portion 16 can be efficiently guided upward and released to the outside of the upper surface 13 of the concrete base 12.

A metal mesh pipe may be used if only electrical continuity is required between the earth wall portion 16 and the outside of the upper surface 13 of the concrete base 12; however, if the metal mesh pipe rusts due to moisture absorbed by the earth wall portion 16, this can cause deterioration of the earth wall portion 16. In particular, when using Japanese clay for the wall soil layer 16a that forms the earth wall portion 16, the bittern contained in the Japanese clay can easily cause rust in the metal mesh pipe, so it is preferable to embed a resin mesh pipe 32 in the earth wall portion 16.

In addition, in the wall panel 11 of this embodiment, two resin mesh pipes 32 are embedded, but the number of embedded resin mesh pipes 32 is not particularly limited, and one to multiple resin mesh pipes 32 can be embedded as appropriate depending on the width of the wall panel 11.

Furthermore, the method of embedding the resin mesh pipe 32 is not particularly limited, but for example, the wall panel 11 of this embodiment can be obtained by placing the resin mesh pipe 32 filled with sand 34 in advance during the production stage of the concrete base 12, and forming the earth wall portion 16 in the recess 15 of the concrete base 12 in which the resin mesh pipe 32 is arranged.

Furthermore, the wall panel 11 of this embodiment may also have a finished surface 18 formed, similar to the wall panel 10 of the above embodiment.

The wall panel 11 of this embodiment has been described above in detail, but as another aspect of the wall panel 11 of this embodiment, the wall panel 11a of the embodiment shown in FIG. 7 has a basic configuration similar to that of the wall panel 11 of the above-mentioned embodiment, and the earthen wall section 16 of the wall panel 11a has a two-layer structure of wall soil layers 16a and 16b. By making the earthen wall section 16 of the wall panel 11a of this embodiment have a two-layer structure of wall soil layers 16a and 16b, and applying, for example, Japanese clay to the wall soil layer 16a and diatomaceous earth or shirasu to the wall soil layer 16b, the surface of the earthen wall section 16 is very strong, while the internal wall soil layer 16b can further improve workability and humidity control.

In addition, when the resin mesh pipe 32 is buried in the earth wall portion 16 of the wall panel 11a of this embodiment, it is preferable to bury it in a state in which it straddles the wall soil layer 16a and the wall soil layer 16b that form the earth wall portion 16. Although the resin mesh pipe 32 may be buried in each of the wall soil layers 16a and 16b, as in the case of the resin mesh pipe 32 of the wall panel 11a of this embodiment, by burying it in a state in which it straddles the wall soil layer 16a and the wall soil layer 16b, the moisture absorbed in the wall soil layer 16a and the wall soil layer 16b can be efficiently released to the outside. In addition, in the embodiment in which the resin mesh plate 28 is buried in each of the wall soil layer 16a and the wall soil layer 16b, it is difficult to secure a place to bury the resin mesh pipe 32, but by burying the resin mesh pipe 32 in a state in which it straddles the wall soil layer 16a and the wall soil layer 16b as in this embodiment, it is also easy to secure a place to bury it.

The wall panels 10, 10a, 11, and 11a according to the embodiments of the present invention have been described in detail above, but this should not be interpreted as substantially limiting the technical idea of the present invention. For example, in the wall panels 10, 11, etc. according to the embodiments of the present invention, the back side (the side attached to the front side 12a of the concrete base 12) of the glass plate 14 opposite the front side 12a of the concrete base 12 according to each embodiment may be colored. By coloring the back side of the glass plate 14, a wall surface with excellent design can be provided, and since the colored surface is not exposed to the outside, durability is improved. The present invention can be implemented with appropriate improvements, changes, or additions based on the ingenuity and ingenuity of those skilled in the art, within the scope of the gist of the present invention.

Reference Signs List 10, 10a, 11, 11a: Wall panel 12: Concrete base 14: Glass plate 15: Recess 16: Earthen wall section 16a, 16b: Earthen wall layer 18: Finished surface 20: Connecting pipe member 22: Spacer 24: Steel bar 26: Connecting member 28: Resin mesh plate 30: Connecting steel bar 32: Resin mesh pipe 34: Sand

Claims (5)

A concrete substrate;
A glass plate attached to the front side of the concrete substrate;
An earthen wall portion disposed in a recess formed on the back side of the concrete base;
Included,
A wall panel characterized in that the earthen wall portion is formed of one or more wall earth layers. The wall panel according to claim 1, characterized in that a resin mesh plate is embedded in the wall soil layer. The wall panel according to claim 1 or 2, characterized in that a plurality of connecting pipe members are arranged in the lateral direction of the concrete base. A wall panel according to any one of claims 1 to 3, characterized in that one or more resin mesh pipes are embedded in the earth wall section in the vertical direction of the concrete base, the resin mesh pipes are filled with sand, and the upper ends of the resin mesh pipes are exposed on the upper surface of the concrete base. A wall panel according to any one of claims 1 to 4, characterized in that the back side of the glass plate opposite the front side of the concrete base is colored.