JP7507443B1 - Tunnel reinforcement and repair method using curved resin concrete panels - Google Patents

Abstract

[Problem] To provide a tunnel reinforcement/repair method using a thin-walled cylindrical structure in which curved resin concrete panels with a curved surface that matches the diameter of a circular waterway tunnel are connected with a high-strength adhesive to obtain a structure that is safe against the internal water pressure and external pressure applied to the circular waterway tunnel, and has excellent watertightness and durability. [Solution] The tunnel reinforcement/repair method using curved resin concrete panels is characterized by comprising the steps of: temporarily installing a plastic spacer and a height adjustment member to be placed on the plastic spacer on the existing lining concrete side, and then temporarily installing the curved resin concrete panel; installing the curved resin concrete panel, the plastic spacer, and the height adjustment member on anchors embedded in the existing lining concrete side by countersunk bolts; and filling and adhering a joint material into the joint gaps between the curved resin concrete panels. [Selected drawing] Figure 1

Description

The present invention relates to a tunnel reinforcement and repair method using curved resin concrete panels, which have a curved surface that matches the curvature diameter of the waterway tunnel and are connected with high-strength adhesive.

Materials that have generally been used to form the lining of a waterway tunnel include unreinforced concrete, reinforced concrete, and steel materials. The strength of the materials that form the lining of a waterway tunnel is determined through material testing, and the thickness of the tunnel lining wall and the ground support structure are designed based on the determined material strength. Furthermore, stress analysis is used to calculate the stress acting on the tunnel lining structure, and the structure is designed so that the stress does not exceed the durability of the material. Not only are the earth pressure and external water pressure that the waterway tunnel is subjected to from the ground and other external sources, but the internal water pressure caused by the head difference between the intake and discharge sides of the water flowing inside the waterway tunnel and the flow rate also affect the strength design of the waterway tunnel lining.

On the other hand, when reinforcing and repairing a waterway tunnel, it is important to consider that the structure must be safe against the internal water pressure and external pressure applied to the waterway tunnel, and have excellent watertightness and durability. Specifically, assuming a waterway tunnel with a circular cross section, it is necessary to form a "single cylindrical structure for reinforcing and repairing the tunnel's inner wall over 360°" to be constructed on the inner wall of the waterway tunnel in order to make the structure safe against the internal water pressure and external pressure applied to the waterway tunnel, and have excellent watertightness and durability. The applicants have conducted extensive research based on the above idea, and have developed a thin-walled cylindrical structure connected to resin concrete panels of any curvature that can ensure the same level of strength as a thin-walled steel pipe.

Patent Document 1 aims to provide a method for seismic reinforcement of existing concrete structures that can obtain a seismic reinforcement structure that can pass structural calculations by using improved resin concrete panel materials without using structural materials such as H-shaped steel supports. It discloses an inner surface reinforcement method for installing a resin concrete panel by bonding the back surface of the resin concrete panel to the inner surface of an existing concrete structure, characterized in that the resin concrete panel is a composite resin concrete panel that is formed into a curved or flat shape by integrating a bidirectional carbon fiber sheet with the back surface, and further characterized in that, when installing the panel, a bidirectional carbon fiber sheet for connection, which has an area that can secure a predetermined lap length and lap the entire area of the connection, is bonded in advance to the panel connection part on the inner surface of the structure that is parallel to the axial direction of the structure.

JP 2014-163120 A

The earthquake-resistance reinforcement method using composite resin concrete panel material described in Patent Document 1 provides an earthquake-resistance reinforcement structure that can pass structural calculations for an existing concrete structure whose inner surface is reinforced with this composite resin concrete panel, without using structural materials such as reinforcing bars or H-shaped steel supports. However, looking at Figure 1 in Patent Document 1, it can be seen that the rear ground part of the tunnel, which is an existing concrete structure, has not been reinforced or repaired.

The object of the present invention is to provide a reinforcement and repair method using a thin-walled cylindrical structure in which curved resin concrete panels with a curved surface that matches the diameter of the circular waterway tunnel are connected with a high-strength adhesive to obtain a structure that is safe against the internal water pressure and external pressure applied to the circular waterway tunnel, and has excellent watertightness and durability.

In order to solve the above problems, the invention described in claim 1 is a thin-walled cylindrical structure in which a plurality of curved resin concrete panels formed when reinforcing and repairing a waterway tunnel are connected into a cylindrical shape and integrated into a ring shape , and is provided with a plurality of curved resin concrete panels having a predetermined radius of curvature that matches the inner wall diameter of the waterway tunnel to be reinforced and repaired, and a joint material that fills and adheres to fill the gaps between the curved resin concrete panels and the curved resin concrete panels, the joint material being an epoxy resin-based sealing material for wet surface application, and adopting at least one or more hardeners selected from amine-based hardeners, anhydride-based hardeners, phenol-based hardeners, and polyhydric alcohol-based hardeners as a hardener necessary for hardening the epoxy resin, and the adhesive strength between the curved resin concrete panel and the joint material is 16.8 N/mm2 or more, which is greater than the tensile strength of the curved resin concrete panel ^itself .

The invention described in claim 2 is a tunnel reinforcement and repair method using a curved resin concrete panel having an arbitrary curvature, characterized in that it comprises the steps of: temporarily installing a plastic spacer and a height adjustment member so as to be placed on the plastic spacer on the existing concrete side of the tunnel, and then temporarily installing the curved resin concrete panel; installing the curved resin concrete panel, the plastic spacer, and the height adjustment member on an anchor buried in the existing concrete side of the tunnel by countersunk bolt fastening; and filling and adhering a joint material into the joint gap between the curved resin concrete panel and the curved resin concrete panel. Note that in the present invention, the predetermined radius of curvature of the multiple curved resin concrete panels is not necessarily the same.

The thin-walled cylindrical structure formed by the tunnel reinforcement/repair method using curved resin concrete panels according to the present invention is a thin-walled cylindrical structure in which multiple curved resin concrete panels formed when reinforcing and repairing a waterway tunnel are connected into a cylindrical shape with high-strength adhesive. The curved resin concrete panels have an arbitrary radius of curvature (the radius of curvature is determined by the inner wall diameter of the waterway tunnel) that matches the diameter of the waterway tunnel (which has a circular cross-sectional shape) to be reinforced/repaired. The curved resin concrete panels are provided with multiple curved resin concrete panels and a joint material that fills and adheres the curved resin concrete panels to fill the gaps between the curved resin concrete panels.

The main component of the joint material is a high-strength adhesive with an adhesive strength such that the tensile strength at the adhesive surface between the curved resin concrete panel and the joint material is greater than the tensile strength of the curved resin concrete panel itself, so that multiple curved resin concrete panels and the joint material (which connects them together) are integrated into a large cylinder (with a ring-shaped cross section) (installed on the inner wall of the waterway tunnel). Therefore, it is now possible to provide a thin-walled cylindrical structure in which curved resin concrete panels with a curved surface that matches the diameter of the waterway tunnel are connected with a high-strength adhesive to obtain a structure that is safe against the internal water pressure and external pressure applied to the waterway tunnel (with a ring-shaped cross section), and has excellent watertightness and durability.

1 is a cross-sectional view of a curved resin concrete panel connected thin-walled cylindrical structure formed by a tunnel reinforcement and repair method using curved resin concrete panels according to the present invention. FIG. 2 is a side view of a thin-walled cylindrical structure. FIG. 13 is a development view for explaining a joining state of thin-walled cylindrical structures.

One embodiment of a thin-walled cylindrical structure 10 according to the present invention will be described in detail below with reference to Figs. 1 to 3. Fig. 1 is a cross-sectional view of a curved resin concrete panel-connected thin-walled cylindrical structure 10 formed by a tunnel reinforcement and repair method using curved resin concrete panels according to the present invention. Fig. 2 is a side view of the thin-walled cylindrical structure 10.

The curved resin concrete panel connected thin-walled cylindrical structure 10 formed by the tunnel reinforcement and repair method using the curved resin concrete panel according to the present invention is formed when reinforcing and repairing a waterway tunnel. That is, it is formed by construction aimed at reinforcing and repairing the inner wall of an aging waterway tunnel. As a specific process, the curved resin concrete panel 20 having a hole required for screwing in a countersunk bolt is temporarily installed (so that a space is created between the existing tunnel) by screwing the countersunk bolt into a metal expansion anchor embedded in the inner wall of the existing tunnel, and then a high-flow grout material is injected and filled into the space between the existing tunnel and the curved resin concrete panel 20. Furthermore, the curved resin concrete panels 20 having a curvature surface that matches the curvature of the inner wall of the waterway tunnel and the curved resin concrete panel 20 are connected in a cylindrical shape (continuously laid in a cylindrical shape in the direction of travel of the waterway tunnel) by a high-strength adhesive that fills the joint gaps between the curved resin concrete panels 20. Furthermore, before the process of injecting and filling the high-fluidity grout material, the process of filling the joints with high-strength adhesive is completed for each span to be injected.

The curved resin concrete panel connected thin-walled cylindrical structure 10 formed by the tunnel reinforcement/repair method using curved resin concrete panels is formed by the above process, and as shown in Figures 1 and 2, it is provided with a plurality of curved resin concrete panels 20 having a predetermined radius of curvature that matches the diameter of the waterway tunnel to be reinforced/repaired, and a joint material 30 that fills the joint gaps between the curved resin concrete panels 20 and the curved resin concrete panels 20. (The high-flow grout material filled in the space between the back of the panels between the existing tunnel lining surface and the curved resin concrete panels 20 is not included.) The thin-walled cylindrical structure 10 is characterized in that it is a thin-walled cylindrical structure 10 in which the curved resin concrete panels 20 and the joint material 30 are integrated in a ring shape (when viewed in cross section) over 360° of the inner wall side of the waterway tunnel, which has a circular cross section (see Figure 1). The overall shape of the thin-walled cylindrical structure 10 resembles a cylindrical (tubular) structure in which a large ring body made of curved resin concrete panels 20 and joint material 30 formed along the inner wall surface of the waterway tunnel is continuously extended in the direction of travel of the waterway tunnel (see Figure 2).

The thin-walled cylindrical structure 10 must have sufficient adhesive strength (between the curved resin concrete panel 20 and the joint material 30) so that the curved resin concrete panel 20 and the joint material 30 can be integrated into a large ring shape (when viewed in cross section) over 360° of the inner wall side of the waterway tunnel, which has a circular cross section. The main component of the joint material 30 (which fills the gaps between the curved resin concrete panels 20 and the curved resin concrete panels 20, and has a predetermined radius of curvature that matches the diameter of the waterway tunnel to be reinforced and repaired) is a high-strength adhesive with an adhesive strength (evaluated by tensile strength) such that the tensile strength at the adhesive surface between the curved resin concrete panel 20 and the joint material 30 is equal to or greater than the tensile strength of the curved resin concrete panel 20 itself.

To explain the joint material 30 in detail, it is an epoxy resin-based sealant for wet surface application. The degree of hardening of the adhesive of the epoxy resin-based sealant is increased by adjusting the so-called hardener (a component necessary for hardening the epoxy resin), and the adhesive strength is improved. In order to obtain a high-strength adhesive with an adhesive strength such that the tensile strength at the adhesive surface between the curved resin concrete panel 20 and the joint material 30 is greater than the tensile strength of the curved resin concrete panel 20 itself, the hardener, which is a component necessary for hardening the epoxy resin-based sealant, can be an amine-based hardener (alkylamine, allylamine, amidoamine, xylideneamine, etc.), which is an organic compound containing an amine group, an acid anhydride-based hardener that is a type of hardener that hardens by mixing an acid anhydride and an epoxy resin, a phenol-based hardener that is a type of adhesive that uses a phenol resin as a hardener, a polyhydric alcohol-based hardener that is a type of hardener that hardens by mixing a polyhydric alcohol and an epoxy resin, etc. These may be used alone, or a combination of one or more types of hardeners may be used.

Furthermore, in order to obtain a high-strength adhesive with an adhesive strength such that the tensile strength at the adhesive surface between the curved resin concrete panel 20 and the joint material 30 is greater than the tensile strength of the curved resin concrete panel 20 itself, in addition to selecting and adjusting the hardener, it is also possible to add a fiber-reinforced material that can improve the strength of the adhesive by adding fibers to the epoxy resin, and a filler that can fill in the unevenness of the surface to which the adhesive is adhered and increase the adhesive area of the adhesive.

<Bonding state of thin-walled cylindrical structure>
Fig. 3 is a development view for explaining the joint state of the curved resin concrete panel connected thin-walled cylindrical structure 10 formed by the tunnel reinforcement and repair method using the curved resin concrete panel. Fig. 3 is a 360° development view along the inner wall surface of the waterway tunnel (when viewed from the inside of the tunnel), and shows that the joint gap between the curved resin control panel 20 and the curved resin control panel 20 is filled with the joint material 30.

As shown in the development view of Figure 3, the thin-walled cylindrical structure 10 is joined by bonding the curved resin concrete panels 20, each measuring approximately 1000 mm x 1000 mm, with the joint gaps (10 mm to 20 mm) between the curved resin concrete panels 20 filled with the joint material 30. This structure is continuously formed from the start point of the waterway tunnel renovation to the end point of the waterway tunnel renovation. In other words, the thin-walled cylindrical structure 10 is continuously formed by the curved resin concrete panels 20 and the joint material 30.

<Effect of thin cylindrical structure>
The curved resin concrete panel-connected thin-walled cylindrical structure 10 formed by the tunnel reinforcement/repair method using the curved resin concrete panel according to the present invention is inspired by the reinforcing bar cross-sectional area per unit tunnel axis converted into a thin-walled cylinder (the ability to convert reinforcing bars into a thin-walled cylinder) in the structural design calculation of a circular cross section in a waterway tunnel. As a result of the applicants' studies, it is a thin-walled cylindrical structure 10 connected by a high-strength adhesive with an adhesive strength (for example, tensile strength: 16.8 N/mm ² ) that is greater than the tensile strength of the curved resin concrete panel 20 itself, using the tensile strength at the adhesive surface between the curved resin concrete panel 20 and the joint material 30 as a guide. The thin-walled cylindrical structure 10 is like a cylindrical (tube-shaped) structure in which a large ring body formed along the inner wall surface of the waterway tunnel and the joint material 30 are integrated is extended in the direction of travel of the waterway tunnel.

By forming a thin-walled cylindrical structure 10 (with a tensile strength equal to or greater than that of the curved resin concrete panel 20) on the inner wall side of the waterway tunnel, it is now possible to provide a thin-walled cylindrical structure in which curved resin concrete panels with a curvature matching the diameter of the circular waterway tunnel are connected with high-strength adhesive to obtain a structure that is safe against the internal water pressure and external pressure applied to the circular waterway tunnel, and has excellent watertightness and durability. Furthermore, it has become possible to shorten the construction period to less than half compared to similar construction methods for thin-walled cylindrical structures.

<Example of modification of thin-walled cylindrical structure>
The curved resin concrete panel connected thin-walled cylindrical structure formed by the tunnel reinforcement/repair method using the curved resin concrete panel according to the present invention is not limited to the above-mentioned embodiments, and the configurations of the resin concrete panel, joint material, etc. can be appropriately changed as necessary without departing from the spirit of the present invention. It is also possible to devise a method (pressing at high temperature and high pressure) to prevent ultra-fine air bubbles from being contained inside the base material of the curved resin concrete panel.

The thin-walled cylindrical structure of the present invention has the excellent effects described above, and can be suitably used as a thin-walled cylindrical structure in which curved resin concrete panels with a curvature matching the diameter of a circular waterway tunnel are connected with a high-strength adhesive to obtain a structure that is safe against the internal water pressure and external pressure applied to the circular waterway tunnel, and has excellent watertightness and durability.

10: Thin-walled cylindrical structure 20: Curved resin concrete panel 30: Joint material

Claims (2)

A thin-walled cylindrical structure formed by connecting a plurality of curved resin concrete panels formed when reinforcing and repairing a waterway tunnel into a cylindrical ring shape ,
A plurality of curved resin concrete panels having a predetermined radius of curvature that matches the inner wall diameter of the waterway tunnel to be reinforced or repaired;
The curved resin concrete panel is provided with a joint material that fills and adheres to the joint gap between the curved resin concrete panel and the curved resin concrete panel,
The joint material is an epoxy resin-based sealant for wet surface application, and employs at least one hardener selected from an amine-based hardener, an anhydride-based hardener, a phenol-based hardener, and a polyhydric alcohol-based hardener as a hardener required for curing the epoxy resin;
A curved resin concrete panel connected thin-walled cylindrical structure, characterized in that the adhesive strength between the curved resin concrete panel and the joint material is 16.8 N/mm2 or more, which is greater than the tensile strength of the curved resin concrete panel ^itself . A tunnel reinforcement and repair method using a curved resin concrete panel having any curvature,
A step of temporarily installing a plastic spacer and a height adjustment member on the existing concrete structure so as to be placed on the plastic spacer, and then temporarily installing a curved resin concrete panel;
A step of installing the curved resin concrete panel, the plastic spacer, and the height adjustment member to an anchor embedded in the existing concrete structure side by countersunk bolt fastening;
A tunnel reinforcement and repair method using curved resin concrete panels as described in claim 1, characterized in that it includes a process of filling and adhering joint gaps between the curved resin concrete panels with joint material.

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