KR102342137B1 - Seismic reinforcing super frame - Google Patents

Abstract

Seismic reinforcement super frame according to an embodiment of the present invention as to implement the earthquake-resistant reinforcement of the existing building, a first reinforcement pillar disposed on the outside of the pillar of the building; a second reinforcement pillar spaced apart from the first reinforcement pillar in the longitudinal direction and disposed on the outside of the pillar of the building; and a first reinforcement bearing disposed on the outside of the underground beam of the building, extending in the longitudinal direction, and connected to the first reinforcement column and the second reinforcement column; An external force may be transmitted from the first reinforcing pillar to the second reinforcing pillar and from the second reinforcing pillar to the first reinforcing pillar.

Description

Seismic reinforcing super frame

The present invention relates to a seismic reinforcement super frame and an earthquake-resistant reinforcement method using the same, and more particularly, to an earthquake-resistant reinforcement super frame installed in an existing building to implement earthquake-resistant reinforcement of an existing building, and a seismic reinforcement method using the same.

Existing buildings constructed before the seismic design standards were established lack seismic performance, so considerable damage and collapse are expected in the event of an earthquake.

To solve these problems, the government is continuously conducting seismic performance evaluation and seismic reinforcement projects for public buildings.

The government's earthquake-resistance reinforcement project for existing buildings is being carried out extensively for schools, local government offices, hospitals, fire stations, and other important buildings that serve as shelters and bases for disaster relief in the event of an earthquake.

In particular, the front and rear elevations of most school buildings differ only in the finishing materials, but the lower part where the windows are installed on each floor is constructed in a form with a very short net length as a masonry or concrete wall (hereafter waist wall) is formed. .

In this case, as can be seen from overseas earthquake damage cases, when an earthquake occurs, the column member does not behave as a flexural member but is brittle and destroyed by shear.

Therefore, in the case of overseas, an elastic body is placed between the junction of the waist wall and the column to form a gap, but when this method is applied, the scope of construction is wide and it is not a realistic alternative.

In addition, even if the junction between the column and the waist wall is cut, the ductility of the column itself is slightly improved, but the insufficient strength is not improved.

In Korean Patent Registration 10-1397800, a longitudinal member is installed for seismic reinforcement on an existing concrete column, and after the permanent formwork is installed, concrete is poured into the permanent formwork.

However, this method has a problem in that it cannot effectively implement the seismic reinforcement function by increasing only the cross section of the column.

The present invention is to solve the above problems, and to provide an earthquake-resistant reinforcement super frame that can be easily installed in an existing building and further maximizes the earthquake-resistance function, and an earthquake-resistant reinforcement method using the same.

The problem to be solved by the present invention is not limited to the above-mentioned problems, and the problems not mentioned will be clearly understood by those of ordinary skill in the art to which the present invention belongs from the present specification and the accompanying drawings. .

Seismic reinforcement super frame according to an embodiment of the present invention as to implement the earthquake-resistant reinforcement of the existing building, a first reinforcement pillar disposed on the outside of the pillar of the building; a second reinforcement pillar spaced apart from the first reinforcement pillar in the longitudinal direction and disposed on the outside of the pillar of the building; and a first reinforcement bearing disposed on the outside of the underground beam of the building, extending in the longitudinal direction, and connected to the first reinforcement column and the second reinforcement column; An external force may be transmitted from the first reinforcing pillar to the second reinforcing pillar and from the second reinforcing pillar to the first reinforcing pillar.

The earthquake-resistant reinforcement super frame according to an embodiment of the present invention can be easily installed in an existing building, and furthermore, the earthquake-resistant function can be maximized.

Effects of the present invention are not limited to the above-described effects, and effects not mentioned will be clearly understood by those of ordinary skill in the art to which the present invention pertains from the present specification and accompanying drawings.

1 is a schematic perspective view showing an earthquake-resistant reinforcement super frame of the present invention and an existing building.
Figure 2 is a schematic perspective view showing the earthquake-resistant reinforcement super frame of the present invention omitting the existing building.
Figure 3 is a schematic cross-sectional view showing a reinforcing column of the present invention.
Figure 4 is a schematic cross-sectional view showing a reinforced underground beam of the present invention.
Figure 5 is a schematic cross-sectional view showing the reinforcement of the present invention.
6 is a schematic cross-sectional view showing a connection part of the present invention.
Figure 7 is a schematic perspective view showing a seismic reinforcement pillar frame of the present invention.
Figure 8 is a schematic side view showing the seismic reinforcement pillar frame of the present invention.
Figure 9 is a schematic cross-sectional view showing the seismic reinforcement pillar frame of the present invention.
Figure 10 is a schematic cross-sectional view showing another embodiment of the reinforcement column of the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. However, the spirit of the present invention is not limited to the presented embodiments, and those skilled in the art who understand the spirit of the present invention may add, change, delete, etc. other elements within the scope of the same spirit, and may use other degenerative inventions or the present invention. Other embodiments included within the scope of the present invention may be easily proposed, but these will also be included within the scope of the present invention.

Seismic reinforcement super frame according to an embodiment of the present invention as to implement the earthquake-resistant reinforcement of the existing building, a first reinforcement pillar disposed on the outside of the pillar of the building; a second reinforcement pillar spaced apart from the first reinforcement pillar in the longitudinal direction and disposed on the outside of the pillar of the building; and a first reinforcement bearing disposed on the outside of the underground beam of the building, extending in the longitudinal direction, and connected to the first reinforcement column and the second reinforcement column; An external force may be transmitted from the first reinforcing pillar to the second reinforcing pillar and from the second reinforcing pillar to the first reinforcing pillar.

In addition, the first reinforcement beam is disposed on the outside of the above-ground beam of the building and extends in the longitudinal direction to be connected to the first reinforcement pillar and the second reinforcement pillar; further comprising,

The first reinforcing supporting beam may transmit an external force from the first reinforcing pillar to the second reinforcing pillar and from the second reinforcing pillar to the first reinforcing pillar.

In addition, spaced apart from the first reinforcing pillar in the width direction, the third reinforcing pillar disposed on the outside of the pillar of the building; a fourth reinforcing pillar spaced apart from the second reinforcing pillar in the width direction, spaced apart from the third reinforcing pillar in the longitudinal direction, and disposed on the outside of the pillar of the building; and a second reinforcement bearing spaced apart from the first reinforcement underground beam in the width direction, disposed on the outer side of the underground beam of the building, extending in the longitudinal direction, and connected to the third reinforcement column and the fourth reinforcement column It further includes, and the second reinforcing bearing may transmit an external force from the third reinforcing pillar to the fourth reinforcing pillar and from the fourth reinforcing pillar to the third reinforcing pillar.

In addition, it is disposed on the outer side of the above ground beam of the building, the second reinforcing crossbeam is extended in the longitudinal direction and connected to the third reinforcing pillar and the fourth reinforcing pillar; further comprising, the second reinforcing crossbeam An external force may be transmitted from the third reinforcing pillar to the fourth reinforcing pillar and from the fourth reinforcing pillar to the third reinforcing pillar.

In addition, the first reinforcing support beam may be disposed at a different height from that of the second reinforcing support beam in the height direction.

In addition, the first reinforcing pillar, the second reinforcing pillar, the third reinforcing pillar and the fourth reinforcing pillar are arranged to protrude further than the building in the height direction, and extend in the width direction to extend the first reinforcing pillar and the third reinforcing pillar a first connector connected to the column; and a second connecting portion extending in the width direction and connected to the second reinforcing pillar and the fourth reinforcing pillar, wherein the first connecting portion and the second connecting portion are not constrained to the building in the height direction. They may be spaced apart.

The earthquake-resistant reinforcement method according to another embodiment of the present invention may be a method of implementing earthquake-resistant reinforcement in an existing building using the earthquake-resistant reinforcement super frame.

Seismic reinforcement pillar frame according to another embodiment of the present invention as to implement the earthquake resistance reinforcement of the pillar of the existing building, the body portion disposed inside the pillar of the building; an upper extension portion extending obliquely from the body portion and facing the upper slab; and a lower extension part extending obliquely from the body part and facing the lower slab, wherein the body part may form an insertion space into which the ground beam of the building is inserted.

In addition, the upper extension portion may extend to be inclined in a direction different from the inclination direction of the lower extension portion.

In addition, the upper extension part is fixed to the upper slab by a fastening member, the lower extension part is fixed to the lower slab by a fastening member, and the fastening member fixed to the upper slab is fixed to the lower slab in the height direction. It may not overlap the fastening member.

In addition, the reinforcing bar surrounding at least a portion of the pillar of the building; may further include.

In addition, the band reinforcement is opposed to the first band reinforcement disposed on one side of the pillar of the building, the second belt reinforcement disposed on the other side of the pillar of the building, and the body portion, and the first band reinforcement and the second band reinforcement It may be provided with a third reinforcing bar to connect.

In addition, one end of the first reinforcing bar is welded to the body portion, one end of the second reinforcing bar is welded to the main body, and the third reinforcing bar is the first reinforcing bar and the second band. It can be connected to the other end of the reinforcing bar.

In addition, the band reinforcement is surrounded by the concrete by concrete pouring, the body portion may function as a formwork in the concrete pouring.

The earthquake-resistant reinforcement method according to another embodiment of the present invention may be a method of implementing earthquake-resistant reinforcement of a column of an existing building using the earthquake-resistant reinforcement column frame.

Elements having the same function within the scope of the same idea shown in the drawings of each embodiment will be described using the same reference numerals.

1 is a schematic perspective view showing an earthquake-resistant reinforcement super frame of the present invention and an existing building, Figure 2 is a schematic perspective view showing the earthquake-resistant reinforcement super frame of the present invention omitting the existing building.

Figure 3 is a schematic cross-sectional view showing the reinforcement column of the present invention, Figure 4 is a schematic cross-sectional view showing the reinforcement ground beam of the present invention, Figure 5 is a schematic cross-sectional view showing the reinforcement support beam of the present invention, Figure 6 is this It is a schematic cross-sectional view showing the connection part of the invention.

Figure 7 is a schematic perspective view showing the earthquake-resistant reinforcement column frame of the present invention, Figure 8 is a schematic side view showing the earthquake-resistant reinforcement column frame of the present invention, Figure 9 is a schematic cross-sectional view showing the earthquake-resistant reinforcement column frame of the present invention .

In the accompanying drawings, in order to more clearly express the technical spirit of the present invention, parts that are not related to the technical spirit of the present invention or that can be easily derived from those skilled in the art have been simplified or omitted.

1 to 6 , the earthquake-resistant reinforcement super frame 10 according to an embodiment of the present invention may be constructed in the existing building B to reinforce the earthquake resistance of the existing building B.

As an example, the existing building (B) may be a building (B) including a foundation (B3), a column (B1), a beam (B2), a slab (B4), and the like.

As an example, the existing building (B) may be a school, a hospital, etc., but is not limited thereto, and may correspond to the existing building (B) if it is a structure requiring seismic reinforcement.

Here, as an example, the earthquake-resistant reinforcement super frame 10 is spaced apart from the first reinforcing pillar 100 and the first reinforcing pillar 100 disposed on the outside of the pillar B1 of the building B in the longitudinal direction. and may include a second reinforcing pillar 200 disposed on the outside of the pillar B1 of the building B.

For example, the first reinforcing pillar 100 may be constructed to overlap on the pillar B1 on the outside of the building B, and may receive external force from the pillar B1 of the building B.

As an example, the second reinforcing pillar 200 is another pillar B1 on the outside of the building B spaced apart in the longitudinal direction from the pillar B1 of the building B on which the first reinforcing pillar 100 is constructed. ) may be overlapped and constructed, and an external force may be transmitted from the pillar B1 of the building B.

The first reinforcing pillar 100 and the second reinforcing pillar 200 may extend in a height direction, and may be spaced apart from each other in the longitudinal direction to cover at least a portion of one side of the building (B).

Here, as an example, the earthquake-resistant reinforcement super frame 10 is disposed on the outer side of the underground beam (B2) of the building (B), and extends in the longitudinal direction to the first reinforcement column 100 and the second reinforcement It may further include a first reinforcing ground beam 300 connected to the pillar 200 .

For example, the first reinforcing underground beam 300 may be constructed underground by excavating the ground.

For example, the first reinforcing beam 300 may extend in the longitudinal direction, and at the same time, one end may be connected to the first reinforcing pillar 100 and the other end may be connected to the second reinforcing pillar 200 .

As a result, the first reinforcing subbeam 300 is from the first reinforcing pillar 100 to the second reinforcing pillar 200 and from the second reinforcing pillar 200 to the first reinforcing pillar 100 . It can transmit external force.

Here, as an example, the earthquake-resistant reinforcement super frame 10 is disposed on the outside of the above-ground beam B2 of the building B, and extends in the longitudinal direction to the first reinforcement column 100 and the second reinforcement It may further include a first reinforcing ground beam 400 connected to the pillar 200 .

As an example, the first reinforcement beam 400 may be constructed on the beam B2 of the building B exposed to the ground.

For example, the first reinforcing supporting beam 400 may be disposed to be spaced apart from the first reinforcing supporting beam 300 in the height direction.

For example, the first reinforcing support beam 400 may extend in the longitudinal direction, and at the same time, one end may be connected to the first reinforcing pillar 100 and the other end may be connected to the second reinforcing pillar 200 .

As a result, the first reinforcing beam 400 is from the first reinforcing pillar 100 to the second reinforcing pillar 200 and from the second reinforcing pillar 200 to the first reinforcing pillar 100 . It can transmit external force.

Here, as an example, the earthquake-resistant reinforcement super frame 10 is spaced apart from the first reinforcement pillar 100 in the width direction, and a third reinforcement pillar 500 disposed on the outside of the pillar B1 of the building B ) and a fourth spaced apart from the second reinforcing pillar 200 in the width direction, spaced apart from the third reinforcing pillar 500 in the longitudinal direction, and disposed on the outside of the pillar B1 of the building B It may further include a reinforcing column (600).

As an example, the third reinforcing pillar 500 may be constructed to be overlapped on the other outer pillar B1 of the building B, and may receive external force from the pillar B1 of the building B.

As an example, the fourth reinforcing pillar 600 is another pillar ( It may be constructed by overlapping on B1), and external force may be transmitted from the pillar B1 of the building B.

The third reinforcing pillar 500 and the fourth reinforcing pillar 600 may extend in the height direction and may be spaced apart from each other in the longitudinal direction to cover at least a portion of the other side of the building (B).

For example, the third reinforcing pillar 500 may be spaced apart from the first reinforcing pillar 100 in the width direction, and may be spaced apart from the fourth reinforcing pillar 600 in the longitudinal direction.

For example, the fourth reinforcing pillar 600 may be spaced apart from the second reinforcing pillar 200 in the width direction, and may be spaced apart from the third reinforcing pillar 500 in the longitudinal direction.

Here, as an example, the earthquake-resistant reinforcement super frame 10 is spaced apart from the first reinforcement underground beam 300 in the width direction, and is disposed on the outside of the underground beam B2 of the building B, and the longitudinal direction It further includes a second reinforcing sub-beam 700 connected to the third reinforcing pillar 500 and the fourth reinforcing pillar 600,

As an example, the second reinforcement underground beam 700 may be constructed underground by excavating the ground.

For example, the second reinforcing beam 700 may extend in the longitudinal direction, and at the same time, one end may be connected to the third reinforcing pillar 500 and the other end may be connected to the fourth reinforcing pillar 600 .

As a result, the second reinforcing beam 700 is from the third reinforcing pillar 500 to the fourth reinforcing pillar 600 and from the fourth reinforcing pillar 600 to the third reinforcing pillar 500 . It can transmit external force.

Here, as an example, the earthquake-resistant reinforcement super frame 10 is disposed on the outside of the ground beam B2 of the building B, and extends in the longitudinal direction to the third reinforcement column 500 and the fourth reinforcement It may further include a second reinforcing ground beam 800 connected to the pillar 600 .

As an example, the second reinforcement beam 800 may be constructed on the ground beam B2 of the building B exposed to the ground.

For example, the second reinforcing supporting beam 800 may be disposed to be spaced apart from the second reinforcing supporting beam 700 in the height direction.

For example, the second reinforcing beam 800 may extend in the longitudinal direction, and at the same time, one end may be connected to the third reinforcing pillar 500 and the other end may be connected to the fourth reinforcing pillar 600 .

As a result, the second reinforcing ground beam 800 is from the third reinforcing pillar 500 to the fourth reinforcing pillar 600 and from the fourth reinforcing pillar 600 to the third reinforcing pillar 500 . It can transmit external force.

Here, as an example, the first reinforcing supporting beam 400 may be disposed at a different height from the second reinforcing supporting beam 800 in the height direction.

To explain this in more detail, as an example, when the first reinforcement beam 400 is disposed at the height K1 of the second floor of the existing building B, the second reinforcement beam 800 is the existing building (B). It can be arranged at the height K2 of the third floor of B).

If it is assumed that the first reinforcement beam 400 and the second reinforcement beam 800 are disposed at the same height in the height direction, for example, they are disposed at the height of the second floor of the existing building (B). If it is assumed that there is an earthquake, when an external force is concentrated on the second floor of the existing building B due to an earthquake, the first reinforcing crossbeam 400 and the second reinforcing crossbeam 800 may be destroyed.

Accordingly, the first reinforcing crossbeam 400 is disposed at the height K1 of the second floor of the existing building B, and the second reinforcing crossbeam 800 is the height K2 of the third floor of the existing building B. ), when an external force is concentrated on the second floor of the existing building (B) due to an earthquake, etc., only the first reinforcing cross-beam 400 is destroyed, but the second reinforcing cross-beam 800 is not destroyed. The building (B) can be supported more firmly.

Here, as an example, the first reinforcing pillar 100 , the second reinforcing pillar 200 , the third reinforcing pillar 500 and the fourth reinforcing pillar 600 are higher than the building B in the height direction. It may be arranged to protrude further.

That is, as an example, the first reinforcing pillar 100 , the second reinforcing pillar 200 , the third reinforcing pillar 500 , and the fourth reinforcing pillar 600 are the height directions of the building (B). Rather than extending only to the pillar B1, it may extend beyond the pillar B1 of the building B and be disposed higher than the building B to protrude upward from the building B.

Here, as an example, the earthquake-resistant reinforcement super frame 10 extends in the width direction and is connected to the first reinforcing pillar 100 and the third reinforcing pillar 500 in the first connection part 910 and the width direction. It may further include a second connection portion 920 extending to the second reinforcing pillar 200 and the fourth reinforcing pillar 600 connected to.

For example, the first connection part 910 may extend in the width direction, and at the same time, one end may be connected to the first reinforcing pillar 100 and the other end may be connected to the third reinforcing pillar 500 .

As a result, the first connection part 910 applies an external force from the first reinforcing pillar 100 to the third reinforcing pillar 500 and from the third reinforcing pillar 500 to the first reinforcing pillar 100 . can transmit

Also, as an example, the second connection part 920 may extend in the width direction, and at the same time, one end may be connected to the second reinforcing pillar 200 and the other end may be connected to the fourth reinforcing pillar 600 .

As a result, the second connection part 920 applies an external force from the second reinforcing pillar 200 to the fourth reinforcing pillar 600 and from the fourth reinforcing pillar 600 to the second reinforcing pillar 200 . can transmit

Here, for example, the first connection part 910 and the second connection part 920 may be disposed to be spaced apart from the building B in the height direction so as not to be constrained by the building B.

That is, the first connecting portion 910 may be connected to the first reinforcing pillar 100 and the third reinforcing pillar 500 that further protrude upward from the building B, and the second connecting portion 920 is It may be connected to the second reinforcing pillar 200 and the fourth reinforcing pillar 600 that further protrude upward from the building (B).

As a result, the first connection part 910 and the second connection part 920 can implement the internal force only to implement the earthquake-resistant function without receiving the external force directly from the existing building (B).

The earthquake-resistant reinforcement method according to another embodiment of the present invention may be a method of implementing the earthquake-resistant reinforcement of the existing building (B) by using and constructing the earthquake-resistant super frame 10 in the existing building (B).

For example, as shown in FIG. 3 , the first reinforcing pillar 100 , the second reinforcing pillar 200 , the third reinforcing pillar 500 and the fourth reinforcing pillar 600 are ) and may be constructed in contact with the column B1, and may be constructed as a reinforced concrete structure.

In addition, as an example, as shown in Figure 10 (a), the first reinforcing pillar 100, the second reinforcing pillar 200, the third reinforcing pillar 500 and the fourth reinforcing pillar 600 ) can be constructed as a reinforced concrete structure that is extended to the pillars B1 of the building B.

In addition, as an example, as shown in Figure 10 (b), the first reinforcing pillar 100, the second reinforcing pillar 200, the third reinforcing pillar 500 and the fourth reinforcing pillar 600 ) is added to the pillar (B1) of the building (B), but it can also be constructed in the form of a wing wall.

At this time, the upper end of the first reinforcing pillar 100, the second reinforcing pillar 200, the third reinforcing pillar 500 and the fourth reinforcing pillar 600 may form a plurality of pillar protrusions, , the first connection part 910 and the second connection part 920 may form a plurality of connection depressions into which the pillar protrusion is inserted.

That is, the first reinforcing pillar 100 , the second reinforcing pillar 200 , the third reinforcing pillar 500 and the fourth reinforcing pillar 600 and the The coupling and external force transmission between the first connection part 910 and the second connection part 920 may be implemented more efficiently.

Although not shown in the drawings, the first reinforcing pillar 100 , the second reinforcing pillar 200 , the third reinforcing pillar 500 , and the fourth reinforcing pillar 600 may be constructed in the form of a wing wall. .

For example, as shown in FIG. 4 , the first reinforced underground beam 300 and the second reinforced underground beam 700 may be constructed in contact with the underground beam B2 of the building B, and reinforcing bars It can be constructed as a concrete structure.

As an example, the first reinforced underground beam 300 and the second reinforced underground beam 700 may be constructed in contact with not only the underground beam B2 of the building B but also the foundation B3 of the building B. have.

For example, as shown in FIG. 5 , the first reinforcing ground beam 400 and the second reinforcing ground beam 800 may be constructed in contact with the ground beam B2 of the building B, and reinforcing bars It can be constructed as a concrete structure.

For example, as shown in FIG. 6 , the first connection part 910 and the second connection part 920 may be constructed apart from the building B without contacting the building B, and have a reinforced concrete structure. can be constructed with

Previously, the configuration of the earthquake-resistant reinforcement super frame 10 has been described as a reinforced concrete structure that can be constructed in the existing building (B), but is not limited thereto, and may be a steel structure in whole or in part, It can be changed in various ways from the point of view.

Hereinafter, with reference to FIGS. 7 to 9, an earthquake-resistant reinforcement pillar frame 1000 according to another embodiment of the present invention will be described in detail.

As an example, the earthquake-resistant reinforcement pillar frame 1000 may be configured to implement earthquake-resistant reinforcement of the pillar B1 of the existing building (B).

As an example, the earthquake-resistant reinforcement pillar frame 1000 includes the first reinforcement pillar 100, the second reinforcement pillar 200, the third reinforcement pillar 500 and It may be a configuration used to construct the fourth reinforcement pillar 600, but is not limited thereto, and if it can reinforce the pillar B1 of the existing building B, the earthquake-resistant reinforcement pillar frame 1000 this can be used

Here, as an example, the earthquake-resistant reinforcement pillar frame 1000 is a body portion 1100 disposed inside the pillar B1 of the building B, and extends to be inclined from the body portion 1100 and includes an upper slab B4 and It may include an opposing upper extension 1200 and a lower extension 1300 extending obliquely from the main body 1100 and facing the lower slab B4.

For example, the main body 1100 may have a plate shape having a predetermined area.

As an example, the body part 1100 may be made of a steel material, but is not limited thereto and may be variously changed from the standpoint of a person skilled in the art.

For example, the main body 1100 may be disposed on the inside of the pillar B1 of the building B.

For example, the main body 1100 may be disposed in contact with the inner surface of the pillar B1 of the building B.

Accordingly, it is possible to minimize the loss of the internal space of the building (B).

For example, the upper extension portion 1200 may be disposed to face the upper slab B4 of the building B positioned above the height direction.

For example, the upper extension part 1200 may be bent and extended from the main body part 1100 .

For example, the upper extension part 1200 may be made of a steel material, but is not limited thereto and may be variously changed from the standpoint of a person skilled in the art.

For example, the lower extension part 1300 may be disposed to face the lower slab B4 of the building B located on the lower side in the height direction.

For example, the lower extension part 1300 may be bent and extended from the main body part 1100 .

For example, the lower extension part 1300 may be made of a steel material, but is not limited thereto and may be variously changed from the standpoint of a person skilled in the art.

Here, as an example, the main body 1100 may form an insertion space S1 into which the above-ground beam B2 of the building B is inserted.

For example, the above-ground beam B2 of the existing building B may be inserted and positioned on the insertion space S1.

For example, the main body 1100 defining the insertion space S1 may be in contact with the ground beam B2.

For example, as the above-ground beam B2 is inserted into the insertion space S1, the main body 1100 may be fixed on the existing building B.

Here, as an example, the upper extension 1200 may extend to be inclined in a direction different from that of the lower extension 1300 .

For example, the upper extension 1200 may extend from the main body 1100 to be inclined inward of the building B, and the lower extension 1300 may extend from the main body 1100 to the building B. ) may be extended to be inclined to the outside.

Here, as an example, the upper extension 1200 is fixed to the upper slab B4 by a fastening member, and the lower extension 1300 is fixed to the lower slab B4 by a fastening member. .

For example, the upper extension 1200 and the lower extension 1300 may include a through hole H through which a fastening member such as an anchor can be fastened.

The fastening member may be fixed to the upper slab B4 and the lower slab B4 through the through hole H, thereby fixing the earthquake-resistant reinforcement pillar frame 1000 on the building B.

Here, the fastening member fixed to the upper slab B4 may not overlap with the fastening member fixed to the lower slab B4 in the height direction.

To explain this in more detail, as an example, the upper extension 1200 may extend from the main body 1100 to be inclined to the inside of the building B, and the lower extension 1300 may include the main body ( 1100) may extend to the outside of the building B, and the lower slab through the fastening member fixed to the upper slab B4 through the upper extension 1200 and the lower extension 1300 Between the fastening members fixed to (B4) may not overlap in the height direction.

As a result, the fastening members respectively fixed to the upper slab B4 and the lower slab B4 are fastened so as not to be concentrated on one of the upper slab B4 and the lower slab B4, and the upper slab B4 And it is possible to minimize the reduction in yield strength due to the loss of the cross-section of the lower slab (B4).

Here, as an example, the earthquake-resistant reinforcement pillar frame 1000 may further include a band reinforcement 1400 surrounding at least a portion of the pillar (B1) of the building (B).

As an example, the earthquake-resistant reinforcement pillar frame 1000 may further include a main reinforcing bar (C) disposed adjacent to the pillar (B1) of the building (B).

As an example, the band reinforcing bar 1400 may surround the main reinforcing bar (C).

Here, as an example, the reinforcing bar 1400 is a first reinforcing bar 1410 disposed on one side of the pillar B1 of the building B, and a second reinforcing bar 1410 disposed on the other side of the pillar B1 of the building B. A belt reinforcement 1420 and a third belt reinforcement 1430 facing the body portion 1100 and connecting the first belt reinforcement 1410 and the second belt reinforcement 1420 may be provided.

For example, the first reinforcing bar 1410 , the second reinforcing bar 1420 , and the third band reinforcing bar 1430 may surround the main reinforcing bar (C).

Here, as an example, one end of the first reinforcing bar 1410 is connected to the main body 1100 by welding, and one end of the second reinforcing bar 1420 is connected to the main body 1100 by welding, and the The third band reinforcing bar 1430 may be connected to the other end of the first band reinforcing bar 1410 and the second band reinforcing bar 1420 .

As a result, the first reinforcing bar 1410 and the body portion 1100 may be integrated with each other by welding, and the second reinforcing bar 1420 and the body portion 1100 may also be integrated with each other by welding. can

Accordingly, the body portion 1100 may also function as a tension member, similarly to the band reinforcement 1400 .

Here, as an example, the reinforcing bar 1400 may be surrounded by the concrete D by pouring the concrete D, and the body 1100 may function as a formwork for the concrete D pouring. have.

That is, as the main body 1100 is disposed on the inside of the pillar B1 of the building B, it implements the function of earthquake-resistant reinforcement, and at the same time may have a formwork function in the concrete D pouring operation.

Hereinafter, a construction method of the earthquake-resistant reinforcement pillar frame 1000 will be described in more detail with reference to FIG. 9 .

As shown in Fig. 9 (a), as an example, the main body 1100 may be disposed inside the pillar B1 of the building B, and the pillar (B) of the building B by fastening to the fastening member. B1) Can be fixed on the inside.

For example, the first reinforcing bar 1410 and the second reinforcing bar 1420 may be disposed on the main body 1100 by welding.

Here, as shown in FIG. 9B , the main reinforcing bar C may be disposed, and the third band reinforcing bar 1430 may be disposed.

Accordingly, the band reinforcing bar 1400 may surround the main reinforcing bar (C).

Here, as shown in Fig. 9(c), a formwork (T) may be installed, and the body part 1100 cooperates with the formwork (T) so that the concrete (D) poured does not leak to the outside. It is possible to implement the function of the formwork.

As a result, as shown in Figure 9 (d), the earthquake-resistant reinforcement pillar frame 1000 can reinforce the pillar (B1) of the existing building (B).

In the above, the configuration and features of the present invention have been described based on the embodiments according to the present invention, but the present invention is not limited thereto, and it is understood that various changes or modifications can be made within the spirit and scope of the present invention. It is intended that such changes or modifications will be apparent to those skilled in the art, and therefore fall within the scope of the appended claims.

100: first reinforcement column
200: second reinforcement column
300: first reinforcement ground beam
400: first reinforcement ground beam

Claims (1)

In the earthquake-resistant reinforcement super frame that implements the earthquake-resistant reinforcement of an existing building,
A first reinforcing column disposed on the outside of the column of the building;
a second reinforcement pillar spaced apart from the first reinforcement pillar in the longitudinal direction and disposed on the outside of the pillar of the building; and
A first reinforcement underground beam disposed on the outer side of the underground beam of the building and extending in the longitudinal direction to be connected to the first reinforcement pillar and the second reinforcement pillar; and
The first reinforcement supporting beam,
Transmitting an external force from the first reinforcing pillar to the second reinforcing pillar and from the second reinforcing pillar to the first reinforcing pillar,
It is disposed on the outer side of the above ground beam of the building, the first reinforcing beam extending in the longitudinal direction and connected to the first reinforcing pillar and the second reinforcing pillar; further comprising,
The first reinforcing support,
Transmitting an external force from the first reinforcing pillar to the second reinforcing pillar and from the second reinforcing pillar to the first reinforcing pillar,
a third reinforcement pillar spaced apart from the first reinforcement pillar in the width direction and disposed on the outside of the pillar of the building;
a fourth reinforcing pillar spaced apart from the second reinforcing pillar in the width direction, spaced apart from the third reinforcing pillar in the longitudinal direction, and disposed on the outside of the pillar of the building; and
a second reinforcement bearing spaced apart from the first reinforcement bearing in the width direction, disposed on the outer side of the underground beam of the building, extending in the longitudinal direction, and connected to the third reinforcement column and the fourth reinforcement column; further comprising,
The second reinforcement supporting beam,
Transmitting an external force from the third reinforcing pillar to the fourth reinforcing pillar and from the fourth reinforcing pillar to the third reinforcing pillar,
It is disposed on the outer side of the ground beam of the building, the second reinforcement beam extending in the longitudinal direction and connected to the third reinforcement pillar and the fourth reinforcement pillar; further comprising,
The second reinforcing support,
Transmitting an external force from the third reinforcing pillar to the fourth reinforcing pillar and from the fourth reinforcing pillar to the third reinforcing pillar,
The first reinforcing pillar, the second reinforcing pillar, the third reinforcing pillar and the fourth reinforcing pillar,
It is arranged to protrude more than the building in the height direction,
a first connecting portion extending in the width direction and connected to the first reinforcing pillar and the third reinforcing pillar; and
It further comprises;
The first connection part and the second connection part,
It is spaced apart from the building in the height direction so as not to be constrained by the building.
The first reinforcing sub-beam and the second reinforcing sub-beam,
It is constructed in contact with the building's underground beam and the building's foundation, and receives external force from the building's underground beam and the building's foundation.
Each of the first reinforcing pillar, the second reinforcing pillar, the third reinforcing pillar and the fourth reinforcing pillar,
A main body disposed inside a pillar of a building, an upper extension extending obliquely from the main body and facing the upper slab, and a lower extension extending obliquely from the main body and facing the lower slab,
Seismic reinforcement super frame.

Images