KR102017728B1 - Seismic retrofit frame structure with fixing adapter - Google Patents

Abstract

The present invention relates to a seismic reinforcement frame structure with a fixing adapter, which can couple, by a fixing adapter, a vertical member and a horizontal member of a conventional frame to a vertical reinforcement member and a horizontal reinforcement member of a reinforcing frame without the interference of anchor bolts and the reinforcing frame and can respond easily to errors in the construction of each member constituting the conventional frame. According to the present invention, the seismic reinforcement frame structure with a fixing adapter, for reinforcing the conventional frame including the vertical member and the horizontal member comprises: the reinforcing frame including the vertical reinforcing member and the horizontal reinforcing member and provided inside the conventional frame; a fixing adapter provided between the reinforcing frame and the conventional frame to fix each member of the reinforcing frame to a corresponding member of the conventional frame; and a fixing adapter provided between the conventional frame and the reinforcing frame on edges of the conventional frame and the reinforcing frame and simultaneously and respectively fixing, to the vertical member and the horizontal member, the vertical reinforcement member and the horizontal reinforcement member each having ends inclinedly formed at angles corresponding to each other and distanced from each other.

Description

Seismic retrofit frame structure with fixing adapter

The present invention can be coupled to the vertical reinforcing member and horizontal reinforcing member of the reinforcing frame provided inside the existing frame by the fixed adapter to the vertical member and the horizontal member of the existing frame without interference of the anchor bolt and the reinforcing frame, and constitutes the existing frame The present invention relates to a seismic reinforcing frame structure having a fixed adapter that can easily cope with a construction error of each member.

With the recent increase in the frequency and intensity of earthquakes, the demand for seismic reinforcement for existing reinforced concrete structures is steadily increasing.

In addition, seismic reinforcement is inevitable in buildings that were built before the seismic design was introduced or existing low-rise buildings where seismic design regulations were not applied.

Therefore, in the case of the ramen jaw consisting of columns and beams, H-steel frame is installed inside the pillar-beam frame in order to secure the seismic performance and to maintain the maximum opening area of the opening, thereby increasing the rigidity and ductility of the structure. Many were used (Patent No. 10-1185974, etc.).

In this prior art, the outer flange of the H-shaped steel member is fixed to the inner side of the existing member by using an anchor bolt to fix the H-shaped steel frame to the existing member.

In this method, however, anchor bolts may be missing or not properly constructed due to interference of the H-beam inner flange during anchor hole drilling or anchor bolt installation.

In addition, the existing reinforced concrete frame may be manufactured in a different member size due to construction error. Therefore, there is a hassle to cut and use the steel member in the field because the size of the steel member and the existing member that is manufactured in the factory for the frame reinforcement and the existing member does not match each other.

In order to solve the construction difficulties as described above, seismic reinforcement technology was developed to facilitate anchor bolt construction by using a T-shaped steel to fix the web later with bolts (Patent No. 10-1459082).

However, since the registered patent has a large concentrated stress at the site where the web of the T-beam is bolted, there is a high risk of damage to this part during an earthquake.

In addition, as in the prior art, there is a problem that it is difficult to easily cope with the field error of the existing reinforced concrete member.

In order to solve the above problems, the present invention is to provide a seismic reinforcement frame structure provided with a fixed adapter that is easy to join the steel frame for seismic reinforcement when the seismic reinforcement of the existing structure.

The present invention is to provide a seismic reinforcement frame structure having a fixed adapter that can easily cope with the construction error of the existing reinforced concrete member.

The present invention according to a preferred embodiment is to reinforce an existing frame consisting of a vertical member and a horizontal member, the reinforcing frame consisting of a vertical reinforcing member and a horizontal reinforcing member provided inside the existing frame; A fixed adapter provided between the reinforcement frame and the existing frame to fix each member of the reinforcement frame to a corresponding member of the existing frame; And a vertical reinforcing member and a horizontal reinforcing member, which are provided between the existing frame and the reinforcing frame at the corners of the existing frame and the reinforcing frame, and each end is formed to be inclined at an angle corresponding to each other. An edge fixing adapter for simultaneously fixing the vertical member and the horizontal member; Provides a seismic reinforcement frame structure having a fixed adapter, characterized in that consisting of.

According to another exemplary embodiment of the present invention, the fixed adapter includes a fixing plate provided between the reinforcing member of the reinforcing frame and the existing member of the existing frame, an anchor bolt fixing the fixing plate to the existing frame, and a reinforcing frame to the fixing plate. It provides a seismic reinforcement frame structure having a fixed adapter, characterized in that consisting of a fixed bolt for fixing.

According to another preferred embodiment of the present invention, a first receiving groove is formed in the first fastening hole of the fixing plate into which the anchor bolt is inserted, and the fixing nut of the anchor bolt is formed, and the fixing bolt is inserted into the fixing plate. The second fastening hole provides a seismic reinforcement frame structure having a fixed adapter, characterized in that the second receiving groove is formed to accommodate the head portion of the fixing bolt.

According to another exemplary embodiment of the present invention, the second fastening hole is formed as a long hole in a vertical or horizontal direction, and the third fastening hole of the reinforcing frame to which the fixing bolt is inserted and fastened is perpendicular to the second fastening hole. It provides a seismic reinforcement frame structure having a fixed adapter, characterized in that formed in the long hole.

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In accordance with another preferred embodiment of the present invention, the inner end and side surfaces of the vertical reinforcing member and the horizontal reinforcing member are fixed to each other by a first splice plate and a second splice plate, respectively. Provide a reinforcement frame structure.

According to the present invention has the following effects.

First, each reinforcing member of the reinforcing frame installed to reinforce the existing frame consisting of the vertical member and the horizontal member is fixed to the existing member by a fixed adapter. In particular, since the fixing adapter to the existing member can be coupled to each reinforcing member of the reinforcing frame to the fixed adapter, there is no interference with the reinforcing frame during the fixing process of the fixed adapter is easy to install.

Second, since the existing H-shaped steel member can be used as each reinforcing member of the reinforcing frame, it is possible to prevent performance deterioration due to the concentration of stress and easy supply of materials.

Third, if the second fastening hole formed in the fixing plate and the third fastening hole formed in the reinforcing frame for inserting the fixing bolts to form the orthogonal to each other to form a fixed bolt to the fixing plate of the fixed adapter to the orthogonal to each other, The member error between the frame and the reinforcement frame can be absorbed in two directions by the fixed adapter.

Fourth, if the fixed adapter for the corner is provided between the existing frame and the reinforcement frame at the edge of the existing frame and the reinforcement frame, the vertical reinforcement member and the horizontal reinforcement member can be fixed to the vertical member and the horizontal member at the same time, and the vertical reinforcement member and It can be integrated by connecting the ends of the horizontal reinforcing member, and the length error between the existing frame and the reinforcement frame can be absorbed by the fixed adapter for the corner.

Fifth, when the ends of the vertical reinforcing member and the horizontal reinforcing member are formed to be inclined at a corresponding angle to each other so that the inclined ends are spaced apart from each other, the length error of the vertical reinforcing member or the horizontal reinforcing member can be absorbed within the separated distance. have.

Figure 1 is a front view showing a seismic reinforcement frame structure provided with a fixed adapter of the present invention.
2 is a perspective view showing an embodiment of a fixed adapter;
3 is an enlarged view illustrating a portion 'A' of FIG. 1.
4 and 5 are perspective views showing a coupling relationship between the fixed adapter and the reinforcing member.
Figure 6 is a view showing the construction sequence of the seismic reinforcement frame structure provided with a fixed adapter of the present invention.
7 is a perspective view showing an embodiment of the fixing plate.
8 is a diagram illustrating a relationship between a second fastening hole and a third fastening hole.
9 is a perspective view showing a coupling relationship of a corner fixed adapter.
10 is a front view showing the junction of the vertical reinforcing member and the horizontal reinforcing member.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings and preferred embodiments.

1 is a front view showing a structure of a seismic reinforcing frame having a fixed adapter according to the present invention.

As shown in Figure 1, the seismic reinforcement frame structure with a fixed adapter of the present invention is to reinforce the existing frame (1) consisting of the vertical member 11 and the horizontal member 12, the vertical reinforcement member 21 ) And a reinforcing frame (2) consisting of a horizontal reinforcing member (22) is provided inside the existing frame (1); And a fixed adapter provided between the reinforcing frame 2 and the existing frame 1 to fix each member 21 and 22 of the reinforcing frame 2 to the corresponding member 11 and 12 of the existing frame 1. (3); Characterized in that consists of.

The present invention relates to a seismic reinforcement frame structure having a fixed adapter for seismic reinforcement of the existing frame (1) comprising a vertical member (11) and a horizontal member (12) such as a ramen jaw composed of columns and beams.

The present invention can easily combine the reinforcement frame (2) for seismic reinforcement to the existing frame (1), seismic reinforcement provided with a fixed adapter that is easy to cope with the field construction error of the existing frame (1), which is a reinforced concrete member It is possible to provide a frame structure.

The existing frame 1 has a reinforced concrete ramen structure consisting of a pair of vertical members 11 and horizontal members 12.

The vertical member 11 is a pillar, and the horizontal member 12 is a beam or slab.

The seismic reinforcement frame structure provided with the fixed adapter of the present invention includes a reinforcing frame 2 and a fixed adapter 3.

The reinforcement frame 2 is composed of a vertical reinforcement member 21 and a horizontal reinforcement member 22 is provided inside the existing frame (1).

The inner side here means the inner side of the existing frame 1.

The reinforcement frame 2 is for reinforcing the existing frame 1, the inner surface of the existing frame 1, that is, the inner surface of the left and right vertical member 11 and the lower surface and lower horizontal member of the upper horizontal member 12 Respectively coupled to the upper surface of the (12).

That is, the reinforcing frame 2 is composed of a vertical reinforcing member 21 coupled to one side of the vertical member 11 and a horizontal reinforcing member 22 coupled to one side of the horizontal member 12.

The reinforcement frame 2 can be configured as a steel frame member.

The fixed adapter 3 is provided between the reinforcement frame 2 and the existing frame (1).

The fixing adapter 3 fixes each member 21, 22 of the reinforcing frame 2 to the corresponding member 11, 12 of the existing frame 1.

That is, the fixing adapter 3 connects and fixes each of the reinforcing members 21 and 22 of the reinforcing frame 2 and each of the existing members 11 and 12 of the existing frame 1.

In other words, each of the reinforcing members 21 and 22 of the reinforcing frame 2 is not directly fixed to the existing members 11 and 12, but is fixed to the existing members 11 and 12 through the fixing adapter 3.

Therefore, the fixing adapter 3 can be fixed to the existing members 11 and 12 first, and then the respective reinforcing members 21 and 22 of the reinforcing frame 2 can be coupled to the fixing adapter 3, so that the fixing adapter 3 There is no interference with the reinforcing frame (2) during the fixing process of the construction is very easy.

In addition, each reinforcing member (21, 22) of the reinforcing frame (2) can use the existing H-shaped steel member as it is. Therefore, performance degradation due to stress concentration can be prevented, and material supply and demand is easy.

FIG. 2 is a perspective view showing an embodiment of a fixed adapter, and FIG. 3 is an enlarged view showing a portion 'A' of FIG. 1. 4 and 5 are perspective views illustrating a coupling relationship between the fixed adapter and the reinforcing member, and FIG. 6 is a view illustrating a construction sequence of the seismic reinforcing frame structure having the fixed adapter according to the present invention.

2 to 5, the fixed adapter 3 is fixed between the reinforcing members 21 and 22 of the reinforcement frame 2 and the existing members 11 and 12 of the existing frame 1. Plate 31, anchor bolt 32 for fixing the fixing plate 31 to the existing frame (1) and the fixing bolt 33 for fixing the reinforcing frame (2) to the fixing plate 31 can be configured. .

The fixed adapter 3 may be composed of a fixed plate 31, an anchor bolt 32 and a fixed bolt 33.

The fixing plate 31 is provided between the reinforcing members 21 and 22 of the reinforcing frame 2 and the existing members 11 and 12 of the existing frame 1.

The fixing plate 31 is an anchor bolt 32 for fixing the fixing plate 31 to each existing member (11, 12) of the existing frame (1) and the angle of the reinforcement frame (2) to the fixing plate 31 The fixing bolt 33 for coupling the reinforcing members (21, 22) is a member that is coupled.

To this end, the fixing plate 31 has a first fastening hole 311 for coupling the anchor bolt 32 and a second fastening hole 313 for coupling the fixing bolt 33 to each other.

2 and 7, the first fastening holes 311 are formed at portions close to four corners of the fixing plate 31, respectively, and the second fastening holes 313 are first fastening holes 311. It was formed in a portion closer to the center of the fixed plate 31 so as to be spaced apart from).

As shown in Figure 3, the anchor bolt 32 is the outer side of the fixing plate 31, the fixing bolt 33 is the first fastening hole of the fixing plate 31 in opposite directions so as to face the inner side of the fixing plate 31 311 and the second fastening hole 313 can be coupled to each.

4, 5 and the like, an embodiment using H-shaped steel as the reinforcing members 21 and 22 of the reinforcing frame 2 is shown.

Accordingly, each of the reinforcing members 21 and 22 includes an outer flange 211 and 221, an inner flange 212 and 222, and a web 213 and 223.

Referring to Figure 6 describes the construction process of the seismic reinforcement frame structure provided with a fixed adapter of the present invention.

First, each of the existing members (11, 12) of the existing frame (1) forms an anchor hole for inserting the anchor bolt 32 at a position corresponding to the first fastening hole (311) of the fixing plate (31). And the anchor bolt 32 is constructed in the anchor hole (Fig. 6 (a)).

Next, as shown in Figure 6 (b), the fixing plate 31 and the fixing bolt 33 is combined.

That is, the fixing plate 31 of the fixing adapter 3 is coupled to the anchor bolt 32, and the anchor bolt 32 is fixed to the fixing plate 31 with the fixing nut 321.

At this time, the anchor bolt 32 passes through the first fastening hole 311 of the fixing plate (31).

After construction of the anchor bolt 32, the anchor bolt 32 may be fixed by injecting epoxy into the anchor hole.

Particularly, the fixing plate 31 may be fixed to the existing members 11 and 12 of the existing frame 1 by the anchor bolt 32 in the state in which the fixing bolt 33 is previously coupled to the fixing plate 31. .

At this time, the fixing bolt 33 passes through the second fastening hole 313 of the fixing plate 31.

Finally, as shown in (c) of Figure 6, the fixing bolts 33 of the fixed adapter (3) by coupling the respective reinforcing members (21, 22) of the reinforcement frame (2).

That is, the reinforcing members 21 and 22 are coupled to the fixing bolt 33 protruding into the fixing plate 31.

To this end, third fastening holes 214 and 224 may be formed in the outer flanges 211 and 221 of the reinforcing members 21 and 22 to allow the fixing bolt 33 to pass therethrough.

Therefore, the reinforcing members 21 and 22 are installed and fixed so that the fixing bolts 33 are inserted into the third fastening holes 214 and 224 formed in the outer flanges 211 and 221 of the reinforcing members 21 and 22. Secure with nut 332.

As described above, in the present invention, the anchor bolt 32 before the construction of each reinforcing member (21, 22) of the reinforcing frame (2) is first installed on the existing members (11, 12). Therefore, there is no interference with the reinforcing frame (2) during the anchor hole formation or anchor bolt 32 installation process is very easy to construct.

As shown in FIG. 1, a plurality of the fixed adapters 3 may be installed to be spaced apart from each other. Therefore, mortar or the like may be filled between the existing members 11 and 12 and the reinforcing members 21 and 22 at the portion where the fixing plate 31 is not present.

7 is a perspective view showing an embodiment of the fixing plate.

As shown in FIG. 7, the first accommodation housing in which the fixing nut 321 of the anchor bolt 32 is accommodated inside the first fastening hole 311 of the fixing plate 31 into which the anchor bolt 32 is inserted. The second receiving housing 312 is formed and the head portion 331 of the fixing bolt 33 is accommodated outside the second fastening hole 313 of the fixing plate 31 into which the fixing bolt 33 is inserted. Grooves 314 may be formed.

The fixing plate 31 includes a first receiving groove 312 and a second receiving groove 314 in which the fixing nut 321 of the anchor bolt 32 and the head 331 of the fixing bolt 33 are accommodated, respectively. Each of the first fastening holes 311 and the second fastening holes 313 may be formed.

The depth of the first receiving groove 312 can be formed more than the thickness of the fixing nut 321 of the anchor bolt (32). Accordingly, the fixing nut 321 of the anchor bolt 32 may be accommodated in the first accommodation groove 312.

And the depth of the second accommodation groove 314 can be formed more than the thickness of the head portion 331 of the fixing bolt 33. Accordingly, the head part 331 of the fixing bolt 33 may be accommodated in the second accommodation groove 314.

Therefore, the fixing nut 321 and the head portion 331 of the fixing bolt 33 of the anchor bolt 32 can be configured so as not to protrude to the inner and outer surfaces of the fixing plate 31, respectively, the fixing plate 31 ) May be in close contact with the inner surface of the existing member (11, 12), the reinforcing members (21, 22) may be in close contact with the inner surface of the fixing plate (31).

Accordingly, the fixing plate 31 is existing while the reinforcing members 21 and 22 of the reinforcing frame 2 are fixed to the existing members 11 and 12 of the existing frame 1 by the fixing adapter 3. The facing surfaces of the members 11 and 12 and the reinforcing members 21 and 22 are in close contact with each other to be firmly supported.

To this end, the anchor bolt 32 should also be constructed so as not to protrude to the inner surface of the fixing plate (31).

8 is a diagram illustrating a relationship between a second fastening hole and a third fastening hole.

As shown in FIG. 8, the second fastening hole 313 is formed as a long hole in a vertical or horizontal direction, and the third fastening hole 214 of the reinforcing frame 2 to which the fixing bolt 33 is inserted and fastened. , 224 may be formed as a long hole in a direction orthogonal to the second fastening hole 313.

Second fastening of the fixed adapter (3) to absorb the error between the existing member (11, 12) of the existing frame (1) and the reinforcing members (21, 22) of the reinforcing frame (2) in the fixed adapter (3) The holes 313 and the third fastening holes 214 and 224 of the reinforcing members 21 and 22 may be formed as long holes to be perpendicular to each other.

Accordingly, the error between the existing members 11 and 12 and the reinforcing members 21 and 22 may be simultaneously absorbed in two directions, a vertical direction and a horizontal direction.

For example, the second fastening hole 313 may be formed long in the axial direction of the reinforcing members 21 and 22 (or the existing members 11 and 12). Then, the fixing bolt 33 can be moved a predetermined distance in the axial direction can absorb the axial error.

In addition, the third fastening holes 214 and 224 may be formed long in the width direction of the reinforcing members 21 and 22. Then, the width direction errors can be absorbed by adjusting the positions of the reinforcing members 21 and 22 in the width direction.

That is, the fixing bolt 33 is moved in the axial direction, and the reinforcing members 21 and 22 are moved in the width direction, so that errors can be absorbed in two directions.

9 is a perspective view showing a coupling relationship of a corner fixed adapter.

1 and 9, the edge of the existing frame 1 and the reinforcing frame (2) is provided between the existing frame (1) and the reinforcing frame (2) horizontally with the vertical reinforcing member (21) An edge fixing adapter 3 ′ for simultaneously fixing the reinforcing member 22 to the vertical member 11 and the horizontal member 12 may be provided.

An angled fixed adapter (3) is formed between the existing frame (1) and the reinforcing frame (2) so that the vertical reinforcing member (21) and the horizontal reinforcing member (22) can be fixed at the corners of the existing frame (1) at the same time. ') Can be installed.

The corner fixed adapter 3 ′ has the vertical reinforcing member 21 and the horizontal reinforcing member 22 of the reinforcing frame 2, respectively, and the inner side of the vertical member 11 and the horizontal member 12 of the existing frame 1. As well as fixed to the end of the vertical reinforcing member 21 and the horizontal reinforcing member 22 is connected to each other to integrate.

In particular, the length error between the existing frame 1 and the reinforcement frame 2 may be absorbed by the corner fixed adapter 3 '.

That is, the length of the vertical reinforcing member 21 and the horizontal reinforcing member 22 of the reinforcing frame 2 is made shorter than the inner side length of the vertical member 11 and the horizontal member 12 of the existing frame 1, respectively. do. And the fixed adapter for the corner of the outer flange (211, 221) of the vertical reinforcing member 21 and the horizontal reinforcing member 22 in a state where the ends of the vertical reinforcing member 21 and the horizontal reinforcing member 22 are separated by a predetermined distance. By fixing to 3 ', the error between the existing frame 1 and the reinforcement frame 2 can be easily absorbed.

To this end, the corner fixed adapter 3 'is coupled to the first fastening hole 311 formed on each surface of the fixed plate 31' of the L-shape and the fixed plate 31 ', thereby fixing the plate 31'. Is coupled to the anchor bolt 32 and the second fastening hole 313 formed on each side of the fixing plate 31 'to fix the vertical member 11 or the horizontal member 12 of the existing frame 1 to the vertical. The reinforcing member 21 or the horizontal reinforcing member 22 may be configured as a fixed bolt 33 is coupled.

The third fastening holes 214 and 224 of the reinforcing members 21 and 22 to which the second fastening holes 313 and the fixing bolts 33 of the fixed plate 31 'are coupled may be formed to be perpendicular to each other. In this case, the error is more easily absorbed at the frame edge.

End portions of the vertical reinforcing member 21 and the horizontal reinforcing member 22 may be formed to be inclined at an angle corresponding to each other so that the inclined ends are spaced apart from each other.

In this case, the reinforcing members 21 and 22 may absorb the length error of the vertical reinforcing member 21 or the horizontal reinforcing member 22 within the distance of the end.

10 is a front view showing the junction of the vertical reinforcing member and the horizontal reinforcing member.

As shown in FIG. 10, the inner ends and side surfaces of the vertical reinforcing member 21 and the horizontal reinforcing member 22 are fixed to each other by the first splice plate 4 and the second splice plate 5, respectively. Can be.

FIG. 10 is an enlarged view of a portion 'B' of FIG. 1.

Since the corner fixed adapter 3 'connects only the outer flanges 211 and 221 of the vertical reinforcement member 21 and the horizontal reinforcement member 22, the vertical reinforcement member 21 is formed only by the corner fixed adapter 3'. It is difficult to strongly join the joint of the horizontal reinforcing member 22 and the end moment is difficult to transmit.

Therefore, the inner end and side surfaces of the vertical reinforcing member 21 and the horizontal reinforcing member 22 may be joined by a sprite plate.

When the reinforcing members 21 and 22 are H-shaped steel, the inner end means an inner flange 212 and 222 and the side means a web 213 and 223.

Accordingly, the vertical reinforcing member 21 and the horizontal reinforcing member 22 adjacent to each other may have the inner flanges 212 and 222 and the webs 213 and 223, respectively. 5) can be connected to each other.

The first splice plate 4 may be formed in an L-shape in cross section, and each leg may be mutually coupled to the inner flanges 212 and 222 of the vertical reinforcing member 21 and the horizontal reinforcing member 22.

The second splice plate 5 may be formed in a planar L-shape, and each leg may be mutually coupled to the webs 213 and 223 of the vertical reinforcing member 21 and the horizontal reinforcing member 22.

The first splice plate 4 and the second splice plate 5 may be bolted to the flanges 212 and 222 and the webs 213 and 223, respectively.

The first splice plate 4 and the second splice plate 5 can be easily processed in the field. Therefore, in accordance with the position of the bolt fastening hole formed in the vertical reinforcing member 21 and the horizontal reinforcing member 22, it is possible to form a fastening hole for fastening the bolt in the field.

Of course, it is also possible to configure the fastening holes of the first and second splice plates 4 and 5 to form long holes to absorb field errors.

When the webs 213 and 223 of the vertical reinforcing member 21 and the horizontal reinforcing member 22 are not centered with each other, a simple rate is formed between the second splice plate 5 and the webs 213 and 223. It can be configured to absorb the width error by inserting.

1: Existing frame 11: Vertical member
12: horizontal member 2: reinforcing frame
21: vertical reinforcing member 22: horizontal reinforcing member
211, 221: outer flange 212, 222: inner flange
213, 223: Web 214, 224: Third Fastener
3: fixed adapter 3 ': fixed adapter for corners
31: fixed plate 311: first fastener
312: 1st acceptance home 313: 2nd fastener
314: second receiving groove 32: anchor bolt
321: fixing nut 33: fixing bolt
331: head 332: fixing nut
4: first splice plate 5: second splice plate

Claims (7)

To reinforce the existing frame (1) consisting of a vertical member (11) and a horizontal member (12),
A reinforcing frame 2 composed of a vertical reinforcing member 21 and a horizontal reinforcing member 22 provided inside the existing frame 1;
A fixed adapter provided between the reinforcing frame 2 and the existing frame 1 to fix each member 21 and 22 of the reinforcing frame 2 to the corresponding member 11 and 12 of the existing frame 1; 3); And
It is provided between the existing frame 1 and the reinforcement frame 2 at the edges of the existing frame 1 and the reinforcement frame 2 so that each end is inclined at an angle corresponding to each other so that the inclined ends are spaced apart from each other. An edge fixed adapter 3 'for simultaneously fixing the vertical reinforcing member 21 and the horizontal reinforcing member 22 to the vertical member 11 and the horizontal member 12, respectively; Seismic reinforcement frame structure having a fixed adapter, characterized in that consisting of.
In claim 1,
The fixed adapter 3 is a fixed plate 31 provided between the reinforcing members 21 and 22 of the reinforcement frame 2 and the existing members 11 and 12 of the existing frame 1, the fixed plate 31. A seismic reinforcement frame having a fixed adapter, characterized in that consisting of an anchor bolt 32 for fixing to the existing frame (1) and a fixing bolt 33 for fixing the reinforcement frame (2) to the fixing plate (31) rescue.
In claim 2,
A first receiving groove 312 is formed inside the first fastening hole 311 of the fixing plate 31 into which the anchor bolt 32 is inserted, in which the fixing nut 321 of the anchor bolt 32 is accommodated. On the outside of the second fastening hole 313 of the fixing plate 31 into which the fixing bolt 33 is inserted, a second receiving groove 314 is formed in which the head part 331 of the fixing bolt 33 is accommodated. Seismic reinforcement frame structure with a fixed adapter characterized in that.
In claim 3,
The second fastening hole 313 is formed as a long hole in the vertical or horizontal direction, the third fastening holes (214, 224) of the reinforcing frame (2) to which the fixing bolt 33 is inserted and fastened to the second fastening Seismic reinforcement frame structure having a fixed adapter, characterized in that formed in the long hole in the direction orthogonal to the ball (313).
delete delete In claim 1,
The inner ends and side surfaces of the vertical reinforcing member 21 and the horizontal reinforcing member 22 are fixed to each other by the first splice plate 4 and the second splice plate 5, respectively. Seismic reinforcement frame structure provided.

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