KR20180104435A - Seismic Retrofit device of the building which consists of the masonry wall and method thereof - Google Patents

Abstract

An object of the present invention is to provide a seismic retrofit device for a masonry wall building and a method for building the same. In seismic retrofitting of a masonry wall building and in giving a seismic retrofitting force with respect to a masonry wall, a further improved seismic retrofitting force can be applied and building can be facilitated. According to one aspect of the present invention, provided is a seismic retrofit device for a masonry wall building including a plurality of holding blocks (10) erected in a first direction perpendicular to the ground to face both side surfaces (ES) of an edge (E) with respect to the edge of an outer wall (W) of a masonry wall building, a fixing block (20) for fixing and coupling of the holding block (10) adjacent in a second direction perpendicular to the first direction, a flexible FRP band (30) made of an FRP resin material to be in close contact with the outer wall (W) of the building in the second direction, and a variable length coupling block (40) for variable length coupling between both end portions of the flexible FRP band (30) and the holding block (10), which is for the flexible FRP band (30) to apply a close contact pressure (P) in the second direction and inwards in the building with respect to the outer wall (W) of the building.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a seismic retrofit device,

More particularly, the present invention relates to a seismic strengthening apparatus for a building wall structure, and more particularly, to a seismic reinforcing system for a building wall structure, And to improve the ease of construction and the reduction of the construction cost in the reinforcement construction, and to a method of manufacturing the same.

Most of the low-rise buildings built in the Republic of Korea in the 1970s and before the 1980s were mostly constructed using coarse bricks. In constructing a building using such a rough brick, since the bonding force between the rough bricks is made by the cement mortar about 1 cm between the rough bricks, when the earthquake occurs, the shear force between the rough bricks is weak There is a problem that the building is collapsed or damaged as the breakage occurs, resulting in loss of life and property damage.

Therefore, technical attempts have been made to reinforce the seismic performance of existing buildings. As shown in FIG. 1, according to the related art, as shown in FIG. 1, a lower steel plate 100 in the form of a plate, which is elongated in one direction so as to be installed along the surface of a conventional concrete structure, A plurality of anchor bolts 200 installed in the anchor holes formed in the outer region of the steel plate 100 and a fixing nut 210 inserted into the anchor bolts 200 and fastened to the anchor bolts 200, Shaped fixing clamp 300 for fixing the lower steel plate 100 to the surface of the concrete structure by welding the steel plate 100 in the longitudinal direction along the center of the upper surface of the lower steel plate 100 so as to be perpendicular to the lower steel plate 100, A load transfer plate 400 coupled to the lower plate 100 and projecting to the upper portion of the lower plate 100 and a load transfer plate 400 welded to the upper end of the load transfer plate 400, And an anchor elongated hole 310 through which the anchor bolt 200 passes is elongated in the longitudinal direction of the stationary clamp 300 so that the stationary clamp 300 is opened, The position of the light source 300 can be adjusted.

However, according to the related art, since the steel plate is fixed through the fixing clam fixed to the anchor hole in the state where the anchor holes are drilled along the surface of the existing concrete structure, the uniformity of the shear force The seismic performance can not be reinforced. In order to reinforce the uniform seismic performance against the shear force against the entire outer wall of the building, the anchor work and the steel plate corresponding thereto must be used, which lowers the workability and increases the construction cost due to the increase of the load. Therefore, development of a technique capable of solving such a problem is required.

On the other hand, Japanese Patent No. 985886 discloses a seismic strengthening method of a concrete structure using a composite fiber reinforced plate having a polyacetal safety belt. According to the patent, the reinforcing seat belt 100, in which the polyacetal fiber is woven in the shape of a flat belt and impregnated with the thermosetting resin to be drawn and formed, the upper part of the reinforcing seat belt 100, A unidirectional fiber layer (200) laminated on a surface and a lower surface of the unidirectional fiber layer (200) in a longitudinal direction in a state of being impregnated with a thermosetting resin, an adhesive reinforcing concave portion (300) formed on one side or both outer surfaces of the unidirectional fiber layer And a plurality of adhesive reinforcing hole portions (400) penetrating the upper and lower portions along the longitudinally opposite side edge portions of the composite fiber reinforced plate integral with the seat belt (100) and the unidirectional fiber layer (200) A method is disclosed.

According to the above-described technique, the concrete structure is reinforced by using the composite fiber reinforced plate, but it is bound to the concrete structure through a plurality of adhesive strengthening holes penetrating the upper and lower surfaces, There is a problem that is difficult to apply.

Therefore, development of a technique capable of solving these problems is required.

Therefore, it is an object of the present invention to provide an anti-seismic reinforcement device for a masonry wall structure which not only applies a seismic strengthening effect to a masonry wall, but also can easily be applied in the seismic reinforcement of masonry wall masonry And to provide the construction method.

According to an aspect of the present invention, a plurality of stanchion blocks (10), which are erected in a first direction perpendicular to the ground surface, for interfacing opposite side surfaces (ES) of corners (E) of an outer wall (W) A fixed block 20 for fixedly connecting adjacent stanchion blocks 10 in a second direction perpendicular to the first direction, a flexible FRP made of FRP resin to be brought into close contact with the outer wall W of the building in the second direction, The band 30 and the flexible end of the flexible FRP band 30 in order to apply the urging pressure P to the inside of the building with respect to the outer wall W of the building in the second direction And a variable-length coupling block (40) for coupling the strut block (10) with a variable length.

Here, it is preferable that the end face of the holding block 10 is formed of a section steel having a cross-sectional shape of a cross section corresponding to a corner section of the outer wall W of the building.

On the other hand, the holding block 10 has an opening 12 partially opened in correspondence with a part where both side edges ES of the outer wall W of the building meet, and the joining block 40 has an opening 12, Length coupling member 40C with respect to the connecting portion 40C.

The support block 10 is provided with a guide groove 14 for guiding the flexible FRP band 30 to the opening 12 inside the one side surface of the transverse section and a guide groove 14 It is preferable that a variable length coupling hole 16h is provided for the variable length coupling block 40 so as to variably maintain the spacing distance D with respect to the variable length coupling block 40 .

The opening 12 of the support block 10 in which the guide groove 14 and the variable-length coupling hole 16h are formed has a guide groove 14 and a variable-length coupling hole 16h in the adjacent opening 12 It is preferable that they are arranged continuously with respect to the longitudinal direction of the stanchion block 10 so as to be offset from each other.

Both ends of the flexible FRP band 30 may be fixedly coupled to the coupling block 40 via the coupling hole 40h of the coupling block 40 and the coupling block 40c, 40 are formed integrally with each other.

The joint G and the brick BR between the bricks BR of the outer wall W of the building in the state where the liquid FRP resin mixed with the curing agent is applied is provided inside the flexible FRP band 30 It is preferable that they are in close contact with each other.

The joint block 40 to which both end portions of the flexible FRP band 30 are fixed is disposed so that the spacing D between the opposing faces of the joint block 40 and the opening end face 16 of the support block 10 is minimum The variable length coupling member 40C passes through the hole 40H provided in the coupling block 40 with respect to the variable length coupling hole 16h of the support block 10 so that the opening end face of the support block 10 (16) and the coupling block (40) are coupled to each other.

According to another aspect of the present invention, a plurality of strut blocks (hereinafter referred to as " strut blocks ") are installed in a first direction perpendicular to the ground surface to face the both sides ES of the corner with respect to the edge E of the outer wall W of the building, 10), a second step of fixing the fixing block (20) for fixing the adjacent stanchion block (10) in the second direction perpendicular to the first direction to the stanchion block (10), and a second step of fixing the FRP The flexible FRP band 30 of the resin material is brought into close contact with the outer wall W of the building in the second direction so that the flexible FRP band 30 is moved in the second direction relative to the outer wall W of the building And a third step of connecting both end portions of the flexible FRP band 30 to the stanchion block 10 in a variable length by the variable-length coupling block 40 so as to apply an urging pressure P to the inside of the fixed- Is provided.

Therefore, according to the present invention, in the seismic strengthening of the masonry wall building, it is possible not only to apply the improved earthquake resistance to the masonry wall, but also to easily construct it.

Fig. 1 is a schematic view of an advanced steel structure in cross-sectional expansion according to Japanese Patent No. 1214139.
2 is a schematic perspective view of an anti-seismic reinforcement of a concrete structure using a composite fiber reinforced plate with a polyacetal seat belt according to Japanese Patent No. 985886. Fig.
3 is a schematic perspective view of an apparatus for seismic strengthening of masonry wall tiles according to a preferred embodiment of the present invention.
FIGS. 4A to 4C are partial enlarged views of FIG. 3 illustrating a process of installing an anti-seismic reinforcement of a masonry wall blank according to a preferred embodiment of the present invention.
5 is a cross-sectional view taken along the line XX of 4c.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a seismic retrofitting apparatus for a building wall structure according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a schematic perspective view of an apparatus for reinforcing seismically strengthened walls according to a preferred embodiment of the present invention, and FIGS. 4a to 4c are views showing an installation process of a seismic strengthening apparatus for a wall- Fig. 5 is a partial enlarged view of Fig. 3, and Fig. 5 is a sectional view taken along the line XX of 4c.

3 to 5, according to the seismic retrofitting apparatus of the present invention, the edge E of the outer wall W of the building, A fixed block 20 for fixedly connecting the adjacent stanchion blocks 10 in a second direction perpendicular to the first direction, a plurality of support blocks 10 fixedly installed in the first direction, A flexible FRP band 30 made of an FRP resin material and a flexible FRP band 30 arranged in a second direction so as to be brought into close contact with the outer wall W of the building in two directions, And a variable length coupling block 40 for coupling both ends of the flexible FRP band 30 to the landing block 10 in a variable length so as to apply the contact pressure P to the inside.

The support block 10 is erected in a first direction perpendicular to the ground so as to be in contact with both edges ES of the corners E of the outer wall W of the building, At this time, it is preferable that the end face of the support block 10 be formed of a section having a cross-sectional shape corresponding to a corner section of the outer wall W of the building, preferably a section having a cross-sectional shape.

At the upper and lower ends of the support block 10, adjoining support blocks 10 are provided with coupling holes 10h for coupling by the fixed block 20. [ On the other hand, the holding block 10 has openings 12 partially open to partially correspond to the portions where both side edges ES of the corners of the outer wall W of the building meet. The opening 12 of the stake block 10 is opened in the longitudinal direction of the stake block 10 with an a-shaped cross section so that the end portions of both side edges ES of the corners of the outer wall W of the building are partially exposed . The support block 10 is formed with a guide groove 14 for guiding the flexible FRP band 30 to the opening 12 inside one side of the cross section. The variable length coupling block 40 is provided with a variable length coupling block 40 on the opening end face 16 of the other side where the guide groove 14 is not formed so as to variably maintain the spacing distance D with respect to the variable length coupling block 40. [ A hole 16h is provided.

The opening 12 of the support block 10 in which the guide groove 14 and the variable-length coupling hole 16h are formed is formed such that the guide groove 14 and the variable-length coupling hole 16h in the neighboring opening 12 are positioned Are continuously arranged with respect to the longitudinal direction of the support block (10) so as to be staggered.

A plurality of openings 12 are formed in the support block 10 such that the guide grooves 14 of the adjacent openings 12 and the variable-length engagement holes 16h are staggered with respect to the longitudinal direction of the support blocks 10 It is possible to provide ease of construction and firm adhesion when the flexible FRP band 30 is applied to the inside of the outer wall W of the building with respect to the outer wall W of the building.

The fixed block 20 is formed of a plate for fixedly coupling adjacent stanchion blocks 10 in a second direction perpendicular to the first direction which is the longitudinal direction of the stanchion block 10, And a fastening hole 20h corresponding to the engaging hole 10h and the fastening block 20 is engaged with the holding block 10 by the fastening member S. [

The flexible FRP band 30 is made of a flexible band made of FRP resin so as to be brought into close contact with the outer wall W of the building in the second direction which is the transverse direction of the outer wall W of the building. Both ends of the flexible FRP band 30 are fixedly coupled to the coupling block 40 via the coupling hole 40h of the coupling block 40 and the coupling member 40c. The joint block 40 is fixed to both ends of the flexible FRP band 30 in a state where the flexible FRP band 30 is cut so as to correspond to the lateral length of the outer wall W of the building.

On the other hand, in a state where a liquid FRP resin mixed with a curing agent is applied to the inside of the flexible FRP band 30, the joint G or the brick BR between the bricks BR of the outer wall W of the building . At this time, the coupling block 40 to which both end portions of the flexible FRP band 30 are fixed is spaced apart from the opposing face D of the coupling block 40 by the opening end face 16 of the support block 10 The variable length coupling member 40C passing through the hole 40H provided in the coupling block 40 with respect to the variable length coupling hole 16h of the pillar block 10 is made to be the minimum The side surface 16 and the coupling block 40 are fastened together.

As described above, according to the present invention, since the FRP resin mixed with the curing agent is applied to the inside of the flexible FRP band 30, the flexible FRP band 30 is more firmly bonded to the brick BR of the outer wall W of the building, And the flexible FRP band 30 is supported on the inner side of the outer wall W of the building with the longitudinal axis of the support block 10 as a support shaft irrespective of the lateral length of the outer wall W of the building By making the contact pressure P act in the direction, the vibration resistance can be more firmly improved and the field workability can be improved.

In the above embodiment, the coupling block 40 is fixed at both ends of the flexible FRP band 30 by the coupling member 40c. According to a modification of the present invention, And FRP blocks integrally formed at both ends of the FRP band 30.

As described above, according to the present invention, in the state where the holding block 10 and the fixed block 20 provide the anti-vibration force of the base frame with respect to the corner surfaces of the outer wall W of the building as a whole, The coupling block 40 is coupled to the opening 12 of the stake block 10 so as to minimize the spacing D relative to the opening end face 16 of the opening 12 of the building, The flexible FRP band 30 which is brought into close contact with the outer wall W of the building can provide a strong anti-vibration force against the inside of the outer wall W of the building, and the convenience of the construction can be improved.

D: Spacing space
E: Corner
ES: Both sides of corner
P: Adhesion pressure
S: fastening member
W: Outer wall of the building
10: holding block
10h: coupling ball
12: opening
14: Guide groove
16: opening end face
16h: Variable Length Coupling Balls
20: Fixed block
20h: fastening hole
30: Flexible FRP band
40: variable length coupling block
40C: Variable length fastening member
40h: coupling ball
40H: hole

Claims (9)

A plurality of strut blocks (10) erected in a first direction perpendicular to the ground so as to face both side edges (ES) of a corner (E) of an outer wall (W)
A fixed block (20) for fixedly coupling adjacent stanchion blocks (10) in a second direction perpendicular to the first direction;
A flexible FRP band 30 made of FRP resin material to be brought into close contact with the outer wall W of the building in the second direction; And
Both ends of the flexible FRP band 30 are moved to the holding block 10 so that the flexible FRP band 30 applies the urging pressure P to the inside of the building with respect to the outer wall W of the building in the second direction And a variable-length coupling block (40) for connecting the variable-length coupling block (40) with the variable-length coupling block (40). The seismic retrofitting apparatus according to claim 1, characterized in that the end face of the holding block (10) is formed of a section having a cross section in the shape of a section corresponding to a corner section of the outer wall (W) of the building. The building block (10) according to claim 1 or 2, wherein the holding block (10) has an opening (12) partially open corresponding partly to a part where both side edges (ES) of a corner of an outer wall (W) (40) is coupled to the opening (12) by a variable-length fastening member (40C). The support block (10) according to claim 3, wherein a guide groove (14) for guiding the flexible FRP band (30) to the opening (12) is formed inside one side of the transverse section, and the guide groove A variable length engaging hole 16h for the variable length engaging block 40 is provided in the opening end surface 16 of the other side which is not formed so as to variably maintain the spacing distance D with respect to the variable length engaging block 40 Wherein the reinforcing member is made of a synthetic resin. 5. The apparatus according to claim 4, wherein the opening (12) of the stanchion block (10) having the guide groove (14) and the variable length coupling hole (16h) is formed in the opening (12) adjacent to the guide groove (16h) are arranged continuously with respect to the longitudinal direction of the stanchion block (10) so as to be offset from each other. The flexible FRP band according to claim 1 or 2, wherein both ends of the flexible FRP band (30) are fixedly coupled to the coupling block (40) through the coupling hole (40h) of the coupling block (40) and the coupling member , And is integrally formed with the joint block (40) by FRP resin. The method as claimed in claim 6, wherein a joint G between the bricks (BR) of the outer wall (W) of the building and a brick (brick) BR) of the outer wall of the building wall. The joining block (40) according to claim 5, wherein the joint block (40) to which both ends of the flexible FRP band (30) are fixed is a spacing space Length coupling member 40C passing through the hole 40H provided in the coupling block 40 with respect to the variable-length coupling hole 16h of the support block 10 so that the support block 10 is at a minimum, And the joint block (40) is coupled to the opening end surface (16) of the joint wall (40). A first step of erecting a plurality of stanchion blocks (10) erected in a first direction perpendicular to the ground so as to face both side edges (ES) of corners (E) of an outer wall (W)
A second step of fixing the fixed block (20) to the holding block (10) for fixing the adjacent stanchion blocks (10) in a second direction perpendicular to the first direction; And
The flexible FRP band 30 of the flexible FRP band 30 is brought into contact with the outer wall W of the building in the second direction and the flexible FRP band 30 of the flexible FRP band 30 is pressed against the outer wall W of the building in the second direction, And a third step of joining both ends of the flexible FRP band 30 to the stanchion block 10 in a variable length by the variable-length coupling block 40 so as to apply an urging pressure P to the inside of the building. Of reinforced concrete structures.

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