JP2013087427A - Earthquake strengthening structure of building - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an earthquake strengthening structure of a building that increases the shearing transmission of a staircase room.SOLUTION: There is provided the earthquake strengthening structure of the building that uses an upper staircase 21 and a lower staircase 22 constituting a dog-legged staircase 20 as a shearing transmission member. The earthquake strengthening structure includes a reinforcing beam 11 orthogonal to moving-up/down directions of the upper staircase 21 and lower staircase 22, and the reinforcing beam 11 is installed horizontally along an under surface of a stair landing 23 at a joint part among the upper staircase 21, lower staircase 22, and stair landing 23, and connects the upper staircase 21 and lower staircase 22.

Description

  The present invention relates to a seismic reinforcement structure for buildings.

When an existing building is seismically reinforced, it is common to install seismic walls and braces on the column beam frame.
If a seismic wall, braces, etc. are installed on a building in service, the living space may be narrowed or the view may be obstructed. Therefore, it may be difficult to obtain understanding from residents and users.

  On the other hand, since the staircase is a common part, it is easy to obtain an understanding from residents when installing reinforcing members, and by reinforcing the staircase, the amount of seismic reinforcement in other parts of the building Can be reduced.

  Therefore, Patent Document 1 discloses an earthquake-resistant reinforcement structure that uses a staircase as an earthquake-resistant element by attaching a plate-like reinforcing member to the top surface of the staircase landing or the bottom surface of the staircase.

JP 2005-76262 A

  In general, it was evaluated that the staircase portion had an opening on the floor surface and had poor shear transfer capability and had a limited reinforcing effect.

  This invention solves the said problem, and makes it a subject to propose the earthquake-proof reinforcement structure of the building which made it possible to raise the shear transmission capability of a staircase.

  In order to solve the above-mentioned problem, the earthquake-proof reinforcement structure for a building according to claim 1 uses the upper and lower staircase portions constituting the folded staircase as shear transmission members, and is a reinforcement perpendicular to the ascending / descending direction of the staircase portion. The reinforcing beam is horizontally mounted along the lower surface of the landing at the joint between the staircase and the landing.

  According to the seismic reinforcement structure of such a building, the upper and lower staircase portions are connected via the reinforcing beam, thereby functioning as a shearing force transmission member. Therefore, the shear transmission capability of the staircase is improved.

  Further, the seismic reinforcement structure for a building according to claim 2 uses the upper and lower staircase portions constituting the folded staircase as a shear transmission member, and is provided between the upper staircase portion and the lower staircase portion. It is characterized by having a formed seismic wall.

  According to the seismic reinforcement structure of such a building, the upper and lower staircase portions function as a shearing force transmission member by being connected via the earthquake-resistant wall. Therefore, the shear transmission capability of the staircase is improved.

  Furthermore, the seismic reinforcement structure for a building of claim 3 uses the upper and lower stairs constituting the folded stairs as a shear transmission member, and is characterized by including a reinforcement slab that covers the lower surface of the landing.

  According to the seismic reinforcement structure for such a building, the upper and lower staircase portions function as a shearing force transmission member by being connected via a landing reinforced by a reinforcing slab. Therefore, the shear transmission capability of the staircase is improved.

  According to the seismic reinforcement structure of a building of the present invention, it is possible to increase the shear transmission capability of the staircase.

It is a figure which shows the earthquake-proof reinforcement structure of the building which concerns on 1st embodiment, Comprising: (a) is sectional drawing, (b) is an AA arrow line view of (a). (A) is a plane sectional view of the existing building provided with the earthquake-proof reinforcement structure of FIG. 1, (b) is a plane sectional view of the existing building provided with the conventional earthquake-resistant structure. It is a figure which shows the earthquake-proof reinforcement structure of the building which concerns on 2nd embodiment, Comprising: (a) is sectional drawing, (b) is a BB arrow line view of (a). (A) is a plane sectional view of the existing building provided with the earthquake-proof reinforcement structure of FIG. 3, (b) is a plane sectional view of the existing building provided with the conventional earthquake-resistant structure. It is a figure which shows the earthquake-proof reinforcement structure of the building which concerns on 3rd embodiment, Comprising: (a) is sectional drawing, (b) is a perspective view. (A) is a plane sectional view of the existing building provided with the earthquake-proof reinforcement structure of FIG. 5, (b) is a plane sectional view of the existing building provided with the conventional earthquake-resistant structure. It is a figure which shows the seismic reinforcement structure of the building which concerns on 4th embodiment, Comprising: (a) is sectional drawing, (b) is CC arrow view of (a), (c) is a formwork jig | tool FIG.

<First embodiment>
As shown in FIGS. 1A and 1B, the earthquake-proof reinforcement structure for a building according to the first embodiment includes a reinforcing beam 11 that is horizontally installed in the staircase 2 of the existing building 1.

As shown in FIG. 2A, the existing building 1 of the present embodiment is a concrete building having a rectangular shape in plan view, and the interior is divided into a staircase 2 and a living space 3.
In addition, the planar shape of the existing building 1 is not limited to a rectangular shape. Further, the arrangement and installation location of the staircase 2 are not limited.

  The existing building 1 is surrounded by side walls 4, 4,... And a boundary wall 5 is formed at the boundary between the staircase 2 and the living space 3.

The side walls 4 and 4 and the boundary wall 5 on the left and right sides (both ends in the X direction) of the existing building 1 are earthquake-resistant walls 10 to which earthquake-proof reinforcement has been applied. The earthquake-resistant wall 10 (side walls 4 and 4 and boundary wall 5) may be constructed by reinforcing existing walls, or may be constructed by removing existing walls.
In the living space 3, each level is divided by a floor slab 6.

A folded staircase 20 is formed inside the staircase 2.
As shown in FIGS. 1A and 1B, the folded staircase 20 includes an upper staircase portion (hereinafter simply referred to as “upper staircase”) 21 and a lower staircase portion (hereinafter simply referred to as “upper staircase”). 22) and a landing 23 to which the upper stairs 21 and the lower stairs 22 are connected.
A beam 24 is formed at the junction between the landing 23 and the side wall 4.

The reinforcing beam 11 is laid along the lower surface of the landing 23 at the joint between the staircase portions 21 and 22 and the landing 23.
The reinforcing beam 11 is orthogonal to the ascending / descending direction of the stair portions 21 and 22 and connects the lower end of the upper stair 21 and the upper end of the lower stair 22.

  One end of the reinforcing beam 11 is connected to the side wall 4, and the other end is connected to the boundary wall 5. That is, the reinforcing beam 11 of the present embodiment is laid horizontally with both ends connected to the earthquake resistant wall 10.

  Although not shown in FIG. 1, the reinforcing beam 11 is also laid across the upper end of the upper stair 21 and the lower end of the lower stair 22. That is, in addition to the landing 23 connected to the floor of each floor, the reinforcing beam 11 is also laid across the landing 23 formed at an intermediate height between the upper floor and the lower floor.

Although the method of forming the reinforcing beam 11 is not limited, in this embodiment, after anchors are planted on the lower surface of the landing 23 and the reinforcing beams 11 are arranged, the formwork is installed and the concrete is placed. It is formed by casting.
A precast member may be used as the reinforcing beam 11. Further, the reinforcing beam 11 may be formed using a half precast member or a discarded formwork.

  According to the seismic reinforcement structure of a building of this embodiment, since the upper stair 21 and the lower stair 22 are connected by the reinforcing beam 11, the upper stair 21 and the lower stair 22 can be used as a shear transmission member. Therefore, when the side wall 4 adjacent to the upper staircase 21 (the outer wall located on the opposite side of the boundary wall 5 across the staircase 2) is used as the earthquake resistant wall 10, the reinforcing effect can be expected.

  That is, when an external force in the Y direction acts on the existing building 1, the shearing force from the side wall 4 (seismic wall 10) is transmitted to the reinforcing beam 11 through the lower stair 22, and passes from the reinforcing beam 11 to the upper stair 21. Then, it is transmitted to the boundary wall 5 (seismic wall 10) (see (a) of FIG. 2).

As described above, since the staircase 2 can be used as a seismic reinforcement part, the amount of reinforcement to other parts is reduced as compared with the conventional seismic reinforcement structure (see FIG. 2B). be able to.
As shown in FIG. 2 (b), the conventional seismic reinforcement structure is evaluated to have an opening in the floor surface of the staircase 102. Therefore, the side wall 104 adjacent to the staircase 102 is reinforced. However, it is not possible to expect a reinforcing effect on the building main body, and therefore it is necessary to increase the amount of reinforcement of the seismic walls 110, 110 (side walls 104, boundary walls 105) formed on the left and right sides of the living space 103. As a result, the living space 103 is narrowed.

  Since the staircase 2 is a shared part, it is easy to obtain an understanding of reinforcement even in a separately owned building. Moreover, it becomes possible to reduce the burden on a user by reducing the reinforcement amount to parts other than the staircase 2. FIG.

<Second Embodiment>
As shown in FIGS. 3A and 3B, the building earthquake-proof reinforcement structure of the second embodiment includes a reinforcement wall 12 formed in the staircase 2 of the existing building 1.

The existing building 1 of this embodiment is a concrete building having a rectangular shape in plan view as shown in FIG. 4A, and the interior is divided into a staircase 2 and a living space 3.
The details of the existing building 1 are the same as the contents shown in the first embodiment, and thus detailed description thereof is omitted.

A folded staircase 20 is formed inside the staircase 2.
As shown in FIGS. 3A and 3B, the folded staircase 20 includes an upper staircase portion (hereinafter simply referred to as “upper staircase”) 21 and a lower staircase portion (hereinafter simply referred to as “upper staircase”). 22) and a landing 23 to which the upper stairs 21 and the lower stairs 22 are connected.
A beam 24 is formed at the junction between the landing 23 and the side wall 4.

  The reinforcing wall 12 is a so-called earthquake resistant wall, and is formed between the upper step 21 and the lower step 22 so as to be parallel to the left side wall 4 and the boundary wall 5 (along the Y direction). That is, the reinforcing wall 12 connects the upper and lower stairs 21 and 22 arranged vertically. The end face of the reinforcing wall 12 is connected to the landing 23, and is positioned diagonally below the landing 23 and another landing located diagonally above the landing 23 (a landing located between the upper floor and the lower floor). It is also connected to other landings (a landing located between the upper and lower floors).

The reinforcing wall 12 is formed by using an existing handrail portion formed in the staircase 2. That is, it is formed by reinforcing the handrail portion with earthquake resistance and extending the wall portion as necessary.
In addition, the formation method of the reinforcement wall 12 is not limited, For example, the existing handrail part may be removed and it may newly construct | assemble.

  According to the seismic reinforcement structure of a building of the present embodiment, the upper stair 21 and the lower stair 22 are connected by the reinforcing wall 12, and therefore the upper stair 21 and the lower stair 22 can be used as a shear transmission member. Therefore, when the side wall 4 adjacent to the upper staircase 21 (the outer wall located on the opposite side of the boundary wall 5 across the staircase 2) is used as the earthquake resistant wall 10, the reinforcing effect can be expected.

  That is, when an external force in the Y direction acts on the existing building 1, the shearing force from the side wall 4 (seismic wall 10) is transmitted to the reinforcing wall 12 through the lower stair 22 and passes from the reinforcing wall 12 through the upper stair 21. Then, it is transmitted to the boundary wall 5 (seismic wall 10) (see FIG. 4A).

As described above, since the staircase 2 can be used as a seismic reinforcement part, the amount of reinforcement to other parts is reduced as compared with the conventional seismic reinforcement structure (see FIG. 4B). be able to.
As shown in FIG. 4B, the conventional seismic reinforcement structure is evaluated as having an opening in the floor surface of the staircase 102. Therefore, the seismic walls 110 and 110 formed on the left and right sides of the living space 103 are used. It is necessary to increase the amount of reinforcement of the (side wall 104, boundary wall 105). As a result, the living space 103 is narrowed.

  Since the staircase 2 is a shared part, it is easy to obtain an understanding of reinforcement even in a separately owned building. Moreover, it becomes possible to reduce the burden on a user by reducing the reinforcement amount to parts other than the staircase 2. FIG.

<Third embodiment>
As shown in FIGS. 5A and 5B, the building earthquake-proof reinforcement structure of the third embodiment includes a reinforcement slab 13 formed in the staircase 2 of the existing building 1.

The existing building 1 of the present embodiment is a concrete building and includes two staircases 2 and 2 and a living space 3 as shown in FIG. The staircases 2 and 2 are connected to the rear side surface (upper surface in the drawing) of the building body (residential space 3).
In addition, the planar shape of the existing building 1 is not limited. Further, the arrangement and installation location of the staircase 2 are not limited.

The existing building 1 is surrounded by side walls 4, 4,.
A part (corner part) of the side wall 4 on the front side (the lower side in the drawing) of the existing building 1 of the present embodiment is subjected to earthquake-proof reinforcement, and the earthquake-resistant wall 10 is formed.
The side wall 4 on the rear side (upper side in the drawing) of the staircase 2 is seismically reinforced and is constituted by a seismic wall 10.

  In the living space 3, each level is divided by a floor slab 6.

A folded staircase 20 is formed inside the staircase 2.
As shown in FIGS. 5A and 5B, the folded staircase 20 includes an upper staircase portion (hereinafter simply referred to as “upper staircase”) 21 and a lower staircase portion (hereinafter simply referred to as “upper staircase”). 22) and a landing 23 to which the upper stairs 21 and the lower stairs 22 are connected.
A beam 24 is formed at the junction between the landing 23 and the side wall 4.

The reinforcing slab 13 is formed so as to cover the lower surface of the landing 23.
The reinforcing slab 13 is connected to the lower end of the upper stair 21 and the upper end of the lower stair 22 via a landing 23.
5 is the landing 23 formed between the upper floor and the lower floor, but the reinforcing slab 13 is also formed on the lower surface of the landing 23 connected to the floor of each floor.

Although the formation method of the reinforcement slab 13 is not limited, in this embodiment, after anchors are planted on the lower surface of the landing 23 and the reinforcement slab 13 is arranged, the formwork is installed and the formwork is installed. It is formed by placing concrete inside.
Note that a precast member may be fixed to the lower surface of the landing 23 as the reinforcing slab 13.

  According to the seismic reinforcement structure of a building of this embodiment, the reinforcing slab 13 provided on the lower surface of the landing 23 is connected to the upper staircase 21 and the lower staircase 22, so that the upper staircase 21 and the lower staircase 22 are shear-transmitted. Therefore, when the side wall 4 adjacent to the staircase 2 (the outer wall located on the opposite side of the living space 3 across the staircase 2) is used as the earthquake resistant wall 10, the reinforcing effect is obtained. You can expect.

  That is, when an external force in the X direction acts on the existing building 1, the shearing force from the side wall 4 (seismic wall 10) is transmitted from the reinforcing slab 13 to the upper stairs 21 and the lower stairs 22, and the upper stairs 21 or the lower stairs. 22 is transmitted to the reinforcing slab 13 on the opposite side via 22 (see FIG. 6A).

As described above, since the staircase 2 can be used as a seismic reinforcement part, the amount of reinforcement to other parts is reduced as compared with the conventional seismic reinforcement structure (see FIG. 6B). be able to.
As shown in FIG. 6B, in the conventional seismic reinforcement structure, since the staircase 102 is evaluated as having an opening on the floor surface, each corner of the living space 103 with respect to an external force in the X direction. It is necessary to increase the amount of reinforcement of the entire building by forming earthquake-resistant walls 110, 110,. As a result, the living space 103 is narrowed.

  Since the staircase 2 is a shared part, it is easy to obtain an understanding of reinforcement even in a separately owned building. Moreover, it becomes possible to reduce the burden on a user by reducing the reinforcement amount to parts other than the staircase 2. FIG.

<Fourth embodiment>
As shown in FIG. 7, the building earthquake-proof reinforcement structure according to the fourth embodiment is different from the building earthquake-proof reinforcement structure of the first embodiment in that it includes a column 25 that penetrates the landing 23. .

  The pillar 25 penetrates the landing 23 and the reinforcing beam 11 at the joint between the upper stair 21 and the lower stair 22 of the landing 23. The column 25 functions as a support member and also functions as a handrail.

  Although the pillar 25 of this embodiment is comprised with a steel pipe, the material which comprises the pillar 25 is not limited.

  As shown in FIGS. 7A and 7B, the column 25 is fixed to the landing 23 via an attachment member 26.

  The attachment member 26 includes base plates 26a and 26a disposed so as to sandwich the landing 23 from above and below, and anchor bolts 26b, 26b and 26b for fixing the upper and lower base plates 26a and 26a.

The base plate 26a is a substantially triangular steel plate, and a through hole through which the pillar 25 passes is formed in the center, and a through hole through which the anchor bolt 26b passes is formed at each corner.
The shape of the base plate 26a is not limited.

The anchor bolt 26b penetrates the landing 23 and fixes the upper and lower base plates 26a, 26a.
In addition, it may replace with the anchor bolt 26b and a chemical anchor may be employ | adopted and the fixing method of the base plate 26a is not limited. Further, the arrangement and number of anchor bolts 26b are not limited.

  Since the structure of the seismic reinforcement structure of the building of the other fourth embodiment is the same as the contents shown in the first embodiment, detailed description thereof is omitted.

  Although the method of forming the reinforcing beam 11 is not limited, in the present embodiment, after the mold frame 30 is installed via the mold jig 27 fixed to the column 25 and the reinforcing beam 11 is arranged. It is formed by placing concrete in the mold 30.

  As shown in FIG. 7C, the mold jig 27 includes a fixing member 27a and a separator 27b.

  The fixing member 27a of the present embodiment is formed of an angle (section steel material) and is welded to the column 25. In addition, if the material which comprises the fixing member 27a can be fixed to the pillar 25, it will not be limited to a shape steel material. Moreover, the fixing method of the fixing member 27a is not limited.

The separator 27b has an upper end fixed to the shape steel 27a and holds the mold 30 at the lower end.
A cone 27c for holding the upper surface of the mold 30 is fixed to the lower end of the separator 27b.
The mold 30 is held by a cone 27c disposed on the upper surface and a fastener 27d disposed on the lower surface.

  In addition, if the filling hole 25a is formed in the position corresponding to the reinforcing beam 11 of the steel pipe which comprises the pillar 25, when placing concrete of the reinforcing beam 11, the pillar 25 can be utilized. Further, the column 25 and the reinforcing beam 11 are integrally joined through the filling hole 25a.

By using the column 25, the installation of the form 30 of the reinforcing beam 11 is facilitated, so that the workability is improved.
Moreover, the reinforcement effect by the pillar 25 can also be expected.

Since the other effects of the seismic reinforcement structure of the building of this embodiment are the same as the contents shown in the first embodiment, detailed description is omitted.
In addition, in the earthquake-proof reinforcement structure of the building of this embodiment, it may replace with the reinforcement beam 11 and may employ | adopt a reinforcement slab (refer FIG. 5).

  The preferred embodiments of the present invention have been described above. However, the present invention is not limited to the above-described embodiment, and the above-described constituent elements can be appropriately changed without departing from the spirit of the present invention.

1 Existing building 11 Reinforcement beam 12 Reinforcement wall (seismic wall)
13 Reinforced slab 2 Staircase 20 Folding stairs 21 Upper stairs (staircase)
22 Lower stairs (stairs)
23 landing

Claims (3)

It is a seismic reinforcement structure for buildings that uses the upper and lower stairs constituting the folded stairs as shear transmission members,
Comprising a reinforcing beam orthogonal to the elevating direction of the staircase,
An earthquake-proof reinforcement structure for a building, wherein the reinforcing beam is laid across the lower surface of the landing at the joint between the staircase and the landing. It is a seismic reinforcement structure for buildings that uses the upper and lower stairs constituting the folded stairs as shear transmission members,
A seismic reinforcement structure for a building, comprising a seismic wall formed between the upper staircase and the lower staircase. It is a seismic reinforcement structure for buildings that uses the upper and lower stairs constituting the folded stairs as shear transmission members,
A seismic reinforcement structure for buildings, comprising a reinforcement slab that covers the underside of the landing.

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