JP3232092U - Reinforcement structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the safety of evacuees and passersby by reinforcing the side wall of a structure composed of a plurality of stacked concrete blocks so that the structure maintains an independent structure without falling or collapsing. Provide a reinforcing structure that can be secured. SOLUTION: A reinforcing structure 10 includes a structure 1 composed of a plurality of stacked concrete blocks, a high-strength fiber mesh cloth 3 for reinforcing at least one side of the structure 1, and both sides and high strength of the structure 1. It includes a resin layer made of polyurea resin 2 that covers the fiber mesh cloth 3. [Selection diagram] Fig. 1

Description

The present invention relates to a reinforced structure in which a structure composed of a plurality of stacked concrete blocks is reinforced with a high-strength fiber mesh cloth.

Block walls made by stacking multiple concrete blocks are used as side walls of shelters and mountain lodges near the crater of a volcano, or as outer walls of private houses, but the sides are almost unreinforced.

Patent Document 1 describes that the surface of a structure that has been subjected to base treatment such as cleaning, sanding treatment, blast treatment, primer treatment, etc., is made of acrylic resin, urethane resin, silicone resin, fluororesin, polyurea resin, etc. A method is disclosed in which a resin is sprayed to form an adhesive layer, a reinforcing net is attached to the upper surface of the adhesive layer, and an adhesive protective agent is sprayed from above the reinforcing net.

As the reinforcing net, one in which synthetic fiber bundles such as aramid fiber, vinylon fiber, polypropylene fiber, and polyethylene fiber are woven, or one in which they are simply overlapped is used.

The method disclosed in Patent Document 1 can easily form a reinforcing layer in which an adhesive layer, a reinforcing net, and an adhesive protective layer are integrated, so that the reinforcing layer causes soft rocks and floating rocks to fall from the rock surface. It can be prevented from doing so.

However, in recent years, there have been accidents in the vicinity of the crater of a volcano injuring climbers due to the arrival of volcanic blocks due to the eruption. There are evacuation sites such as shelters and mountain lodges near the crater, but block walls made by stacking concrete blocks are used as the side walls. However, with conventional block walls, the collision of volcanic bombs could destroy the block walls, injuring evacuated climbers. In addition, there were accidents in which block walls of private houses collapsed due to the earthquake, and accidents in which old block walls collapsed, and there was a risk that passers-by would be involved in the accident.

Japanese Unexamined Patent Publication No. 2004-27764

The present invention has been made in view of the above circumstances, and reinforces the side wall of a structure composed of a plurality of stacked concrete blocks so that the structure maintains a self-supporting structure without falling or collapsing. The challenge is to provide a reinforcing structure that can ensure the safety of evacuees and passers-by.

In order to solve the above problems, the present inventor has prepared a structure composed of a plurality of stacked concrete blocks, a high-strength fiber mesh cloth for reinforcing at least one side of the structure, and both sides of the structure and the height of the structure. Provided is a reinforcing structure characterized by comprising a resin layer made of a polyurea resin for coating a mesh cloth made of strong fibers.

According to the present invention, it is possible to efficiently reinforce a structure composed of a plurality of stacked concrete blocks, and even if an impact force is applied to the structure, the structure does not tip over or collapse. Provided is a reinforced structure capable of maintaining a self-supporting structure.
Therefore, it is possible to ensure the safety of evacuees by applying it to the side walls of new or existing shelters and mountain lodges, which are provided to protect climbers from volcanic eruptions. In addition, it is possible to ensure the safety of passers-by from accidents in which block walls collapse or collapse due to earthquakes or aging.

It is explanatory drawing (front view (a) and rear view (b)) explaining the reinforcement structure (block wall) which is one Embodiment of this invention, polyurea resin is sprayed on both sides of a block wall, and height only on one side. This is an example of reinforcing by adhering a mesh cloth made of strong fiber. It is explanatory drawing (front view (a) and back view (b)) explaining the reinforcement structure (block wall) which is one Embodiment of this invention, and both sides of the block wall were reinforced with the high-strength fiber mesh cloth. This is an example. FIG. 5 is a schematic view showing a reinforcing structure in which a high-strength fiber mesh cloth is adhered to one side of a plurality of concrete blocks using a polyurea resin in the reinforcing structure of the present invention. FIG. 3 is a plan sectional view of the reinforcing structure of FIG. It is explanatory drawing explaining the space ratio, the opening and the thread width of the high-strength fiber mesh cloth of this invention.

Hereinafter, the present invention will be specifically described with reference to the drawings.

1 and 2 are embodiments of the reinforced structure of the present invention, and are views for explaining the reinforced structure of the structure composed of a plurality of stacked concrete blocks. In FIGS. 1 and 2, 1 is a block wall (structure), 2 and 2a are resin layers made of polyurea resin, 3 is a high-strength fiber mesh cloth, and 10 is a reinforcing structure.

The reinforcing structure 10 according to the present invention can be formed by the following method. First, concrete blocks (hereinafter abbreviated as "blocks") are stacked and each block is connected by mortar on the entire surface of the block wall (structure) 1 (corresponding to the side where impact objects and flying objects hit). , Polyurea resin 2 is sprayed (FIG. 1 (a)).

On the other hand, on the back surface of the block wall (structure) 1 (corresponding to the shelter side of the mountain hut), first, an appropriate amount of polyurea resin 2a is sprayed on the entire surface, and immediately after that, the high-strength fiber mesh cloth 3 is attached to the entire surface. wear. After crimping the cloth 3 with a roller to firmly bond the cloth 3 to the block wall 1, the polyurea resin 2 is sprayed onto the high-strength fiber mesh cloth 3 to completely bond the high-strength fiber mesh cloth 3 to the structure 1. (Fig. 1 (b)).
In the above description, the case where the three-layer structure including the high-strength fiber mesh cloth 3 is arranged only on the back surface of the block wall has been described, but the three-layer structure including the high-strength fiber mesh cloth 3 is arranged only on the front surface. It can also be a reinforced structure.

Further, a high-strength fiber mesh cloth may be attached to both sides of the structure 1 to form a reinforcing structure. As in the case of single-sided reinforcement of the structure 1, polyurea resin is sprayed on the entire surface of the block wall (structure) 1 on one side, and immediately after that, the high-strength fiber mesh cloth 3 is attached to the entire surface to firmly attach the cloth 3. After adhering to the structure 1, the polyurea resin is further sprayed onto the high-strength fiber mesh cloth 3 (FIG. 2 (a)).
Similarly, on the opposite surface of the block wall (structure) 1, the polyurea resin is sprayed on the entire surface, and immediately after that, the high-strength fiber mesh cloth 3 is attached to the entire surface, and the cloth 3 is firmly attached to the structure 1. After bonding, the polyurea resin is sprayed onto the high-strength fiber mesh cloth 3 to completely bond the high-strength fiber mesh cloth 3 to the structure 1 (FIG. 2B).

The reinforced structure of the present invention reinforces a structure composed of a plurality of stacked blocks, and the high tensile strength and high tensile elasticity of the high-strength fiber mesh fabric make it possible to maintain the connection of the plurality of blocks. Therefore, it is possible to prevent the block from falling apart when it receives an impact.

On the other hand, the polyurea resin not only has a high adhesive force to the side surface of the block, but also does not have an adverse effect of dissolving and disintegrating the mortar connecting the blocks. The polyurea resin also has a function of connecting each block by adhering to the blocks and forming a film on the upper surface of the blocks. Further, since it has a high affinity (wetting property) with high-strength fibers, it is not necessary to use a high-strength fiber mesh fabric that has been pretreated to enhance the adhesiveness to the polyurea resin, which is economically excellent.

FIG. 3 shows a reinforcing structure in which resin layers 2 and 2a made of polyurea resin and mesh cloth 3 made of high-strength fibers are applied to a block wall 1, and the polyurea resin layer 2 and high-strength fibers are sandwiched between blocks. FIG. 4 is a schematic view showing a state in which the mesh fabric 3 is firmly connected, and FIG. 4 is a cross-sectional view thereof.

In the reinforced structure of the present invention, the thickness of the polyurea resin layer 2 formed on the side surface of the block wall (structure) 1 is preferably 1 mm or more when the high-strength fiber mesh cloth 3 is not used. It is more preferably 5.5 mm or more, and particularly preferably 2 mm or more. If the thickness is insufficient, the toughness of the resin film becomes insufficient, and it becomes difficult to maintain the reinforcing structure against large shaking and impact.

On the other hand, when the high-strength fiber mesh cloth 3 is used, the thickness of the polyurea resin layer 2 formed on the high-strength fiber mesh cloth 3 adhered to the block 1 via the polyurea resin 2a is 1 mm or more. It is preferably 1.5 mm or more, and particularly preferably 2 mm or more. In this case, the thickness of the polyurea resin 2a sprayed on the structure 1 in advance is not particularly limited, but is preferably a thickness that can cover the entire surface of one side of the structure 1, for example, about 0.5 mm to 1 mm.

Polyurea resin is a compound formed by a chemical reaction between an isocyanate compound (main agent) and an amine compound (curing agent) having active hydrogen. Examples of the polyurea resin include Extreme 11-50 (manufactured by Rhino Lining Co., Ltd.). It is presumed that the polyurea resin adheres the block to the high-strength fiber mesh cloth and forms a film having high toughness and high elongation on the surface of the block.

Examples of the method for applying the polyurea resin include a method of applying or spraying the polyurea resin on the block with a predetermined thickness dimension, but spraying is desirable because it is excellent in workability. As a spraying device for spraying the polyurea resin on the block, a known spraying device can be used. The polyurea resin is produced by subjecting a polyisocyanate compound (main agent) and an amine compound having active hydrogen (curing agent) to a collision mixture with a spray gun to cause a chemical reaction. The spraying device is a device in which a polyisocyanate compound and an amine compound are collision-mixed to form a mist and sprayed onto a block.

The spraying device heats a tank containing a polyisocyanate compound, a tank containing an amine compound, a pump that delivers the compound from each tank, a high-pressure metering pump that applies sufficient pressure to the compound to deliver a predetermined amount, and a compound to be transported. A heater, a hose with a heater that holds the temperature of a compound, a spray gun that collides and mixes both compounds and ejects them in a mist state, a control device that changes the mixing ratio of both compounds, a control device that changes the heating temperature, etc. Can be used. Both compounds are heated to a predetermined temperature by a heater and sent to a spray gun while being held at a predetermined temperature by a hose with a heater, and the spray gun collides and mixes both compounds and ejects them in the form of mist. Both compounds form a polyurea resin by a chemical reaction and solidify on the surface of the object to be sprayed to form a coating film. Therefore, there is an advantage that the working time can be extremely short.

A plan sectional view of the reinforcing structure thus obtained is shown in FIG. 4, and since the surface of the block wall (the surface on which the impact object hits) is protected by the polyurea resin 2, the impact caused by the impact object is alleviated. On the other hand, the back surface of the block wall (shelter side) is protected by a three-layer structure of polyurea resin 2a, high-strength fiber mesh cloth 3, and polyurea resin 2, so that the impact mitigation effect of the polyurea resin and the tensile strength are high. The high-strength fiber mesh fabric can withstand higher impacts.
The same effect can be obtained when a three-layer structure of polyurea resin 2a, high-strength fiber mesh cloth 3, and polyurea resin 2 is arranged on the surface of the block wall, and polyurea resin 2 is arranged on the back surface of the block wall. ..

As the high-strength fiber mesh fabric, at least one selected from woven fabrics, knitted fabrics, knitted fabrics, lattice sheets and honeycomb-shaped materials is preferably used, depending on the shape of the structure and the reinforcing effect required for the structure. , One type may be used, or two types or three or more types of fabrics may be used in combination. From the viewpoint of high tensile strength of the high-strength fiber mesh fabric, a woven fabric or a honeycomb-like material is preferable. The woven fabric structure is preferably plain weave, twill weave, satin weave, etc., and may be a general biaxial woven fabric, or a multiaxial woven fabric such as a triaxial woven fabric or a quadrilateral woven fabric. Further, the high-strength fiber mesh cloth used for the front surface and the back surface of the block wall may have the same or different types and fineness of the high-strength fibers and the type and shape of the cloth.

The high-strength fiber may be at least one selected from the group consisting of glass fiber, boron fiber, ceramic fiber, aramid fiber, polyparaphenylene benzbisoxazole fiber, high-strength polyethylene fiber and total aromatic polyester fiber. preferable. Aramid fibers are particularly preferable because of their high strength and high elastic modulus. The aramid fiber is a meta-type aramid fiber, a para-type aramid fiber, or a copolymer thereof. Specific examples include fibers made of polyparaphenylene terephthalamide, polymethphenylene isophthalamide, poly-3,4'-oxydiphenylene terephthalamide copolymer and the like. The fineness of the high-strength fiber is preferably 100 to 8,000 dtex, more preferably 100 to 6,300 dtex.

If the high-strength fibers constituting the high-strength fiber mesh fabric are untwisted, yarn disorder and yarn spread are likely to occur when the polyurea resin is sprayed, and the fabric strength is likely to decrease or the space ratio is likely to change. In order to prevent them, it is preferable that the high-strength fibers are twisted. The preferred twist coefficient (lower twist coefficient) is 0.1 to 5.0, more preferably 0.1 to 2.2, and even more preferably 0.1 to 1.6. If the twist coefficient exceeds 5.0, the strength decreases and the twisted yarn becomes thicker, which may not be preferable from the viewpoint of ensuring the space ratio and lightness. The twist coefficient is calculated by the following formula (1).

The high-strength fiber mesh fabric preferably has 0.5 or more and 10 or less warp and weft threads per inch. More preferably, it is 7 or less. When the number of threads is less than 0.5, it becomes difficult to play a role as a ripstop depending on the fineness, so it is more preferably 1 to 7 threads / inch.

In the case of the lattice-shaped mesh sheet, the space ratio of the mesh fabric is preferably 70% or more, more preferably 75% or more. When the space ratio is 70% or more, the impact resistance of the reinforced structure can be further improved in combination with the effect of improving the adhesiveness of the polyurea resin to the structure. On the other hand, if the space ratio becomes too high, the strength of the high-strength fiber mesh fabric itself decreases and the reinforcing effect becomes insufficient. Therefore, the space ratio is preferably 93% or less, more preferably 90% or less. Is.

In the case of a general biaxial woven fabric, the space ratio is calculated by the following formula (2).

Further, in a multi-axis woven fabric such as a triaxial woven fabric and a quadruple woven fabric, the spatial ratio can be obtained by using an image analysis device. Simply, a black-and-white copy is taken with an electrophotographic (ZEROX) type copier, and it can be obtained by using the copied image (area of the black portion / area of the entire effective portion) × 100.

FIG. 5 is a diagram for explaining the spatial ratio, the opening, and the thread width when the high-strength fiber mesh fabric of the present invention is a lattice-shaped mesh sheet. The opening (Me, Mf) of the warp and weft is the length between adjacent fibers. The widths of the warp and weft (We, Wf) are both the widths of the fibers constituting the mesh fabric. The width of the fiber is related to the degree of fiber opening, widening / flattening, and the number of twists. The width of the fiber increases as the width / flattening of the fiber progresses, and decreases as the number of twists increases.

In the case of high-strength fiber mesh fabric, by reducing the number of fibers per inch and reducing the width of the fibers used, the opening of the fabric can be increased, and as a result, the space ratio is increased. be able to. In order to reduce the width of the fiber while maintaining the strength of the mesh fabric, it is effective to use a high-strength fiber that is hard to cut even if it is thin.

The reinforcing structure 10 of the present embodiment includes a structure 1 composed of a plurality of stacked concrete blocks, a high-strength fiber mesh cloth 3 for reinforcing at least one side of the structure 1, both sides of the structure 1, and both sides of the structure 1. It includes a resin layer 2 made of a polyurea resin that covers the high-strength fiber mesh cloth 3. That is, the presence of the structure 1 and the resin layer 2 having extremely high toughness alleviates the force of peeling the mortar connecting the blocks. Further, even when an impact is applied from the outside, the high-strength fiber mesh fabric 3 having high strength and elastic modulus exists without breaking, so that the impact from the outside is alleviated and the impact on the block 1 is weakened. Be done. At the same time, the high-strength fiber mesh fabric 3 freely expands and contracts or bends in accordance with the deformation of the resin layer 2, so that the movement of the resin layer 2 is appropriately relaxed. As a result, even if a large impact is applied to the structure at the time of collision with a flying object, the resin layer 2 expands and contracts following the deformation of the structure 1 and the high-strength fiber mesh cloth 3, and the block stands on its own without collapsing. Can be retained. Even in the absence of the high-strength fiber mesh fabric 3, the resin layer 2 made of polyurea resin having extremely high toughness bends following the deformation of the structure 1 to prevent the block from collapsing. be able to. When the high-strength fiber mesh fabric 3 is subjected to a strong impact, the resin and the fiber surface are peeled off. Therefore, when reinforcing only one side with the high-strength fiber mesh fabric, it is better to arrange it on the opposite surface that receives the impact. High effect can be expected. Further, polyurea resins 2a and 2 and a high-strength fiber mesh cloth 3 may be applied to the surface of the primer-treated structure 1.

The reinforcing structure described in the above embodiment is an example for embodying the technical idea of the present invention, and the shape and dimensions of each material are not limited to those of this embodiment. , Various changes can be made within the scope of the utility model registration claim of the present invention.

Hereinafter, the present invention will be described in more detail with reference to Examples, but the present invention is not limited to the following Examples.

(Example 1)
Polyurea resin (Extreme 11-50 manufactured by Rhino Lining Co., Ltd.) is applied to the surface of the block wall (the surface where impact objects hit) where concrete blocks are stacked and each block is connected by mortar, and the amount applied is approximately 2.2 kg / m. ^It was sprayed so as to be 2 (Fig. 1 (a)).
On the other hand, on the back surface (evacuation center side) of the block wall, first, the same polyurea resin as above is ^{sprayed so that the coating amount is about 0.5 kg / m 2,} and immediately after that, a mesh cloth made of aramid fiber (aramid fiber; Kevlar (R) manufactured by Toray DuPont Co., Ltd., with a cloth texture; 45 g / m ² , space ratio; 90%) was attached. After the fabric was firmly adhered to the block wall, the polyurea resin ^{was sprayed onto the mesh fabric so that the coating amount was about 2.2 kg / m 2} (FIG. 1 (b)).

(Example 2)
Polyurea resin (Extreme 11-50 manufactured by Rhino Linings Co., Ltd.) is applied to the surface of the block wall (the surface where impact objects hit) where concrete blocks are stacked and each block is connected by mortar, and the amount applied is about 0.5 kg / m. ^{It was sprayed so as to be 2,} and immediately after that, a mesh cloth made of aramid fiber (aramid fiber; Kevlar (R) manufactured by Toray DuPont Co., Ltd., cloth grain; 45 g / m ² , space ratio; 90%) was pasted. After the cloth was firmly adhered to the block wall, the polyurea resin ^{was sprayed onto the mesh cloth so that the coating amount was about 2.2 kg / m 2} (FIG. 2 (a)).
On the other hand, the back surface of the block wall (shelter side) is also ^{sprayed with the same polyurea resin as above so that the coating amount is about 0.5 kg / m 2,} and immediately after that, it is made of aramid fiber. A mesh cloth (aramid fiber; Kevlar (R) manufactured by Toray DuPont Co., Ltd., cloth grain; 45 g / m ² , space ratio; 90%) is attached, and the cloth is firmly adhered to the block wall, and then the polyurea resin is applied. , Sprayed onto the mesh fabric so that the coating amount was about 2.2 kg / m ² (FIG. 2 (b)).

The block wall reinforced in the above embodiment does not penetrate even if a volcanic bomb flying from the crater collides, and the safety of the evacuees can be ensured.

The reinforced structure of the present invention can be used for a block wall provided to protect the body from volcanic stones, falling objects, and flying objects such as shelters and mountain lodges. Furthermore, by using it for a block wall provided around a public facility such as an apartment house, a school, a hospital, or a private house, it is possible to prevent the block wall from collapsing and causing harm to the surrounding area.

1 block wall (structure)
2 Resin layer (coating layer) made of polyurea resin
2a Resin layer made of polyurea resin (adhesive layer)
3 High-strength fiber mesh fabric 10 Reinforcing structure

Claims (5)

A structure consisting of multiple stacked concrete blocks and
A high-strength fiber mesh fabric that reinforces at least one side of the structure,
A resin layer made of polyurea resin that covers both sides of the structure and the high-strength fiber mesh fabric, and
Reinforcing structure characterized by being equipped with. The reinforcing structure according to claim 1, wherein the high-strength fiber mesh fabric is at least one selected from a woven fabric, a knitted fabric, a knitted fabric, and a honeycomb-shaped fabric. The high-strength fiber is at least one selected from the group consisting of glass fiber, boron fiber, ceramic fiber, aramid fiber, polyparaphenylene benzbisoxazole fiber, high-strength polyethylene fiber and total aromatic polyester fiber. The reinforcing structure according to claim 1 or 2. The reinforcing structure according to any one of claims 1 to 3, wherein the high-strength fiber is an aramid fiber. Any of claims 1 to 4, wherein the high-strength fiber mesh fabric has a space ratio of 70% or more, and the number of warp and weft threads per inch is 0.5 to 10. Reinforcing structure described in Crab.

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