JP6134098B2 - Masonry structure - Google Patents

Description

  The present invention relates to a masonry structure in which a masonry body in which a plurality of stones are integrally provided by frictional force is reinforced.

  Conventionally, masonry structures such as masonry piers and masonry retaining walls are known. Such a masonry structure is constructed so that the mutual stones are united by the frictional force between the masonry and do not collapse easily, but in order to further enhance the integrity, the masonry stones are bonded with an adhesive or metal wire. It is also carried out by using, for example, a patent document 1).

JP 2008-190181 A

However, in the conventional masonry structure described above, even if the stones are fixed using an adhesive or a metal wire, the strength and stability of the masonry structure as a whole are sufficient, for example, in the event of an earthquake of depth 5 or more. Since it is not a thing, the more reliable reinforcement method was calculated | required. In the case of a masonry structure, there is a possibility that the entire structure may collapse even if it is a local destruction, as well as a mere partial scattering of the masonry. There was a problem of damage to things.
In addition, masonry structures are often found in old existing structures, and it is difficult to cope with reinforcement as in the case of new constructions. Therefore, there is a need for a reinforcement method for existing masonry structures, and there is room for improvement in that respect.

  The present invention has been made in view of the above-described problems, and provides a masonry structure that can retain the shape of the entire masonry and can prevent the stone from escaping from the destroyed masonry. Objective.

In order to achieve the above object, in the masonry structure according to the present invention, a resin reinforcing coating is coated on the surface of a masonry body in which a plurality of masonry stones are integrally provided by frictional force, The body has a shape having a plurality of planes, and the reinforcing coating film is made of a polyurea resin or a polyurethane resin having a tensile strength of 10 to 25 MPa and a breaking elongation of 200% or more, and the entire surface of the masonry body Even if a failure occurs without maintaining the integrity of the masonry body, the shape of the masonry body covered with the reinforcing coating film is maintained by the deformation resistance of the reinforcing coating film. It is characterized in that it is provided to prevent local destruction and total destruction of the masonry body .

In the present invention, a reinforcing coating film made of a compound formed by a chemical reaction with a curing agent made of a polyurea resin or a polyurethane resin has a high shear adhesion, a high bending tensile strength, and a high elongation performance. It is a synthetic resin excellent in characteristics (strength and elongation), and has a high strength of, for example, about 10 to 25 MPa and a large breaking elongation (elongation deformation performance) of, for example, 200% or more. For this reason, even if destruction occurs without maintaining the integrity of the masonry body, the reinforcing coating film stretches and deforms following the fluctuation (displacement) of the masonry body. Energy absorption performance is demonstrated. Therefore, it is possible to provide a masonry structure that can cope with impact forces such as earthquake motion and tsunami.

  Even if the masonry body is destroyed by a change in the stones due to earthquake motion or impact force, the reinforcing coating does not break even if it extends, and the surface of the masonry body is covered with the reinforcing coating Is maintained. Thereby, dissipation of the stone of a masonry body is prevented, and the self-supporting shape is maintained, without the masonry body falling down or collapsing. For example, when the masonry is a masonry pier, it is possible to prevent an increase in damage such as a stone that has been dissipated due to destruction when the tsunami occurs and flows out together with the tsunami and collides with other structures. In addition, since the reinforcing coating film has deformation resistance, when a shock is applied to the masonry body and a change or shift occurs, a force to return the masonry body to its original shape is exerted by the deformation resistance force of the reinforcing coating film. . As a result, the masonry body is moved back slightly after being moved greatly, and the final fluctuation amount can be kept small.

  According to the masonry structure of the present invention, even if the masonry body is destroyed by an impact force such as earthquake motion or tsunami, the masonry of the masonry body is prevented from dissipating (preventing local destruction), and it is self-supporting without collapsing. The shape can be retained (prevention of overall destruction / shape retention). Therefore, damage caused by the dissipation of stones can be suppressed.

It is a perspective view which shows schematic structure of the masonry pier by embodiment of this invention. It is a side view of the masonry pier shown in FIG. It is a figure which shows the mechanical characteristic of a polyurea resin. It is a figure which shows the test result by an Example.

  Hereinafter, a masonry structure according to an embodiment of the present invention will be described with reference to the drawings.

As shown in FIGS. 1 and 2, the masonry pier 1 (masonry structure) according to the present embodiment has high toughness on the surface of a masonry body 2 in which a plurality of stones 2A are integrally provided by frictional force. It is a structure reinforced by covering with a resin reinforcing coating 3.
The masonry body 2 has a square frustum shape having a top end 2a, a bottom surface 2b, and four inclined side surfaces 2c.

The reinforcing coating 3 to be coated on the masonry body 2 covers the surfaces of the top end 2a and the four inclined side surfaces 2c with a predetermined coating thickness (for example, the thickness dimension D shown in FIG. 2 is 4 mm).
That is, the reinforcing coating 3 that covers the masonry body 2 is continuously provided from the top end 2a of the masonry body 2 to the four inclined side surfaces 2c and is integrally formed.

  The above-described reinforcing coating 3 is a resin coating applied to the surface of the masonry body 2 by spraying or using a roller, and a chemical reaction between an isocyanate and a curing agent made of at least one of a polyol and an amine. It consists of a compound formed by For example, as the reinforcing coating 3, a polyurea resin that is a compound formed by a chemical reaction between an isocyanate and an amine can be used.

  Specifically, the reinforcing coating film 3 is made of a synthetic resin having high mechanical properties (strength and elongation) with high shear adhesion, high bending tensile strength, and high elongation performance. For example, a polyurea resin has mechanical characteristics as shown in FIG. Here, the synthetic resin constituting the reinforcing coating 3 is made of, for example, a resin having a physical property of about 20 MPa (10 to 25 MPa) having a tensile strength of about one tenth of a reinforcing bar and having a breaking elongation of 200% or more. For example, “Swaer AR-100 (registered trademark: manufactured by Mitsui Chemicals, Inc.)” is used. In addition, it is preferable that the thickness dimension D of the reinforcement coating film 3 is 2 mm or more.

  Here, as a construction method for covering the masonry body 2 with the reinforcing coating 3, the surface of the masonry body 2 to be applied is sufficiently cleaned to remove dust and the like, and then a primer is applied. A predetermined thickness is applied over the entire surface of the top end 2a of the body 2 and the inclined side surfaces 2c. Thereby, the layered reinforcement coating 3 is formed on the masonry body 2. The primer application can be omitted. Moreover, since the surface of each stone 2A is generally uneven, it is not necessary to scratch the surface in order to improve the adhesion between the reinforcing coating 3 and the stone body 2, but if necessary, You may scratch the surface.

Next, the operation of the masonry pier 1 having the above-described configuration will be specifically described.
As shown in FIGS. 1 and 2, in the present embodiment, the reinforcing coating film 3 has excellent mechanical properties (strength and elongation) with high shear adhesion, high bending tensile strength, and high elongation performance. Since it is a synthetic resin, even if the integrity of the masonry body 2 is not maintained and breakage occurs, the reinforcing coating film 3 stretches and deforms following the fluctuation (displacement) of the masonry body 2. The energy absorption performance according to the fluctuation of the masonry 2 is exhibited. Therefore, the masonry pier 1 capable of dealing with impact forces such as earthquake motion and tsunami can be provided.

  Even if the masonry body 2 is broken due to the fluctuation of the stone 2A due to the seismic motion or impact force, the reinforcing coating 3 does not break even if it extends, and the surface of the masonry 2 is covered by the reinforcing coating 3 Is kept covered. Thereby, dissipation of the stone 2A of the masonry 2 is prevented, and the self-standing shape is maintained without the masonry 2 falling or collapsing. For example, in the case where the masonry body 2 is the masonry pier 1 as in the present embodiment, the masonry 2A dissipated due to the destruction when the tsunami occurs will flow out together with the tsunami and increase the damage such as colliding with other structures. Can be prevented.

  In addition, since the reinforcing coating 3 has deformation resistance, when the impact is applied to the masonry body 2 and a change or shift occurs, the masonry body 2 is restored to its original shape by the deformation resistance force of the reinforcing coating film 3. The power to return works. As a result, the masonry body 2 moves slightly and then returns slightly, so that the final fluctuation amount can be kept small.

  Moreover, since it forms by spraying or apply | coating the reinforcement coating film 3 to the masonry body 2, it can construct easily and cheaply and can also construct easily in the existing protective wall.

  Moreover, since the reinforcement coating 3 of the masonry pier 1 is provided on two or more surfaces of the masonry body 2, two or more surfaces of the masonry body 2 are encased in the reinforcement coating 3, and the effect (wrapping) (Effect), the above-described shape retention is more effectively exhibited.

  As described above, in the masonry structure according to the present embodiment, even if the masonry body 2 is destroyed by an impact force such as an earthquake motion or a tsunami, the masonry 2A of the masonry body 2 is prevented from dissipating (preventing local destruction) and falling. It is possible to maintain a self-supporting shape without preventing or collapsing (preventing overall destruction / holding shape). Therefore, damage caused by the dissipation of the stone 2A can be suppressed.

  Next, test examples (examples) performed to support the effects of the masonry pier 1 (masonry structure) according to the above-described embodiment will be described below.

(Example)
In the examples, the center of the rectangular parallelepiped concrete specimen was cut and brought into a butted state again, using a specimen coated with polyurea resin on the surface of the specimen, and performing an impact bending test using a loading device, The deformation state (crack and peeling) was confirmed.
The concrete specimen has a shape of 150 mm in length and 150 mm in width and a length of 530 mm. As a loading condition, a load of 30 kN was applied to the cut portion at a quasi-static speed of 0.0001 m / s while supporting both ends of the specimen. The specimen is obtained by applying a polyurea resin having a coating thickness of 4 mm only on the upper and lower surfaces.

FIG. 4 shows a bending test result in which the horizontal axis is the deformation amount δ (mm) of the loading point and the vertical axis is the load P (kN) in the specimen.
As a result, it was found that the upper parts were pressed so as to be compressed with each other at the cutting part between the two specimens, and the polyurea resin was stretched while being pulled in the length direction at the lower part, and as shown in FIG. It was confirmed that the load displacement was similar to that of the previous rectangular parallelepiped concrete. Thus, it can be seen that by applying the polyurea resin, the effect of wrapping the cut specimens is obtained, and the shape retention effect is high.

As mentioned above, although embodiment of the masonry structure by this invention was described, this invention is not limited to said embodiment, In the range which does not deviate from the meaning, it can change suitably.
For example, in the present embodiment, the masonry pier 1 is applied as a masonry structure, but the present invention is not limited to this, and can be applied to other types of masonry structures such as a masonry retaining wall. Further, the shape of the masonry pier 1 is not limited to the present embodiment, and other shapes may be used.

Furthermore, the stones of the masonry body 2 may be concrete blocks or bricks instead of stones.
Furthermore, in the above-described embodiment, the reinforcing coating 3 is provided on the top end 2a and the four inclined side surfaces 2c of the masonry body 2, but is not limited to such a covering range, and the inclined side surface 2c. It is also possible to have a structure in which only the reinforcing coating 3 is coated, and the inclined side surface 2c may be any two or three surfaces instead of four.

  Further, in the reinforcing coating 3, it is also possible to mix a nonflammable mixed material in which, for example, glass pieces, glass fibers, glass frit and the like are dispersed, into the polyurea resin. Alternatively, the mixed material may be a nonflammable material other than glass, such as concrete, brick, tile, asbestos slate, steel, aluminum, mortar, or plaster.

  In the above-described embodiment, a polyurea resin made of a compound formed by a chemical reaction between an isocyanate and an amine is used as the reinforcing coating film 3, but the present invention is based on a chemical reaction between an isocyanate and a polyol. It is also possible to use a polyurethane resin made of the formed compound as a reinforcing coating film, and it is also possible to use a resin made of a compound formed by a chemical reaction of isocyanate, polyol and amine as a reinforcing coating film. .

  In addition, it is possible to appropriately replace the components in the above-described embodiments with known components without departing from the spirit of the present invention.

1 Masonry piers (masonry structure)
2 Masonry body 2A Masonry stone 2a Top edge 2c Inclined side surface 3 Reinforced coating

Claims (1)

The surface of the masonry body in which a plurality of stones are integrally provided by frictional force is coated with a resin reinforcing coating,
The masonry body has a shape having a plurality of planes,
The reinforcing coating film is composed of a polyurea resin having a tensile strength of 10 to 25 MPa and a breaking elongation of 200% or more, or a polyurethane resin, and is coated on the entire surface of the masonry body,
Even if destruction occurs without maintaining the integrity of the masonry body, the shape of the masonry body covered with the reinforcing coating film is maintained by the deformation resistance of the reinforcing coating film,
A masonry structure characterized in that the masonry body is provided so as to prevent local destruction and total destruction .

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