KR20240035774A - Strut Buckling Preventing Type Steel Slit Damper, Earthquake-Resistant Reinforcement Structure and Construction Method - Google Patents

Abstract

The present invention relates to a seismic energy attenuation device for earthquake-resistant reinforcement of a structure, which is a plate-shaped member consisting of a plurality of slits 110 cut in parallel in the center and an uncut area between the slits 110. Steel slit plate (100) provided with struts (140); As a section steel member, a first section steel bracket 210 is coupled so that a portion of the steel slit plate 100 overlaps the web while a coupling bolt 410 is fastened so that one rear side of the steel slit plate 100 is in close contact with the web; As a section steel member, the second section steel bracket 220 is coupled so that the rear surface of the other side of the steel slit plate 100 is in close contact with the web and the coupling bolt 410 is fastened so that a portion of the remaining area of the steel slit plate 100 overlaps the web. ; It is disposed on the front of the steel slit plate 100 so as to cross one side of the slit 110 and the strut 140 of the steel slit plate 100, and both sides of the area outside the steel slit plate 100 are first section steel brackets 210. ) A first out-of-plane deformation prevention plate 310 to which a coupling bolt 410 is fastened so as to be coupled to the web of ); It is disposed on the front of the steel slit plate 100 so as to cross the other side of the slit 110 and the strut 140 of the steel slit plate 100, and both sides of the area outside the steel slit plate 100 are second section steel brackets 220. ) A second out-of-plane deformation prevention plate 320 to which a coupling bolt 410 is fastened so as to be coupled to the web of ); A first close contact bolt 511 that penetrates the first out-of-plane deformation prevention plate 310, passes through one side of the slit 110 of the steel slit plate 100, and is fastened through the first section steel bracket 210; And, a second close bolt 512 that penetrates the second out-of-plane deformation prevention plate 310, passes through the other side of the slit 110 of the steel slit plate 100, and is fastened through the second shape steel bracket 210. It is characterized by including; and provides related seismic reinforcement structures and construction methods.

Description

Strut out-of-plane deformation prevention type steel slit damper and earthquake-resistant reinforcement structure and construction method using the same {Strut Buckling Preventing Type Steel Slit Damper, Earthquake-Resistant Reinforcement Structure and Construction Method}

The present invention relates to a strut out-of-plane deformation prevention type steel slit damper, which includes a plurality of slits 110 provided in a steel slit plate 100, a plurality of struts 140 provided in parallel between the plurality of slits 110, A first out-of-plane deformation prevention plate 310 and a second out-of-plane deformation prevention plate 320 are provided on one side and the other side of the slit 110 and the strut 140, respectively, to press both ends of the strut 140 evenly to press the strut. It is characterized by being able to effectively induce in-plane deformation of (140).

In a steel slit damper, a portion of a plate-shaped steel plate is cut to form a plurality of slits in parallel at regular intervals, and the strut area between the slits undergoes plastic deformation to attenuate wind or seismic loads.

However, the existing steel slit damper does not provide a method to effectively prevent out-of-plane deformation by evenly adhering multiple struts provided at regular intervals, so when wind load or seismic load is input, out-of-plane deformation occurs in the strut area, resulting in wind or seismic load. The effect of attenuating is being significantly halved.

Recently, in-plane deformation guide plates have been developed and applied to prevent out-of-plane deformation that occurs in the strut area of steel slit dampers. However, steel slit dampers are equipped with multiple slits and struts at regular intervals, and existing in-plane deformation guide plates have steel slits. Since the damper is only fixed with bolts at both ends and supports multiple struts, it is difficult to properly suppress out-of-plane deformation of the central struts that are away from the bolt fixings at both ends.

Therefore, there is a need to develop a new concept of a steel slit damper that can evenly adhere both ends of a plurality of struts by fastening bolts that closely adhere the in-plane deformation guide plate to each end of the plurality of slits provided in the steel slit damper.

[Prior art literature]

Registered Patent No. 10-1578198

Registered Patent No. 10-1753011

Registered Patent No. 10-2447986

The purpose of the present invention, which was created to solve the above problems, is to provide a new concept of a steel slit damper that can secure the basic behavior of the steel slit damper and at the same time effectively prevent out-of-plane deformation of the strut area where the slit is formed.

The technical structure of the present invention created to achieve the above purpose is as follows.

The present invention relates to a seismic energy attenuation device for earthquake-resistant reinforcement of a structure, which is a plate-shaped member consisting of a plurality of slits 110 cut in parallel in the center and a plurality of uncut areas between the slits 110. A steel slit plate (100) provided with a strut (140); As a section steel member, the first section steel bracket 210 is coupled so that a portion of the steel slit plate 100 overlaps the web while the coupling bolt 410 is fastened so that one rear side of the steel slit plate 100 is in close contact with the web. ); As a section steel member, the second section steel bracket is coupled so that the other rear side of the steel slit plate 100 is in close contact with the web, and a portion of the remaining area of the steel slit plate 100 overlaps the web. 220); It is disposed on the front side of the steel slit plate 100 so as to cross one side of the slit 110 and the strut 140 of the steel slit plate 100, and both sides of the area outside the steel slit plate 100 are the first A first out-of-plane deformation prevention plate 310 to which a coupling bolt 410 is fastened to be coupled to the web of the section steel bracket 210; It is disposed on the front of the steel slit plate 100 so as to cross the other side of the slit 110 and the strut 140 of the steel slit plate 100, and both sides of the area outside the steel slit plate 100 are the second A second out-of-plane deformation prevention plate 320 to which a coupling bolt 410 is fastened to be coupled to the web of the section steel bracket 220; A first contact bolt 511 that penetrates the first out-of-plane deformation prevention plate 310, passes through one side of the slit 110 of the steel slit plate 100, and is fastened through the first shape steel bracket 210. ); And, a second close bolt that penetrates the second out-of-plane deformation prevention plate 310, passes through the other side of the slit 110 of the steel slit plate 100, and is fastened through the second shape steel bracket 210. It is characterized by including (512);

In addition, the present invention relates to a seismic reinforcement structure using a strut out-of-plane deformation prevention type steel slit damper, comprising: an upper steel frame portion 610 formed by combining steel frames; A lower steel frame portion 620 formed by combining steel frames; A steel slit damper 101 in which a first section steel bracket 210 is coupled to the upper end of the lower steel frame portion 620 and a second section steel bracket 220 is coupled to the lower end of the upper steel frame section 610; And, it is installed spaced apart on both left and right sides of the steel slit damper 101, the upper part is pinned to the lower end of the upper steel frame part 610, and the lower part is pinned to the upper end of the lower steel frame part 620. It is characterized by including a hinge portion (630).

also. The present invention relates to a method of constructing an earthquake-resistant reinforced structure using a strut out-of-plane deformation prevention type steel slit damper. After demolishing the existing finishing material, paint and foreign substances on the surface of the existing structure reinforcement area are removed, and the steel slit damper (101) is used to remove paint and foreign substances from the surface of the existing structure reinforcement area. A first step of pre-treating the surface of the area where the seismic reinforcement structure will be installed by chipping; A second step of determining the location where the earthquake-resistant reinforcement structure using the steel slit damper 101 will be installed and using the reinforcement explorer to identify and display the location of the reinforcement inside the existing structure (structure to be reinforced); Holes for mounting anchor bolts 690 are drilled at the top and bottom of the existing structure according to the hole pattern pre-formed in the base plate 670 installed between the existing structure and the earthquake-resistant reinforcement structure using the steel slit damper 101. Stage 3; Anchor bolts (690) are pre-fastened to the top of the existing structure to temporarily assemble the base plate (670) to which the ) A fourth step of temporarily assembling only the base plate 670 to which the X-type brace 680 is not coupled so that there is a gap at the bottom of the existing structure; The seismic reinforcement structure using the steel slit damper (101) with the After coming into contact with the bottom of the X-type brace (680), the X-type brace (680) and the base plate (670) are welded together, and the ) is pushed or pulled so that the Fifth step of combining; A sixth step of completely tightening the anchor bolts (690) temporarily fastened to the top and bottom of the existing structure; The seventh step of installing formwork in the space between the earthquake-resistant reinforcement structure using the steel slit damper (101) and the existing structure and curing it by pouring mortar or concrete; And, an eighth step of completing construction after dismantling the formwork and performing a finishing process.

The technical effects of the configuration of the present invention are as follows.

First, according to an embodiment of the present invention (Figure 1), when a close contact bolt provided with a close contact spacer is fastened, each of the front and rear surfaces of one side and the other side of both ends of the strut provided between the slits of the steel slit plate is deformed out of plane. The web of the prevention plate and the section steel bracket effectively prevents out-of-plane deformation of the strut by pressing it evenly, thereby attenuating wind or seismic loads through stable energy dissipation through in-plane deformation of the strut.

Second, according to another embodiment of the present invention (FIG. 2), when a close contact bolt provided with a close contact spacer is fastened, the front and rear surfaces of both ends of the strut provided between the slits of the steel slit plate are separated by two outer surfaces each. The deformation prevention plate presses evenly and effectively prevents out-of-plane deformation of both ends of the strut, thereby attenuating wind or seismic loads through stable energy dissipation through in-plane deformation of the strut.

Third, in the case of a seismic reinforcement structure using a steel slit damper, a hinge using a pin is added to effectively attenuate external forces by preventing out-of-plane buckling of the slit steel damper through axial rotation of the hinge when external shock and seismic loads are transmitted. .

Fourth, out-of-plane deformation of the strut provided on the steel slit plate is prevented, plastic deformation is achieved, and the hinge portion is properly rotated, thereby effectively attenuating external shock or seismic load while preventing deformation or damage to the seismic reinforcement structure.

Fifth, when installing a seismic reinforcement structure corresponding to a heavy object using the construction method of the present invention, the reinforcing bars of the existing structure can be easily avoided at the site, and field errors can be easily resolved, thereby improving work efficiency and quality.

Figure 1 shows a specific embodiment of the steel slit damper of the present invention.
Figure 2 shows another specific embodiment of the steel slit damper of the present invention.
Figure 3 shows a specific example of a seismic reinforcement structure using a steel slit damper 101.
Figure 4 shows another specific embodiment of a seismic reinforcement structure using a steel slit damper 101.
Figure 5 briefly shows a construction method related to the present invention.

Hereinafter, specific embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

The present invention relates to a strut out-of-plane deformation prevention type steel slit damper, which, as shown in Figure 1, includes a steel slit plate 100, a first section steel bracket 210, a second section steel bracket 220, and a first out-of-plane deformation prevention plate. It includes (310), a second out-of-plane deformation prevention plate (320), a first close bolt, and a second close bolt (512).

The steel slit plate 100 is a plate-shaped member, and is provided with a plurality of slits 110 cut in the center in parallel, and between the slits 110 and the slits 110, a strut 140 in an uncut area is arranged side by side. It is well equipped.

The first beam bracket 210 is a beam member, and is not limited to only the 'H' beam shown in Figure 1, and beam members with various cross sections can be selected.

As the coupling bolt 410 is fastened so that one rear side of the steel slit plate 100 is in close contact with one side of the web of the first section steel bracket 210, a portion of the area (one side) of the steel slit plate 100 is attached to the first section steel bracket 210. ) is combined to overlap the web.

The second section steel bracket 220 is a section steel member, and is not limited to only the 'H' section steel shown in Figure 1, and section steel members with various cross sections can be selected.

As the coupling bolt 410 is fastened so that the rear side of the other side of the steel slit plate 100 is in close contact with the other side of the web of the second section steel bracket 220, a portion of the remaining area (the other side) of the steel slit plate 100 is attached to the second section steel bracket. It is combined to overlap the web of (220).

The first out-of-plane deformation prevention plate 310 is disposed on the front of the steel slit plate 100 in a direction crossing one side of the plurality of slits 110 arranged in parallel on the steel slit plate 100.

The left and right areas of the first out-of-plane deformation prevention plate 310 outside the steel slit plate 100 are coupled with coupling bolts 410 to be coupled to the web of the first beam bracket 210.

The first contact bolt 511 is fastened to penetrate the first out-of-plane deformation prevention plate 310 and the first section steel bracket 210 so as to pass through one side of the slit 110 of the steel slit plate 100.

The second out-of-plane deformation prevention plate 320 is disposed on the front of the steel slit plate 100 in a direction crossing the other side of the plurality of slits 110 arranged in parallel on the steel slit plate 100.

The left and right areas of the second out-of-plane deformation prevention plate 320 outside the steel slit plate 100 are coupled with coupling bolts 410 to be coupled to the web of the second shape steel bracket 220.

The second close bolt 512 is fastened to penetrate the second out-of-plane deformation prevention plate 320 and the second shape steel bracket 220 so as to pass through the other side of the slit 110 of the steel slit plate 100.

The coupling spacer 420 is installed in the empty space between the left and right sides of the first out-of-plane deformation prevention plate 310 outside the steel slit plate 100 and the first section steel bracket 210. In addition, the coupling spacer 420 is installed in the empty space between the second beam bracket 220 and each of the left and right sides of the second out-of-plane deformation prevention plate 320 outside the steel slit plate 100.

In this way, when the coupling spacer 420 is installed and the coupling bolt 410 is fastened, it supports both sides of the first out-of-plane deformation prevention plate 310 and the first section steel bracket 210, or the second out-of-plane deformation prevention plate 320 ) Even when the coupling bolt 410 is tightened while supporting both sides and the second section steel bracket 220, the first out-of-plane deformation prevention plate 310, the web of the first section steel bracket 210, and the second out-of-plane deformation prevention plate 320 ) Alternatively, the web of the second section steel bracket 220 can be prevented from bending.

This coupling spacer 420 has a hole formed so that it can be inserted into the coupling bolt 410 as shown in Figure 1, and each of the left and right sides of the first out-of-plane deformation prevention plate 310 and the first beam bracket 210 are formed. The specific shape can be freely modified as long as it can support or support the left and right sides of the second out-of-plane deformation prevention plate 320 and the second beam bracket 210.

The close contact spacer 520 is inserted into each of the first close bolt 511 and the second close bolt 512 and forms a steel slit plate 100 between the first out-of-plane deformation prevention plate 310 and the first section steel bracket 210. ) is located inside one side of the slit 110 provided in, and is also located inside the other side of the slit 110 provided in the steel slit plate 100 between the second out-of-plane deformation prevention plate 320 and the second shape steel bracket 220. .

Therefore, when the first close bolt 511 is fastened, it is a structure that supports the first anti-buckling plate 310 and the first section steel bracket 210, and when the first close bolt 511 is tightened, the first out-of-plane deformation prevention plate It is possible to prevent the web of (310) or the first beam bracket (210) from bending or excessive restraint of the struts (140) provided on the steel slit plate (100), and when the second close bolt (512) is fastened, It is a structure that supports the two-plane deformation prevention plate 320 and the second shape steel bracket 220, and when the second close bolt 512 is tightened, the web of the second out-of-plane deformation prevention plate 320 or the second shape steel bracket 220 It is possible to prevent bending or excessive restraint of the strut 140 provided on the steel slit plate 100.

As this close contact spacer 520 is provided, when the first close bolt 511 is fastened, the front and rear surfaces of one side of the slit of the steel slit plate 100 are connected to the first out-of-plane deformation prevention plate 310 and the first shape steel bracket 210. The web is pressed evenly, and when the second adhesive bolt 512 is tightened, the web of the second external deformation prevention plate 320 and the second shape steel bracket 220 is attached to the front and rear surfaces of the other slit side of the steel slit plate 100. By pressing evenly, out-of-plane deformation of the struts 140 provided on the steel slit plate 100 is effectively prevented and at the same time, the normal behavior of the steel slit plate 100 is not disturbed.

Figure 2 shows another specific embodiment of a strut out-of-plane deformation prevention type steel slit damper.

The steel slit plate 100 is a plate-shaped member, and is provided with a plurality of slits 110 formed by cutting the central part arranged side by side, and between the slits 110 and the slits 110, there is a strut in the uncut area ( 140) is provided parallel to the slit 110.

The first out-of-plane deformation prevention plate coupling piece 131 extends from each of the left and right ends of one side of the steel slit plate 100 outside the slit area toward the other side of the steel slit plate 100 in a direction parallel to the slit 110. is formed.

The second out-of-plane deformation prevention plate coupling piece 132 extends toward one side of the steel slit plate 100 in a direction parallel to the slit 110 from each of the left and right ends of the other side of the steel slit plate 100 outside the slit area. is formed.

The first beam bracket 210 is a beam member, and is not limited to only the 'H' beam as shown in Figure 2, and beam members with various cross sections can be selected.

A coupling bolt 410 is fastened to the web of the first section steel bracket 210 so that the rear side of one side of the steel slit plate 100 is in close contact, and a partial area (one side) of the steel slit plate 100 is attached to the first section steel bracket 210. It is combined to overlap the web of.

The second section steel bracket 220 is a section steel member, and is not limited to only the 'H' section steel as shown in Figure 2, and section steel members with various cross sections can be selected.

A coupling bolt 410 is fastened to the web of the second section steel bracket 220 so that the rear side of the other side of the steel slit plate 100 is in close contact, and a portion of the remaining area (the other side) of the steel slit plate 100 is attached to the first section steel bracket 210. ) is combined to overlap the web.

The first out-of-plane deformation prevention plate 310 is disposed on each of the front and rear sides of the steel slit plate 100 so as to cross one side of the slit 110 of the steel slit plate 100.

A first out-of-plane deformation is formed on each of the left and right ends of the first out-of-plane deformation prevention plate 310 that goes beyond the slit area of the steel slit plate 100 and faces each other with the first out-of-plane deformation prevention plate coupling piece 131 in between. The coupling bolt 410 is fastened to penetrate the prevention plate coupling piece 131.

That is, the first out-of-plane deformation prevention plate coupling piece 131 of the steel slit plate 100 is sandwiched between the two first out-of-plane deformation prevention plates 310.

The second out-of-plane deformation prevention plate 320 is disposed on each of the front and rear sides of the steel slit plate 100 so as to cross the other side of the slit 110 of the steel slit plate 100.

A second out-of-plane deformation is formed on each of the left and right ends of the second out-of-plane deformation prevention plate 320, which goes beyond the slit area of the steel slit plate 100 and faces each other with the second out-of-plane deformation prevention plate coupling piece 132 in between. The coupling bolt 410 is fastened to penetrate the prevention plate coupling piece 132.

That is, the second out-of-plane deformation prevention plate coupling piece 132 of the steel slit plate 100 is sandwiched between the two second out-of-plane deformation prevention plates 320.

The first close bolt 511 is inserted into a pair of overlapping first out-of-plane deformation prevention plates 310 with the steel slit plate 100 in between so as to pass through one side of the slit 110 of the steel slit plate 100. It is concluded.

The close contact spacer 520 is inserted into the first close bolt 511 and is located on one side of the slit 110 provided in the steel slit plate 100 between the pair of first out-of-plane deformation prevention plates 310 facing each other. When the first close bolt 511 is fastened, it supports the two first out-of-plane deformation prevention plates 310 and prevents the first out-of-plane deformation prevention plate 310 from bending even when the first close bolt 511 is tightened. At the same time, excessive restraint of the strut 140 provided on the steel slit plate 100 can be prevented.

As this close contact spacer 520 is provided, when the first close contact bolt 511 is fastened, the two first out-of-plane deformation prevention plates 310 are evenly spaced at the front and rear surfaces of one side of the slit 110 of the steel slit plate 100. While pressing, out-of-plane deformation of the strut 140 provided on the steel slit plate 100 is effectively prevented, and wind load or earthquake load can be stably attenuated by the steel slit plate 100.

The second close bolt 512 is passed through the other side of the slit 110 of the steel slit plate 100 and passes through a pair of second out-of-plane deformation prevention plates 320 that overlap with the steel slit plate 100 in between. It is concluded.

The close contact spacer 520 is inserted into the second close bolt 512 and is located on the other side of the slit 110 provided in the steel slit plate 100 between the pair of second out-of-plane deformation prevention plates 320 facing each other. When the second close bolt 512 is fastened, the second out-of-plane deformation prevention plate 320 is supported and the second out-of-plane deformation prevention plate 320 is bent even when the second close bolt 512 is tightened. At the same time, it is possible to prevent excessive restraint of the strut 140 provided on the steel slit plate 100.

As this close contact spacer 520 is provided, when the second close bolt 512 is fastened, the two second out-of-plane deformation prevention plates 320 are evenly spaced at the front and rear surfaces of the other side of the slit 110 of the steel slit plate 100. While pressing, out-of-plane deformation of the strut 140 provided on the steel slit plate 100 is effectively prevented, and wind load or earthquake load can be stably attenuated by the steel slit plate 100.

The seismic reinforcement structure using the strut out-of-plane deformation prevention type steel slit damper shown in Figure 1 or Figure 2 may be the structure shown in Figure 3 or Figure 4.

The steel slit damper 101 shown in FIG. 3 is a strut out-of-plane deformation prevention type steel slit damper shown in FIG. 1, and the steel slit damper 101 shown in FIG. 4 is a strut out-of-plane deformation prevention type steel material shown in FIG. 2. It is a slit damper, and these steel slit dampers (101) are compatible with each other, so an appropriate steel slit damper (101) can be selected as needed. That is, in the case of FIG. 4, the steel slit damper 101 shown in FIG. 1 can be used, and in the case of FIG. 3, the steel slit damper 101 shown in FIG. 2 can also be used.

The upper steel frame portion 610 and the lower steel frame portion 620 of the seismic reinforcement structure shown in Figure 3 are each formed by combining steel frames (steel members) to form a specific type of skeleton. The horizontal and vertical frames are combined to form a skeleton. It is generally rectangular in shape overall, and if necessary, an 'X' steel frame that intersects the inner space of the rectangle may be added as shown in Figure 3.

The steel slit damper 101 is installed between the upper steel frame part 610 and the lower steel frame part 620 and connects the upper steel frame part 610 and the lower steel frame part 620. The steel slit damper 101 ) Among the configurations, the first section steel bracket 210 is coupled to the upper end of the lower steel frame portion 620, and the second section steel bracket 220 is coupled to the lower end of the upper steel frame section 610.

The general welding method is applied for joining.

The hinge portion 630 is installed spaced apart on both left and right sides of the steel slit damper 101. The upper portion of the hinge portion 630 is pin-coupled to the lower end of the upper steel frame portion 610, and the lower portion of the hinge portion 630 is pin coupled to the upper end of the lower steel frame portion 620 and connects the upper steel frame portion 610 and the lower steel frame portion 620 with the steel slit damper 101.

That is, with the steel slit damper 101 in the center, the hinge portion 630 is disposed on both left and right sides, and the steel slit damper 101 and the hinge portion 630 are connected to the upper steel frame portion 610 and the lower steel frame portion 620. ) into one structure, and when an external shock or seismic load acts, the steel slit plate 100 and the hinge portion 630 of the steel slit damper 101 move and the external force is gradually attenuated.

Figure 4 shows another embodiment of a seismic reinforcement structure using a strut out-of-plane deformation prevention type steel slit damper.

A pair of horizontal steel frames 640 are arranged side by side and spaced apart at the upper and lower parts.

A pair of vertical steel frames 650 are coupled to the left and right sides of the horizontal steel frames 640 spaced apart from the upper and lower parts, thereby forming an overall square-shaped steel frame.

The hinge portion 630 is installed at a location where the horizontal steel frame 640 and the vertical steel frame 650 are joined. One side of the hinge portion 630 is pin-connected to the horizontal steel frame 640, and the other side of the hinge portion 630 The side is pin-connected to the vertical steel frame (650).

Pin coupling can be done in a way that the main pin is fastened in the center and auxiliary pins are fastened to the circular cut portion (not shown) on both sides around it. In this case, rotation is possible only as much as the cut area of the circular cut portion.

The bridge-type steel frame 660 is coupled to the upper and lower parts of each of the vertical steel frames 650, and extends in directions facing each other to form an overall symmetrical structure in the shape of "〕〔".

The steel slit damper (101) is installed between bridge-type steel frames (660) forming an overall symmetrical structure in the shape of "〕〔". The first section steel bracket (210) of the steel slit damper (101) is connected to the bridge-type steel frame (660). It is coupled to any one of the bridge-type steel frames 660, and the second beam bracket 220 is coupled to the remaining one of the bridge-type steel frames 660, connecting the spaced apart bridge-type steel frames 660 into one, and when an external shock or seismic load acts, the steel As the steel slit plate 100 and the hinge portion 630 of the slit damper 101 move, external force is gradually attenuated.

The construction method of a seismic reinforcement structure using a strut out-of-plane deformation prevention type steel slit damper will be described with reference to Figure 5.

(1) Stage 1

After demolition of the existing finishing material, paint and foreign substances are removed from the surface of the reinforcement area of the existing structure, and the surface of the area where the seismic reinforcement structure using the steel slit damper (101) will be installed is pretreated by chipping. This process can be performed in the following steps. there is.

1) After checking safety scaffolding, dust scattering measures, noise measures, electricity, communication, and plumbing facilities, etc., existing finishing materials in areas expected to be earthquake-resistant are thoroughly removed.

2) Confirm the installation location of the anti-buckling steel slit seismic energy attenuation device and proceed with field measurements of obstacles and relevant areas.

3) Roughly treat the surface of the installation location of the anti-buckling steel slit seismic energy attenuation device by hand grinding or chipping away finishing paint or other foreign substances.

(2) Second stage

This is the process of determining the location where the seismic reinforcement structure using the steel slit damper (101) will be installed, and using the reinforcement explorer to identify and display the location of the reinforcement inside the existing structure (structure subject to reinforcement).

(3) Third stage

Holes for mounting anchor bolts 690 are drilled at the top and bottom of the existing structure according to the hole pattern pre-formed in the base plate 670 installed between the existing structure and the earthquake-resistant reinforcement structure using the steel slit damper 101. .

(4) Step 4

Anchor bolts (690) are pre-fastened to the top of the existing structure to temporarily assemble the base plate (670) to which the ) is pre-assembled so that only the base plate (670) to which the

(5) Step 5

The seismic reinforcement structure using the steel slit damper (101) with the After coming into contact with the bottom of the

In addition, the 680) and the top of the seismic reinforcement structure are welded together.

This welding and joining process must be performed while checking the verticality and horizontality of the seismic reinforcement structure using the steel slit damper (101).

(6) Step 6

This is the process of completely tightening the anchor bolts (690) temporarily fastened to the top and bottom of the existing structure to complete the final mechanical connection. In this process, the seismic reinforcement structure using the already set steel slit damper (101) is divided into sections and tightened sequentially to prevent horizontal and vertical distortion.

(7) Step 7

This is the process of installing formwork in the space between the earthquake-resistant reinforcement structure using a steel slit damper (101) and the existing structure and pouring mortar or concrete to cure it.

To surround the space between the earthquake-resistant reinforcement structure using a steel slit damper (101) and the existing structure, formwork is installed using galvanized steel plates, wood, uniforms, etc. to suit site conditions, and high-strength non-shrinking mortar or concrete is used along with vibration work. After casting tightly, cure sufficiently for a preset curing time (for example, 72 hours).

(8) Step 8

After dismantling the form and carrying out the finishing process, construction is completed.

As described above, specific embodiments of the present invention have been described with reference to the accompanying drawings, but the scope of protection of the present invention is not necessarily limited to these embodiments, and various design changes, It is clarified that addition or deletion of known technology, or simple numerical limitation, also falls within the scope of protection of the present invention.

101: Steel slit damper
100: Steel slit plate
110: Slit
131: First surface external deformation prevention plate combination piece
132: Second surface deformation prevention plate combination piece
140: Strut
210: 1st section steel bracket
220:Second steel bracket
310: First surface external deformation prevention plate
320: Second surface deformation prevention plate
410: Combined bolt
420: Spacer for combination
511: 1st close bolt
512: Second close bolt
520: Close fitting spacer
610: Upper steel frame part
620: Lower steel frame part
630: Hinge part
640:Horizontal steel frame
650: Vertical steel frame
660: Bridge type steel frame
670: Base plate
680:X-type brace
690: Anchor bolt

Claims (7)

It relates to a seismic energy attenuation device for earthquake-resistant reinforcement of structures,
A steel slit plate (100), which is a plate-shaped member and is provided with a plurality of slits (110) cut in parallel in the center and a plurality of struts (140) made of uncut areas between the slits (110);
As a section steel member, the first section steel bracket 210 is coupled so that a portion of the steel slit plate 100 overlaps the web while the coupling bolt 410 is fastened so that one rear side of the steel slit plate 100 is in close contact with the web. );
As a section steel member, the second section steel bracket is coupled so that the other rear side of the steel slit plate 100 is in close contact with the web, and a portion of the remaining area of the steel slit plate 100 overlaps the web. 220);
It is disposed on the front side of the steel slit plate 100 so as to cross one side of the slit 110 and the strut 140 of the steel slit plate 100, and both sides of the area outside the steel slit plate 100 are the first A first out-of-plane deformation prevention plate 310 to which a coupling bolt 410 is fastened to be coupled to the web of the section steel bracket 210;
It is disposed on the front of the steel slit plate 100 so as to cross the other side of the slit 110 and the strut 140 of the steel slit plate 100, and both sides of the area outside the steel slit plate 100 are the second A second out-of-plane deformation prevention plate 320 to which a coupling bolt 410 is fastened to be coupled to the web of the section steel bracket 220;
A first contact bolt 511 that penetrates the first out-of-plane deformation prevention plate 310, passes through one side of the slit 110 of the steel slit plate 100, and is fastened through the first shape steel bracket 210. );and,
A second close bolt 512 penetrates the second out-of-plane deformation prevention plate 310, passes through the other side of the slit 110 of the steel slit plate 100, and is fastened through the second shape steel bracket 210. );
A strut out-of-plane deformation prevention type steel slit damper comprising a. In paragraph 1:
It is inserted into the first close bolt 511 and the second close bolt 512, and when the first close bolt 511 is fastened, the first out-of-plane deformation prevention plate 310 and the first section steel bracket ( 210) and supports the first out-of-plane deformation prevention plate 310 and the first section steel bracket 210 while being located inside one side of the slit 110 between them, and when the second close bolt 512 is fastened, the It is located inside the other side of the slit 110 between the second out-of-plane deformation prevention plate 320 and the second section steel bracket 220, and the second out-of-plane deformation prevention plate 320 and the second section steel bracket 220 are connected to each other. A supporting spacer for close contact (520); and,
Between both sides of the first out-of-plane deformation prevention plate 310 outside the steel slit plate 100 and the first section steel bracket 210, and between the second out-of-plane deformation prevention plate 320 outside of the steel slit plate 100 It is installed between both sides and the second section steel bracket 220, and supports both sides of the first out-of-plane deformation prevention plate 310 and the first section steel bracket 210 when the coupling bolt 410 is fastened, or A spacer for coupling (420) supporting both sides of the second out-of-plane deformation prevention plate (320) and the second beam bracket (220);
Strut out-of-plane deformation prevention type steel slit damper, characterized in that it further includes. It relates to a seismic energy attenuation device for earthquake-resistant reinforcement of structures,
It is a plate-shaped member, and is provided with a plurality of slits 110 formed by cutting in parallel in the center, and a plurality of struts 140 consisting of an uncut area between the slits 110, and a groove on one side outside the slit area. A first out-of-plane deformation prevention plate coupling piece 131 is provided extending in a direction parallel to the slit 110 at the left and right ends, and the slit 110 is formed at the left and right ends of the other side outside the slit area. ) A steel slit plate (100) provided with a second out-of-plane deformation prevention plate coupling piece (132) extending toward the first out-of-plane deformation prevention plate coupling piece (131) in a direction parallel to );
As a section steel member, the first section steel bracket 210 is coupled so that a portion of the steel slit plate 100 overlaps the web while the coupling bolt 410 is fastened so that one rear side of the steel slit plate 100 is in close contact with the web. );
As a section steel member, the second section steel bracket is coupled so that the other rear side of the steel slit plate 100 is in close contact with the web, and a portion of the remaining area of the steel slit plate 100 overlaps the web. 220);
It is disposed on the front and rear sides of the steel slit plate 100 so as to cross one side of the slit 110 of the steel slit plate 100, and prevents the first out-of-plane deformation beyond the slit area of the steel slit plate 100. A first out-of-plane deformation prevention plate 310 to which coupling bolts 410 are fastened to the left and right sides facing each other with the plate coupling piece 131 in between;
It is disposed on the front and rear sides of the steel slit plate 100 so as to cross the other side of the slit 110 of the steel slit plate 100, and prevents the second out-of-plane deformation beyond the slit area of the steel slit plate 100. A second out-of-plane deformation prevention plate 320 to which coupling bolts 410 are fastened to the left and right sides facing each other with the plate coupling piece 132 in between;
A first close contact fastened to pass through one side of the slit 110 of the steel slit plate 100 and a pair of overlapping first out-of-plane deformation prevention plates 310 with the steel slit plate 100 in between. bolt(511); and,
A second close contact fastened to pass through the other side of the slit 110 of the steel slit plate 100 and a pair of overlapping second out-of-plane deformation prevention plates 320 with the steel slit plate 100 in between. bolt(512);
A strut out-of-plane deformation prevention type steel slit damper comprising a. In paragraph 3,
A pair of the above is inserted into the first close bolt 511 and the second close bolt 512 and overlaps with the steel slit plate 100 between them when the first close bolt 511 is fastened. A pair of second out-of-plane deformation prevention plates 320 that support the first out-of-plane deformation prevention plate 310 and overlap with the steel slit plate 100 between them when the second close bolt 512 is fastened. ) a spacer for close contact (520) supporting the;
Strut out-of-plane deformation prevention type steel slit damper, characterized in that it further includes. It relates to a seismic reinforcement structure using a strut out-of-plane deformation prevention type steel slit damper according to any one of claims 1 to 4,
An upper steel frame portion 610 formed by combining steel frames;
A lower steel frame portion 620 formed by combining steel frames;
A steel slit damper 101 in which a first section steel bracket 210 is coupled to the upper end of the lower steel frame portion 620 and a second section steel bracket 220 is coupled to the lower end of the upper steel frame section 610; and,
It is installed spaced apart on both left and right sides of the steel slit damper 101, the upper part is pinned to the lower end of the upper steel frame part 610, and the lower part is pinned to the upper end of the lower steel frame part 620. (630);
Seismic reinforcement structure using a strut out-of-plane deformation prevention type steel slit damper, characterized in that it includes. It relates to a seismic reinforcement structure using a strut out-of-plane deformation prevention type steel slit damper according to any one of claims 1 to 4,
A pair of horizontal steel frames 640 arranged side by side and spaced apart at the upper and lower parts;
A pair of vertical steel frames 650 coupled to the left and right sides of the horizontal steel frames 640 spaced apart from the upper and lower parts;
A hinge portion 630 is installed at a location where the horizontal steel frame 640 and the vertical steel frame 650 are joined, and one side is pin-connected to the horizontal steel frame 640, and the other side is pin-connected to the vertical steel frame 650. );
Bridge-type steel frames 660 that are coupled to the upper and lower parts of each of the vertical steel frames 650 and extend in directions facing each other to form an overall symmetrical structure in the shape of "〕〔"; and,
The bridge-type steel frame in which the first section steel bracket 210 is coupled to one of the bridge-type steel frames 660 and the second section steel bracket 220 is coupled to the remaining one of the bridge-type steel frames 660 and are spaced apart. Steel slit damper (101) connecting (660);
Seismic reinforcement structure using a strut out-of-plane deformation prevention type steel slit damper, characterized in that it includes. Concerning the construction method of earthquake-resistant reinforcement structure using strut out-of-plane deformation prevention type steel slit damper,
A first step of removing paint and foreign substances from the surface of the reinforcement area of the existing structure after demolishing the existing finishing material, and pre-treating the surface of the area where the earthquake-resistant reinforcement structure using the steel slit damper 101 will be installed by chipping;
A second step of determining the location where the earthquake-resistant reinforcement structure using the steel slit damper 101 will be installed and using the reinforcement explorer to identify and display the location of the reinforcement inside the existing structure (structure to be reinforced);
Holes for mounting anchor bolts 690 are drilled at the top and bottom of the existing structure according to the hole pattern pre-formed in the base plate 670 installed between the existing structure and the earthquake-resistant reinforcement structure using the steel slit damper 101. Stage 3;
Anchor bolts 690 are temporarily fastened to the top of the existing structure to temporarily assemble the base plate 670, to which the
A fourth step of temporarily assembling the base plate 670 to which the
The seismic reinforcement structure using the steel slit damper (101) with the After making contact with the bottom of the X-type brace (680), weld the X-type brace (680) and the base plate (670),
The X-type brace (680) pre-assembled on the top of the existing structure pushes or pulls the base plate (670) to which the X-type brace (680) is in contact with the top of the seismic reinforcement structure using the steel slit damper (101). A fifth step of welding and combining the earthquake-resistant reinforcement structure using the rear X-type brace (680) and the steel slit damper (101);
A sixth step of completely tightening the anchor bolts (690) temporarily fastened to the top and bottom of the existing structure;
The seventh step of installing formwork in the space between the earthquake-resistant reinforcement structure using the steel slit damper (101) and the existing structure and curing it by pouring mortar or concrete; and,
Step 8, where the formwork is dismantled, the finishing process is performed, and construction is completed;
A method of constructing a seismic reinforcement structure using a steel slit damper, comprising: