JP2009046966A5 - - Google Patents

Description

Seismic reinforcement method and reinforcement piece

  The present invention relates to a reinforcing method in seismic reinforcement work for existing buildings.

Some existing buildings do not satisfy the current building standards, and there are many that need to increase seismic strength. As techniques for increasing the seismic strength of such existing buildings, there are two methods: a method of adding reinforced concrete walls and a method of adding steel braces.
However, in the method of adding reinforced concrete walls, the opening is covered with the wall surface, so that there is a problem that lighting in the room is affected.
Therefore, when it is desired to open the interior of a building, it is common to perform seismic reinforcement by a method of adding steel braces.

As a method of seismic reinforcement using such a steel brace, methods as shown in Patent Documents 1 to 3 can be cited.
In Patent Document 1, as a method for seismic reinforcement of an opening of an RC structure, a shear panel is suspended from the upper side of a rectangular frame that fits in the opening, and the lower side of the rectangular frame is provided with the shear panel as a vertex. A method is shown in which a brace that forms a hypotenuse of a triangle is provided from the lower side toward the shear panel so that the portion forms a triangular shape that is the base.

Patent Document 2 discloses a method of assembling with a bolt after a unit obtained by dividing a steel frame into a plurality of units is suspended in a building frame at a reinforcement site as a steel frame assembling method.
In addition, in Patent Literature 3, as a steel brace reinforcement method for seismic reinforcement, a steel frame brace attached with a brace that forms a hypotenuse so that the upper side becomes the bottom side of a rectangular frame that fits in the opening is incorporated into the opening. There is shown a method characterized by injecting an adhesive into the contact surface between the frame and the opening and bonding them.
Japanese Patent Publication No. 7-51803 No. 7-26520 Japanese Patent Laid-Open No. 11-71906

However, the prior art has the following problems.
(1) Since a part of the opening is blocked by the steel brace, the scenery from the window may be damaged.
A steel brace that reinforces an existing building is generally configured by inserting a brace so as to form a triangle with respect to the opening. This is because the frame is resistant to deformation by reinforcing it in a triangular shape, but the brace that forms the hypotenuse requires an appropriate thickness.
However, by providing such a steel brace in the opening, the field of view of the opening is blocked by the brace portion that forms the hypotenuse.
Thus, since the reinforcement using the braces forming the hypotenuse does not block the entire opening, the opening is ensured, but when looking outside the window from the inside, the brace is damaged by the scenery. Moreover, although it looks strong in appearance, it may be damaged in terms of beauty.

(2) There is a possibility that it takes time and effort to transport and carry in the steel brace.
The size of a steel brace that reinforces an existing building is determined according to the opening. However, the opening in structures that require reinforcement, such as buildings, is often about 6m x 3m or larger, and the steel brace needs to be several meters in size. Is common.
Therefore, the weight of the steel brace itself is increased accordingly, and often has a weight of several tons, so that it is difficult to carry it manually.

However, if materials are brought into the site, aggregates are welded, and concrete is to be made from scratch, it will take days and special equipment will be required, resulting in poor work efficiency.
Moreover, when attaching a steel brace from the exterior of a building, if it uses a heavy machine, it can be attached comparatively easily, However Depending on a structure, the attachment from the inside may be required.
In this case, in order to carry the steel brace into the building, an opening of the size of the steel brace is necessary. If there is no carry-in entrance, a part of the building is demolished to secure the carry-in entrance, and then It needs to be restored again.

In addition, when a steel brace is inserted around the opening, if the opening is like an entrance to a building, a step will be created in the floor, which may cause problems such as obstacles to entry and exit or raising the entire floor. It was necessary to complete the construction.
Thus, in the conventional methods of Patent Document 1 to Patent Document 3, (1) a part of the opening is blocked and the scenery from the window is damaged, (2) it takes time to carry in the reinforcing member, ( 3) There was a problem such as a step formed on the floor of the opening.

  Therefore, the present invention has been made to solve such a problem, and provides an earthquake-proof reinforcement method and a reinforcement piece that can be easily carried in and can secure the opening of the opening without causing a step in the floor portion. The purpose is to do.

In order to achieve the above object, the seismic reinforcement method according to the present invention has the following characteristics.
(1) In the seismic retrofitting method for seismic reinforcement of a column beam frame composed of columns and beams of an existing building with a reinforcement unit ,
The reinforcement unit is configured in a gate shape by joining a plurality of reinforcement pieces symmetrically, and the plurality of reinforcement pieces are arranged at two corners of the portal shape and orthogonal to each other. Including two L-shaped reinforcing pieces each having two sides, and a prismatic I-shaped reinforcing piece connected so as to extend one side of each of the L-shaped reinforcing pieces. A steel material is used as a bone and is integrally formed by winding concrete around the steel material, and at one end of the L-shaped reinforcing piece, a joint that joins one end of the other L-shaped reinforcing piece The other end portion of the L-shaped reinforcing piece is provided with a joining portion that joins with one end portion of the I-shaped reinforcing piece, and the one end portion of the I-shaped reinforcing piece has the above-mentioned A joining portion that joins the other end of the L-shaped reinforcing piece is provided, and the two L The one end of the reinforcing piece is aligned with each other and bonded by the bonding portion, and the other end of the L-shaped reinforcing piece and the one end of the I-shaped reinforcing piece are aligned with each other to form the bonding portion. After joining by, the non-shrink mortar additional part is formed in the part of each joint part,
The portal-shaped reinforcing unit is configured by joining the plurality of reinforcing pieces symmetrically,
Thereafter, the portal-shaped reinforcing unit is inserted and fitted into the inner periphery of the rectangular opening of the column beam frame,
Then, the column beam frame and the reinforcing unit are integrated by filling a bonding agent between the column beam frame and the reinforcing unit.

Therefore, the portability of a reinforcement unit can be improved by employ | adopting the system which assembles a reinforcement unit combining a reinforcement piece.
In addition, since the reinforcing unit is configured in a gate shape, the opening is effective for the type of the floor type, and no step is generated in the floor portion.

(2) In the seismic reinforcement method described in (1),
The joint portion includes a bolt fastening side provided with a bolt fastening hole and a plate side provided with a bolt insertion hole.
The bolt fastening side joint provided at the one end of one L-shaped reinforcing piece and the plate side joint provided at the one end of the other L-shaped reinforcing piece are bolted. And the bolt fastening side or the plate side joint provided at the other end of each L-shaped reinforcing piece and the plate side provided at the one end of the I-shaped reinforcing piece Alternatively, the L-type reinforcing piece and the I-type reinforcing piece are integrated as the reinforcing unit by fastening the joint portion on the bolt fastening side with a bolt .

Therefore, since the reinforcement piece is provided with the bolt fastening side joint and the plate side joint is fastened with the assigned bolt to form an integrated reinforcement unit, it is easy to assemble the reinforcement piece at the site. By being coupled to, it is possible to obtain the necessary strength when disposed on the column beam frame.
In addition, the size of the opening to be reinforced in the existing building is measured in advance, a reinforcement piece that can constitute a reinforcement unit that matches the size is manufactured at the factory, and the reinforcement piece is brought into the field. Thus, the transportation cost can be reduced as compared with the case of transporting the integral reinforcing unit.
Furthermore, when carrying in an existing building, it is difficult to be restricted by the opening, so there is a possibility that a dedicated carry-in entrance may not be required.

(3) In the seismic reinforcement method described in (1) or (2),
The thickness of the frame constituting the reinforcing unit is thinner than the thickness of the pillar and the beam of the existing building,
One surface having an opening of the reinforcing unit and one surface having an opening of another adjacent reinforcing unit are located on substantially the same plane.
As a result, the reinforcement units attached to the plurality of column beam frames are in a state in which the columns are sandwiched between the adjacent reinforcement units. Therefore, in the portion sandwiched between the column reinforcement units, more than the simple addition of the columns and the reinforcement units. An effect will be obtained. For example, if there are adjacent units vertically and horizontally, the effect can be expected to be further enhanced.
Moreover, since the floor part comprised by a beam is reinforced by the reinforcement unit provided in the opening part of the lower part, it becomes possible to reinforce without generating a level | step difference.

(4) In the seismic reinforcement method described in any of (1) to (3),
The bonding agent filled between the column beam frame and the reinforcing unit is a non-shrink mortar,
A plurality of headed studs are welded to the outer peripheral surface of the reinforcing unit,
Post-installed anchors are provided at positions that do not interfere with the plurality of headed studs at positions corresponding to the outer peripheral surface of the reinforcing unit when the reinforcing unit is inserted on the inner peripheral surface of the opening of the column beam frame. ,
Inserting the reinforcing piece or the reinforcing unit into the opening of the column beam frame,
Spiral streaks are arranged to alternately repair the post-installed anchor and the headed stud,
By injecting the non-shrink mortar into the gap between the opening of the column beam frame and the reinforcement unit, the reinforcement unit and the column beam frame are integrated.

  Therefore, by providing such headed studs, post-installed anchors and spiral bars, injecting non-shrink mortar between the column beam frame and the reinforcement unit makes the column beam frame and the reinforcement unit more efficient. It becomes possible to integrate them, and it is possible to effectively perform seismic reinforcement.

(5) In the seismic reinforcement method according to any one of (1) to (4),
When the existing building is a structure in which the column protrudes from the outer surface of the existing building rather than the beam,
The thickness of the L-shaped reinforcing piece and the I-shaped reinforcing piece is the thickness of the protrusion of the column,
The column beam frame and the reinforcing unit are integrated by filling the adhesive between the I-shaped reinforcing piece and the outer surface of the existing building and between the L-shaped reinforcing piece and the column. It is characterized by doing.

Therefore, when the structure of the existing building is a structure in which the pillar protrudes from the outer surface of the existing building rather than the beam, the building structure can be used for reinforcement.
In the column portion, the I-type reinforcement piece and the L-type reinforcement piece that is an extension of the I-type reinforcement piece project inward, but a part of the L-type reinforcement piece is disposed on the side surface of the beam portion, so that it is more The existing building can be reinforced without deteriorating the appearance from the inside of the building.

(6) In the seismic reinforcement method described in (5),
In the opening of the column beam frame, a T-shaped reinforcing piece composed of two orthogonal sides having the same thickness as the I-shaped reinforcing piece and the L-shaped reinforcing piece, the I-shaped reinforcing piece, and the L-shaped reinforcing piece Are inserted so as to constitute a ladder-like reinforcement unit,
The column beam frame and the reinforcing unit are integrated by filling a bonding agent between the column beam frame and the reinforcing unit.

Therefore, it becomes possible to construct a ladder-shaped reinforcement unit on the outer surface of the existing building, and reinforcement according to the structure of the existing building becomes possible.
Similarly to (5), the I-type reinforcement piece and the L-type reinforcement piece and the T-type reinforcement piece as an extension of the I-type reinforcement piece protrude inward, but one of the L-type reinforcement piece and the T-type reinforcement piece. Since the portion is arranged on the side surface of the beam portion, the existing building can be reinforced without damaging the appearance from the inside of the existing building.

Moreover, in order to achieve the said objective, the reinforcement piece by this invention has the following characteristics.
(7) It is a reinforcement piece used for the earthquake-proof reinforcement method described in any one of (1) to (6).
Therefore, it is possible to configure a reinforcing unit that has good portability and can provide the required strength.

The following functions and effects can be obtained by the seismic reinforcement method and the reinforcing piece according to the present invention having such characteristics.
(1) Since the reinforcing unit is configured in a gate shape, there is no step on the floor of the opening, and people can come and go, desks, bookshelves, etc., so the range of use of the reinforced opening Becomes wider. In addition, the opening can be made larger than the reinforcement by the square frame-shaped reinforcement unit.
(2) By constructing the reinforcement unit in a gate shape, the reinforcement piece (precast member made of a combination of fiber concrete and steel frame) is reduced by one side compared to the reinforcement by the square frame reinforcement unit. The construction period can be shortened.

(3) By using a portal-shaped reinforcement unit from the upper layer to the lower layer of an existing building, the existing column beam frame will be reinforced from all sides. Yield strength is obtained.
In addition, by increasing the joint strength of the portal-shaped reinforcement unit with post-installed anchors, it is possible to expect equivalent strength or higher.
(4) The existing column beam frame and the gate-shaped reinforcement unit are joined by epoxy resin, so there is less noise, vibration, and dust during construction compared to conventional anchor and stud joining. Become.

Next, an embodiment of the seismic reinforcement method and the reinforcing piece according to the present invention will be described with reference to the drawings.
Here, FIG. 1 is a diagram showing a schematic front view of the reinforcement unit, and FIG. 2 is a schematic front view of the reinforcement piece constituting the reinforcement unit.

(First embodiment)
First, the configuration of the first embodiment will be described.
As shown in FIGS. 1 and 2, the reinforcement unit 10 extends two L-shaped reinforcement pieces 20, 20 composed of two orthogonal sides and one side of each of the L-type reinforcement pieces 20, 20. The prismatic I-shaped reinforcement pieces 30 and 30 connected to each other are joined symmetrically so that the other ends of the L-shaped reinforcement pieces 20 and 20 are connected to each other. It is the reinforcing member which comprised concrete around the steel frame.

The L-shaped reinforcing piece 20 includes an upper side portion 201 disposed on an upper portion of the opening inner peripheral surface 15a (see FIG. 4) of the column beam frame 15, and an orthogonal to the upper side portion 201 and on the side portion of the opening inner peripheral surface 15a. It is formed in an L shape from the arranged vertical column part 202.
The I-shaped reinforcing piece 30 is disposed on the side portion of the opening inner peripheral surface 15a of the columnar frame 15, the upper end is connected to the lower end of the vertical column portion 202 of the L-shaped reinforcing piece 20, and the columnar frame 15 is connected to the lower end. This is a prismatic shape provided with a base plate 303 placed under the inner peripheral surface 15a of the opening.

As shown in FIGS. 7 and 8, the reinforcing pieces 20 and 30 are so-called steel concrete in which concrete is wound around a steel material as a bone. H-type steel is used as the steel material, and the concrete wound around the steel may be used for general SRC (Steel Reinforced Concrete) construction or may be a fiber reinforced concrete.
The H-shaped steel 21 serving as the bone of the L-shaped reinforcing piece 20 is composed of two sides welded so as to be orthogonal to each other, and the H-shaped steel 31 serving as the bone of the I-shaped reinforcing piece 30 is linear. .

Headed studs 22 are welded to the H-shaped steels 21 and 31 serving as the bones in two rows in the width direction on the parallel plate portions constituting the H-shaped steels 21 and 31 at regular intervals in the longitudinal direction.
A base plate 303 is placed on the lower end of the H-shaped steel 31 so that the lower end of the base plate 303 comes into contact with the base plate 303, and is fixed by welding.

Further, bolt holes 21a are provided at the end portions of the reinforcing pieces 20 and 30, and plates 21b are attached to the other end portions facing each other. The plate 21b is provided with a through hole, and is configured so that a bolt can be fastened to the corresponding bolt hole 21a when assembled with the other reinforcing pieces 20 and 30.
In FIG. 2, one L-shaped reinforcing piece 20 bolt hole 21 a and one plate 21 b are provided, and one I-shaped reinforcing piece 30 has a bolt hole 21 a and the other I-shaped reinforcing piece 30 has one. Although the plate 21b is provided, it is only necessary that the reinforcing pieces 20 and 30 can be connected.

Next, the construction method of the reinforcement unit 10 is demonstrated.
First, the corresponding opening of an existing building to be seismically reinforced is measured, the size of the reinforcing unit 10 is determined, and the reinforcing pieces 20 and 30 are manufactured at the factory. In addition, if there is a possibility that the reinforcing pieces 20 and 30 are frequently used with the same dimensions, the same pieces may be manufactured in advance.
At the stage where the reinforcing pieces 20 and 30 are completed, in order to attach the reinforcing unit 10 to an existing building, the L-shaped reinforcing pieces 20 and the L-shaped reinforcing pieces 20 and the I-shaped reinforcing pieces 30 are fastened with bolts on site. The reinforcement unit 10 is configured.

The fixing method at this time may be welding or bonding, and such a joining method is not denied. However, if the purpose of seismic reinforcement is assumed, the reinforcing unit 10 is configured integrally. However, it is preferable to join them mechanically. When welding or the like is performed, a welding machine or a power source is required locally, and there is a problem such as extra costs. Therefore, it is more advantageous to be able to easily perform the fastening with bolts or the like.
FIG. 3 shows a detailed view of a portion A which is a joining portion of the L-shaped reinforcing piece 20 shown in FIG. The same applies to the joint portion between the L-shaped reinforcing piece 20 and the I-shaped reinforcing piece 30.
In this way, the joint portions of the reinforcing pieces 20 and 30 are bolted using the plate 21b and the bolt hole 21a.
Thereafter, the fiber reinforced concrete additional portion 18 is formed. The portion of the fiber reinforced concrete additional portion 18 may be composed of non-shrink mortar, but in this embodiment, fiber reinforced concrete is used in order to increase the strength of the reinforcing unit 10.

Then, an anchor 16 is installed on the column beam frame 15 in the opening of the existing building.
FIG. 4 is a diagram in which an anchor 16 is constructed on an existing column beam frame 15.
In the column beam frame 15, a plurality of anchors 16 are constructed over the entire inner peripheral surface excluding the floor portion of the opening. The type of the anchor 16 is not particularly limited as long as it can integrally construct a protruding object on a column or beam, such as a hole-in anchor or a chemical anchor.
For example, when the anchor 16 is a chemical anchor, the construction method is such that a hole is drilled with a concrete drill on three sides of the opening inner peripheral surface 15a of the column beam frame 15, and a cutting bolt is implanted together with the chemical to be hardened. .

Then, as shown in FIG. 4, after the construction of the anchor 16 is completed on three sides of the opening inner peripheral surface 15a, the reinforcing unit 10 is installed in that portion. 7 and 8 are arranged so that the anchor 16 and the headed stud 22 are alternately repaired.
The spiral muscles 23 may be generally used, and the anchors 16 and the headed studs 22 are arranged so as to be repaired alternately, thereby preventing the non-shrinkage mortar to be injected thereafter from cracking and reinforcing the reinforcement more firmly. The unit 10 can be constructed.
In addition, the base plate 303 at the lower end of the I-shaped reinforcing piece 30 is firmly attached to the lower side of the inner peripheral surface 15a of the opening with a concrete mounting bolt or the like.

In FIG. 5, the front view of the state which attached the reinforcement unit 10 to the existing column beam frame 15 is shown. That is, in a state where the reinforcing unit 10 is fitted into the opening inner peripheral surface 15a portion of the column beam frame 15 as shown in FIG. 5 and the anchor 16 and the headed stud 22 are alternately repaired by the spiral muscles 23. In order to inject non-shrink mortar into the gap between the column beam frame 15 and the reinforcing unit 10, a wooden frame (not shown) is provided.
This wooden frame (not shown) is constructed so as to cover the fiber-reinforced concrete additional portion 18 shown in FIG. 3, and non-shrink mortar is injected to form the non-shrink mortar portion 17 in three sides of the opening 15a.
The dimensional accuracy of the reinforcing unit 10 and the column beam frame 15 cannot be increased because the reinforcing pieces 20 and 30 are manufactured at the factory after measuring at the site. Therefore, some dimensional errors are absorbed by the non-shrink mortar portion 17.

By forming the non-shrink mortar portion 17 in this manner, the reinforcing unit 10 and the column beam frame 15 are firmly integrated by the action of the anchor 16, the headed stud 22 and the spiral muscle 23.
FIG. 6 shows a front view when the reinforcing unit 10 is constructed in an existing building having a plurality of openings. 7 shows a cross section of the AA portion of FIG. 6 and FIG. 8 shows a cross section of the BB portion.
Since existing buildings that require seismic reinforcement are middle- and low-rise buildings of a plurality of floors, a plurality of openings are often present as shown in FIG. However, it goes without saying that construction is possible without a plurality of openings.
And fundamentally, the reinforcement unit 10 is installed in a required location according to the earthquake-resistant performance requested | required of the existing building. Moreover, when it constructs in the state inserted | pinched with the reinforcement unit 10 with respect to the pillar of the column beam frame 15, as shown in FIG. 7, since the frame part of the reinforcement unit 10 is arrange | positioned at the both sides of a pillar, the thickness It will be stronger than simply accumulating minutes.

That is, as shown in FIG. 7, when the frame of the reinforcing unit 10 is integrally attached to both sides with the column beam frame 15 as the center, the bending and compression strength are more than the case of reinforcing the same thickness on one side. It is possible to increase the yield strength.
Further, when the lower surface of the beam of the column beam frame 15 is supported by the upper side portion 201 of the L-shaped reinforcing piece 20 of the reinforcing unit 10, as shown in FIG. 8, the upper side portion 201 of the reinforcing unit 10 is placed on the lower surface of the beam. Since the portions are arranged, it is possible to provide an earthquake-proof reinforcement structure in which a step does not occur in the floor portion while reinforcing each other with both the beam and the upper side portion 201.

As shown in FIGS. 7 and 8, the frame of the reinforcing unit 10 is thinner than the column beam frame 15, so that it can be constructed from the inside or the outside of the existing building.
If the column or beam of the column beam frame 15 protrudes from the outside of the building, the reinforcement unit 10 will be installed from the outside. If the inside of the building, the reinforcement unit 10 will be installed from the inside. become.
In particular, when the reinforcement unit 10 is constructed from the inside of an existing building, the reinforcement unit 10 can be divided into the reinforcement pieces 20 and 30 so that it is easy to carry in, and a special carrying route for the reinforcement pieces 20 and 30 is secured. There is a high possibility that it will not be necessary.

In addition, the weight of the reinforcing pieces 20 and 30 is less than a quarter of the state of the reinforcing unit 10, and the size is also small. Therefore, the reinforcing pieces 20 and 30 can be moved by an operator without using a heavy machine. .
As described above, after the reinforcement unit 10 is applied to the column beam frame 15, when it is applied to the outside of the existing building, the surface of the reinforcement unit 10 is painted and applied to the inside of the existing building. By making an inner wall material on the surface of the reinforcing unit 10 to make it inconspicuous, it is not a concern that the building is subjected to seismic reinforcement in appearance.

Since the present embodiment adopts the construction method as described above with the configuration as described above, the following effects can be expected.
First, by dividing the reinforcing unit 10 into units of reinforcing pieces 20 and 30, a member having a weight of several tons can reduce the weight to several hundred kilometer level, which is effective in improving portability. is there.
If the weight of the reinforcement pieces 20 and 30 is several hundred kilometer level, it can be easily carried in by hand and can be easily ridden on a cart or the like, so that portability is improved. Furthermore, if the elevator is set to a size that can be carried, there is an advantage that it is not necessary to provide a carry-in entrance in order to carry in the reinforcing unit 10.

Even if it is necessary to provide a carry-in entrance, the reinforcement pieces 20 and 30 are smaller than the reinforcement unit 10 and need only have an opening slightly larger than the length of the short side of the reinforcement unit 10. If the size of the opening is 6 m × 3 m, it is sufficient if the opening has a size of 1.5 m, that is, a door size that allows people to pass through.
If it is this degree of opening, work such as removing a part of the window provided in the existing building will be sufficient, and there are usually cases where openings for carrying large equipment are provided Since there are restrictions on the entrance, it can be considered almost irrelevant.
In addition, when the length of the passage is required to be transported, the number of cases that can be limited is considered to be reduced.

Furthermore, since it can be easily assembled with bolts or the like, it is not necessary to arrange an operator with special skills. For example, when welding is necessary, it is necessary that an operator with welding technology needs to be present at the site, and there are various problems such as securing a power source for welding, which is not necessary.
In addition, assembly in a short time is possible, and there is an effect of shortening the construction time. Since the bolt hole 21a and the plate 21b provided in the reinforcing unit 10 are directly provided in the H-shaped steels 21 and 31 constituting the aggregate of the reinforcing unit 10, there is no fear of insufficient strength, and in the reinforcement of the earthquake However, in this point, the L-shaped reinforcing piece 20 is composed of two orthogonal sides, and the I-shaped reinforcing piece 30 is connected to the lower end thereof. As a result, both the L-shaped reinforcing piece 20 and the I-shaped reinforcing piece 30 receive stress, so there is no shortage in strength.

Further, since the reinforcing unit 10 has an opening in the center and releases the floor portion, the opening portion of the column beam frame 15 is not unnecessarily narrowed, and a step does not occur in the floor portion. Can do well. From the viewpoint of structural strength, the structure in which the braces are provided or the case where the steel brace having a truss shape is provided is stronger, so the thickness of the frame itself of the reinforcing piece 20 is thicker than these. it's possible.
However, when the frame of the reinforcing unit 10 is somewhat thicker than when it crosses the opening diagonally, it does not give a sense of pressure visually, and as a result, the scenery from the window is less likely to be damaged. . In addition, even when the reinforcement unit 10 is constructed outside the existing building, it is difficult to understand if it is seismically reinforced, even when it is constructed inside, rather than in the case of a brace or truss shape. There is no risk of damage.

According to the seismic reinforcement method and the reinforcing piece of the first embodiment described above, the following excellent actions and effects can be obtained.
That is, in the seismic reinforcement method for seismically reinforcing a column beam frame 15 composed of columns and beams of an existing building, an L-shaped reinforcement piece 20 composed of two orthogonal sides and one side of the L-shaped reinforcement piece 20 The prismatic I-shaped reinforcement piece 30 connected so as to extend is joined symmetrically so that the tips of the other sides of the L-shaped reinforcement piece 20 are connected to each other, thereby reinforcing the portal-shaped reinforcement. The unit 10 is configured, and the reinforcing unit 10 is inserted in a gate shape into the opening of the column beam frame 15, and a bonding agent is filled between the column beam frame 15 and the reinforcement unit 10. The column beam frame 15 and the reinforcing unit 10 are integrated.
Therefore, the portability of a reinforcement unit can be improved by employ | adopting the system which assembles a reinforcement unit combining a reinforcement piece.
In addition, since the reinforcing unit is configured in a gate shape, the opening is effective for the type of the floor type, and no step is generated in the floor portion.

(Second Embodiment)
Next, a second embodiment will be described. This 2nd Embodiment changed the structure of the junction part of L type | mold reinforcement pieces or the said L type | mold reinforcement piece, and the said I type reinforcement piece, and also changed the method of installing in an existing building. is there. Therefore, only this change part is demonstrated.
A joining portion between the L-shaped reinforcing pieces 20 of the second embodiment is shown in FIG. 9 which is a detailed view of a portion A in FIG. The same applies to the joint portion between the L-shaped reinforcing piece 20 and the I-shaped reinforcing piece 30.
A bolt hole 210a on the bolt fastening side is provided in the H-shaped steel 21 (31), while a bolt insertion hole corresponding to the bolt hole 210a provided in both L-shaped reinforcing pieces 20 is provided in the flat steel plate on the plate side. The provided splice plate 210b is applied to both surfaces of the H-shaped steel 21 (31), and a high-tension bolt is inserted and tightened into the bolt hole 210a and the bolt insertion hole to establish a friction joint.

  Moreover, in 1st Embodiment, when attaching the reinforcement unit 10 to an existing building, the L-type reinforcement pieces 20 and L-type reinforcement piece 20 and the I-type reinforcement piece 30 are fastened beforehand with a volt | bolt in the field, Although the method of assembling the reinforcing unit 10 has been described, in this second embodiment, the L-shaped reinforcing piece 20 and the I-shaped reinforcing piece 30 are used one by one using the post-installed anchor 16, the spiral muscle 23 is connected to the anchor 16. By arranging the head studs 22 and the headed studs 22 alternately, the reinforcing unit 10 is assembled by being installed in an existing building. Thereafter, a wooden frame (not shown) is provided, and non-shrink mortar is injected into the gap between the column beam frame 15 and the reinforcing unit 10.

According to the seismic reinforcement method and the reinforcing piece of the second embodiment described above, the following excellent actions and effects can be obtained.
That is, in the seismic reinforcement method for seismically reinforcing a column beam frame 15 composed of columns and beams of an existing building, an L-shaped reinforcement piece 20 composed of two orthogonal sides and one side of the L-shaped reinforcement piece 20 The columnar I-shaped reinforcing pieces 30 connected so as to be extended are installed one by one using the construction anchor 16 provided in the opening of the column beam frame 15, and the column beam frame 15 The columnar frame 15 and the reinforcing unit 10 are integrated by filling a bonding agent between the reinforcing unit 10 and the reinforcing unit 10.
Therefore, since the L-shaped reinforcing piece 20 and the I-shaped reinforcing piece 30 are separately installed on the column beam frame 15, transportation and assembly are easy, and work with a small number of people is possible.
In addition, since the L-shaped reinforcing pieces 20 or the L-shaped reinforcing piece 20 and the I-shaped reinforcing piece 30 are connected by the plate 210b and the high tension bolt, a strong fastening force can be obtained and frictional joining can be performed.

(Third embodiment)
Next, the configuration of the third embodiment will be described.
In FIG. 10, the schematic front view of the reinforcement unit 10 of 3rd Embodiment is shown. FIG. 11 is a cross-sectional view taken along CC in FIG. FIG. 12 shows a DD cross-sectional view of FIG.
The reinforcing unit 10 according to the third embodiment includes three types of pieces, that is, an L-shaped reinforcing piece 20, an I-shaped reinforcing piece 30, and a T-shaped reinforcing piece 40.
As shown in FIGS. 11 and 12, the existing building 50 in which the reinforcing unit 10 of the third embodiment is constructed is such that the shapes of the columns 15A and 15B of the column beam frame 15 are larger than those of the beam 15B. The structure is such that it protrudes outside the existing building 50.

The L-shaped reinforcing piece 20, the I-shaped reinforcing piece 30, and the T-shaped reinforcing piece 40 are formed with a thickness such that the column 15A protrudes from the beam 15B, as shown in FIGS.
As in the first and second embodiments, each of the L-shaped reinforcing piece 20, the I-shaped reinforcing piece 30, and the T-shaped reinforcing piece 40 is made of H-shaped steel as a core material, and fiber-reinforced concrete is surrounded around it. It is rolled up. Similar to the L-shaped reinforcing piece 20, the T-shaped reinforcing piece 40 is also welded so that the H-shaped steels are orthogonal to each other.
As for the L-shaped reinforcement piece 20, as described above, the upper side portion 201 that is one side of the L-type reinforcement piece 20 is joined so as to face the upper side portion 201 that is one side of the other L-type reinforcement piece 20. It is formed in an upright shape. As a joining method, the method shown in FIG. 3 shown in the first embodiment, the method shown in FIG. 9 of the second embodiment, or the like can be considered.
A T-shaped reinforcing piece 40 is disposed below the L-shaped reinforcing piece 20 in a state where the two are joined.

The T-shaped reinforcing piece 40 is formed in an H shape by joining a beam portion 402 that is one side of the T-shaped reinforcing piece 40 and a beam portion 402 that is one side of the other T-shaped reinforcing piece 40 to face each other. The And the edge part of the vertical column part 202 of the combined L-shaped reinforcement piece 20 and the edge part of the vertical column part 401 of the T-shaped reinforcement piece 40 formed in H shape are joined.
The I-shaped reinforcing piece 30 is provided on the first floor portion of the existing building 50 having the column beam frame 15. The I-type reinforcement piece 40 is extended to the end of the vertical column 401 of the T-type reinforcement piece 40 that is not joined in a state where the T-type reinforcement piece 40 and the L-type reinforcement piece 20 are combined. The reinforcing piece 30 is connected.
The reinforcing unit 10 thus formed is applied to the existing building 50 in a state where the base plate 303 included in the I-type reinforcing piece 30 and the first floor portion of the existing building 50 are coupled.

In FIG. 10, two sets of T-shaped reinforcing pieces 40 are used. However, if the existing building 50 having the column beam frame 15 has three or more layers, one set of two T-shaped reinforcing pieces 40 per layer. By adding the die reinforcement piece 40, the ladder-shaped reinforcement unit 10 matched to the existing building 50 is formed.
In the construction method of the reinforcing unit 10, the anchor is partially driven and fixed to the outer side surface of the existing building 50, and then an adhesive is poured to adhere.
As shown in FIGS. 11 and 12, the portions into which the adhesive is poured are the vertical column portion 202 portion of the L-shaped reinforcement piece 20, the vertical column portion 401 portion of the T-type reinforcement piece 40, and the column portion of the I-type reinforcement piece 30. Adheres to the column 15A.
Further, the upper side portion 201 of the L-shaped reinforcing piece 20 and the beam portion 402 of the T-shaped reinforcing piece 40 are bonded to each other using an anchor partially on the outer surface of the beam 15B, that is, the outer surface of the existing building 50. Do.

As for the method of using the adhesive and driving the anchor, as shown in the first embodiment, the headed stud 22, the anchor 16, and the spiral muscle 23 may be used for fixing.
In addition, since the reinforcement unit 10 of 3rd Embodiment can be constructed only to the outer surface side of the existing building 50 from the characteristic of the shape, it is possible to construct to the 4 surfaces which face the outer side of the existing building 50. Of course, depending on the shape of the existing building 50 and the location conditions, there are cases where the number of surfaces that can be constructed is two, but in such cases, it may be combined with the first embodiment and the second embodiment. .

According to the seismic reinforcement method and the reinforcing piece of the third embodiment described above, the following excellent actions and effects can be obtained.
When the existing building 50 has a structure in which the column 15A protrudes from the outer surface of the existing building 50 rather than the beam 15B, the thickness of the L-type reinforcing piece 20 and the I-type reinforcing piece 30 is set to the protrusion of the column 15A. The T-shaped reinforcing piece 40 composed of two orthogonal sides having the same thickness as the I-shaped reinforcing piece 30 and the L-shaped reinforcing piece 20 is formed in the opening of the column beam frame 15. It is inserted between the reinforcement pieces 20 so as to constitute the ladder-like reinforcement unit 10, and is inserted between the I-type reinforcement piece 30 and the outer surface of the existing building 50, and the L-type reinforcement piece 20 By filling the column 15A with an adhesive, the column beam frame 15 and the reinforcing unit 10 can be integrated.

Accordingly, if the structure of the existing building 50 satisfies a certain condition, the outer surface of the existing building 50 can be reinforced by the ladder-like reinforcing unit 10. The I-type reinforcement piece 30 and the L-type reinforcement piece 20 and the T-type reinforcement piece 40 that are extensions of the column 15A protrude inward, but the L-type reinforcement piece 20 and the T-type reinforcement piece 40 Since a part is arrange | positioned at the side surface of the beam 15B part, the reinforcement | strengthening of the existing building 50 is attained, without impairing the external appearance from the inside of the existing building 50 more.
In addition, since the outer surface of the existing building 50 can be reinforced with the reinforcing unit 10 rather than being divided at each floor, if the existing building 50 can be reinforced with higher strength and can satisfy the conditions, there is a possibility of construction. High and effective.

In addition, since it is disassembled into the L-shaped reinforcing piece 20, the I-shaped reinforcing piece 30, and the T-shaped reinforcing piece 40, it is excellent in portability and can be easily constructed, so that the existing building 50 can be properly reinforced. .
In addition, although mentioned above, although the reinforcement unit 10 of 3rd Embodiment is reinforcement for the outer surface of the existing building 50, if the reinforcement unit 10 shown by 1st Embodiment and 2nd Embodiment is used, existing building will be used. Since the interior of the object 50 can be reinforced, it is possible to enhance the effect by using it in combination.

In addition, this invention is not limited to the said embodiment, A various change is possible in the range which does not deviate from the meaning.
For example, although the aggregates constituting the reinforcing pieces 20 and 30 of the reinforcing unit 10 are H-shaped steels 21 and 31, for example, the reinforcing pieces 20 and 30 are made of reinforced concrete even if not necessarily made of SRC material. Also good. Further, the concrete used for the reinforcing pieces 20 and 30 does not prevent the use of a member such as a high toughness fiber reinforced cement composite material mixed with high strength fibers. Furthermore, you may comprise only a steel frame or only a lightweight steel frame, without winding with concrete.
Moreover, although the division | segmentation number of the reinforcement piece 20 is set to 2 in a present Example, it does not prevent that a straight part is divided | segmented into 3 divisions or 4 divisions.

In addition, as a bonding agent to be filled between the reinforcing unit 10 and the column beam frame 15, a method of filling the non-shrink mortar using the anchor 16 and the headed stud 22 is given as an example. Also, for example, the anchor 16 and the headed stud 22 are not hindered from being fixed with an adhesive.
Moreover, it does not prevent using the method of fixing with an adhesive agent without using the anchor 16 or the headed stud 22. In this case, management of the clearance between the reinforcing unit 10 and the column beam frame 15 becomes a problem. For example, by inserting a non-shrink mortar plate, inserting a steel material or a mesh material, the clearance is managed, and an adhesive is used. It is considered that the strength can be secured by using.
Moreover, the combination of the joining part in the said 1st Embodiment thru | or 3rd Embodiment and the assembly order of a reinforcement piece is not limited to the said embodiment.

It is a schematic front view of the reinforcement unit of 1st Embodiment. It is a schematic front view of the reinforcement piece which comprises a reinforcement unit of 1st Embodiment. It is detail drawing of A part which is a junction part of the reinforcement pieces shown in FIG. 1 of 1st Embodiment. It is the figure which constructed the anchor to the existing column beam frame of a 1st embodiment. It is a front view of the state which attached the reinforcement unit to the existing column beam frame of 1st Embodiment. It is a front view at the time of constructing a reinforcement unit in the existing building with a plurality of openings of a 1st embodiment. It is a cross section of the AA part of Drawing 6 of a 1st embodiment. It is a cross section of the BB part of Drawing 1 of a 1st embodiment. It is detail drawing of A part which is a junction part of the reinforcement pieces shown in FIG. 1 of 2nd Embodiment. It is a schematic front view of the reinforcement unit 10 of 3rd Embodiment. It is sectional drawing of CC part of FIG. 10 of 3rd Embodiment. It is sectional drawing of DD part of FIG. 10 of 3rd Embodiment.

10 Reinforcement unit 15 Column beam frame 15a Opening inner peripheral surface 16 Anchor (post-installed anchor)
17 Non-shrinking mortar part 18 Non-shrinking mortar additional part 20 L-shaped reinforcement piece 201 Upper side part 202 Vertical column part 21 H-shaped steel 21a, 210a Bolt hole (bolt fastening side)
21b, 210b Plate (plate side)
22 Stud with head 23 Spiral muscle 30 I type reinforcement piece 303 Anchor panel 31 H type steel 40 T type reinforcement piece 50 Existing building

Claims (7)

In the seismic retrofitting method that seismically reinforces a column beam frame composed of columns and beams of an existing building with a reinforcement unit ,
The reinforcement unit is configured in a gate shape by joining a plurality of reinforcement pieces symmetrically, and the plurality of reinforcement pieces are arranged at two corners of the portal shape and orthogonal to each other. Including two L-shaped reinforcing pieces composed of two sides, and a prismatic I-shaped reinforcing piece connected so as to extend one side of each L-shaped reinforcing piece. It is integrally formed by winding concrete around the steel material as a bone, and one end portion of the L-shaped reinforcing piece is provided with a joint portion that joins one end portion of the other L-shaped reinforcing piece The other end portion of the L-shaped reinforcing piece is provided with a joining portion that joins with one end portion of the I-shaped reinforcing piece, and the one end portion of the I-shaped reinforcing piece has the L-shaped portion. A joining portion is provided for joining to the other end of the reinforcing piece, and the two L-shaped complementary parts are provided. The one end portions of the pieces are aligned with each other and joined by the joint portion, and the other end portions of the L-shaped reinforcing piece and the one end portion of the I-shaped reinforcing piece are aligned with each other by the joining portion. After joining, it is designed to form a non-shrink mortar additional part in each joint part,
The portal-shaped reinforcing unit is configured by joining the plurality of reinforcing pieces symmetrically,
Thereafter, the portal-shaped reinforcing unit is inserted and fitted into the inner periphery of the rectangular opening of the column beam frame,
Thereafter, the column beam frame and the reinforcement unit are integrated by filling a bonding agent between the column beam frame and the reinforcement unit. In the seismic reinforcement method according to claim 1,
The joint portion includes a bolt fastening side provided with a bolt fastening hole and a plate side provided with a bolt insertion hole.
The bolt fastening side joint provided at the one end of one L-shaped reinforcing piece and the plate side joint provided at the one end of the other L-shaped reinforcing piece are bolted. And the bolt fastening side or the plate side joint provided at the other end of each L-shaped reinforcing piece and the plate side provided at the one end of the I-shaped reinforcing piece Alternatively, the L-type reinforcing piece and the I-type reinforcing piece are integrated as the reinforcing unit by fastening the joint portion on the bolt fastening side with a bolt . In the seismic reinforcement method described in claim 1 or claim 2,
The thickness of the frame constituting the reinforcing unit is thinner than the thickness of the pillar and the beam of the existing building,
An earthquake-resistant reinforcement method, wherein one surface having an opening of the reinforcing unit and one surface having an opening of another adjacent reinforcing unit are located on substantially the same plane. In the seismic reinforcement method according to any one of claims 1 to 3,
The bonding agent filled between the column beam frame and the reinforcing unit is a non-shrink mortar,
A plurality of headed studs are welded to the outer peripheral surface of the reinforcing unit,
Post-installed anchors are provided at positions that do not interfere with the plurality of headed studs at positions corresponding to the outer peripheral surface of the reinforcing unit when the reinforcing unit is inserted on the inner peripheral surface of the opening of the column beam frame. ,
Insert the reinforcing piece or the reinforcing unit into the opening of the column beam frame, and arrange spiral streaks so as to alternately repair the post-installed anchor and the headed stud,
A seismic strengthening method characterized in that the reinforcing unit and the column beam frame are integrated by injecting the non-shrink mortar into a gap between the opening of the column beam frame and the reinforcing unit. In the earthquake-proof reinforcement construction method according to any one of claims 1 to 4,
When the existing building is a structure in which the column protrudes from the outer surface of the existing building rather than the beam,
The thickness of the L-shaped reinforcing piece and the I-shaped reinforcing piece is the thickness of the protrusion of the column,
The column beam frame and the reinforcing unit are integrated by filling the adhesive between the I-shaped reinforcing piece and the outer surface of the existing building and between the L-shaped reinforcing piece and the column. Seismic reinforcement construction method characterized by doing. In the seismic reinforcement method according to claim 5,
In the opening of the column beam frame, a T-shaped reinforcing piece composed of two orthogonal sides having the same thickness as the I-shaped reinforcing piece and the L-shaped reinforcing piece, the I-shaped reinforcing piece, and the L-shaped reinforcing piece Are inserted so as to constitute a ladder-like reinforcement unit,
A seismic strengthening method characterized in that the column beam frame and the reinforcing unit are integrated by filling a bonding agent between the column beam frame and the reinforcing unit.   A reinforcing piece for use in the seismic reinforcement method according to any one of claims 1 to 6.