JP6787562B2 - Ant-proof structure - Google Patents

Description

The present invention relates to an anti-termite structure of a building, particularly, an anti-termite structure of a building having a standing portion of foundation concrete and a horizontal concrete portion provided inside the building at right angles to the standing portion. Is.

Termites travel underground from the outside of the building toward the basement inside the building, sew gaps and cracks between concrete and invade the inside of the building, and devour buildings such as wood and heat insulating materials that serve as pillars. Termite-proofing means have been developed, and for example, it has been proposed to apply termite-proofing treatment to the rising portion of foundation concrete. This is because termites travel along the rising part to reach the wood above it. Specifically, it has been proposed to dispose a granular or liquid anti-termite agent on the foundation concrete. However, with this method, the chemical had a useful life, after which the anti-termite agent had to be reapplied.

As a means for achieving termite prevention without using chemicals, Patent Document 1 discloses that a plate-like material is provided in close contact with the rising portion of the concrete foundation, and that a termite shielding material is used as the plate-like material. There is. The termite shielding material referred to in Patent Document 1 is said to have resistance to termite secretions and strength to prevent the formation of holes due to biting by termites, and is a resin sheet such as polycarbonate. , Ceramic sheet, glass fiber sheet and the like are exemplified. However, these plate-like substances do not have a termite repellent effect when a drug is not added. In that case, although it is possible to prevent the invasion of termites digging inside the plate-shaped object, it is not possible to prevent the passage of termites on the surface of the plate-shaped object. In particular, in Patent Document 1, the plate-shaped object is inserted between the rising portion of the foundation and the ground, and the termite that comes out from the ground side to the ground surface and reaches the building base along the surface of the plate-shaped object. It is vulnerable to intrusion routes.

Patent Document 2 discloses that soil concrete is applied to the soil surface inside the rising portion of the cloth foundation. This suppresses the invasion of termites from the soil surface. However, gaps are likely to occur between the soil concrete and the rising part of the cloth foundation, and it is necessary to prevent termites from invading from there. Therefore, in Patent Document 2, granular slag (blast furnace cooling slag, converter slag, etc.) is spread on the lower surface of the soil concrete and in contact with the foundation concrete and hardened. By using this hardened slag as a barrier layer, termite digging is prevented. However, since the hardened slag is hard, it can prevent termites from digging, but there is a concern that cracks may occur due to an impact such as an earthquake. Once cracked, termite invasion cannot be prevented.

Japanese Unexamined Patent Publication No. 2007-21414 Japanese Unexamined Patent Publication No. 2014-62435

When a concrete horizontal portion such as a soil concrete or a solid foundation is formed, it is required to reliably prevent ants in a gap formed between the concrete horizontal portion such as a cloth foundation rising portion and the concrete standing portion for a long period of time. In particular, when the concrete of the horizontal part is cast and hardened after the vertical part is formed first, the gap between the vertical part and the horizontal part is widened due to the hardening shrinkage, and termites easily invade. Is a concern. In addition, there is a concern that a new gap may be created or widened at the boundary between the horizontal concrete portion and the vertical portion due to receiving an external force due to an earthquake or the like, and it is required to reliably prevent ants at such a boundary surface.
Therefore, an object of the present invention is to provide an anti-termite structure capable of reliably preventing the invasion of termites over a long period of time without causing a decrease in anti-termite performance due to an external force or a decrease in chemical efficacy.

The gist of the present invention is as follows:
[1] A space between the standing part and the horizontal part provided with a standing part of the foundation concrete of the building and a concrete horizontal part provided at right angles to the standing part inside the building. An anti-termite structure in which an aggregate of inorganic fibers is compressed.
[2] The ant-proof structure according to [1], wherein the horizontal portion is soil concrete or a concrete base board.
[3] The method according to [1] or [2], wherein the upper surface of the inorganic fiber aggregate is covered with the concrete horizontal portion, and the upper surface of the concrete horizontal portion is in contact with the concrete vertical portion while remaining flat. Anti-termite structure.
[4] The ant-proof structure according to any one of [1] to [3], wherein a heat insulating material is laid on the entire lower surface of the concrete horizontal portion.
[5] The ant-proof structure according to [4], wherein the heat insulating material is a resin-based heat insulating material, and a waterproof sheet and / or an inorganic sheet is laid on at least the entire lower surface of the resin-based heat insulating material.
[6] The ant-proof structure according to any one of [1] to [5], wherein the inorganic fiber aggregate contains a molded body of glass wool or rock wool.
[7] The prevention according to [6], wherein the glass wool or rock wool molded product has a multi-layer structure and is compressed in a space between the vertical portion and the horizontal portion with the layer surface in the vertical direction. Ant structure.

According to the present invention, since glass wool is compressed in the space between the concrete standing portion and the concrete horizontal portion, it can be maintained for a long period of time without causing deterioration of termite-proof performance due to external force or deterioration of chemical effect. It is possible to prevent the invasion of termites reliably.

FIG. 1 is a schematic cross-sectional view showing an example of the ant-proof structure of the present invention. FIG. 2 is a schematic cross-sectional view showing another example of the anti-termite structure of the present invention. FIG. 3 is a schematic cross-sectional view showing still another example of the anti-termite structure of the present invention. FIG. 4 is a schematic cross-sectional view showing another example of the anti-termite structure of the present invention. FIG. 5 is a schematic cross-sectional view showing still another example of the anti-termite structure of the present invention. FIG. 6 is a schematic cross-sectional view for explaining the anti-termite performance test method in the examples.

Hereinafter, the present invention will be described in more detail with reference to the drawings. In the present specification, "inside of the building" indicates the direction from the concrete erection part toward the inside of the building (indicated by B in FIGS. 1 to 5), and "outside of the building" indicates concrete erection. The direction from the part to the outside of the building is shown (indicated by A in FIGS. 1 to 5).

FIG. 1 is a schematic cross-sectional view showing an example of the ant-proof structure of the present invention. In the anti-termite structure of FIG. 1, the standing portion 1 of the foundation concrete 10 of the building (in the illustrated example, the rising portion of the cloth foundation) is orthogonal to the standing portion 1 on the ground 16 inside the building. An inorganic fiber aggregate 3 having the same height as the concrete horizontal portion 3 is compressed in the space between the concrete horizontal portion 2 (in the illustrated example, the soil concrete).

Specifically, in such an anti-termite structure, after laying the inorganic fiber aggregate 3 along the standing portion 1, the concrete 2 for the horizontal portion is poured into the space surrounded by the inorganic fiber aggregate 3. It can be formed by curing and hardening the concrete 2 while pressing the inorganic fiber aggregate 3 by the weight of the concrete 2. Then, even after the horizontal portion concrete 2 is hardened and shrunk, it is possible to prevent a gap from being formed between the horizontal portion concrete 2 and the vertical portion 1 due to the repulsive action of the inorganic fiber aggregate 3. In addition, the inorganic fiber aggregate 3 can follow even the fine irregularities of the vertical portion surface 1a and the horizontal portion surface 3a, and gap prevention can be achieved at a higher level. Furthermore, since the inorganic fiber aggregate 3 itself is flexible, there is no concern that gaps will be generated due to cracking of the inorganic fiber aggregate even if it receives an impact such as an earthquake, and the standing portion 1 Even if the gap between the horizontal portions 2 becomes wide, the inorganic fiber aggregate 3 itself is laid in a compressed state, so that it expands according to the expansion of the gap. Therefore, it is possible to continuously prevent termites from invading for a long period of time.

As long as there is a space between the standing concrete 1 and the horizontal concrete 2 where the inorganic fiber aggregate 3 can be laid, a part of the horizontal concrete 2 is the same as the standing concrete 1. It may be in contact. FIG. 2 is a schematic cross-sectional view showing an example of such an anti-termite structure. In the example of FIG. 2, the thickness of the concrete horizontal portion 2 is larger than that of the inorganic fiber aggregate 3, and as a result, the upper surface of the inorganic fiber aggregate 3 is covered with the concrete horizontal portion 2. The upper surface of the concrete horizontal portion 2 is in contact with the concrete vertical portion 1 while being flat. By doing so, the inorganic fiber aggregate 3 can be protected on the upper surface of the concrete horizontal portion 2, and the long-term sustainability of the anti-termite effect is further improved. In addition, the inorganic fiber aggregate 3 can be hidden on the upper surface of the concrete horizontal portion 2, which also contributes to improving the aesthetic appearance.

The heights of the inorganic fiber aggregate 3 and the concrete horizontal portion 2 may be different, and examples in which the upper surfaces thereof are different are as shown in the examples of FIGS. 2 and 3. Further, the heights of the lower surfaces of the inorganic fiber aggregate 3 and the concrete horizontal portion 2 may also be different. FIG. 3 is a schematic cross-sectional view showing an example of such an anti-termite structure. In the example of FIG. 3, the lower surface of the inorganic fiber aggregate 3 is deeper than the lower surface of the concrete horizontal portion 2. Therefore, the thickness of the inorganic fiber aggregate 3 can be made sufficiently thick, and the heat insulating property can be improved. Further, in the example of FIG. 3, the lower surface of the inorganic fiber aggregate 3 is flush with the lower surface of the heat insulating material 4. Therefore, one heat insulating material protective sheet 5 can be laid on the lower surfaces of both the inorganic fiber aggregate 3 and the heat insulating material 4, and the inorganic fiber aggregate 3 and the heat insulating material 4 can be efficiently protected. The heat insulating material protective sheet does not have to be in contact with the upright portion, and may be laid on the lower surface of the heat insulating material and the lower surface of a part of the inorganic fiber aggregate continuous thereto.

If necessary, a heat insulating material 4 may be laid between the concrete horizontal portion 2 and the ground 16. FIG. 4 is a schematic cross-sectional view showing an example of such an anti-termite structure. In the example of FIG. 4, the heat insulating material 4 is laid on the entire lower surface of the concrete horizontal portion 2. Therefore, the heat retention in the building can be improved. In the example of FIG. 4, the lower surface of the concrete horizontal portion 2 and the lower surface of the inorganic fiber aggregate 3 are flush with each other, and the heat insulating material 4 is also laid on the lower surface of the inorganic fiber aggregate 3. Then, the heat insulating property of the inorganic fiber aggregate 3 and the heat insulating property of the heat insulating material 4 exert a synergistic effect, and heat exchange through the gap between the concrete horizontal portion 2 and the vertical portion 3 can be prevented more highly. , The heat insulating property can be further improved. Further, in the example of FIG. 4, a heat insulating material protective sheet 5 is laid between the heat insulating material 4 and the ground 16. The protective sheet 5 can prevent the heat insulating material 4 from absorbing moisture and the heat insulating material 4 from being damaged by termites and the like.

By the way, what the inorganic fiber aggregate 3 is laid on is not particularly limited. For example, it may be laid on the ground 16 as in the examples of FIGS. 1 and 2, and it is insulated as in the example of FIG. It may be laid on the material (first heat insulating material) 4, or may be laid on the heat insulating material protective sheet 5 as in the example of FIG. FIG. 5 shows an example in which the inorganic fiber aggregate 3 is laid on the second heat insulating material 6 provided separately from the first heat insulating material 4. The second heat insulating material 6 may be selected from the same materials that can form the heat insulating material 4, or may be selected from the same materials that can form the inorganic fiber aggregate 3. When the second heat insulating material 6 (preferably glass wool molded body 8) is formed by using the inorganic fiber aggregates, the inorganic fiber aggregates 3 (preferably glass wool molded bodies 7) laid on the second heat insulating material 6 (preferably glass wool molded body 7) are the same as each other. It may be present or different.

In the anti-termite structure of the present invention as described above, the standing portion 1 of the foundation concrete 10 is not limited to the rising portion of the cloth foundation concrete, but may be the rising portion of the solid foundation concrete. Further, the concrete horizontal portion 2 may be soil concrete or another concrete base board, and may be, for example, pressed concrete in the cloth foundation method, bottom plate in the solid foundation method, or the like. Preferred are the rising portion of the cloth foundation concrete and the soil concrete. Since these are formed by splicing and easily generate gaps, the anti-termite effect according to the present invention can be enjoyed more effectively.

The horizontal length of the space filled with the inorganic fiber aggregate 3 (that is, the horizontal length of the inorganic fiber aggregate 3 after filling) is, for example, 0.1 mm to 500 mm, preferably 1 mm to 200 mm, and more preferably 5 mm. It is ~ 100 mm. The vertical length of the packed inorganic fiber aggregate 3 is, for example, about 10 to 200 mm, preferably about 30 to 100 mm, and more preferably about 40 to 80 mm. The inorganic fiber aggregate 3 before filling the space is larger than the form after filling. That is, the inorganic fiber aggregate 3 is compressed. The compressibility (= (1-horizontal length after filling / horizontal length before filling) × 100 (%)) is, for example, about 3 to 80%, preferably about 5 to 60%, more preferably about. It is about 10 to 50%.

The density (equivalent density) of the inorganic fiber aggregate 3 is, for example, 1 kg / m ³ or more and 100 kg / m ³ or less, preferably 5 kg / m ³ or more and 50 kg / m ³ or less, and more preferably 10 kg / m ³ or more. It is 35 kg / m ³ or less, particularly preferably 15 kg / m ³ or more and 25 kg / m ³ or less. The equivalent density is a density display described in the Japan Housing Finance Agency specifications. For example, an equivalent density of 10 [kg / m ³ ] means about 10 kg / m ³ .

The thermal conductivity of the inorganic fiber aggregate 3 is, for example, 0.015 W / m · K or more, preferably 0.025 W / m · K or more, more preferably 0.030 W / m · K or more, for example, 0. It is 1 W / m · K or less, preferably 0.05 W / m · K or less. The thermal conductivity can be measured at 25 ° C. using, for example, a temperature gradient method, a laser flash method, a hot wire method, or the like.

The fiber diameter of the inorganic fiber aggregate is preferably 1 to 15 μm, more preferably 1 to 10 μm, still more preferably 2 to 8 μm, and even more preferably 2 to 6 μm. The smaller the fiber diameter, the better the ability to follow the surface irregularities of concrete, and the more highly prevent termites can enter. Further, the smaller the fiber diameter, the higher the density per unit area and the higher the heat insulating property.

The inorganic fiber aggregate 3 is preferably a molded or non-molded body of an artificial inorganic fiber aggregate, and more preferably a molded or non-molded body of glass wool or rock wool. The non-molded body of glass wool or rock wool means a product processed into small lumps, and is sold as "Aquria Blow (trade name)" by Asahi Fiber Glass Co., Ltd. as a blow-in type glass wool, for example. Further, as a blow-in type rock wool, "Blow-in method residential rock wool" of the Rock Wool Industry Association and the like can be mentioned.

The inorganic fiber aggregate 3 is preferably a molded product. By using the molded body, it becomes easy to place concrete in the space surrounded by the inorganic fiber aggregate, and the ant-proof structure can be formed more appropriately. The molded body is required to have the ability to follow the uneven surface of concrete, the flexibility to expand to follow the shrinkage of concrete, and the elastic recovery property, and does not include a hard glass fiber plate which is difficult to be deformed. Specifically, the molded body of such an inorganic fiber aggregate 3 preferably has the above-mentioned density and thermal conductivity. For example, the molded body of glass wool is described by Asahi Fiber Glass Co., Ltd. as "Aclear Wool 16K (Aclear Wool 16K). Product name) ”is sold. Rock wool moldings are sold as "residential rock wool" by the Rock Wool Industry Association.

The molded body of the inorganic fiber aggregate usually has a multi-layer structure. This multi-layer structure means, for example, a structure in which the inorganic fibers are fixed in layers by heating and compressing the inorganic fibers, in other words, a structure formed in a direction orthogonal to the length direction of the inorganic fibers. When the molded body of the inorganic fiber aggregate is laid between the upright portion 1 and the horizontal portion 2, it is preferable to lay the molded body with the layer forming surface in the vertical direction. That is, it is preferable that the molded body of the inorganic fiber aggregate has a multi-layer structure and is compressed in the space between the vertical portion and the horizontal portion with the layer surface in the vertical direction. In this way, when the layered surface of the multi-layered structure is laid in the vertical direction, the shrinkage of the concrete can be followed with a higher restoring force even when compressed by the concrete, as compared with the case where the layered surface of the multi-layered structure is laid in the horizontal direction.

When the inorganic fiber aggregate 3 and the second heat insulating material 6 are used on top of each other as in the example of FIG. 5, they may be the same or different as described above. Further, when the molded bodies of the inorganic fiber aggregates having a multi-layer structure are used in layers on top of each other, the orientations of the layer-forming surfaces of the molded bodies of the inorganic fiber aggregates may be the same on the upper side and the lower side, or may be different. Good. Preferably, the layer-forming surface of the upper inorganic fiber assembly is in the vertical direction, and the layer-forming surface of the lower inorganic fiber assembly is either horizontal or vertical.

As the heat insulating material 4, the same material as the inorganic fiber aggregate 3 may be used, but it is preferable to use a different material, for example, a resin-based material such as polyurethane foam, polyethylene foam, polystyrene foam, or a laminate thereof. Insulation material can be mentioned. While the inorganic fiber aggregate 3 has a flexible structure and can be greatly deformed, the resin-based heat insulating material has a small amount of deformation when a load is applied. Therefore, the concrete horizontal portion 2 formed on the concrete horizontal portion 2 can be supported by a surface, and exhibits excellent underfloor strength.

As the heat insulating material protective sheet 5, a waterproof sheet, an inorganic sheet, or the like can be used. Only one of the waterproof sheet and the inorganic sheet may be used, or both may be used at the same time. When both are used, it is preferable to place the inorganic sheet on the waterproof sheet on the ground side.

The waterproof sheet preferably includes a resin sheet exhibiting flexibility, and may be treated with a water repellent agent. Examples of the resin used for the waterproof sheet include polymer resins such as polyethylene resin, polypropylene resin, and ethylene vinyl acetate resin. Examples of the water repellent include paraffin-based water repellents, fluorine-based water repellents, and polysiloxane-based water repellents. The thickness of the waterproof sheet is, for example, 0.01 to 5 mm, preferably 0.03 to 3 mm, and more preferably 0.05 to 2 mm.

The inorganic sheet may preferably be flexible, and for example, carbon fiber paper such as paper made of glass fiber, carbon such as paper made of PAN-based carbon fiber or pitch-based carbon fiber. Locks such as textile paper, inorganic filled paper such as paper made from silicic acid-containing fine fibers, ceramic fiber paper such as paper made from ceramic fibers containing alumina and silica, and paper made from artificial mineral fibers. Examples include high-performance paper such as wool paper and paper made from an adsorptive material, or a combination thereof.

The inorganic sheet is preferably a sheet of inorganic fiber or inorganic powder. The inorganic fiber is preferably one or more inorganic fibers selected from the group consisting of glass fiber, carbon fiber, fiber containing silicic acid and alkaline earth metal, ceramic fiber, and artificial mineral fiber. The inorganic powder is preferably one or more inorganic powders selected from the group consisting of calcium carbonate, calcium silicate, aluminum hydroxide, talc, activated carbon, zeolite, silica gel and titanium oxide. Of these, artificial mineral fibers, activated carbon, zeolite, and silica gel are particularly preferable.

When using glass fiber, even if you use acrylic, polyvinyl alcohol / vinyl acetate, unsaturated polyester, epoxy / acrylic binder, epoxy, acrylic, polyvinyl alcohol, acrylic / latex, etc. Good.

The thickness of the inorganic sheet is, for example, 0.01 mm or more and 5 mm or less, preferably 0.03 mm or more and 4 mm or less. The inorganic sheet may have one layer or two or more layers.

The heat insulating material protective sheet 5 (waterproof sheet, inorganic sheet, etc.) is not always necessary. However, when a resin-based heat insulating material is used as the heat insulating material 4, it is preferable to use the heat insulating material protective sheet 5. Resin-based heat insulating materials are easily damaged by termites, but by laying a heat insulating material protective sheet, the damage can be prevented.

Hereinafter, the present invention will be described in more detail with reference to examples, but the present invention is not limited by the following examples as well as the present invention, and appropriate modifications are made to the extent that it can be adapted to the purpose of the preceding and the following. Of course, it is possible to carry out, and all of them are included in the technical scope of the present invention.

Example 1
A long-term anti-termite test was conducted as follows. Hereinafter, the test method will be described with reference to FIG.
(1) Preparation In order to level a part of the test site of Tanegashima and promote the activity of termites, a bait tree 17a (about 30 cmφ) is placed deep in the ground, and the soil 16 is backfilled on it to make the meeting place mass 15. Placed.

(2) Installation of test piece After putting soil 16 from the lower end of the meeting place mass 15 to 50 mm and leveling the ground, a glass wool molded body (trade name "Aclear wool 16K", Asahi fiber glass) as an inorganic fiber aggregate 3 along the inner wall of the meeting place mass 15 (Made by Co., Ltd.) was installed so that the layer boundary surface was in the vertical direction. The concrete 19 was poured into the space surrounded by the glass wool molded body 3 so as to have a thickness of 60 mm, and the concrete was cured and hardened while pressing the glass wool molded body by the weight of the concrete 19. The second bait tree 17b was placed on the hardened concrete 19. After that, a concrete plate 18 was used to cover the meeting place mass, a corrugated plate 14 was placed so that ventilation could be performed, and a heat insulating material 13, an iron plate 12, and a concrete block 11 were further placed.

Comparative Example 1
The same as in Example 1 was carried out except that the molded body of the inorganic fiber aggregate 3 was not used and a slight gap was left between the meeting place mass 15 and the concrete 19.

Anti-termite test After leaving the meeting place mass 15 installed as in Example 1 and Comparative Example 1 for 12 months, the condition of the bait tree 17b on the concrete 19 was observed. In the meeting place mass 15 of Example 1, the bait tree 17b was not damaged by feeding, whereas in the meeting place mass 15 of Comparative Example 1, the feeding tree 17b was damaged by feeding.

1: Concrete erecting part 2: Concrete horizontal part 3: Inorganic fiber aggregate 4, 6: Insulation material 5: Insulation material protective sheet 7, 8: Glass wool molded body 10: Foundation concrete 11: Concrete block 12: Iron plate 13: Insulation 14: Corrugated plate 15: Meeting place mass 16: Soil 17a, 17b: Bait wood 18: Concrete plate (lid)
19: Concrete

Claims (6)

It is provided with an upright part of the foundation concrete of the building and a horizontal concrete part provided inside the building at right angles to the upright part of the foundation concrete .
The molded body of the inorganic fiber aggregate has a multi-layer structure, and is compressed in a gap between the standing portion of the foundation concrete and the horizontal portion of the concrete with the layer surface in the vertical direction. Construction. The ant-proof structure according to claim 1, wherein the concrete horizontal portion is soil concrete or a concrete base board. The top surface of the molded body of the inorganic fiber aggregate is covered by the concrete lateral portion, an upper surface of the concrete lateral portion is described in which claim 1 or 2 in contact with the standing portion of the foundation concrete remains flat Anti-termite structure. The ant-proof structure according to any one of claims 1 to 3, wherein a heat insulating material is laid on the entire lower surface of the concrete horizontal portion. The ant-proof structure according to claim 4, wherein the heat insulating material is a resin-based heat insulating material, and a waterproof sheet and / or an inorganic sheet is laid on at least the entire lower surface of the resin-based heat insulating material. The anti-termite structure according to any one of claims 1 to 5, wherein the molded body of the inorganic fiber aggregate includes a molded body of glass wool or rock wool.

Images