JP2014173319A - Aseismic reinforcement structure and aseismic reinforcement method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an aseismic reinforcement structure and an aseismic reinforcement method capable of shortening a construction period without hindering an aseismic reinforcement function while curbing noise, vibration and scatter of dust.SOLUTION: A PCa reinforcement frame 20 (a reinforcement column 22 and a reinforcement beam 23) to reinforce a building 1 is joined to an existing beam 5 and an existing column 7 of the building 1 through a PCa slab 30 (a column side PCa slab 33 and a beam side PCa slab 34). Joint cotters 27 (building side joint cotters 28 and reinforcement side joint cotters 29) are embedded in joint sections between the PCa slab 30 (the column side PCa slab 33 and the beam side PCa slab 34) and the building 1 and between the PCa slab 30 (the column side PCa slab 33 and the beam side PCa slab 34) and the reinforcement frame 20 (the reinforcement column 22 and the reinforcement beam 23).

Description

  The present invention relates to a seismic reinforcement structure and a seismic reinforcement method.

  Traditionally, buildings have been earthquake resistant. The earthquake-resistant structure is designed to resist the horizontal force that the building receives during an earthquake by increasing the strength of the members that make up the building. The seismic structure is applied not only to new buildings but also to existing buildings as seismic reinforcement. Seismic reinforcement (seismic structure) varies depending on the type of building. When it is difficult to reinforce indoors, there are cases where a reinforcing member such as a reinforcing frame is provided outside the building.

  As a construction method of earthquake-proof reinforcement in which a reinforcing member is provided on the outside of a building, for example, there is a construction method of an outer frame for earthquake-proof reinforcement described in Patent Document 1 below. According to this method, a plurality of reinforcing column units and reinforcing beam units are assembled to form the outer frame, and the outer frame and the existing building are connected by the connection slab. This connecting slab is concrete cast at the construction site.

Japanese Patent Publication No. 2005-155139

  However, since the construction method of the above-mentioned seismic reinforcement outer frame is formed by casting concrete using connecting slabs, post-construction anchors and joint reinforcing bars, drilling with a drill to strike post-construction anchors, Noise, vibration, and dust impact on building residents and nearby residents during construction work, such as reinforcing bars, and the length of the construction period are problems.

  The present invention has been proposed in view of the above circumstances. In other words, the seismic reinforcement structure and seismic reinforcement construction method that can minimize the stress on the residents by reducing the construction period without impairing the seismic reinforcement function while suppressing noise, vibration, and dust scattering. For the purpose of provision.

  The seismic retrofit structure according to the present invention is a seismic retrofit structure in which a precast concrete reinforcing frame for reinforcing the building is attached to the outside of the building, between the precast concrete reinforcing frame and the outside of the building. The slab of precast concrete is arranged, and the slab of precast concrete is joined to the outside of the building by a joining cotter buried in the joint with the outside of the building and joined to the reinforcing frame of the precast concrete. It is characterized by being joined to the precast concrete reinforcing frame by a joining cotter buried in the part.

  The seismic reinforcement structure according to the present invention is a seismic reinforcement structure in which a precast concrete reinforcement frame for reinforcing the building is attached to the outside of the building, wherein the precast concrete reinforcement frame is connected to the outside of the building. It is characterized in that it is joined to the outside of the building by a joining cotter buried in the joint part.

  Further, the seismic reinforcement method according to the present invention is a seismic reinforcement method in which a precast concrete reinforcing frame for reinforcing the building is attached to the outside of the building. A precast concrete slab installation step embedded in a joint with the building and joined to the outside of the building, a precast concrete reinforcing frame, and a second joint cotter joined to the other end of the precast concrete slab. And a step of installing a precast concrete reinforcing frame that is embedded in a part and joined to the other side of the slab of the precast concrete.

  Further, in the seismic reinforcement method of attaching a precast concrete reinforcing frame for reinforcing the building to the outside of the building, an anchoring process for filling the other end of the first joining cotter on the outside of the building, and the first Inserting and filling one end of the joining cotter into a joining groove formed on one side of the precast concrete slab, and joining one side of the precast concrete slab to the outside of the building; The other end of the second joining cotter, one end of which is buried in the precast concrete reinforcing frame, is inserted into the joining groove formed on the other side of the slab of the precast concrete and buried, and the precast concrete reinforcing frame is used as the precast concrete. The other end of the slab Bonding, including a reinforcing frame provision step of precast concrete, is characterized in that.

  The earthquake-proof reinforcement structure and the earthquake-proof reinforcement method according to the present invention have the above-described configuration. According to this configuration, since the slab of precast concrete is used, the concrete placing operation at the construction site is simplified. Therefore, the seismic reinforcing structure and the seismic reinforcing method can shorten the construction period.

  In particular, in the seismic reinforcement structure and the seismic reinforcement method, a junction cotter is buried in the junction. Therefore, the seismic reinforcement structure and the seismic reinforcement method can suppress noise, vibration, and dust scattering, and can minimize the stress on the occupants.

1 is a schematic external view of a seismic reinforcement structure according to an embodiment of the present invention. It is a schematic sectional drawing of the building provided with the earthquake-proof reinforcement structure which concerns on embodiment of this invention. It is a schematic sectional drawing of the building provided with the earthquake-proof reinforcement structure which concerns on embodiment of this invention. It is a figure which shows the earthquake-proof reinforcement construction method which concerns on embodiment of this invention, (a) is an anchor process, (b) is a slab installation process of precast concrete, (c) is a reinforcement frame installation process of precast concrete. It is a flowchart which shows the flow of the earthquake-proof reinforcement construction method which concerns on embodiment of this invention. It is the schematic of the surface of the building where the slab of precast concrete is joined in the process of the seismic reinforcement method according to the embodiment of the present invention.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 is a schematic external view of a seismic reinforcement structure 10 according to the present embodiment. In FIG. 1, the seismic reinforcement structure 10 according to the present embodiment has a structure in which a reinforcement frame 20 that reinforces the building is attached to the outside of the building (not shown). The reinforcing frame 20 is formed in a lattice shape, and includes a reinforcing foundation 21, reinforcing columns 22, and reinforcing beams 23. The reinforcement foundation 21 is cast-in-place concrete. The reinforcing column 22 and the reinforcing beam 23 are both precast concrete (hereinafter referred to as “PCa”).

  FIG. 2 is a cross-sectional view of the building 1 including the seismic reinforcement structure 10 according to the present embodiment. In FIG. 2, the building 1 is composed of an existing floor slab 4 constructed on an existing foundation 3, an existing pillar (not shown), and an existing beam 5. An opening (window) 6 is formed in the building 1, and the veranda 2 protrudes from the opening (window) 6. The building 1 is provided with a reinforcing frame 20 with the veranda 2 in between. In the reinforcing frame 20, the reinforcing foundation 21 is placed corresponding to the existing foundation 3 of the building 1, the reinforcing pillar 22 faces the existing pillar of the building 1, and the reinforcing beam 23 faces the existing beam 5 of the building 1. Yes.

  The building 1 and the reinforcing frame 20 are joined by a PCa slab 30. The PCa slab 30 is a rectangular flat plate, and is disposed directly below the veranda 2 and joined to the existing beam 5 and the reinforcing beam 23. In each of the PCa slabs 30, the side joined to the existing beam 5 is “one side”, and the side joined to the reinforcing frame 20 (the reinforcing beam 23 and the reinforcing column 22) is “the other side” (FIG. 4). (See (a)).

  In FIG. 2, the PCa slab 30, the building 1, and the reinforcing frame 20 are joined by a joining cotter 27. The joining cotter 27 is a substantially cylindrical steel pipe or a columnar PCa, and has a diameter larger than that of the post-construction anchor. The joining cotter 27 includes a building side joining cotter 28 (first joining cotter) and a reinforcing side joining cotter 29 (second joining cotter). The building-side joint cotter 28 is buried in and joined to the joint between the PCa slab 30 and the existing beam 5, while the reinforcement-side joint cotter 29 is joined to the PCa slab 30, the reinforcement beam 23, and the reinforcement column 22. It is buried in the part and these are joined. The joint portion by the joining cotter 27 (28, 29) is filled with non-shrink mortar.

  In addition, the proof stress of the junction part by the joining cotter 27 (28, 29) is determined by the proof stress of the steel pipe and the surrounding concrete. The proof strength of the joining cotter 27 (28, 29) is the bearing pressure failure of the concrete of the building 1, the shear breaking force of the concrete of the building 1, the bearing failure of the reinforcing frame 20 (23, 22), and the reinforcing frame 20 (23, 22). ) Of the shear fracture strength and the shear strength of the steel pipe.

  In each of the building-side joining cotters 28, the side buried in the existing beam 5 is the “other end”, and the side to which one side of the PCa slab 30 is attached is the “one end” (see FIG. 4A). On the other hand, in each of the reinforcing side joining cotters 29, the side embedded in the reinforcing frame 20 (reinforcing beam 23, reinforcing column 22) is “one end”, and the side attached to the other side of the PCa slab 30 is “other end” (see FIG. 4 (b)).

  In FIG. 4, the PCa slab 30 includes a column side PCa slab 33 and a beam side PCa slab 34. The column-side PCa slab 33 joins the existing column 7 and the reinforcing column 22 of the building 1, while the beam-side PCa slab 34 joins the existing beam 5 and the reinforcing beam 23 of the building 1.

  A substantially cylindrical one-side groove 31 into which the building-side joining cotter 28 is inserted is formed on one side of the PCa slab 30 (33, 34). On the other hand, on the other side of the PCa slab 30 (33, 34), a substantially cylindrical other side groove 32 into which the reinforcing side joining cotter 29 is inserted is formed. Both grooves 31 and 32 are formed in the same number so as to be symmetrical. The column-side PCa slab 33 is formed with the same number of anchor holes 35 on one side and the other side so as to be symmetrical. The length of the PCa slab 30 (33, 34) is appropriately changed according to the stress and the amount of deflection. Further, the number of the grooves 31 and 32 is appropriately increased and decreased as the number of the joining cotters 27 is increased and decreased according to the shearing force.

  Here, when the veranda is not formed in the building, as shown in FIG. 3, the reinforcing pillars 22 and the reinforcing beams 23 of the reinforcing frame 20 are joined to the existing beams 5 and the existing pillars 7 through a joining cotter 27. . The junction cotter 27 is embedded in the junction.

  The above is the earthquake-proof reinforcement structure 10 which concerns on this embodiment. The horizontal force received by the building 1 during an earthquake is transmitted to the reinforcing frame 20 (23, 22) via the joining cotter 27 (28, 29) and the non-shrink mortar. That is, the joining cotter 27 (28, 29) directly transmits the force without using a stud or a joining plate.

  Next, the seismic reinforcement method according to this embodiment will be described.

  FIG. 5 is a flowchart showing the flow of the seismic reinforcement method. In FIG. 5, the seismic reinforcement construction method includes at least a basic process 40, a ground treatment process 41, an anchor process 42, a PCa slab installation process 43, a reinforcement frame installation process 44, and a finishing process 45.

  In the foundation process 40, in FIG. 2, foundation slabs and piles are used according to the ground of the building 1, and reinforcing foundations 21 such as slabs and connecting beams are placed corresponding to the existing foundation 3.

In the ground processing step 41, in FIG. 6, the mortar for coating finish, the tile for finishing tension, and the like are removed from the existing beam 5 and the existing column 7 to which the PCa slab 30 is joined, and roughened. A portion surrounded by a broken line in FIG. When the compressive strength (design standard strength Fc) of the mortar is 15 N / mm ² or more and the coating thickness is 30 mm or less, the mortar removal and the roughening treatment on the existing beam 5 are unnecessary.

  In the anchoring step 42, the building-side joining cotter 28 and the post-construction anchor 9 are driven into the building 1 in order to join the PCa slabs 30 (33, 34) in FIG. More specifically, grooves for inserting and filling the other end of the joining cotter 28 in the existing beam 5 are formed at substantially equal intervals by a rotary core drill or the like. The groove is about 80φ and about 30 mm deep. The other end of the building-side joining cotter 28 is inserted into this groove, and the building-side joining cotter 28 is buried in the existing beam 5 and fixed with an adhesive with one end protruding from the existing beam 5. On the other hand, the post-construction anchor 9 is hit to the existing column 7 and the existing beam 5 in the vicinity thereof. In addition, the groove | channel and depth for inserting the joining cotter 28 can be changed suitably.

  In the PCa slab installation step 43, the PCa slab 30 (33, 34) is joined to the existing beam 5 and the existing column 7. More specifically, one side groove 31 of the beam side PCa slab 34 is attached to one end of the building side joining cotter 28 whose other end is buried in the groove of the existing beam 5, and one end of the building side joining cotter 28 is inserted into the one side groove 31. To fill it up. On the other hand, one side groove 31 of the column side PCa slab 33 is attached to one end of the building side joining cotter 28, and one end of the building side joining cotter 28 is inserted into the one side groove 31 so as to be buried. The anchor hole 35 is attached to the post-construction anchor 9, and the post-construction anchor 9 is inserted into the anchor hole 35. The non-shrink mortar is filled into the one-side groove 31 into which the building-side joining cotter 28 is inserted and the anchor hole 35 into which the post-installed anchor 9 is inserted, and the PCa slab 30 (34, 34), the existing beam 5 and the existing column 7 Fill with non-shrink mortar. In the PCa slab installation step 43, a support for supporting the PCa slab 30 (33, 34) is appropriately used.

  Here, the one-side groove 31 is formed by a rotary core drill or the like, similar to the groove formed in the anchoring step 42 described above. Depending on the case, you may form at the time of concrete placement.

  A PC steel material (not shown) is inserted into a sheath (not shown) embedded in the PCa slab 30 (33, 34), and this PC steel material penetrates the adjacent PCa slab 30 (33, 34). The PC steel material penetrated is strained with a jack and the grout material is injected into the sheath. Moreover, grout material is inject | poured into the joint (joint) of PCa slabs 30 (33, 34) as joint processing.

  In the reinforcing frame installation step 44, in FIG. 4B, the reinforcing pillars 22 and the reinforcing beams 23 are assembled on the reinforcing foundation 21 and joined to the PCa slabs 30 (33, 34) (see FIG. 2). One end of the reinforcing side joining cotter 29 is embedded in the reinforcing beam 23, while one end of the reinforcing side joining cotter 29 is embedded in the reinforcing column 22, and the post-construction anchor 9 is hit. That is, the reinforcing beam 23 and the reinforcing column 22 are manufactured in a state where one end of the reinforcing side joining cotter 29 is embedded.

  In FIG. 4C, the other end of the reinforcing-side joining cotter 29 and the post-installed anchor 9 are inserted into the other-side groove 32 and the anchor hole 35 of the column-side PCa slab 33, and the reinforcing column 22 is embedded. It joins to the other side of the column side PCa slab 33. On the other hand, the other end of the reinforcing-side joining cotter 29 is inserted into the other-side groove 32 of the beam-side PCa slab 34 so as to be buried, and the reinforcing beam 23 is joined to the other side of the beam-side PCa slab 34. The other side groove 32 into which the reinforcing side joining cotter 29 is inserted and the anchor hole 35 into which the post-installed anchor 9 is inserted are filled with non-shrink mortar, and the PCa slab 30 (34, 34), the reinforcing column 22 and the reinforcing beam 23 Fill with non-shrink mortar. In addition, the other side groove | channel 32 is formed with a rotary core drill etc. similarly to the above-mentioned one side groove | channel 31. FIG. Depending on the case, you may form at the time of concrete placement.

  A PC steel material is inserted into the sheath embedded in the reinforcing column 22 and the reinforcing beam 23, and the adjacent reinforcing column 22 and the reinforcing beam 23 are penetrated by the PC steel material. The PC steel material penetrated is strained with a jack and the grout material is injected into the sheath. Moreover, grout material is inject | poured into the joint (joint) of the reinforcement pillar 22 and the reinforcement beam 23 as joint treatment.

  The above steps are repeated for each layer.

  In the finishing process 45, the support work supporting the PCa slab 30 is removed, and other miscellaneous work is performed.

  As described above, the seismic reinforcement method is applied. In addition, among each process mentioned above, the work in the veranda 2 is from the ground treatment process 41 to the PCa slab installation process 43.

  Next, the effect of this embodiment will be described.

  As described above, according to the present embodiment, the building 1 and the reinforcing frame 20 (the reinforcing column 22 and the reinforcing beam 23) are joined by the PCa slab 30 (the column side PCa slab 33 and the beam side PCa slab 34). The building-side joining cotter 28 joins the PCa slab 30 (33, 34) to the existing beam 5 and the existing column 7, while the reinforcement-side joining cotter 29 reinforces the PCa slab 30 (33, 34). The column 22 and the reinforcing beam 23 are joined.

  According to this configuration, in this embodiment, since the respective members of PCa that have been placed in advance are assembled, the concrete placement work at the construction site is simplified. Therefore, this embodiment can shorten a construction period.

  Moreover, the work in the veranda 2 is from the ground treatment process 41 to the PCa slab installation process 43. Therefore, this embodiment can shorten the work in exclusive parts, such as the veranda 2, and can suppress the stress to a resident to the minimum.

  In particular, in this embodiment, a substantially cylindrical steel pipe or a columnar PCa joining cotter 27 (28, 29) is buried in the joint, and the joining cotter 27 (28, 29) is larger than the post-installed anchor 9. Is the diameter. The groove for inserting the joining cotter 27 (28, 29) is opened to, for example, about 80φ and a depth of about 30 mm by a rotary core drill or the like.

  With this configuration, since the groove into which the joining cotter 27 (28, 29) is inserted has a relatively large diameter, noise and vibration during opening can be suppressed, and stress on the occupant can be minimized.

In the present embodiment, when the compressive strength (design standard strength Fc) of the mortar is 15 N / mm ² or more and the coating thickness is 30 mm or less, the removal of the mortar and the roughening treatment on the existing beam 5 become unnecessary. Therefore, dust scattering during removal of the mortar can be suppressed.

  As mentioned above, although embodiment of this invention was explained in full detail, this invention is not limited to the said embodiment. The present invention can be modified in various ways without departing from the scope of the claims.

1 Building 2 Veranda 3 Existing Foundation 4 Existing Floor Slab 5 Existing Beam 6 Opening (Window)
7 Existing pillar 8 Surface roughening 9 Post-construction anchor 10 Seismic reinforcement structure 20 Reinforcement frame 21 Reinforcement foundation 22 Reinforcement pillar 23 Reinforcement beam 27 Joint cotter 28 Building side joint cotter 29 Reinforcement side joint cotter 30 PCa slab 31 One side groove 32 Other side groove 33 Column side PCa slab 34 Beam side PCa slab 35 Anchor hole 40 Fundamental process 41 Ground treatment process 42 Anchor process 43 PCa slab installation process 44 Reinforcement frame installation process 45 Finishing process

Claims (4)

In the seismic reinforcement structure in which the reinforcement frame of the precast concrete to reinforce this building is attached to the outside of the building,
A precast concrete slab is disposed between the precast concrete reinforcing frame and the outside of the building,
The slab of precast concrete is joined to the outside of the building by a joining cotter buried in the joint with the outside of the building, and the joint cotter buried in the joint with the reinforcing frame of the precast concrete Bonded to a precast concrete reinforcement frame,
Seismic reinforcement structure characterized by that. In the seismic reinforcement structure in which the reinforcement frame of the precast concrete to reinforce this building is attached to the outside of the building,
The reinforcing frame of the precast concrete was joined to the outside of the building by a joining cotter buried in the joint with the outside of the building.
Seismic reinforcement structure characterized by that. In the seismic reinforcement method of attaching a precast concrete reinforcement frame to reinforce this building on the outside of the building,
A precast concrete slab installation step in which one side of the precast concrete slab is embedded in the joint with the building and joined to the outside of the building;
A precast concrete reinforcing frame, a second joining cotter embedded in a joint with the other end of the precast concrete slab and joined to the other side of the precast concrete slab; and a precast concrete reinforcing frame installation step;
including,
Seismic reinforcement construction method characterized by that. In the seismic reinforcement method of attaching a precast concrete reinforcement frame to reinforce this building on the outside of the building,
An anchor step of filling the other end of the first joining cotter outside the building;
One end of the first joint cotter is inserted into a joint groove formed on one side of the slab of precast concrete and buried, and one side of the slab of precast concrete is joined to the outside of the building. Process,
The other end of the second joining cotter, one end of which is embedded in the precast concrete reinforcing frame, is inserted into a joining groove formed on the other side of the slab of the precast concrete and buried, and the precast concrete reinforcing frame is embedded in the precast concrete. A precast concrete reinforcing frame installation process to be joined to the other end of the concrete slab;
including,
Seismic reinforcement construction method characterized by that.

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