KR20200128323A - Buttress assembly for seismic reinforcing of building - Google Patents

Abstract

The present invention relates to a buttress assembly (100) which is engaged with both side walls (11) placed in a long-side direction of an existing building (10) and is filled with concrete, comprising: a large number of strap rebar members (110) embedded in a vertical direction at regular intervals and made in a ′ㅁ′ shape, having an open unit (111) toward the existing building (10); ㄷ-shaped reinforcing members (115), respectively placed on the strap rebar members (110) and opened toward the open unit (111); and main rebar members (210) placed in an internal corner of the large number of strap rebar members (110) and the reinforcing members (115). The buttress assembly (100) is engaged with the side walls (11) of the existing building (10) by T-shaped reinforcing steel frames (200) placed in a vertical direction. Of the main rebar members (210), a main rebar member placed at a corner in an internal side of the strap rebar members (110) facing the open unit (111) and a main rebar placed at a corner in an internal side of the reinforcing members (115) are embedded as a couple to have a certain interval in the long-side direction. The present invention aims to provide a buttress assembly for reinforcing earthquake resistance, which is able to allow an existing building to withstand a load from an earthquake.

Description

Buttress assembly for seismic reinforcing of building

The present invention relates to an auxiliary shaft wall assembly, and more particularly, to a side shaft wall assembly for seismic reinforcement of an existing building capable of seismic reinforcement of existing buildings that have insufficient wall area but need seismic reinforcement.

In general, the stability evaluation and reinforcement measures for earthquakes in existing non-seismic designed buildings should perform seismic performance evaluation by conducting a field survey on the target building and reflecting the results. In addition, based on the seismic performance evaluation result, the presence or absence of seismic reinforcement and appropriate reinforcement plans are established to reinforce the existing building based on the appropriate reinforcement plan.

Since the existing building with non-seismic design including the conventional wall-type structure and the plate-shaped structure could not withstand the seismic load, the seismic resistance is reinforced after establishing a reinforcement plan in the same manner as above.

In the case of seismic reinforcement of an existing building with a non-seismic design in the direction of the general method, that is, the foundation work is complicated, it was difficult to secure constructability. The process of migrating the residents of the city was essential.

In this process, it was essential to prepare a place for residents and to relocate non-immigrated residents, and this process took a lot of time, making it difficult to shorten the construction period as well as secure constructability.

Look at the related prior art.

Japanese Unexamined Patent Publication No. 1999-081703 relates to an external seismic reinforcement method in consideration of disaster countermeasures, and provides an external seismic reinforcement method that can be constructed while residents of the building reside, and both sides of the existing building (1) It relates to the external seismic reinforcement method of constructing the reinforcing structure (2).

It is not necessary to move the residents of the existing building, but the concrete seismic reinforcement performance has not been proven, and the length, thickness, and strength of the reinforcing structure have not been proposed.

JP 1999-081703 A JP 1999-030045 A KR 10-2013-0018343 A

The present invention was devised to solve the above problems.

It is intended to solve the problem that the existing non-seismic designed buildings including wall-type structures and plate-type structures cannot withstand earthquake loads. In the case of seismic reinforcement of an existing building, it is intended to solve the problem that it was not possible to secure an artificial space within the site of the existing building.

In addition, when reinforcing in the short side direction for seismic reinforcement of an existing non-seismic designed building, it is intended to solve the problem that constructability could not be secured due to the complex foundation work.

In addition, it is intended to solve the problem that residents need to be relocated in case of seismic reinforcement of existing non-seismic designed buildings.

In one embodiment of the present invention for solving the above problems, in the auxiliary shaft wall assembly 100, which is coupled to both side walls 11 located in the long side direction of the existing building 10 and filled with concrete, the vertical direction A plurality of band reinforcement members 110 that are arranged at predetermined intervals and have an open portion 111 toward the existing building 10 and have an ㅁ shape; A U-shaped reinforcing member 115 provided in each of the belt reinforcing bar members 110 and opened toward the opening 111; A main muscle member 210 positioned at an inner edge of the plurality of band reinforcement members 110 and the reinforcement member 115; Including, the auxiliary shaft wall assembly 100 is coupled to the side wall 11 of the existing building 10 by a tee-shaped reinforcing steel frame 200 provided in a vertical direction, the opening of the main member 210 The main muscle member positioned at the inner edge of the band reinforcement member 110 opposite to the part 111 and the main muscle member positioned at the inner edge of the reinforcing member 115 are paired to have a predetermined distance in the long side direction. It provides a reinforced minor axis wall assembly.

In addition, it is preferable that the length of the auxiliary shaft wall assembly 100 is 4 times the length of the side wall 11 of the existing building 10 based on the long side direction.

In addition, it is preferable that the main muscle members 210 of the main muscle members 210 located at the inner corners of the opening part 111 of the belt reinforcement member 110 are in contact with each other in a short side direction and are reinforced in a pair.

In addition, the tee-shaped reinforcing steel frame 200 may include a coupling part 201 facing the side wall 11 of the existing building 10; And an extension part 202 extending from the coupling part 201 toward the long side and having a through hole 202H, and through-coupled to the through hole 202H parallel to the coupling part 201 It is preferable to include a through dowel reinforcement (300).

In addition, at the lower end of the auxiliary shaft wall assembly 100, an end pressure steel plate 180 facing the bottom; Doedoe welding in the vertical direction to the tee-shaped reinforcing steel frame 200, a plurality of stud bolts 190 provided in a pair; further includes, the penetration between the plurality of stud bolts 190 formed in the longitudinal direction It is preferable that the dowel reinforcing bar 300 is located, and the tee-shaped reinforcing steel frame 200 and the plurality of stud bolts 190 are prevented from falling off by the through dowel reinforcing bar 300.

In addition, it is preferable that the sidewall 11 is chipped.

In addition, the tee-shaped reinforcing steel frame 200 is anchored by an anchor 102 that is used in a number of lengthwise directions of the side wall 11 to anchor the minor shaft wall assembly 100 to the side wall 11. Do.

In addition, the belt reinforcement member 110 has a diameter of 13mm and is arranged at 300mm intervals in the vertical direction, and the main root member 210 is preferably 25mm in diameter.

In addition, it is preferable that the width of the reinforcing member 115 in the short side direction is smaller than the width of the reinforcing member 110 in the short side direction.

In addition, it is preferable that the through dowel reinforcement 300 has a diameter of 13 mm.

In addition, the number of anchors 102 corresponding to the area of the side wall 11 is provided, 20 is installed per 1 m of the side wall 11, and the anchor 102 is preferably an m12 anchor bolt.

In addition, the lower end of the minor shaft wall assembly 100 is embedded in the base plate, the stud bolts 190 included in the lower end of the minor shaft wall assembly 100 are 10, and the through dowel reinforcement 300 ) Is preferably 5.

The present invention as described above has the following effects.

First, the existing building has out-of-plane resistance by the auxiliary shaft wall assembly according to the present invention, so that it is possible to withstand an earthquake load.

Second, since the auxiliary shaft wall assembly according to the present invention is installed in the long side direction of an existing building, it is possible to secure a human space within the site of the existing building.

Third, since the auxiliary shaft wall assembly according to the present invention is installed in a long side direction, basic work is simplified than a wall installed in a short side direction, and thus constructability is secured.

Fourth, the auxiliary wall assembly according to the present invention does not require the migration of residents of the existing building, and all the construction for seismic reinforcement is carried out from the outside, so that the residence is possible while the construction for seismic reinforcement is in progress.

Fifth, since the auxiliary shaft wall assembly according to the present invention can be provided in the form of an assembly, it is excellent in workability and has an effect of shortening the construction period.

1 shows a case of seismic reinforcement of an existing building using the auxiliary shaft wall assembly according to the present invention.
In Fig. 2, a schematic perspective view of a minor shaft wall assembly according to the first and second embodiments of the present invention is shown.
3, a cross-sectional view of the minor shaft wall assembly according to the first and second embodiments of the present invention is shown.
4 is a schematic side and plan perspective view of the lower end of the minor shaft wall assembly according to the present invention.
5 to 6 show setting information of the test object and test materials for the verification experiment.
The strength tests of each material are shown in FIGS. 7 to 8.
Referring to Fig. 8, it can be seen that the M12 anchor used in the anchor 102 according to the present invention sufficiently exhibits a predetermined tensile strength suggested in the technical manual.
Figures 9a to 9e show the cracking and fracture patterns of the specimens 1 to 4 (BW1, BW2, BW3, BW4) and the control specimen (NW).
Figure 10a shows the crack shape of each cycle of the specimen 1 (BW1) and specimen 2 (BW2).
Fig. 10b shows the shape of cracks for each cycle of Experiment 3 (BW3) and Experiment 4 (BW4).
In Fig. 10c, a load-displacement comparison graph for each specimen (NW, BW1, BW2, BW3, BW4) is shown.
In FIG. 11, a table of verification experiment results for each test object (NW, BW1, BW2, BW3, BW4) is shown.
12, an envelope comparison graph for each specimen (NW, BW1, BW2, BW3, BW4) is shown.
13A to 13C, graphs for comparing the stiffness reduction for each of the specimens BW1, BW2, BW3, and BW4 are shown.
14, a graph for comparing the energy dissipation ability of each of the test subjects (BW1, BW2, BW3, BW4) is shown.
In FIG. 15, a table for calculating the neutral axis for each of the specimens BW1, BW2, BW3, and BW4 is shown.
16A to 16D, graphs of strain distributions of reinforcing bars for each of the specimens BW1, BW2, BW3, and BW4 are shown.
In FIG. 17, a comparison graph of the strain distribution of the reinforcing bars for each of the specimens BW1, BW2, BW3, and BW4 is shown.

Hereinafter, the'existing building 10' is not limited as long as it is a building requiring seismic reinforcement, but in an embodiment, it may be a wall-type building or a plate-shaped building. However, a non-rectangular building with a different aspect ratio is assumed to determine the'long side direction' to be described later.

Hereinafter, the'long side direction' refers to a direction formed long toward both sidewalls based on the existing building 10, and the'short side direction' refers to the front side of the existing building 10 with respect to the existing building 10. It means a direction formed toward the rear (see Fig. 1).

Hereinafter, the'vertical direction' means the height of the existing building 10, that is, a lengthwise direction extending vertically.

Hereinafter, the auxiliary shaft wall assembly according to the present invention will be described in detail with reference to the drawings. Here, the components constituting the present invention may be used integrally or may be used separately, as necessary. In addition, some components may be omitted depending on the type of use. Various modifications are possible in the form and number of components of the present invention.

Support wall Description of assembly configuration

The configuration of the auxiliary shaft wall assembly according to the present invention will be described with reference to FIGS. 1 to 4.

The auxiliary shaft wall assembly 100 according to the present invention is combined with both side walls 11 located in the long side direction of the existing building 10 to reinforce the seismic performance of the existing building 10.

The auxiliary shaft wall assembly 100 according to the present invention is a side shaft wall specialized for reinforcing seismic performance and is filled with concrete, and includes a belt reinforcing member 110, a reinforcing member 115, and a main member 210.

It is preferable that the auxiliary shaft wall assembly 100 has a length of 4 times the length of the side wall 11 of the existing building 10 based on the long side direction.

The strip reinforcement member 110 is arranged at predetermined intervals in a vertical direction (vertical length direction) in a plurality, and has an opening part 111 toward the existing building 10 while having a shape of ㅁ.

The reinforcing members 115 are provided in each of the band reinforcement members 110 to reinforce strength, and have a U-shaped shape that opens toward the opening 111.

The reinforcing member 115 may be provided while being welded to the belt reinforcing member 110.

By the reinforcing member 115 provided in the band reinforcing member 110, it is possible to secure seismic performance of a certain level or more with a minimum of band reinforcement.

In one embodiment, the width of the reinforcing member 115 in the short side direction may be smaller than the width of the reinforcing member 110 in the short side direction. This is because the reinforcing member 115 is welded to a part of the reinforcing bar of the band reinforcing member 100 to reinforce the strength.

The main root member 210 is located at each inner corner of the band reinforcement member 110 and the reinforcing member 115.

That is, a plurality of band reinforcement members 110 and reinforcing members 115 are arranged in a vertical direction with a predetermined distance to the outside of the main muscle member 210.

Among the main root members 210, the main root members located at the inner corners of the belt reinforcing member 110 facing the opening 111 and the main root members located at the inner corners of the reinforcing member 115 have a predetermined distance in the long side direction. It is laid in pairs to have (see Fig. 3).

The auxiliary shaft wall assembly 100 is coupled to the side wall 11 of the existing building 10 by a T-shaped reinforcing steel frame 200 provided in the vertical direction (height direction) of the side wall 11.

It would be desirable for the T-type reinforced steel frame 200 to have a length corresponding to the height of the side wall 11 of the existing building 10.

The T-type reinforced steel frame 200 includes a coupling part 201 facing the side wall 11 of the existing building 10; And an extension part 202 extending from the coupling part 201 toward a long side and having a through hole 202H.

In one embodiment, the tee-shaped reinforcing steel frame 200 used has a coupling portion 201 having a thickness of 15 mm (length in the long side direction) and a width of 200 mm (length in the short side direction), and the extension portion 202 is It would be desirable to have a thickness of 15 mm (length in the short side direction) and a width of 185 mm (length in the long side direction).

The tee-shaped reinforcing steel frame 200 is anchored by an anchor 102 that is used in a large number in the vertical direction (up and down longitudinal direction) of the side wall 11. By anchoring the T-type reinforcing steel frame 200, the auxiliary shaft wall assembly 100 is anchored to the side wall 11.

The through dowel reinforcement 300 is coupled through the through hole 202H so as to be parallel to the coupling portion 201. To this end, the cross-section of the dowel reinforcing bar 300 and the shape of the through hole 202H correspond to each other and are closely coupled.

The through dowel reinforcement 300 prevents the tee-shaped reinforcing steel frame 200 and the plurality of stud bolts 190 from falling out in the minor shaft wall assembly 100.

In one embodiment, it further includes an end pressure steel plate 180 and a plurality of stud bolts 190 at the lower end of the minor shaft wall assembly 100.

The end acupressure steel plate 180 faces the floor on which the auxiliary shaft wall assembly 100 is installed, and stably supports the auxiliary shaft wall assembly 100.

A plurality of stud bolts 190 are provided and are welded in the vertical direction of the tee-shaped reinforcing steel frame 200. At this time, the stud bolts 190 are provided in a pair having a predetermined interval and are welded to the tee-shaped reinforcing steel frame 200 (see FIG. 3 ).

A through dowel reinforcement 300 is positioned between the plurality of stud bolts 190 formed in the longitudinal direction.

It will be prevented from dropping out of the tee-shaped reinforcement steel frame 200 and the plurality of stud bolts 190 in the minor shaft wall assembly 100 by the through dowel reinforcing bar 300.

The band reinforcement member 110 has a diameter of 13 mm and is arranged at 300 mm intervals in the vertical direction. Depending on the size of the existing building 10, the type of the band reinforcement member 110 is not limited thereto and may be changed.

The main muscle member 210 may preferably have a diameter of 25 mm, but is not limited thereto.

The through dowel reinforcing bar 300 may preferably have a diameter of 13 mm, but is not limited thereto.

The number of anchors 102 is provided in a number corresponding to the area of the side wall 11, and preferably 20 may be installed per 1 m of the width of the side wall 11.

The anchor 102 may preferably be an m12 anchor bolt, but is not limited thereto, and the operator may replace it with a chemical anchor as necessary to reduce the step of bolting.

The lower end of the minor shaft wall assembly 100 is embedded in the base plate 1, and in one embodiment, the number of stud bolts 190 included in the lower end of the minor shaft wall assembly 100 is 10, and through dowel reinforcement 300 ) Can be 5.

Referring to the BW2 & BW4 test specimens disclosed in FIGS. 2 to 3, in the case of the minor shaft wall assembly 100 ′ according to the second embodiment, the opening 111 of the belt reinforcing bar member 110 of the main muscle member 210 The main muscle members located at the inner corners are in contact with each other in the direction of the short side and are laid in a pair.

This is because, depending on the scale of the existing building 10, the auxiliary shaft wall assembly 100 ′ according to the second exemplary embodiment can be installed, which has superior seismic reinforcement performance compared to the auxiliary shaft wall assembly 100 according to the first exemplary embodiment.

In another embodiment, the side walls 11 may be chipped for tight coupling with the minor shaft wall assemblies 100 and 100' according to the first and second embodiments.

Support wall Seismic performance verification of assembly

An experiment and results of verifying the seismic performance of the auxiliary shaft wall assembly 100 according to the present invention will be described with reference to FIGS. 5 to 17.

In order to verify the seismic performance of the auxiliary shaft wall assembly 100 according to the present invention, a member test was repeatedly performed on each of the following specimens.

The control specimen (NW) is an existing wall without reinforced seismic performance.

Test Subject 1 (BW1) and Test Subject 3 (BW3) are the test subjects of the minor shaft wall assembly 100 according to the first embodiment of the present invention, and the difference between Test Subject 1 (BW1) and Test Subject 3 (BW3) is the presence or absence of chipping. 3 (BW3) is a chipping test specimen.

Experiment 2 (BW2) and Experiment 4 (BW4) are the specimens of the auxiliary shaft wall assembly 100 according to the second embodiment of the present invention, and the difference between Experiment 2 (BW2) and Experiment 4 (BW4) is the presence or absence of chipping. 4 (BW4) is a chipped specimen.

5 to 6 show setting information of the test object and the test materials for the verification experiment.

The strength tests of each material are shown in FIGS. 7 to 8.

Referring to Fig. 8, it can be seen that the M12 anchor used in the anchor 102 according to the present invention sufficiently exhibits a predetermined tensile strength suggested in the technical manual.

Figures 9a to 9e show the cracking and fracture patterns of the specimens 1 to 4 (BW1, BW2, BW3, BW4) and the control specimen (NW).

Fig. 10a shows the crack shape of each cycle of the specimen 1 (BW1) and specimen 2 (BW2), and the crack shape of the specimen 3 (BW3) and specimen 4 (BW4) for each cycle is shown in FIG. 10B.

That is, as shown in Figs. 10A to 10B, test bodies 2 (BW2) and test bodies 4 (BW4) according to the second embodiment of the present invention have two cycles compared to the test bodies (BW1 to BW4) according to the first embodiment. It is proven to be more durable.

As can be seen through FIGS. 10 to 17, it can be seen that in the case of Test Subject 1 (BW1) and Test Subject 3 (BW3), the proof strength was increased by about 200 times compared to the control test sample (NW).

In addition, it can be seen that in the case of Test Subject 2 (BW2) and Test Subject 4 (BW4), the proof strength was increased by about 1000 times or more compared to the control test sample (NW).

It was confirmed that the energy dissipation capacity of Test Subjects 1 (BW1) and 3 (BW3) was slightly inferior as the concrete peeling started, but as verified above, Test Subjects 1 to 4 (BW1, BW2, BW3, BW4) were control subjects ( Compared to NW), both have excellent energy dissipation ability, so it can be seen that they have excellent seismic performance.

In conclusion, it is verified that the strength, stiffness and energy dissipation ability will be improved due to the test specimens 1 to 4 (BW1, BW2, BW3, BW4), which are auxiliary shaft wall assemblies according to the first and second embodiments of the present invention , When applying the auxiliary shaft wall assembly 100 according to the present invention to the existing building 10, it will be possible to reinforce the seismic performance of the existing building.

In the above, the present specification has been described with reference to the embodiments shown in the drawings so that those skilled in the art can easily understand and reproduce the present invention, but this is only exemplary, and those skilled in the art can use various modifications and equivalents from the embodiments of the present invention. It will be appreciated that embodiments are possible. Therefore, the scope of protection of the present invention should be determined by the claims.

10: existing building
11: side wall (of an existing building)
100: minor shaft wall assembly
102: anchor
110: band reinforcement member
111: opening
180: end acupressure steel plate
190: stud bolt
200: Tee-shaped reinforcement steel frame
201: coupling portion
202: extension
202H: through hole
210: absence of the main muscle
300: dowel rebar

Claims (12)

In the auxiliary shaft wall assembly 100, which is coupled to both side walls 11 located in the long side direction of the existing building 10 and filled with concrete,
A plurality of band reinforcement members 110 that are arranged at predetermined intervals in the vertical direction and have an open portion 111 toward the existing building 10 but have an ㅁ shape;
A U-shaped reinforcing member 115 provided in each of the belt reinforcing bar members 110 and opened toward the opening 111;
A main muscle member 210 positioned at an inner edge of the plurality of band reinforcement members 110 and the reinforcement member 115; Including,
The auxiliary shaft wall assembly 100 is coupled to the side wall 11 of the existing building 10 by a T-shaped reinforcing steel frame 200 provided in a vertical direction,
Of the main muscle members 210, the main muscle member located at the inner edge of the band reinforcement member 110 opposite to the opening part 111 and the main muscle member located at the inner edge of the reinforcing member 115 are in the long side direction. To be laid in pairs to have a predetermined interval,
Minor shaft assembly.
The method of claim 1,
The length of the auxiliary shaft wall assembly 100 is 4 times the length of the side wall 11 of the existing building 10 based on the long side direction,
Minor shaft assembly.
The method of claim 1,
Among the main root members 210, the main root members located at the inner corners of the open portion 111 of the band reinforcement member 110 are in contact with each other in the short side direction and are reinforced in a pair,
Minor shaft assembly.
The method according to claim 2 or 3,
The tee-shaped reinforcing steel frame 200,
A coupling part 201 facing the side wall 11 of the existing building 10; And
It includes an extension part 202 extending from the coupling part 201 toward the long side and having a through hole 202H,
Including a through dowel reinforcement 300 that is penetrated through the through hole 202H so as to be parallel to the coupling part 201,
Minor shaft assembly.
The method of claim 4,
At the lower end of the auxiliary shaft wall assembly 100,
Acupressure steel plate 180 facing the bottom end;
Doedoe welding in the vertical direction to the tee-shaped reinforcing steel frame 200, a plurality of stud bolts 190 provided as a pair; further includes,
The through dowel reinforcement 300 is positioned between the plurality of stud bolts 190 formed in the longitudinal direction,
The tee-shaped reinforcement steel frame 200 and the plurality of stud bolts 190 are prevented from falling off by the through dowel reinforcing bar 300,
Minor shaft assembly.
The method according to claim 2 or 3,
The sidewall 11 is chipped,
Minor shaft assembly.
The method of claim 1,
The tee-shaped reinforcing steel frame 200 is anchored by an anchor 102 that is used in a number of longitudinal directions of the side wall 11 to anchor the minor shaft wall assembly 100 to the side wall 11,
Minor shaft assembly.
The method of claim 1,
The band reinforcement member 110 has a diameter of 13 mm and is arranged at 300 mm intervals in a vertical direction,
The main muscle member 210 is 25mm in diameter,
Minor shaft assembly.
The method of claim 1,
The width in the short side direction of the reinforcing member 115 is smaller than the width in the short side direction of the band reinforcement member 110,
Minor shaft assembly.
The method of claim 4,
The through dowel reinforcement 300 is 13 mm in diameter,
Minor shaft assembly.
The method of claim 7,
The anchors 102 are provided in a number corresponding to the area of the sidewall 11, and 20 are installed per 1m of the width of the sidewall 11,
The anchor 102 is an m12 anchor bolt,
Minor shaft assembly.
The method of claim 5,
The lower end of the auxiliary shaft wall assembly 100 is embedded in the base plate,
The number of stud bolts 190 included in the lower end of the auxiliary shaft wall assembly 100 is 10, and the through dowel reinforcing bar 300 is 5,
Minor shaft assembly.

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