KR102638837B1 - Steel support for pre-construction of externally attached earthquake-reinforced superstructure and construction method using the same - Google Patents

Abstract

The present invention is an externally attached seismic reinforcement that can be used to pre-construct an externally attached seismic reinforcement superstructure using a steel support before forming the reinforced basic concrete part when seismic reinforcement is carried out with an externally attached seismic reinforcement superstructure for an existing building. A steel support for pre-construction of a superstructure and a construction method using the same, wherein the steel support includes a pair of C-beams (10) placed in opposite positions, and a central upper surface of the upper flange (11) of the C-beams (10). A central support plate 20 that connects the C-beam 10 and the C-beam 10 to each other and integrally supports and fixes the column 1 of the externally attached seismic reinforcement superstructure A, the upper part of the C-beam 10 The C-beam (10) and C-beam (10) are integrally connected to the upper and lower surfaces of both sides of the flange (11) and the lower flange (12), and a pair of left and right are formed between the web (13) of the C-beam (10). An outer connection plate 30 formed with a through hole 30h through which the micropile 3 can pass and be fixed, and the upper and lower surfaces of the upper flange 11 of the C-beam 10 with the central support plate 20 interposed therebetween. The C-beam 10 and the C-beam 10 are integrally connected to the lower surface of the flange 12, and the central tight fixing bar 40, which is in close contact with both end surfaces of the column 1, and the outer connection plate 30 are provided. An outer fixture (50) that integrally connects and supports the C-beam (10) and the C-beam (10) to the upper surface of the upper flange (11) of the C-beam (10) and the lower surface of the lower flange (12) with the C-beam (10) in between. The foundation support 60 is integrally supported and fixed to the C-beam 10 and the central fastener 40 and supported on the foundation 2, and the foundation support 60 is integrally supported and fixed to the C-beam 10 and the outer fixer 50. (2) It is characterized by consisting of an outer support 70 that is seated on the ground or the upper surface of the abandoned concrete layer in the area where the reinforced foundation concrete part (R) is formed by external reinforcement.

Description

Steel support for pre-construction of externally attached earthquake-reinforced superstructure and construction method using the same}

The present invention relates to a steel frame support for pre-construction of an externally attached seismic-reinforced superstructure and a construction method using the same. When seismic reinforcement is performed on an existing building with an externally attached seismically-reinforced superstructure, before forming the reinforced base concrete part. It is possible to pre-construct an externally attached earthquake-reinforced superstructure using a steel frame support.

Generally, in order to earthquake-proof an existing building, seismic reinforcement is installed inside or outside the building. When installing seismic reinforcement inside a building, large steel or concrete reinforcement weighing several tons must be transported inside through a window or narrow door. In addition, for foundation reinforcement work, part of the frame inside the building must be demolished and the foundation reinforced. do. As a result, the overall construction cost and construction period increase significantly, and in the case of schools, many problems arise along with large costs due to various constraints, such as having to complete reinforcement work during a short vacation period.

When seismic reinforcement is installed outside the building, it is advantageous in that construction can proceed without being restricted in activities inside the building due to the installation of seismic reinforcement inside the building as described above. Seismic reinforcement for the exterior of a building involves attaching reinforcing structures to existing concrete structures such as columns and beams, and seismic reinforcement is installed inside or outside the building opening to effectively resist lateral forces when an earthquake occurs. When installed inside the opening, windows and doors are installed on the outside of the building. After the light is dismantled and removed, the inside of the opening is reinforced with a frame frame, etc., and then the inside part of the installed frame frame is used to re-install windows or finish and construct a non-load-bearing wall, making the work very complicated. Because problems arise that require a lot of time and money, building structures are generally installed as external seismic reinforcement elements such as steel frames or PC members outside the frame that makes up the building.

As suggested in Korea Patent Publication No. 10-2231707, "Method of anchoring seismic reinforcement members to the foundation and foundation reinforcement assembly for the same," an externally attached seismic reinforcement method is used to construct a new structure with high rigidity and strength on the outside of the existing frame. Seismic performance is improved by attaching members. In order to install a new member, first of all, the existing foundation must be strengthened and added, or a new foundation must be additionally installed, and then a new member, which is an externally attached seismic reinforcement superstructure, must be installed on the upper part. Because it must be installed sequentially, it is not only difficult to apply in places where rapid construction is required, but also reduces the economic feasibility of construction.

Republic of Korea Patent Publication No. 10-2231707 (registered on March 18, 2021)

Accordingly, the present invention was made in consideration of various conventional problems as described above. When seismic reinforcement is performed on an existing building with an externally attached seismic reinforcement superstructure, the present invention is externally attached using a steel support before forming the reinforced foundation concrete part. By pre-constructing the seismic-reinforced superstructure, the externally attached seismic-reinforced superstructure and finishing work can be pre-constructed without being hindered by air delay factors that may occur during foundation construction, thereby shortening the overall construction period and reducing construction costs. there is.

The steel support for pre-construction of the externally attached earthquake-reinforced superstructure of the present invention is,

A pair of C-beams placed opposite each other, a central support plate on the central upper surface of the upper flange of the C-beams that connects the C-beams and C-beams to each other and integrally supports and fixes the column of the externally attached seismic reinforcement superstructure, The C-beam and C-beam are integrally connected to the upper and lower surfaces of both the upper and lower flanges of the C-beam, and a through-hole is formed between the webs of the C-beam through which a pair of left and right micropiles can pass through and be fixed. Connecting the C-beam and C-beam to the upper surface of the upper flange of the C-beam and the lower surface of the lower flange of the C-beam with the central support plate in between, the central adhesion fixture in close contact with both end surfaces of the column, and the outer connecting plate are provided. An outer fixture that integrally connects and fixes the C-beam and the C-beam to the upper surface of the upper flange and the lower surface of the lower flange of the C-beam in between, and a foundation that is integrally supported and fixed to the C-beam and the central close fixture and is supported on the foundation. It is characterized in that it consists of an outer support that is integrally supported and fixed to the C-beam and the outer fixing bar and is seated on the ground or the upper surface of the abandoned concrete layer in the area where the reinforced foundation concrete part is formed by additional pounding outside the foundation.

In addition, the base support is composed of a pair of inner base supports and a pair of outer base supports, and the length of the inner and outer base supports is such that the inner and outer base supports are in close contact with the foundation depending on the shape of the upper surface of the foundation. It is characterized in that it is adjusted and installed.

In addition, a base support mounting groove is formed on the upper surface of the foundation where the base support supported on the foundation can be seated and supported.

In addition, the central lower support plate and the reinforcing support rib that integrally connect the C-beam and the C-beam are fixed and installed on the central lower surface of the lower flange of the C-beam on the opposite side of the central support plate.

The present inventor's construction method using a steel support for pre-construction of an externally attached earthquake-reinforced superstructure is,

(1) Digging around the foundation where the externally attached earthquake-reinforced superstructure is installed; (2) Confirming the shape and specifications of columns and foundations through field investigation; (3) A step of manufacturing a steel frame pedestal mounted on the foundation and in close contact with a portion of the column periphery for pre-construction of an externally attached earthquake-reinforced superstructure; The steel frame support is a pair of C-beams placed in opposite positions, and the C-beam and C-beam are connected to each other on the upper surface of the central part of the upper flange of the C-beam, while integrally supporting and fixing the column of the externally attached seismic reinforcement superstructure. A central support plate, which integrally connects the C-beam and C-beam to the upper and lower surfaces of both upper and lower flanges of the C-beam, and allows a pair of left and right micropiles to pass through and be fixed between the webs of the C-beam. An outer connecting plate with a through hole, a central tight fixer that connects the C-shaped steel and the C-shaped steel to the upper surface of the upper flange and the lower surface of the lower flange of the C-shaped steel with the central support plate in between, and is in close contact with both end surfaces of the column, respectively, An outer fixture that integrally connects the C-beam and the C-beam to the upper surface of the upper flange and the lower surface of the lower flange of the C-beam with the outer connecting plate in between, and is integrally supported and fixed to the C-beam and the central close fixer. A foundation support supported on the foundation, an outer support that is integrally supported and fixed to the C-beam and the outer fixing bar and is seated on the ground or the upper surface of the abandoned concrete layer in the area where the reinforced foundation concrete part is formed by additional pounding outside the foundation; (4) The outer surface of the pillar is in close contact with the C-beam, and the end surfaces on both sides of the pillar are in close contact with the central fixing bar, so that the foundation support is seated and supported on the upper surface of the foundation, and the outer support is reinforced with foundation concrete by adding reinforcement outside the foundation. A step of allowing the part to be seated on the ground or the upper surface of the abandoned concrete layer in the area where the part is formed; (5) completing the installation of the externally attached earthquake-resistant reinforced superstructure while installing the pillars of the externally attached earthquake-resistant reinforced superstructure on the central support plate; (6) embedding and installing the micropile in the ground through the through hole of the outer connection plate; (7) pouring and curing concrete around the foundation to form a reinforced foundation concrete part, and then finishing the process with backfilling; in step (5), the pillars of the earthquake-resistant reinforced superstructure externally attached to the central support plate. In parallel with the installation of the externally attached seismic reinforcement superstructure, it is possible to proceed with the step of embedding and installing the micropile in the ground through the through hole of the outer connection plate.

The present invention has the effect of being able to pre-construct the externally attached seismic-reinforced superstructure using a steel support before forming the reinforced concrete base when seismic reinforcement is performed on an existing building with an externally attached seismically-reinforced superstructure.

The present invention allows foundation construction, which is highly variable depending on site conditions, to be performed as the final process, allowing the externally attached earthquake-resistant reinforced superstructure and finishing work to be constructed in advance without being hindered by air delay factors that may occur during foundation construction, thereby reducing the overall construction period. It has the effect of reducing shortening time and construction costs.

In addition, the present invention has the effect of allowing easy installation on various types of foundations by adjusting the length of the foundation support of the steel frame support to support it on the foundation surface.

In addition, the present invention has the effect of enabling more precise and stable construction by bringing the central fixing bar of the steel frame support into close contact with both end surfaces of the column and simultaneously bringing one side of the C-shaped steel into close contact with the outer surface of the column.

Figure 1 is a partial perspective view of a foundation with a downwardly sloping haunch formed around a pillar
Figure 2 is a partial perspective view of a steel frame support for pre-construction of an externally attached earthquake-reinforced superstructure installed on the foundation of Figure 1.
Figure 3 is a partial perspective view of a steel column, which is an externally attached seismic reinforcement superstructure, installed on the steel support of Figure 2.
Figure 4 is a partial perspective view of the micropile being buried in the ground after being installed on the steel support of Figure 3.
Figure 5a is an elevation cross-sectional view seen from the AA' side of Figure 4
Figure 5b is a planar cross-sectional state diagram of Figure 4
Figure 5c is an elevation cross-sectional view seen from the BB' side of Figure 4
Figure 5D is a cross-sectional state diagram of the right side of Figure 4
Figures 6 (a) and (b) are elevation and side cross-sectional diagrams of an externally attached seismic reinforcement superstructure pre-constructed using a steel frame pedestal.

Hereinafter, an embodiment of the present invention will be described in detail based on the attached drawings.

Figure 1 is a partial perspective view of a foundation with a downwardly sloping haunch portion formed around a pillar. In forming the foundation 2, a downwardly sloping haunch part c is formed around the pillar 1 as shown in Figure 1 to form the foundation ( In some cases, the punching shear force for 2) is reinforced, while in other cases, the upper surface of the foundation (2) is not formed with a haunch portion (c) but is made a flat surface. The present invention is configured so that a steel frame support can be installed on any foundation (2) regardless of whether or not the haunch portion (c) is formed on the upper surface of the foundation (2).

Figure 2 is a partial perspective view of a steel frame support for pre-construction of an externally attached earthquake-reinforced superstructure (A) installed on the foundation of Figure 1, where a downwardly sloping haunch portion (c) is formed around the pillar (1) of Figure 1. (2) shows that the steel frame support for pre-construction of the externally attached earthquake-reinforced superstructure (A) is installed.

In the present invention, in order to install a steel support for pre-construction of the externally attached earthquake-resistant reinforced superstructure (A), first, dig a trench around the foundation (2) where the steel support is installed, and then dig around the foundation (2) so that the steel support is firmly seated. Perform grading work on the ground.

The steel frame support of the present invention can be manufactured in a factory and installed on site, and depending on site conditions, it is manufactured and installed directly on site. As explained below, in order to manufacture the steel frame support, the pillar (1) and foundation (2) are used. Check the shape or specifications.

The steel support for pre-construction of the externally attached earthquake-reinforced superstructure (A) of the present invention positions a pair of C-beams (10) placed in opposing positions, and the length and size of the C-beams (10) are determined by the foundation (2). ) can be determined according to the shape or size of the externally attached earthquake-reinforced superstructure (A).

In addition, on the central upper surface of the upper flange 11 of the C-beam 10, the C-beam 10 and the C-beam 10 are connected to each other and the pillar 1 of the externally attached seismic reinforcement superstructure A is integrated. A central support plate 20 is installed to support and fix the central support plate 20 and the C-beam 10, as shown in Figure 2, by joining together with fastening bolts and nuts or by a widely used method such as welding. Combine.

The C-beam 10 and the C-beam 10 are integrally connected to the upper and lower surfaces of the upper flange 11 and the lower flange 12 of the C-beam 10, and the web 13 of the C-beam 10 is formed. An outer connecting plate 30 is installed with a through hole 30h through which a pair of left and right micropiles 3 can pass and be fixed. The outer connecting plate 30 and the C-beam 10 are They are joined together using common methods such as welding or fastening bolts and nuts.

The C-beam 10 and the C-beam 10 are integrally connected to the upper surface of the upper flange 11 and the lower flange 12 of the C-beam 10 with the central support plate 20 in between, and the pillar 1 ) can be installed with a circular steel bar as shown in the drawing, and an 'ㄴ'-shaped angle or an 'I'-shaped angle can be selectively applied to the central fixing bar (40), which is in close contact with both end surfaces. can do.

The central tight fixer (40) integrally connects the C-beam (10) and the C-beam (10), and has the ends of a pair of left and right tight fixers (40) and the upper and lower flanges of the C-beam (10) located between them. (11, 12) The corner end surface of the pillar (1) is in close contact with the end surface. In other words, the center tight fixer 40 of the steel frame support is brought into close contact with both end surfaces of the pillar 1, and at the same time, one side of the C-beam 10 is brought into close contact with the outer surface of the pillar 1, making it more precise and stable. It has the effect of being able to be constructed with .

The C-beam 10 and the C-beam 10 are integrally connected and supported on the upper surface of the upper flange 11 and the lower surface of the lower flange 12 of the C-beam 10 with the outer connecting plate 30 in between. The outer fixing bar 50 can be installed as a circular steel bar as shown in the drawing, and although not specifically shown in the drawing, it can be selectively applied as an 'ㄴ'-shaped angle or an 'I'-shaped angle, etc., and the external fixing bar (50 ) plays a complex role in integrally connecting the C-beam 10 and the C-beam 10 while supporting and fixing the outer support 70 by welding, etc.

The base support 60, which is integrally supported and fixed to the C-beam 10 and the central fixer 40 and supported on the foundation 2, includes a pair of inner base supports 61 and a pair of outer base supports. It consists of (62), and as shown in Figure 2, the inner and outer base supports (61, 62) are in close contact with the foundation (2) according to the shape of the upper surface of the foundation (2). 62) is installed by adjusting its length, and by adjusting the length of the foundation supports (61, 62) of the steel frame support to support it on the foundation surface, it has the effect of being able to be easily installed on various types of foundations (2).

In addition, a base support seating groove (2a) is formed on the upper surface of the foundation (2) where the base support (60) supported on the foundation (2) can be seated and supported, and the base support seating groove (2a) is formed in the base support seating groove (2a). After seating the end of the base support 60, grouting with mortar or concrete between the base support 60 and the support axial groove 2a can be performed to further strengthen the seating of the base support 60.

An outer supporter ( 70) may be formed of a steel bar or steel pipe, and as described above, is firmly fixed to the outer fixture 50 and the C-beam 10 by welding. The outer support 70 is a reinforced concrete portion (R) formed. As it is seated on the ground or the upper surface of the abandoned concrete layer, it supports the steel frame support more stably. In addition, although not specifically shown in the drawing, in order to strengthen the external force and seismic force applied from the externally attached seismic reinforcement superstructure (A) on which the already installed foundation (2) is installed according to site conditions, the outer part of the foundation (2) When expanding the foundation in the form of an expanded foundation, it can also be seated on the upper surface of the newly expanded foundation.

Figure 3 is a partial perspective view of a steel column, which is an externally attached seismic reinforcement superstructure, installed on the steel support of Figure 2. The externally attached seismic reinforcement superstructure (A) installed on the outer surface of the column and beam, which is a building structure, is the pillar. In order to be attached to the outside of the beam, it is made of 'H' type or 'I' type steel frame or PC, etc., Figure 3 shows the steel column (h) constituting the externally attached seismic reinforcement superstructure (A) with the central support plate ( 20) It shows that it is installed integrally on the upper surface.

In addition, in the present invention, the externally attached seismic reinforcement superstructure (A) is fixedly supported on the central support plate 20 constituting the steel frame and is sequentially installed upward, and the externally attached seismic reinforcement superstructure (A) is attached to the building. In order to attach and combine the structural column (1) and the outer surface of the beam, generally widely applied methods are applied. As shown in FIG. 6, one method is to use a drill, etc. on the column (1) and the beam. Drill the anchor through-hole (1h), insert the anchor bolt (1a) penetrating the externally attached seismic reinforcement superstructure (A) into the anchor through-hole (1h), and then inject mortar, etc. into the anchor through-hole (1h). curing, and fastening the anchor nut (1b) to the anchor bolt (1a) protruding on the outer side of the externally attached seismic reinforcement superstructure (A) to attach and couple the externally attached seismic reinforcement superstructure (A) to the building structure. The reduction in the self-weight of the externally attached earthquake-reinforced superstructure (A), which is about to be applied downward, reduces the bearing capacity burden on the steel frame support.

Figure 4 is a partial perspective view of the micropile buried in the ground after being installed on the steel support of Figure 3. The externally attached seismic reinforcement superstructure (A) is attached to the building structure using the steel support as shown in Figure 3. Afterwards, the micropile (3) is passed through the through hole (30h) formed in the outer connection plate (30), and then the micropile (3) is embedded in the ground and fixed.

In order to bury and anchor the micropile (3) in the ground, a hole is generally drilled in the ground, the micropile (3) is inserted and installed into the drilled hole, and then grouted by injecting mortar or concrete into the hole. For curing, the present invention omits the specific drawing in which the generally applied micropile (3) is buried in the ground and simply shows only that the micropile (3) is buried in the ground.

In addition, generally, after attaching the externally attached seismic reinforcement superstructure (A) to the building structure using a steel frame support, the micropile (3) can be buried in the ground to complete the installation, but depending on site conditions, the central support plate can be completed. In parallel with the installation of the pillar (1) of the externally attached seismically reinforced superstructure (A) and the other externally attached seismically reinforced superstructure (A) at (20), the through hole of the outer connection plate (30) The micropile (3) can also be buried and installed underground through (30h).

In addition, after the micropile (3) is buried and installed in the ground, a reinforced foundation concrete part (R) described below is formed, and Figure 4 shows a detailed illustration of the formed part of this reinforced foundation concrete part (R), which is explained below. Separate by drawing.

FIG. 5A is an elevation view seen from the A-A' side of FIG. 4, FIG. 5B is a plan cross-sectional state diagram of FIG. 4, FIG. 5C is an elevation cross-sectional view viewed from the B-B' side of FIG. 4, and FIG. 5D is an elevation view on the right side of FIG. 4. As a state diagram, as shown in the enlarged view of another implementation of the contents of FIG. 5A, in order to reinforce the bending stress in the externally attached seismic reinforcement superstructure (A), the lower part of the C-beam 10 on the opposite side of the central support plate 20 On the central lower surface of the flange 12, a central lower support plate 20a and a reinforcing support rib 20b, which integrally connect the C-beam 10 and the C-beam 10, are integrally fixed and installed, and a steel column (h) is installed. In order to strengthen the bearing capacity, a reinforcing piece (20c) is installed at the lower end of the steel column (h) coupled to the central support plate (20).

In addition, the outer support bar 70 is integrally supported and fixed to the C-beam 10 and the outer fixing bar 50 so as to support the ground or abandoned concrete layer of the area where the reinforced foundation concrete part (R) is formed by additional pounding outside the foundation (2). It is seated on the upper surface, and the reinforced foundation concrete part (R) increases seismic stress by integrating the pre-constructed steel support and pillar (1) including the foundation (2) and micropile (3).

The reinforced foundation concrete part (R) is poured and cured to cover the entire steel support including the micropile (3) and includes a part of the foundation (2), and each outer surface forming the reinforced foundation concrete part (R) You can install a form, place reinforcing bars, and cure the inner part by pouring concrete without placing reinforcing bars, or instead of a form, you can install a PC board on the outer part and pour concrete to cure it. The concrete portion R can be formed by other methods that are generally widely applied in addition to the above method.

As shown in Figures 5b and 5c, the ends of the central adhesive fixer 40, which is in close contact with both end surfaces of the pillar 1, are extended longer inside the pillar 1 to increase the adhesion with the pillar 1 when installing the steel frame support. By increasing it, the steel frame support can be seated more stably. In addition, since the steel frame support can be installed by adjusting the length of the inner and outer foundation supports (61, 62) in accordance with the downward sloping surface formed by the haunch portion (c) of the foundation (2), regardless of the change in shape of the foundation. There is an advantage in that the steel frame support can be installed stably.

Figures 6 (a) and (b) are elevation and side cross-sectional diagrams of an externally attached earthquake-reinforced superstructure pre-constructed by a steel support, which is installed on the outer surface of the pillar (1) and beam, which are building structures. The externally attached seismically reinforced superstructure (A) is made of steel, but PC, which is widely used in seismic reinforcement, can also be applied to the externally attached seismically reinforced superstructure (A).

The construction method using a steel frame for pre-construction of the present inventor's externally attached earthquake-reinforced superstructure is as follows.

First, (1) is the step of digging around the foundation (2) where the externally attached seismic reinforcement superstructure (A) is installed. After installing the steel frame support through the upper part of the foundation and the ground, the externally attached seismic reinforcement superstructure (A) is installed. In order to install A) by attaching it to the outer surface of the pillar (1) and beam, which is the building structure, first, dig a trench around the foundation (2) where the externally attached seismic reinforcement superstructure (A) is installed and make sure that the steel frame support is firmly seated. Foundation (2) Perform grading work on the surrounding ground.

Next, (2) is the step of confirming the shape and specifications of the pillar (1) and the foundation (2) through on-site investigation. In the case of a square pillar (1), a pair of left and right close fittings (40) are used to secure the pillar (1) and the foundation (2). Check the shape and size of the pillar (1) to ensure that it adheres closely to the width of (1).

Next, (3) the step of manufacturing a steel frame support mounted on the foundation (2) and in close contact with a portion of the periphery of the column (1) for pre-construction of the externally attached earthquake-reinforced superstructure (A);

The steel frame support includes a pair of C-beams 10 placed in opposite positions, and the C-beams 10 and C-beams 10 are connected to each other on the central upper surface of the upper flange 11 of the C-beams 10. A central support plate (20) that integrally supports and fixes the column (1) of the externally attached seismic reinforcement superstructure (A), upper surfaces on both sides of the upper flange (11) and lower flange (12) of the C-beam (10), and A through hole through which the C-beam (10) and the C-beam (10) are integrally connected to the lower surface and through which a pair of left and right micropiles (3) can pass and be fixed between the webs (13) of the C-beam (10). The C-beam 10 and C are placed on the upper surface of the upper flange 11 and the lower flange 12 of the C-beam 10 with the outer connecting plate 30 formed (30h) and the central support plate 20 in between. A central fixer (40) that integrally connects the section steel (10) and is in close contact with both end surfaces of the pillar (3), and an upper flange (11) of the C-shaped steel (10) with the outer connecting plate (30) interposed therebetween. An outer fixture 50 that integrally connects and supports the C-beam 10 and the C-beam 10 on the upper and lower surfaces of the lower flange 12, and the C-beam 10 and the central close fixture 40. A foundation support bar (60) that is integrally supported and fixed to the foundation (2), and a foundation concrete portion (R) that is integrally supported and fixed to the C-beam (10) and the outer fixing bar (50) and reinforced by additional pounding outside the foundation (2). It consists of an outer support 70 that is seated on the ground or the upper surface of the abandoned concrete layer in the area where is formed.

Next, (4) the outer surface of the pillar (1) is in close contact with the C-beam (10), and both end surfaces of the pillar are in close contact with the central fastener (40), and the foundation support (60) is attached to the upper surface of the foundation (2). It is seated and supported on, and the outer support 70 is seated on the ground or the upper surface of the abandoned concrete layer in the area where the reinforced foundation concrete part (R) is formed by additional pounding outside the foundation (2).

Next, (5) is the step of completing the installation of the externally attached seismically reinforced superstructure (A) while installing the pillars (1) of the externally attached seismically reinforced superstructure (A) on the central support plate 20.

Next, (6) is the step of embedding and installing the micropile (3) in the ground through the through hole (30h) of the outer connection plate (30).

Lastly, (7) is the step of pouring and curing concrete around the foundation (2) to form a reinforced foundation concrete part (R) and then completing the process with backfilling.

However, depending on the site conditions, unlike step (5) above, the pillars 1 of the externally attached seismically reinforced superstructure (A) and the other externally attached seismically reinforced superstructure (A) are attached to the central support plate 20. In parallel with the installation, the micropile (3) is buried and installed in the ground through the through hole (30h) of the outer connection plate (30), and then (6) concrete is placed around the foundation (2). After pouring and curing to form a reinforced foundation concrete part (R), the process proceeds to the final step of backfilling.

The present invention provides an externally attached seismically reinforced superstructure (A) using a steel support before forming the reinforced basic concrete part (R) when seismic reinforcement is performed on an existing building with an externally attached seismically reinforced superstructure (A). It can be constructed in advance, and foundation construction, which is highly variable depending on site conditions, can be done as the final process, so the externally attached earthquake-resistant reinforced superstructure (A) and finishing construction can be completed without being hindered by air delay factors that may occur during foundation construction. Since construction can be done in advance, it has the effect of shortening the overall construction period and reducing construction costs.

As described above, although the present invention has been described with limited examples and drawings, the terms and words used in the specification and claims should not be construed as limited to their ordinary or dictionary meanings, and should not be construed as limiting the technical idea of the present invention. It must be interpreted with corresponding meaning and concept.

Accordingly, the embodiments described in this specification and the configurations shown in the drawings are only one embodiment of the present invention and do not represent the entire technical idea of the present invention, so various equivalents may be used without departing from the scope of the claims of the present invention. It should be understood that there may be variations and examples.

1: Pillar 2: Foundation
3: Microfile
10: C-beam 11: Upper flange
12: lower flange 13: web
20: Central support plate
20a: Central lower support plate 20b, 20c: Reinforcement support rib
30: Outer connection plate 30a: Through hole
40: Central adhesive fixer
50: External fixture
60: base support 61: inner base support
62: External base support
70: Outer support
A: Externally attached earthquake-reinforced superstructure h: Steel column
R: Reinforced foundation concrete part

Claims (6)

A pair of C-beams (10) placed opposite each other,
The central upper surface of the upper flange 11 of the C-beam 10 connects the C-beam 10 and the C-beam 10 to each other and integrally supports the column 1 of the externally attached seismic reinforcement superstructure A. A central support plate (20) for fixing,
The C-beam 10 and the C-beam 10 are integrally connected to the upper and lower surfaces of the upper flange 11 and the lower flange 12 of the C-beam 10, and the web 13 of the C-beam 10 is formed. An outer connection plate (30) formed with a through hole (30h) between which a pair of left and right micropiles (3) can pass and be fixed,
The C-beam 10 and the C-beam 10 are integrally connected to the upper surface of the upper flange 11 and the lower flange 12 of the C-beam 10 with the central support plate 20 in between, and the pillar 1 ), a central adhesive fixer (40) that is in close contact with both end surfaces, respectively,
The C-beam 10 and the C-beam 10 are integrally connected and supported on the upper surface of the upper flange 11 and the lower surface of the lower flange 12 of the C-beam 10 with the outer connecting plate 30 in between. External fixing bar (50) for fixing,
A base support bar (60) integrally supported and fixed to the C-beam (10) and the central fixing bar (40) and supported on the foundation (2),
An outer supporter ( 70), characterized in that it consists of
Steel support for pre-construction of externally attached earthquake-reinforced superstructure.
According to paragraph 1,
The base support 60 consists of a pair of inner base supports 61 and a pair of outer base supports 62, and the inner and outer base supports 61, depending on the shape of the upper surface of the foundation 2. Characterized in that the lengths of the inner and outer base supports (61, 62) are adjusted and installed so that 62) is in close contact with the foundation (2).
Steel support for pre-construction of externally attached earthquake-reinforced superstructure.
According to paragraph 1,
Characterized in that a base support seating groove (2a) is formed on the upper surface of the base (2) where the base support (60) supported on the base (2) can be seated and supported,
Steel support for pre-construction of externally attached earthquake-reinforced superstructure.
According to paragraph 1,
On the central lower surface of the lower flange 12 of the C-beam 10, which is opposite to the central support plate 20, a central lower support plate 20a and a reinforcing support rib are provided to integrally connect the C-beam 10 and the C-beam 10. Characterized in that (20b) is integrally fixed and installed,
Steel support for pre-construction of externally attached earthquake-reinforced superstructure. (1) digging around the foundation (2) on which the externally attached earthquake-reinforced superstructure (A) is installed;
(2) Confirming the shape and specifications of the column (1) and foundation (2) through field investigation;
(3) A step of manufacturing a steel frame support mounted on the foundation (2) and in close contact with a portion of the periphery of the pillar (3) for pre-construction of the externally attached earthquake-reinforced superstructure (A);
The steel frame stand is,
A pair of C-beams (10) placed opposite each other,
The central upper surface of the upper flange 11 of the C-beam 10 connects the C-beam 10 and the C-beam 10 to each other and integrally supports the column 1 of the externally attached seismic reinforcement superstructure A. A central support plate (20) for fixing,
The C-beam 10 and the C-beam 10 are integrally connected to the upper and lower surfaces of the upper flange 11 and the lower flange 12 of the C-beam 10, and the web 13 of the C-beam 10 is formed. An outer connection plate (30) formed with a through hole (30h) between which a pair of left and right micropiles (3) can pass and be fixed,
The C-beam 10 and the C-beam 10 are integrally connected to the upper surface of the upper flange 11 and the lower flange 12 of the C-beam 10 with the central support plate 20 in between, and the pillar 3 ), a central adhesive fixer (40) that is in close contact with both end surfaces, respectively;
The C-beam 10 and the C-beam 10 are integrally connected and supported on the upper surface of the upper flange 11 and the lower surface of the lower flange 12 of the C-beam 10 with the outer connecting plate 30 in between. External fixing bar (50) for fixing,
A base support bar (60) integrally supported and fixed to the C-beam (10) and the central fixing bar (40) and supported on the foundation (2),
An outer supporter ( 70).
(4) As the outer surface of the pillar (1) is in close contact with the C-beam (10), both end surfaces of the pillar are in close contact with the central fixer (40), and the base support (60) is seated on the upper surface of the base (2). supporting, and allowing the outer support 70 to be seated on the ground or the upper surface of the abandoned concrete layer in the area where the reinforced foundation concrete part (R) is formed by adding reinforcement outside the foundation (2);
(5) completing the installation of the externally attached seismically reinforced superstructure (A) while installing the pillars (1) of the externally attached seismically reinforced superstructure (A) on the central support plate (20);
(6) installing the micropile (3) in the ground through the through hole (30h) of the outer connection plate (30);
(7) pouring and curing concrete around the foundation (2) to form a reinforced foundation concrete part (R) and then finishing the process with backfilling;
Construction method using steel support for pre-construction of externally attached earthquake-reinforced superstructure.
(1) Excavation stage around the foundation (1) where the externally attached earthquake-reinforced superstructure (A) is installed;
(2) Confirming the shape and specifications of the column (1) and foundation (2) through field investigation;
(3) A step of moving the steel frame support mounted on the foundation (2) and in close contact around the column (1) to the site for pre-construction of the externally attached earthquake-resistant reinforced superstructure (A);
The steel frame stand is,
A pair of C-beams (10) placed opposite each other,
The central upper surface of the upper flange 11 of the C-beam 10 connects the C-beam 10 and the C-beam 10 to each other and integrally supports the column 1 of the externally attached seismic reinforcement superstructure A. A central support plate (20) for fixing,
The C-beam 10 and the C-beam 10 are integrally connected to the upper and lower surfaces of the upper flange 11 and the lower flange 12 of the C-beam 10, and the web 13 of the C-beam 10 is formed. An outer connection plate (30) formed with a through hole (30h) between which a pair of left and right micropiles (3) can pass and be fixed,
The C-beam 10 and the C-beam 10 are integrally connected to the upper surface of the upper flange 11 and the lower flange 12 of the C-beam 10 with the central support plate 20 in between, and the pillar 3 ), a central adhesive fixer (40) that is in close contact with both end surfaces of the
The C-beam 10 and the C-beam 10 are integrally connected and supported on the upper surface of the upper flange 11 and the lower surface of the lower flange 12 of the C-beam 10 with the outer connecting plate 30 in between. External fixing bar (50) for fixing,
A foundation support (60) integrally supported and fixed to the C-beam (10) and the central fixing bar (40) and supported on the foundation (2),
An outer supporter ( 70).
(4) As the outer surface of the pillar (3) is in close contact with the C-beam (10), both end surfaces of the pillar are in close contact with the central fixer (40), and the base support (60) is seated on the upper surface of the base (2). supporting, and allowing the outer support 70 to be seated on the ground or the upper surface of the abandoned concrete layer in the area where the reinforced foundation concrete part (R) is formed by adding reinforcement outside the foundation (2);
(5) In parallel with the installation of the pillars (1) of the externally attached seismically reinforced superstructure (A) and the other externally attached seismically reinforced superstructure (A) on the central support plate (20), the outer connection plate Step of embedding and installing the micropile (3) in the ground through the through hole (30h) of (30);
(6) pouring and curing concrete around the foundation (2) to form a reinforced foundation concrete part (R) and then finishing the process with backfilling;
Construction method using steel support for pre-construction of externally attached earthquake-reinforced superstructure.