JP7410774B2 - Earthquake reinforcement structure - Google Patents

Description

The present invention relates to an earthquake-resistant reinforced structure in which a steel frame reinforced with braces is fixed inside a column-beam frame.

BACKGROUND ART Buildings with a column-beam frame are sometimes retrofitted by installing a steel frame inside the column-beam frame in order to provide seismic reinforcement. In Patent Document 1, in order to prevent the steel frame from interfering with existing doors, passages, etc. when performing renovations in this way, the lower side of the steel frame is composed of a pair of left and right lower frame parts separated from each other. was. Then, by filling the space between the lower frame part of the lower side part and the lower beam of the column-beam frame with a filler such as mortar to bury the studs and spiral reinforcement provided therein, the lower part of the lower part of the lower beam is It was connected to. In addition, since there is a possibility that sufficient strength cannot be secured with such a connection between the lower side and the lower beam, a base plate is erected across the pair of lower frames, and the base plate is attached to the concrete of the lower beam. It is connected to the lower beam by an anchor bolt driven into the section.

Japanese Patent Application Publication No. 2017-155438

However, due to the presence of the base plate that spans the pair of lower frame sections, a difference in level has occurred where existing doors, passages, etc. exist. In addition, when the lower side part and the lower beam are joined as described above, in addition to joining the lower frame part to the lower beam with the filler, a base plate constructed across the pair of lower frame parts is used. Since it was connected to the lower beam using anchor bolts, the number of steps needed to connect the lower side to the lower beam increased, making it time-consuming to install the steel frame during renovations.

In view of this situation, the main object of the present invention is to provide an earthquake-resistant reinforced structure that can improve the workability of installing a steel frame during renovation while avoiding the occurrence of level differences.

A first feature of the present invention is that in an earthquake-resistant reinforced structure in which a steel frame reinforced with braces is fixed inside a column-beam frame, the lower side of the steel frame is a pair of left and right lower side frames separated from each other. Each of the pair of left and right lower frame portions in the lower side portion is joined to a steel frame portion constituting a lower beam below the slab of the column-beam frame , and the lower beam is made of SRC construction. The lower frame portion is joined to the steel frame portion of the lower beam exposed by cutting off the concrete portion of the lower beam .

According to this configuration, by joining the lower frame part of the steel frame to the steel part constituting the lower beam, the steel part of the lower beam and the lower side of the steel frame can be bonded with sufficient strength. It becomes possible to join. Further, since the pair of left and right lower frame portions are separated from each other and are not connected by a base plate or the like, a step does not occur at a location where an existing door or passage exists. In addition, when a filler is filled between the lower frame and the lower beam and a base plate is constructed across the pair of left and right lower frames sandwiching the notch, and the base plate is joined to the lower beam using anchor bolts. In comparison, it is possible to improve the workability of installing a steel frame during renovation.

In addition , even if the steel part of the lower beam is covered with concrete because the lower beam is SRC, the exposed steel part can be removed by removing the concrete part of the lower beam and exposing the steel part. The lower frame part of the steel frame can be joined to the steel part. Therefore, it is possible to improve the workability of installing a steel frame during renovation while avoiding the occurrence of level differences.

Front view of the seismic reinforcement structure of the column-beam frame in the first embodiment A front view showing the joint between the lower frame part of the steel frame and the steel part of the lower beam in the first embodiment A side view showing a state in which the lower frame portion of the steel frame and the steel portion of the lower beam are being joined in the first embodiment AA sectional view of FIG. 2 in the first embodiment Front view of the seismic reinforcement structure of the column-beam frame in the second embodiment A front view showing the joint between the lower frame part of the steel frame and the steel part of the lower beam in the second embodiment BB sectional view of FIG. 6 in the second embodiment

[First embodiment]
EMBODIMENT OF THE INVENTION Hereinafter, 1st Embodiment of the seismic reinforcement structure based on this invention is described based on drawings.
The seismic reinforcement structure 1 shown in FIG. 1 is a structure in which a steel frame 4 reinforced with braces 3 is fixed inside a column-beam frame 2. To explain, the seismic reinforcement structure 1 is a building equipped with a column-beam frame 2 that undergoes renovation work for seismic reinforcement, and a steel frame reinforced with braces 3 is installed inside the column-beam frame 2. This is a structure in which 4 is fixed.

As shown in FIG. 1, the column-beam frame 2 includes a left column 7, a right column 8, an upper beam 9, and a lower beam 10, and a rectangular space is formed inside these. A steel frame 4 is installed. Note that the direction in which the left column 7 and the right column 8 are lined up is the left-right direction X, the direction perpendicular to the left-right direction The orthogonal direction is defined as the vertical direction Z.

The left column 7, the right column 8, and the upper beam 9 are of SRC construction (steel reinforced concrete construction), and the lower beam 10 is of S construction (steel construction). The lower beam 10 supports the slab 11 from below, and the slab 11 is interposed between the steel frame 4 and the lower beam 10 in the vertical direction Z.

The steel frame 4 has a left side 12, a right side 13, an upper side 14, and a lower side 15, and is formed into a rectangular shape by the left side 12, right side 13, upper side 14, and lower side 15. ing. Each of the left side part 12, the right side part 13, the upper side part 14, and the lower side part 15 is made of H-beam steel. The brace 3 has a mansard type brace structure and is fixed inside the steel frame 4.

The left side part 12 has an upper end connected to the left end of the upper side part 14 and a lower end connected to the left end of the lower side part 15, and is constituted by a continuous H-shaped steel from the upper side part 14 to the lower side part 15. The right side part 13 has an upper end connected to the right end of the upper side part 14 and a lower end connected to the right end of the lower side part 15, and is constituted by a continuous H-shaped steel from the upper side part 14 to the lower side part 15. The upper side part 14 has a left end connected to the upper end of the left side part 12 and a right end connected to the upper end of the right side part 13, and is made of continuous H-beam steel from the left side part 12 to the right side part 13. In addition, continuous H-beam steel means that H-beam steel exists continuously from one side of a pair to the other, and continuous H-beam steel is a single H-beam steel. It may be made of steel or may be made of a plurality of H-beams connected together.

The lower side portion 15 is composed of a pair of left and right lower frame portions 16 that are separated from each other so as to form a gap 17 therebetween. Each of the pair of left and right lower frame portions 16 is made of H-beam steel. To explain further, the lower side part 15 includes a left side lower frame part 16a, which is the lower frame part 16 whose left end is connected to the lower end of the left side part 12, and a lower side frame part whose right end is connected to the lower end of the right side part 13. 16, and a right lower frame portion 16b. The left lower frame part 16a and the right lower frame part 16b are arranged in a line in the left-right direction X, and the left lower frame part 16a and the right lower frame part 16b are separated in the left-right direction A gap 17 is formed between the lower frame portion 16a and the right lower frame portion 16b. In this way, the lower side part 15 is different from the right side part 13, the left side part 12, and the upper side part 14, and is not made of continuous H-beam steel.

The lengths of the left lower frame portion 16a and the right lower frame portion 16b in the left-right direction X are set to be longer than the length required for proof strength. In the example shown in FIG. 1, the left lower frame part 16a and the right lower frame part 16b are formed to have the same length in the left-right direction X, but the left lower frame part 16a and the right lower frame part 16b are They may be formed to different lengths. Further, the total length of the left lower frame portion 16a and the right lower frame portion 16b in the left-right direction X is less than half of the outer dimension of the steel frame 4 in the left-right direction It has become. Therefore, the length in the left-right direction X of the gap 17 formed between the left-hand lower frame part 16a and the right-hand lower frame part 16b is determined by the outer dimension of the steel frame 4 in the left-right direction This is more than half the length of the original. In the example shown in FIG. 1, the length in the left-right direction X of the gap 17 formed between the left-hand lower frame part 16a and the right-hand lower frame part 16b is 2/2 of the outer dimension of the steel frame 4 in the left-right direction X. It is longer than 3.

The left side portion 12 is joined to the left side column 7 by filling a space between the left side portion 12 and the left side column 7 with a filler 23 such as mortar. To explain, a plurality of anchor bolts 21 are fixed to the concrete of the left column 7 so as to protrude toward the right side, and a plurality of anchor bolts 21 are fixed to the web of the left side portion 12 with a plurality of heads that protrude toward the left side. A stud 22 is fixed. In this embodiment, a post-installed anchor is used as the anchor bolt 21, and the anchor bolt 21 is fixed by making a hole in the concrete of the left column 7 and embedding it in the hole. The left side portion 12 is joined to the left side column 7 by filling the space between the left side column 7 and the left side portion 12 with a filler material 23 so as to bury these anchor bolts 21 and headed studs 22. Further, similarly to the left side portion 12, the right side portion 13 is joined to the right side column 8 by filling the space between the right side portion 13 and the right side column 8 with a filler 23. Further, like the left side portion 12 and the right side portion 13, the upper side portion 14 is joined to the upper beam 9 by filling a space between the upper side portion 14 and the upper beam 9 with a filler 23.

The lower side portion 15 is directly joined to the steel frame portion 27 of the lower beam 10 using an intermediate member 26. To explain further, the intermediate member 26 includes a first intermediate member 26a that is installed so as to penetrate the slab 11 in the vertical direction Z and is joined to the left lower frame portion 16a and the steel frame portion 27; There is a pair of left and right intermediate members 26, including a second intermediate member 26b that is installed so as to penetrate through the lower right frame portion 16b and the steel frame portion 27. The left lower frame portion 16a of the lower side portion 15 is joined to the steel frame portion 27 using the first intermediate member 26a, and the right lower frame portion 16b of the lower side portion 15 is joined to the steel frame portion 27 using the second intermediate member 26b. is joined to. In this way, each of the pair of left and right lower frame portions 16 in the lower side portion 15 is joined to the steel frame portion 27 constituting the lower beam 10 below the slab 11 of the column-beam frame 2 without using the filler 23. has been done.

Next, a description will be given of the configuration in which the left and right pair of lower frame parts 16 are joined to the steel frame part 27. Since the configurations to be joined are similar, only the configuration in which the left lower frame portion 16a is joined to the steel frame portion 27 will be explained, and the configuration in which the right side lower frame portion 16b is joined to the steel frame portion 27 will not be explained. Omitted.

As shown in FIGS. 2 and 4, a first intermediate member 26a (hereinafter simply referred to as the intermediate member 26) is used when joining the left lower frame portion 16a (hereinafter simply referred to as the lower frame portion 16) to the steel frame portion 27. ) are a first plate 31, a second plate 32, and a third plate 33 that are joined to the lower frame portion 16 by welding, and a fourth plate 34 and a fifth plate 35 that are joined to the steel frame portion 27 by welding. , and a sixth plate 36. Each of the first plate 31, second plate 32, third plate 33, fourth plate 34, fifth plate 35, and sixth plate 36 is made of a steel plate. The first plate 31, the second plate 32, and the third plate 33 form an upper bracket 37. Further, a lower bracket 38 is formed by the fourth plate 34, the fifth plate 35, and the sixth plate 36. That is, the intermediate member 26 includes an upper bracket 37 and a lower bracket 38. The upper bracket 37 and the lower bracket 38 are integrated by fastening the third plate 33 and the sixth plate 36 to each other using fastening members 28 such as bolts and nuts (for example, high-strength bolts). There is.

The first plate 31 is welded to the right end of the lower frame portion 16 in a posture along the vertical direction Z and the front-back direction Y (a posture perpendicular to the left-right direction X). Further, the first plate 31 is welded to the web and the pair of flanges of the lower frame portion 16 in a state in which it is in contact with the right end surface of the web of the lower frame portion 16 and the right end surfaces of the pair of flanges.

The second plate 32 is positioned along the up-down direction Z and the front-back direction Y (attitude perpendicular to the left-right direction Welded together. Further, the second plate 32 is welded to each of the web and the pair of flanges of the lower frame portion 16 in a state in which it is in contact with the lower surface of the web of the lower frame portion 16 and the inner surface of the pair of flanges.

The third plate 33 is positioned along the vertical direction Z and the horizontal direction Welded together. Further, the third plate 33 is in contact with the lower surface of the web of the lower frame portion 16, the left surface of the first plate 31, and the right surface of the second plate 32, and the third plate 33 is in contact with the web of the lower frame portion 16, the first plate 31 , and the second plate 32 by welding.

The fourth plate 34 is welded to the steel frame portion 27 in a posture along the vertical direction Z and the front-back direction Y (a posture perpendicular to the left-right direction X). Further, the fourth plate 34 is welded to the upper flange of the steel frame portion 27 while being in contact with the upper surface of the upper flange of the steel frame portion 27 .

The fifth plate 35 is welded to a portion of the steel frame portion 27 spaced to the left with respect to the fourth plate 34 in a posture along the vertical direction Z and the front-back direction Y (a posture perpendicular to the left-right direction X). has been done. Further, the fifth plate 35 is welded to the upper flange of the steel frame portion 27 while being in contact with the upper surface of the upper flange of the steel frame portion 27 .

The sixth plate 36 is welded to a portion of the steel frame portion 27 between the fourth plate 34 and the fifth plate 35 in a posture along the vertical direction Z and the horizontal direction X (a posture perpendicular to the longitudinal direction Y). has been done. Further, the sixth plate 36 is in contact with the upper surface of the upper flange of the steel frame portion 27, the left surface of the fourth plate 34, and the right surface of the fifth plate 35, and the sixth plate 36 is in contact with the flange of the steel frame portion 27, the fourth plate 34, and the right surface of the fifth plate 35. It is welded and joined to each of the fifth plates 35.

The upper bracket 37 is formed by welding the first plate 31, the second plate 32, and the third plate 33 to each other. Further, the lower bracket 38 is formed by welding the fourth plate 34, the fifth plate 35, and the sixth plate 36 to each other. Then, the third plate 33 of the upper bracket 37 and the sixth plate 36 of the lower bracket 38 are fastened and joined by the fastening member 28, so that the upper bracket 37 and the lower bracket 38 are integrated, and the intermediate member 26 is formed. Since the upper bracket 37 is welded to the lower frame part 16 and the lower bracket 38 is welded to the steel part 27, the lower frame part 16 is connected to the steel part 27 via the intermediate member 26. Welded together. The fastening member 28 is located between the lower frame portion 16 and the steel frame portion 27 in the vertical direction Z, and is located above the upper surface of the slab 11 and the finished floor surface. Therefore, even after the restoration work described below, the upper bracket 37 and the lower bracket 38 can be fastened together by the fastening member 28.

Next, the work of joining the lower frame portion 16 to the steel frame portion 27 will be explained. When joining the lower frame portion 16 to the steel frame portion 27, a first welding operation is performed to weld the upper bracket 37 to the lower frame portion 16, and a second welding operation is performed to weld the lower bracket 38 to the steel portion 27. , a cutting operation to expose the steel frame part 27 by cutting down the slab part 11a, which is the part of the slab 11 located directly above the steel frame part 27 and the surrounding part, and the upper bracket 37 and the lower bracket 38. A fastening operation for fastening and joining, and a restoration operation for restoring the slab 11 by filling a repair material such as mortar into the slab portion 11a cut out by the scooping operation are performed. Among these operations, the order of the operations may be changed as appropriate, except that the second welding operation is executed after the scooping operation, and the restoration operation is executed after the second welding operation. In addition, welding the first plate 31, the second plate 32, and the third plate 33 to each other to form the upper bracket 37, and welding the fourth plate 34, the fifth plate 35, and the sixth plate 36 to each other. The work of joining to form the lower bracket 38 and the first welding work may be performed at the site where the repair work is to be performed, or may be performed in advance before transporting to the site.

In this embodiment, first, a first welding operation is performed to weld and join the upper bracket 37 to the lower frame portion 16. Further, as shown in FIG. 3, after performing the cutting operation to remove the slab portion 11a, a second welding operation is performed to weld the lower bracket 38 to the steel frame portion 27. Next, as shown in FIG. 4, after performing a fastening work to fasten and join the upper bracket 37 and the lower bracket 38, as shown by dotted lines in FIG. 4, a restoration work is performed to restore the slab 11. let

[Second embodiment]
A second embodiment of the seismic reinforcement structure 1 according to the present invention will be described based on the drawings. The second embodiment has the same structure as the first embodiment except that the lower beam 10 is made of SRC. Next, the seismic reinforcement structure 1 of the second embodiment will be explained, but the explanation will mainly focus on the configuration that is different from the first embodiment, and the explanation will be omitted for the parts that are configured similarly to the first embodiment. .

As shown in FIG. 5, the lower beam 10 is made of SRC. Therefore, the concrete portion 39 of the lower beam 10 exists above the steel frame portion 27 of the lower beam 10. Therefore, in the scooping work, in addition to the work of scooping the slab 11, the work of scooping the concrete portion 39a, which is the portion of the concrete portion 39 located directly above the steel frame portion 27 and the surrounding portion thereof. By performing such a cutting operation, the steel frame portion 27 can be exposed even if the lower beam 10 is made of SRC. The lower frame portion 16 is joined to the steel frame portion 27 of the lower beam 10 exposed by cutting the concrete portion 39 of the lower beam 10 in this manner. Further, in the restoration work, both the slab portion 11a and the concrete portion 39a that were scooped out in the scooping work are filled with a repair material to restore the slab 11 and the concrete portion 39.

By making the lower beam 10 of SRC construction, the distance in the vertical direction Z between the lower frame part 16 and the steel frame part 27 of the lower beam 10 is smaller than that of the steel frame part when the lower beam 10 is made of S construction. The size increases due to the presence of the concrete portion 39 above 27. In this embodiment, the sixth plate 36 of the intermediate member 26 is enlarged in the vertical direction Z. Therefore, even if the lower beam 10 is made of SRC, the fastening member 28 is located between the lower side part 15 and the lower beam 10 in the vertical direction Z, and is located closer to the upper surface of the slab 11 or the finished floor surface. The upper bracket 37 and the lower bracket 38 can be fastened together by the fastening member 28 even after restoration work.

In this embodiment, first, a first welding operation is performed to weld and join the upper bracket 37 to the lower frame portion 16. Further, as shown in FIG. 6, after the slab portion 11a and the concrete portion 39a are removed by performing the cutting operation, a second welding operation is performed to weld the lower bracket 38 to the steel frame portion 27. Next, as shown in FIG. 7, after performing the fastening work to fasten and join the upper bracket 37 and the lower bracket 38, as shown by dotted lines in FIG. 39 will be restored.

[Another embodiment]
Other embodiments of the present invention will be described. Note that the configurations of each embodiment described below are not limited to being applied individually, but can also be applied in combination with the configurations of other embodiments.

(1) In the above embodiment, the left column 7, right column 8, and upper beam 9 of the column-beam frame 2 are made of SRC construction. However, the configurations of the left column 7, right column 8, and upper beam 9 may be changed as appropriate. For example, a part or all of the left column 7, right column 8, and upper beam 9 may be constructed of RC (reinforced concrete).

(2) In the above-described embodiment, a configuration was described in which the lower frame portion 16 is joined to the steel frame portion 27 by welding. However, the configuration is not limited to this. For example, the structure for joining the lower frame part 16 to the steel frame part 27 may be changed as appropriate, such as by mechanically joining the lower frame part 16 to the steel frame part 27 using fastening members such as high-strength bolts. You may.

(3) In the above-described embodiment, the intermediate member 26 is configured to be divided into an upper bracket 37 and a lower bracket 38 that are fastened together, but it may be configured integrally as one bracket. Further, the first plate 31 and the second plate 32 of the upper bracket 37 and the fifth plate 35 and the sixth plate 36 of the lower bracket 38 can be omitted.

(4) In the embodiment described above, the intermediate member 26 includes the first plate 31, the second plate 32, the third plate 33, the fourth plate 34, the fifth plate 35, and the sixth plate 36, as an example. explained. However, the configuration is not limited to this. For example, the intermediate member 26 may be configured not to include some or all of the first plate 31, the second plate 32, the fourth plate 34, and the fifth plate 35, and the intermediate member 26 may not include the plates included in the intermediate member 26. may be changed as necessary.

1 Earthquake reinforcement structure 2 Column beam frame 3 Brace 4 Steel frame 11 Slab 15 Lower side part 16 Lower frame part 27 Steel part 39 Concrete part

Claims (1)

It is an earthquake-resistant reinforced structure in which a steel frame reinforced with braces is fixed inside the column-beam frame.
The lower side part of the steel frame is composed of a pair of left and right lower frame parts separated from each other,
Each of the pair of left and right lower frame portions in the lower side portion is joined to a steel frame portion constituting a lower beam below the slab of the column-beam frame ,
The lower beam is made of SRC,
An earthquake-resistant reinforced structure in which the lower frame portion is joined to a steel frame portion of the lower beam exposed by cutting a concrete portion of the lower beam .

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