KR101977266B1 - Structure for earthquake proofing and reinforcing building structure using high strength polymer mortar and steel structure - Google Patents

Abstract

The present invention relates to a seismic reinforcing structure using high strength polymer mortar and a steel structure. The seismic reinforcing structure using high strength polymer mortar and a steel structure comprises: a middle reinforcing unit which is installed between a conventional left building and a conventional right building; a left reinforcing unit which is installed in a left side of the conventional left building; and a right reinforcing unit which is installed in a right side of the conventional right building. A conventional building includes: a middle parking space which is formed between the conventional left building and the conventional right building; a left parking space which is formed in a left side of the conventional left building; and a right parking space which is formed in a right side of the conventional right building. The present invention is provided to reinforce the conventional building by the middle reinforcing unit and to individually reinforce the conventional left building and the conventional right building by the left reinforcing unit and the right reinforcing unit, thereby increasing a seismic reinforcing effect. The present invention can expand a storing space by using an internal space formed by a reinforcing structure as the storing space for storing and managing public supplies or public materials.

Description

Structure for earthquake proofing and reinforcing building structure using high strength polymer mortar and steel structure}

The present invention relates to a seismic reinforcement structure using a high-strength polymer mortar and steel structure, and more specifically, to strengthen the seismic reinforcement effect by connecting and strengthening the two existing buildings adjacent to each other, and by the reinforcement structure It relates to a seismic reinforcement structure using a high-strength polymer mortar and steel structure to expand the storage space by making the inner space to be used as a storage space for storing and managing common equipment or common materials.

Korea is located inland on the eastern edge of the Eurasian Plate, including China and Russia, and is considered to be relatively safer from earthquakes than neighboring countries located in the Pacific Rim earthquake, but the frequency of earthquakes has recently increased.

Earthquakes have been observed in Korea since 1905, but systematic earthquake observations have been made since 1978. The number of earthquakes that occurred in Korea from 1978 to 2006 totaled 728, 24 times a year.

Therefore, in Korea, the seismic regulations have been revised since the earthquake-related regulations were applied to the Building Act of 1990, and the seismic regulations were revised in 2005.

Since these seismic design codes are applied to new structures, structures constructed before the introduction of seismic design codes are not only designed and constructed without considering the effects of earthquakes, but also deteriorate due to the increase in common years. It is considered that the seismic performance is not properly exhibited.

The ratio of the structures without the seismic design was found to be about 80% of the total structures.

Unexpected earthquakes in these structures are expected to entail significant economic and social losses from reconstruction as well as direct damage from collapse and breakage.

In particular, in case of major national facilities, the economic and social losses on the whole country are enormous when damage occurs.

Unlike the seismic design method applied to new structures, the seismic reinforcement method needs to reinforce existing reinforced concrete structures or reinforced concrete facilities. Therefore, it is necessary to consider usability, economic feasibility, and constructability, and the specificity of existing reinforced concrete structures or reinforced concrete facilities. Consideration should be given to the selection of a suitable method.

Seismic reinforcement methods of existing reinforced concrete structures or reinforced concrete facilities include a method of increasing rigidity, a method of increasing ductility, or a method of simultaneously increasing rigidity and ductility, of which the commonly adopted method is a method of increasing ductility. Methods of increasing the ductility include a method of increasing the cross-sectional area of the member by using the same member in the existing reinforced concrete structure or reinforced concrete facilities and reinforcement coating method.

The method of increasing the cross-sectional area of the member has many disadvantages in that it is impossible to increase the cross-sectional area in the field conditions, and there is a disadvantage in that it takes a long period of construction, and the method of reinforcing the strength of the member by using a steel plate, which is a kind of reinforcement coating method, is the most common method Nevertheless, problems such as corrosion of steel plate, increase of load, and workability have to be solved.

If an earthquake occurs over a certain scale, it can cause a great loss of life in multi-use facilities such as schools and hospitals, and can cause enormous economic losses due to damage to power facilities and communication facilities. There is a risk of accidents, etc., which could result in secondary life and disaster losses.

Therefore, various reinforced concrete structures and important facilities that do not reflect the seismic design should be secured by seismic reinforcement.

There are many ways to seismic reinforcement.

Among them, the key is to prevent damage to reinforced concrete structures when an earthquake occurs, but not to collapse, and to ensure sufficient evacuation time by showing signs of collapse even during collapse.

Therefore, seismic reinforcement is very important to secure ductility of reinforced concrete structures and facilities.

Republic of Korea Patent Registration No. 10-1065439 (2011.09.16.) "Seismic reinforcement structures for reinforced concrete structures and construction methods thereof" is the front or rear or both sides of the precast reinforced concrete pillars and precast reinforced concrete beams Installed in the lattice shape, and tensioned and bonded with PS steel to form a lattice type prestressed precast reinforced concrete seismic structure, connecting the lattice type prestressed reinforced concrete seismic structure and the existing reinforced concrete structure to reinforced concrete The present invention discloses a technique for seismic reinforcing reinforced concrete structures by forming a seismic reinforcing structure by tension bonding with PS steel.

However, most of the conventional seismic reinforcing structures suggest seismic reinforcing structures for a single structure, and thus are not suitable for effectively seismic reinforcing two existing buildings having independent structures adjacent to each other.

Therefore, there is a demand for the development of seismic reinforcement technology for more effective seismic reinforcement by connecting and reinforcing two existing buildings with independent structures adjacent to each other.

Republic of Korea Registered Patent No. 10-1065439 (September 16, 2011) "Seismic Reinforcement Structure for Reinforced Concrete Structure and Its Construction Method"

Therefore, an object of the present invention can enhance the seismic reinforcement effect by connecting and strengthening the two existing buildings adjacent to each other, and can store and manage public equipment or common materials in the internal space formed by the reinforcement structure. It is intended to provide a seismic reinforcement structure using a high strength polymer mortar and steel structure to expand the storage space by utilizing it as a storage space.

The present invention, in order to achieve the above object, the existing left foundation (FD1), the left wall (W11) and the right wall (W12), lower floor slab (S11), middle floor slab (S12), upper floor slab (S13) and An existing left building (SB1) having a rooftop slab (S14); Existing right building (FD2), left wall (W21) and right wall (W22), lower floor slab (S21), middle floor slab (S22), upper floor slab (S23) and rooftop slab (S24) SB2); A central parking lot (P11) formed between the existing left building (SB1) and the existing right building (SB2); A left parking lot P21 formed on the left side of the existing left building SB1; In the seismic reinforcement structure using a high-strength polymer mortar and steel structure to seismic reinforcement of the existing building, including the right parking (P22) formed on the right side of the existing right building (SB2), the existing left building (SB1) and the existing A central reinforcing part 100 installed between the right building SB2; A left reinforcement part 200 installed on the left side of the existing left building SB1; And a right reinforcing part 300 installed on the right side of the existing right building SB2, wherein the central reinforcing part 100 includes a central basic reinforcing part 110 and a central lower reinforcing part 120 and a central middle reinforcing part. The unit 130 and the central upper reinforcement unit 140 and the central roof reinforcement unit 150, the central foundation reinforcement unit 110 is between the existing left base portion (FD1) and the existing right base portion (FD2) Excavating the ground of the ground and formed in the reinforced concrete structure is placed in the ground and connected to the existing left base portion (FD1) and the existing right base portion (FD2) and the central base portion (F11), and at a predetermined interval in the vertical direction A plurality of central foundation left pillars 111a buried in the central foundation part F11, a plurality of central foundation right pillars 111b buried in the central foundation part F11 at regular intervals in the vertical direction, and It is coupled to the upper end of the central foundation left column (111a) and the right wall (W1) of the existing left building (SB1) 2) a plurality of central foundation left side vertical beam 112a fixed by anchor bolt / nut fastening and filling of high strength polymer mortar, and coupled to the upper end of the central foundation right pillar 111b, and of the existing right building SB2 A plurality of central basic right robot 112b fixed to the left wall W21 by fastening anchor bolts / nuts and filling of high-strength polymer mortar, and the central basic left robot 112a and the central basic right side at regular intervals in the vertical direction. It includes a plurality of central foundation crossbeams 113 connecting the longitudinal beams 112b, the lower center reinforcement portion 120 is coupled to the bottom of the upper surface of the central basic left longitudinal crossbeam 112a at a predetermined interval in the vertical direction. In addition, the anchor bolt / nut fastening to the right wall (W12) of the existing left building (SB1) and the lower middle column pillar (121a) fixed by the filling of the high-strength polymer mortar, and in the vertical direction at regular intervals The bottom is coupled to the upper surface of the Anggi-cho right side robot 112b, and the lower middle pillar 120b fixed by anchor bolt / nut fastening to the left wall W21 of the existing right building SB2 and filling of high-strength polymer mortar. In addition, the middle lower floor left column (122a) is coupled to the upper end of the lower left pillar (121a) and fixed by anchor bolt / nut fastening and high-strength polymer mortar to the right wall (W12) of the existing left building (SB1) and And, coupled to the upper end of the lower right column pillar (121b) and the lower middle right side vertical beam (122b) is fixed by fastening the anchor bolt / nut fastening and high-strength polymer mortar to the left wall (W21) of the existing right building (SB2) and , And a plurality of central lower layer horizontal beams 123 connecting the central lower layer left vertical robot 122a and the central lower layer right longitudinal robot 122b at a predetermined interval in the vertical direction, and the central middle layer reinforcing part 130 is vertically aligned. to A plurality of central mezzanine seats coupled to an upper surface of the central lower floor levebo 122a at regular intervals and fixed by anchor bolt / nut fastening to the right wall W12 of the existing left building SB1 and filling of high strength polymer mortar Anchor bolt / nut fastening and high strength polymer mortar filling are coupled to the pillar 131a and the upper surface of the central lower layer right longitudinal robot 122b at a predetermined interval in the clockwise direction and to the left wall W21 of the existing right building SB2. Coupled to the upper end of the central middle layer right pillar 131b and the middle layer left column 131a fixed by the anchor bolt / nut fastening and high strength polymer mortar on the right wall W12 of the existing left building (SB1) Anchor bolts / nuts fastened with high strength to the left side wall (W21) of the existing right side building (SB2), and coupled to the upper end of the center middle left side vertical beam (132a) and the center middle right column (131b) fixed by the filling of A plurality of central mezzanine robos 133 connecting the central mezzanine right side robo 132b fixed by the filling of the polymer mortar and the middle lower layer left cevo 122a and the center lower layer right side ceo 122b at regular intervals in the vertical direction. ), The central upper layer reinforcing portion 140 is coupled to the upper surface of the central middle left longitudinal robo (132a) at regular intervals in the vertical direction, and anchor bolt / on the right wall (W12) of the existing left building (SB1) A plurality of central upper left pillars 141a fixed by nut fastening and filling of high-strength polymer mortar, and coupled to an upper surface of the central middle right vertical robo 132b at regular intervals in the vertical direction, and are also existing right buildings (SB2). And coupled to the upper end of the plurality of central upper right column (141b) and fixed to the left wall (W21) of the anchor bolt / nut by fastening and filling the high-strength polymer mortar In addition, the anchor bolt / nut is fastened to the right wall (W12) of the existing left building (SB1) and the center upper left vertical robo (142a) fixed by the filling of the high-strength polymer mortar, and coupled to the upper end of the central upper right column (141b) and In addition, the central upper layer vertical length portion 142b fixed to the left wall (W21) of the existing right building (SB2) by the anchor bolt / nut fastening and the filling of high-strength polymer mortar, and in the longitudinal direction at a certain interval in the center upper left vertical beam 142a and a plurality of central upper floor robos 143 connecting the central upper right vertical part 142b, wherein the central roof reinforcement part 150 has a predetermined interval in the vertical direction at the center upper left vertical robo 142a. And a plurality of rooftop left pillars 151a having a lower end coupled to an upper surface thereof, and a plurality of rooftop right pillars 151b having a lower end fixed to an upper surface of the central upper right vertical part 142b at regular intervals in a vertical direction. , remind The rooftop left vertical beam 152a coupled to the upper end of the upper left column 151a, the rooftop right vertical beam 152b coupled to the upper end of the rooftop right pillar 151b, and the rooftop left vertical beam at regular intervals in a vertical direction. And a plurality of rooftop robos 153 connecting 152a and the rooftop right vertical beam 152b, wherein the left reinforcement part 200 includes a left base reinforcement part 210, a lower left reinforcement part 220, and a left side. It includes a middle reinforcement portion 230 and the left upper reinforcement portion 240, the left base reinforcement portion 210 is a reinforced concrete structure that excavates the left ground of the existing left base portion (FD1) and is poured into the ground A left foundation part F21 formed and connected to the existing left foundation part FD1, a plurality of left foundation left pillars 211a fixed to the left foundation part F21 at regular intervals in a vertical direction, and a length; A plurality of buried in the left base portion (F21) at regular intervals in the direction The left foundation right column 211b, the left base left vertical crossbeam 212a coupled to the top of the left base left column 211a, and the left base building pillar 211b, and the existing left building (SB1) The left basic right vertical robot (212b) fixed to the left wall (W11) by the anchor bolt / nut fastening and the filling of high-strength polymer mortar, and the left basic left vertical robot (212a) and the left basic right at regular intervals in the vertical direction It includes a plurality of left base cross-beam 213 connecting the stringer (212b), the lower left layer reinforcing portion 220 is coupled to the bottom of the upper surface of the left basic left vertical beam (212a) at regular intervals in the vertical direction A plurality of lower left column left pillars (221a) and the lower end is coupled to the upper surface of the left basic right vertical cross-section (212b) at regular intervals in the vertical direction and anchor bolts on the left wall (W11) of the existing left building (SB1) Nut tightening and high strength A plurality of left lower layer right pillars 221b fixed by the filling of the polymer mortar, a left lower layer left vertical beam 222a coupled to an upper end of the left lower layer left column 221a, and the left lower layer right column 221b. It is coupled to the top and the left lower layer right vertical robo (222b) fixed to the left wall (W11) of the existing left building (SB1) by fastening the anchor bolt / nut fastening and high-strength polymer mortar, the left at a predetermined interval in the vertical direction And a plurality of lower left floor robos 223 connecting the lower left vertical robo 222a and the left lower right vertical robo 222b, wherein the left middle layer reinforcing part 230 has a predetermined interval in the vertical direction to the left lower left vertical robo. A plurality of left mezzanine left pillars 231a coupled to a lower end of the upper surface of 222a, and coupled to an upper surface of the left lower layer right vertical robo 222b at regular intervals in the vertical direction, and the existing left building (SB1) A plurality of left mezzanine right pillars 231b fixed to the left wall W11 by anchor bolt / nut fastening and filling with high-strength polymer mortar, and a left mezzanine left vertical cuboid coupled to an upper end of the left mezzanine left pillar 231a ( 232a) and the left middle layer right side vertical beam which is coupled to the upper end of the left middle layer right column 231b and fixed by anchor bolt / nut fastening and high strength polymer mortar filling to the left wall W11 of the existing left building SB1 ( 232b) and a plurality of left middle layer robos 233 connecting the left middle layer left cevo 232a and the left middle layer right cevo 232b at regular intervals in the vertical direction, and the left upper layer reinforcing part 240 The upper left column left column 241a coupled to the lower end on the upper surface of the left mezzanine left vertical crossbeam 232a at a predetermined interval in the vertical direction, and the upper side of the left mezzanine right vertical beam 232b at regular intervals in the vertical direction. Ha And a plurality of upper left pillars 241b fixed to the left wall W11 of the existing left building SB1 by anchor bolt / nut fastening and filling of high-strength polymer mortar, and the left upper pillar left 241a The left upper left vertical robo (242a) coupled to the upper end of the upper left column (241b) and coupled to the top of the existing left building (SB1) to the left wall (W11) of the anchor bolt / nut fastening and high-strength polymer mortar The left upper right vertical robo 242b fixed by charging and a plurality of upper left upper robos 243 connecting the left upper left vertical robo 242a and the left upper right vertical robo 242b at regular intervals in the vertical direction. The right reinforcement part 300 includes a right basic reinforcement part 310, a right lower reinforcement part 320, a right middle reinforcement part 330, and a right upper reinforcement part 340. Reinforcement portion 310 of the existing right base portion (FD2) Excavated the side ground and formed in the reinforced concrete structure to be placed in the ground and fixed to the right base portion (F31) and the right base portion (F31) connected to the existing right base portion (FD2) at regular intervals in the longitudinal direction A plurality of right base left pillars 311a, a plurality of right base right pillars 311b which are fixed to the right base portion F31 at regular intervals in the vertical direction, and the right base left column 311a. It is coupled to the top and the right base left side vertical beam (312a) and the right base right pillar (311b) fixed to the right wall (W22) of the existing right building (SB1) by fastening the anchor bolt / nut fastening and high-strength polymer mortar And a plurality of right basic crossbeams 313 that are coupled to the upper right basic right robot 312b and connect the right basic left vertical robot 312a and the right basic right vertical robot 312b at regular intervals in the vertical direction. , Award Lower right reinforcement part 320 is coupled to the bottom of the upper right side of the left side vertical beam (312a) at regular intervals in the vertical direction and anchor bolt / nut fastening and high strength to the right wall (W22) of the existing right building (SB1) A plurality of right lower layer left pillars 321a fixed by filling of the polymer mortar, and a plurality of right lower layer right pillars 321b having a lower end coupled to an upper surface of the right basic right vertical beam 312b at a predetermined interval in the vertical direction. And, coupled to the upper end of the lower right column left 321a and the lower right floor left side vertical beam 322a fixed by anchor bolt / nut fastening and high-strength polymer mortar filling to the right wall (W22) of the existing right building (SB1). And, the lower right right side vertical beam 322b coupled to the upper right side of the lower right column 321b, and connects the right lower left left vertical robo 322a and the right lower right side vertical beam 322b at a predetermined interval in the vertical direction. It includes a plurality of lower right floor robo, 323, the right middle reinforcement unit 330 is coupled to the bottom of the upper right side of the lower right floor left vertical beam 322a at regular intervals in the vertical direction and the existing right building (SB1) And a plurality of right middle left column pillars 331a fixed to the right wall W22 by anchor bolt / nut fastening and high-strength polymer mortar filling, and the upper surface of the right lower layer right vertical robo 322b at a predetermined interval in the vertical direction. A plurality of right mezzanine right pillars 331b coupled to the lower end and the right mezzanine left pillar 331a are coupled to the upper end and anchor bolt / nut fastening and high strength polymer to the right wall W22 of the existing right building SB1. The right middle left vertical robo 332a fixed by the filling of mortar, the right middle left vertical robo 332b coupled to the upper end of the right middle right column 331b, and the right middle left space at regular intervals. It includes a plurality of right side girder 333 connecting the side robo (332a) and the right middle lateral right robo (332b), the right upper layer reinforcing portion 340 is the right middle left vertical vowel at regular intervals in the vertical direction ( 332a) is coupled to the lower end and a plurality of upper right column left pillars 341a fixed to the right wall W22 of the existing right building (SB1) by fastening anchor bolts / nuts and filling high-strength polymer mortar. A plurality of upper right upper pillars 341b coupled to a lower end on an upper surface of the right middle layer right vertical beam 332b at regular intervals, and coupled to an upper end of the upper right upper left column 341a, and the existing right building (SB1). Right upper left vertical robot 342a fixed to the right wall W22 by anchor bolt / nut fastening and high-strength polymer mortar filling, and right upper right vertical robot 342b coupled to the upper end of the upper right upper pillar 341b. )Wow And a plurality of upper right floor robos 343 connecting the upper right floor left robo 342a and the right upper floor right robo 342b at a predetermined interval in the vertical direction, and the central lower floor reinforcing part 120 and the lower floor below. Since the reinforcement unit 220 and the lower right reinforcement unit 320 are located on the parking spaces P11, P21, and P31, the front and rear surfaces should be installed in a state where the front and rear surfaces are opened for entrance and exit of the vehicle, but the middle layer reinforcement unit 130 And the central upper reinforcement part 140, the left middle reinforcement part 230, the left upper reinforcement part 240, the right middle reinforcement part 330, and the right upper reinforcement part 340 are installed at a height irrelevant to the entrance and exit of the vehicle. Therefore, it provides a seismic reinforcement structure using a high-strength polymer mortar and steel structure, characterized in that configured to utilize the inner space as a storage space.

According to the seismic reinforcement structure using the high-strength polymer mortar and steel structure of the present invention, to strengthen the seismic reinforcement effect by strengthening the individual reinforcement while connecting two existing buildings adjacent to each other, public space, common space It has the advantage of being extended to the storage space for storing and managing materials.

1 and 2 are a front view and a plan view of a seismic reinforcement structure using a high-strength polymer mortar and steel structure according to the present invention,
3 is a longitudinal front view of a state in which a panel of a seismic reinforcement structure using the high strength polymer mortar and the steel structure according to the present invention is removed;
4 is a plan view of a state of removing the panel of the seismic reinforcement structure using a high-strength polymer mortar and steel structures according to the present invention,
5 is an exploded perspective view of the central foundation reinforcement unit and the central lower layer reinforcement unit,
6 is an exploded perspective view of the central stratified reinforcement part, the central upper reinforcement part and the central roof reinforcement part;
7 is an exploded perspective view of the left base reinforcement unit and the left lower layer reinforcement unit;
8 is an exploded perspective view of the left middle layer and the upper left layer;
9 is an exploded perspective view of the right base reinforcement unit and the right lower layer reinforcement unit;
10 is an exploded perspective view of a right middle layer reinforcing portion and a right upper layer reinforcing portion.

Hereinafter, the seismic reinforcing structure using the high strength polymer mortar and the steel structure according to the present invention will be described in detail according to a preferred embodiment.

1 to 7 show a preferred embodiment of the seismic reinforcement structure using a high-strength polymer mortar and steel structure according to the present invention.

In the description of the present embodiment, various bolts and nuts, bolt through-holes through which bolts pass, and bolt fastening holes through which bolts are fastened are shown in the drawings, and reference numerals and detailed descriptions thereof will be omitted.

In addition, the web and the pair of flanges constituting the H-shaped steel is shown in the drawings, and reference numerals and detailed description thereof will be omitted.

This embodiment is a relatively small building structure collectively referred to as so-called 'row house' or 'villa', and is configured to be suitable for the seismic reinforcement of the existing left building (SB1) and the existing right building (SB2) located adjacent to each other.

The existing left building (SB1) is the existing left foundation (FD1), the left wall (W11) and the right wall (W12), the lower floor slab (S11) and the middle floor slab (S12) and the upper floor slab (S13) and rooftop slab ( S14), the existing right building (SB2) is the existing right base (FD2), the left wall (W21) and the right wall (W22), the lower floor slab (S21) and the middle floor slab (S22) and the upper floor slab ( S23) and a rooftop slab S24.

In addition, a central parking space P11 is provided between the right wall W12 of the existing left building SB1 and the left wall W21 of the existing right building SB2, and the left parking space P21 is provided on the left side of the existing left building SB1. ) Is provided, the right side parking space (P31) is provided on the right side of the existing right building (SB2).

The left walls W11 and W21, the right walls W12 and W22, and the lower floor slabs S11 and S21 are provided on the base portions FP1 and FP2 which are installed in the ground.

The left wall W11 and W21, the right wall W12 and W22, the lower floor slab S11 and S21, the middle floor slab S12 and S22, the upper floor slab S13 and S23 and the rooftop slab S14 and S24 It may be formed of a reinforced concrete structure or may be composed of a steel structure.

The present invention includes a central reinforcing means (100) installed between the right wall (W12) of the existing left building (BS1) and the left wall (W21) of the existing right building (SB2); A left reinforcement part 200 installed outside the left wall W11 of the existing left building SB1; And a right reinforcing part 300 installed outside the right wall W22 of the existing right building SB2.

The central reinforcement means 100 is a central basic reinforcement unit 110, a central lower reinforcement unit 120, a central middle reinforcement unit 130, a central upper reinforcement unit 140, and a central roof reinforcement unit 150 ).

The central foundation reinforcement unit 110 is formed of a reinforced concrete structure that excavates the ground between the existing left foundation (FD1) and the existing right foundation (FD2) and is placed in the ground so that the existing left foundation (FD1) and existing The central foundation portion F11 connected to the right foundation portion FD2, the plurality of central foundation left pillars 111a fixed to the central foundation portion F11 at regular intervals in the longitudinal direction, and in the longitudinal direction. A plurality of central foundation right pillars 111b fixed to the central foundation part F11 at regular intervals and coupled to the upper ends of the central foundation left pillars 111a and the right wall W12 of the existing left building SB1. A plurality of central basic left vertical beams 112a fixed to the upper side and the central basic right vertical beams 111b and a plurality of central basic right vertical beams fixed to the left wall W21 of the existing right building SB2, 112b), spaced longitudinally And a plurality of central foundation crossbeams 113 connecting the central basic left crossbeam 112a and the central basic right crossbeam 112b.

The lower middle reinforcement part 120 has a lower end coupled to an upper surface of the central basic left vertical beam 112a at a predetermined interval in the vertical direction and is fixed to the lower right wall W12 of the existing left building SB1. (121a) and the lower middle column right side (121b) is fixed to the upper wall of the central basic right longitudinal crossbeam (112b) and fixed to the left wall (W21) of the existing right building (SB2) at regular intervals in the longitudinal direction. Is coupled to the upper end of the lower middle column left pillar (121a), and coupled to the upper middle middle floor vertical cross-section (122a) and fixed to the right wall (W12) of the existing left building (SB1), and coupled to the upper end of the lower middle column right pillar (121b) In addition, the central lower floor vertical robot 122b fixed to the left wall W21 of the existing right building SB2 and the central lower floor vertical robot 122a and the central lower floor vertical robot 122b at regular intervals in a vertical direction are connected to each other. A plurality of central lower floor street robos (123) It includes.

The central stratified reinforcement unit 130 is coupled to the upper surface of the central lower left vertical length 122a at a predetermined interval in the vertical direction, and a plurality of central stratified left pillars fixed to the right wall W12 of the existing left building SB1. 131a and a plurality of central mezzanine right pillars 131b which are coupled to an upper surface of the central lower layer right longitudinal robot 122b at a predetermined interval in a clockwise direction and are fixed to the left wall W21 of the existing right building SB2; Is coupled to the upper end of the central stratified left column 131a and coupled to the upper end of the central stratified left vertical beam 132a and fixed to the right wall W12 of the existing left building SB1, and is coupled to the upper end of the central stratified right column 131b. In addition, the central middle right vertical robo (132b) fixed to the left wall (W21) of the existing right building (SB2), and connects the central lower floor left vertical robot (122a) and the central lower floor right vertical (122b) at regular intervals in the vertical direction. A plurality of middle floor street robos 133.

The central upper reinforcement unit 140 is coupled to the upper surface of the central middle left vertical beam 132a at a predetermined interval in the vertical direction, and a plurality of central upper left columns fixed to the right wall W12 of the existing left building SB1. 141a and a plurality of central upper right pillars 141b coupled to an upper surface of the central middle right longitudinal robot 132b at a predetermined interval in the vertical direction and fixed to the left wall W21 of the existing right building SB2; Is coupled to the upper end of the central upper left column (141a), and coupled to the upper middle left side vertical robo (142a) and fixed to the right wall (W12) of the existing left building (SB1), and coupled to the upper end of the central upper right column (141b) In addition, the central upper right vertical part 142b fixed to the left wall W21 of the existing right building SB2, and the central upper left vertical robo 142a and the central upper right vertical part 142b at regular intervals in the vertical direction. A plurality of central upper street robo to connect 143.

The central rooftop reinforcement part 150 has a plurality of rooftop left pillars 151a coupled to a lower end on an upper surface of the central upper left vertical beam 142a at a predetermined interval in the vertical direction, and at a predetermined interval in the vertical direction. A plurality of rooftop right pillars 151b having a lower end fixed to an upper surface of an upper right vertical part 142b, a rooftop left vertical beam 152a coupled to an upper end of the rooftop left pillar 151a, and the rooftop right pillar 151b. Rooftop right side robo (152b) coupled to the upper end of the; and a plurality of rooftop robo (153) for connecting the rooftop left side robo (152a) and the rooftop right side helical (152b) at regular intervals in the vertical direction.

The central foundation left pillar 111a, the central foundation right pillar 111b, the central lower left pillar 121a, the central lower right pillar 121b, the central middle left pillar 131a, the central middle right pillar 131b, the center The upper left column 141a, the central upper right column 141b, the central foundation robo 113, the central lower tier robo 123, the central tier robo 133, the central tier robo 143, and the rooftop robo 153 The number of installations can be varied to correspond to the longitudinal width of the existing left building (SB1) and the existing right building (SB2). In the illustrated example, only one is shown at the front and rear ends for convenience.

The central basic left column 111a, the central basic right column 111b, the central basic left longitudinal crossbeam 112a, the central basic right longitudinal crossbeam 112b, the central basic crossbeam 113, and the central lower left column 121a, Lower middle right pillar 121b, lower middle left vertical robot 122a, lower middle right vertical robot 122b, lower middle horizontal robo 123, middle middle left column 131a, middle middle right column 131b, middle middle floor Left vertical beam 132a, center middle right side robo 132b, center middle floor robo 133, center upper left column 141a, center upper right column 141b, center upper left vertical robo 142a, center upper right vertical robo 142b, the central upper floor robo 143, the rooftop left pillar 151a, the rooftop right pillar 151b, the rooftop left vertical robo 152a, the rooftop right vertical robo 152b, and the rooftop robo 153 are paired with the web. Consists of a typical H-shaped steel with a flange of.

Upper and lower coupling pieces 111c and 111e and lower coupling pieces 111d and 111f are fixed to the upper and lower ends of the central foundation left pillar 111a and the central foundation right pillar 111b by welding. ) And upper and lower coupling pieces 121c and 121e and lower coupling pieces 121d and 121f are fixed by welding at the upper and lower ends of the central lower layer right pillar 121b, and the central middle layer left column 131a and the central middle layer right pillar ( Upper and lower ends of the upper and lower coupling pieces 131c and 131e and the lower coupling pieces 131d and 131f are fixed by welding at upper and lower ends of the upper and lower ends of the upper and lower ends of the upper middle column 141a and the upper middle column 141b. Pieces 141c and 141e and lower coupling pieces 141d and 141f are fixed by welding, and upper and lower coupling pieces 151c and 151e and lower couplings are formed at upper and lower ends of the rooftop left column 151a and the rooftop right column 151b. Pieces 151d and 151f are fixed by welding.

The upper coupling pieces and the lower coupling pieces are formed in an elongated rectangular shape in the transverse direction.

The central foundation left pillar 111a and the central foundation right pillar 111b can be fixed only by embedding in the central foundation portion F11, but are embedded together in the central foundation portion F11 by welding a plurality of rebars or steel bars. By doing so, it can be fixed more firmly.

The lower middle column left (121a), the middle middle column left (131a), the upper middle column left (141a) is a high-strength polymer mortar 124a, 134a, between the web and the flange and the right wall (W12) of the existing left building (SB1) 144a) can be fixed to the right wall (W12) of the existing left building (SB1), the lower middle column right (121b), the middle middle column right (131b), the upper middle column right (141b) And the high strength polymer mortars 124b, 134b, and 144b are filled between the flange and the left wall W21 of the existing right building SB2 to be fixed to the left wall W21 of the existing right building SB2.

In addition, the center lower floor column 121a, the center middle floor column 131a, and the center upper floor column 141a penetrate the anchor bolt embedded in the right wall W12 of the existing left building SB1 through the web, and then the nut. By fastening it can also be fixed to the right wall (W12) of the existing left building (SB1),

The center lower layer right pillar 121b, the center middle layer right pillar 131b, and the center upper layer right pillar 141b penetrate the anchor bolt embedded in the left wall W21 of the existing right building SB2 through the web and fasten the nut. It can also be fixed to the left wall (W21) of the existing right building (SB2).

In addition, the central lower left column 121a, the central middle left column 131a, the central upper left column 141a, the central lower left column 121a, the central middle left column 131a, and the central upper left column 141a. ) May be fixed in duplicate by the above-mentioned high strength polymer mortar and anchor bolts / nuts.

The central foundation left robot 112a, the central lower left vertical robot 122a, the central middle left vertical robot 132a, and the central upper left vertical robot 142a are anchor bolts projected to the right wall W12 of the existing left building SB1. It can be fixed to the right wall (W12) of the existing left building (SB1) by penetrating through the web and the nut, and the central basic right side robot (112b), the center lower layer right side robot (122b), the middle middle layer right side robot ( 132b), the upper middle right vertical robo (142b) is the left wall (W21) of the existing right building (SB2) by passing the anchor bolt embedded in the left wall (W21) of the existing right building (SB2) through the web and tightening the nut. Can be fixed at

At this time, the web and the flange of the central foundation left side robot (112a), the center lower left side robot (122a), the middle middle left side robo (132a), the central upper left side robo (142a) and the existing left building (SB1) (W12) Filled between the high-strength polymer mortar (115a, 125a, 135a, 145a), the middle basic right side robot (112b), the center lower right side robot (122b), the middle middle layer right side robo (132b), the central upper layer right side robot (142b) The high-strength polymer mortars 115b, 125b, 135b, and 145b are filled between the web and the flange of the web and the left wall W21 of the existing right building SB2 and double fixed together with the anchor bolts and nuts. The right wall (W12) and the existing right building (SB2) of the left wall (W21) can be made firmly coupled.

The central basic left longitudinal cross 112a seats the lower flange on the upper engaging piece 111c of the central basic left pillar 111a, and passes the bolt through the lower flange and the upper engaging piece 111c to fasten the nut. It can be coupled to the upper end of the central basic left column (111a), the central basic right vertical crossbeam (112b) is to seat the lower flange on the upper coupling piece (111e) of the central basic right column (111b), and the lower flange and It can be coupled to the upper end of the central foundation right pillar (111b) by fastening the nut through the bolt through the upper coupling piece (111e).

The lower middle column left pillar 121a seats the lower coupling piece 121d on the upper flange of the central foundation left longitudinal crossbeam 112a, and passes the bolt through the upper flange and the lower coupling piece 121d to fasten the nut. It can be coupled to the upper surface of the central basic left longitudinal crossbeam (112a), the central lower layer right pillar (121b) is to seat the lower coupling piece (121f) on the upper flange of the central basic right side crossbeam (112b), and the upper flange and It can be coupled to the upper surface of the central basic right vertical cross-section 112b by fastening the nut through the bolt through the lower coupling piece 121f.

The middle lower floor left longitudinal robot 122a seats the lower flange on the upper engaging piece 121c of the lower middle left column 121a, and passes the bolt through the lower flange and the upper engaging piece 121c to fasten the nut. It can be coupled to the upper end of the central lower left column (121a), the central lower layer right vertical beam (122b) is to seat the lower flange on the upper coupling piece (121e) of the central lower layer right column (121b), The upper coupling piece 121e may be coupled to the upper end of the central lower layer right pillar 121b by fastening a nut through the bolt.

The central stratified left column 131a seats the lower coupling piece 131d on the upper flange of the lower middle left vertical beam 122a, and passes the bolt through the upper flange and the lower coupling piece 131d to fasten the nut. It can be coupled to the upper surface of the central lower left vertical robot (122a), the central middle layer right pillar (131b) seats the lower coupling piece (131f) on the upper flange of the central lower layer right vertical robot (122b), and the upper flange and It can be coupled to the upper surface of the center lower layer right vertical cross-section 122b by fastening the nut through the lower coupling piece 131f.

The middle striking left side vertical beam 132a seats the lower flange on the upper engaging piece 131c of the central straddling left column 131a, and passes the bolt through the lower flange and the upper engaging piece 131c to fasten the nut. It can be coupled to the upper end of the middle-layer left column (131a), the middle-layer right side vertical beam (132b) is seated on the upper coupling piece (131e) of the lower-middle middle layer right column (131b), and the lower flange and It can be coupled to the upper end of the central middle layer right pillar (131b) by fastening the nut through the bolt through the upper coupling piece (131e).

The central upper left column 141a seats the lower coupling piece 141d on the upper flange of the central middle left vertical beam 132a, and fastens the nut by passing a bolt through the upper flange and the lower coupling piece 141d. It can be coupled to the upper surface of the central middle left vertical robo (132a), the central upper right column 141b seats the lower coupling piece (141f) on the upper flange of the central middle right vertical robo (132b), the upper flange and the lower It can be coupled to the upper surface of the central middle layer right vertical beam 132b by fastening the nut through the bolt through the coupling piece 141f.

The central upper left vertical robo 142a seats the lower flange on the upper coupling piece 141c of the central upper left column 141a, and fastens the nut by passing a bolt through the lower flange and the upper coupling piece 141c. It can be coupled to the upper end of the central upper left column (141a), the central upper right side vertical beam (142b) is to seat the lower flange on the upper coupling piece (141e) of the central upper right column (141b), and the lower flange and It can be coupled to the upper end of the central upper right column (141b) by fastening the nut through the bolt through the upper coupling piece (141e).

The rooftop left column 151a seats the lower coupling piece 151d on the upper flange of the central upper left vertical beam 142a, and passes the bolt through the upper flange and the lower coupling piece 151d to fasten the nut. It can be coupled to the upper surface of the central upper left vertical robo (142a), the roof top right column (151b) seats the lower coupling piece (151f) on the upper flange of the central upper right robo (142b), the upper flange and the lower coupling It can be coupled to the upper surface of the center upper layer right side vertical beam 142b by fastening a nut through the piece 151f.

The rooftop left vertical beam 152a seats the lower flange on the upper coupling piece 151c of the rooftop left pillar 151a, and passes the bolt through the lower flange and the upper coupling piece 151c to fasten the nut. It can be coupled to the upper end of the left column (151a), the rooftop right side vertical beam (152b) is seated on the upper coupling piece 151e of the rooftop right column (151b), the lower flange and the upper coupling piece (51e) By fastening the nut through the bolt) can be coupled to the upper end of the rooftop right pillar (151b).

The central foundation crossbeam 113 is inserted between the upper coupling piece 111c of the central foundation left column 111a and the lower coupling piece 121d of the central lower left column 121a, and the lower flange and the upper coupling. The nut is screwed through the bolt 111c, and the nut is screwed into the upper flange and the lower coupling piece 121d. The upper end piece 111e of the central foundation right pillar 111b is fastened to the nut. And the lower coupling piece 121f of the lower middle pillar 120b, through the bolt through the lower flange and the upper coupling piece 111e, and tighten the nut, and the upper flange and the lower coupling piece 121f. The central basic left vertical beam 112a and the central basic right vertical beam 112b are connected to each other by fastening the nut through the bolt, and the central basic left column 111a and the lower middle left column 121a and the central basic right side. It can be coupled to the pillar 111b and the lower right column 121b.

The central lower layer gabor 123 is inserted between the upper coupling piece 121c of the central lower left column 121a and the lower coupling piece 131d of the central middle left column 131a, and the lower flange and the upper coupling piece. The nut is screwed through the bolt through 121c, and the nut is screwed through the bolt through the upper flange and the lower coupling piece 131d, and the upper end is coupled with the upper coupling piece 121e of the lower right column 121b. It is inserted between the lower coupling piece 131f of the middle middle layer right pillar 131b, and the nut is screwed through the lower flange and the upper coupling piece 121e, and the bolt is connected to the upper flange and the lower coupling piece 131f. By connecting the nut through the fastening nut to connect the lower middle left vertical robot 122a and the lower middle right vertical robot 122b, and the lower middle left column 121a, the middle middle left column 131a, and the lower middle right column ( 121b) and the central middle layer right pillar 131b.

The central strata gabor 133 is inserted between the upper coupling piece 131c and the lower coupling piece 141d of the central upper left column 141a, the left end of the central intermediate pillar 131a, the lower flange and the upper coupling piece Through the bolt through the bolt (131c) to fasten the nut, and through the bolt through the upper flange and the lower coupling piece (141d) to fasten the nut, the right end and the upper coupling piece (131e) of the central middle layer right pillar (131b) It is inserted between the lower coupling piece 141f of the upper middle pillar 141b, and the bolt passes through the lower flange and the upper coupling piece 131e to tighten the nut, and the bolt is attached to the upper flange and the lower coupling piece 141f. The central middle left longitudinal robo 132a and the middle middle right longitudinal robo 132b are connected to each other by fastening the nut, and the middle middle left column 131a, the central upper left column 141a, and the middle middle right column ( 131b) and the central upper right column 141b.

The central upper gabor 143 is inserted into the left end between the upper engaging piece 141c of the central upper left column 141a and the lower engaging piece 151d of the rooftop left column 151a, and the lower flange and the upper engaging piece ( 141c) through the bolt to tighten the nut, and through the bolt through the upper flange and the lower coupling piece (151d) to fasten the nut, the right end of the upper coupling piece (141e) and the rooftop of the upper middle column (141b) It is inserted between the lower coupling piece 151f of the right column 151b, and the bolt is passed through the lower flange and the upper coupling piece 141e to tighten the nut, and the bolt passes through the upper flange and the lower coupling piece 151f. The upper middle left vertical robo 142a and the upper middle right vertical robo 142b are connected to each other, and the upper middle left column 141a, the upper left column 151a, and the upper right column 141b are connected to each other. It may be coupled to the rooftop right pillar 151b.

The rooftop robo 153 seats the left end on the upper coupling piece 151c of the rooftop left column 151a, and fastens the nut by passing a bolt through the lower flange and the upper coupling piece 151c, and the right end of the rooftop right side. The rooftop left vertical beam 152a and the rooftop right vertical beam 152b are seated on the upper coupling piece 151e of the column 151b, and the bolts pass through the lower flange and the upper coupling piece 151e to fasten nuts. In addition to the coupling can be coupled to the rooftop left column (151a) and rooftop right column (151b).

The left reinforcement part 200 includes a left basic reinforcement part 210, a lower left reinforcement part 220, a left middle reinforcement part 230, and a left upper reinforcement part 240.

The left foundation reinforcement portion 210 is formed of a reinforced concrete structure that excavates the left ground of the existing left foundation portion (FD1) and is placed in the ground and left foundation portion (F21) connected to the existing left foundation portion (FD1) and A plurality of left foundation pillars 211a buried in the left base portion F21 at regular intervals in the longitudinal direction, and a plurality of left foundation pillars 211a buried in the left foundation portion F21 at regular intervals in the longitudinal direction; The left foundation right column 211b, the left base left vertical crossbeam 212a coupled to the top of the left base left column 211a, and the left base building pillar 211b, and the existing left building (SB1) The left basic right vertical beam (212b) fixed to the left wall (W11) of the) and the plurality of left basic horizontal beams connecting the left basic left vertical beam (212a) and the left basic right vertical beam (212b) at regular intervals in the vertical direction. (213).

The lower left layer reinforcing part 220 has a plurality of lower left column left pillars 221a coupled to a lower end on an upper surface of the left basic left vertical beam 212a at a predetermined interval in the vertical direction, and at a predetermined distance in the vertical direction. A lower end is coupled to the upper surface of the left basic right side robot 212b and a plurality of lower left right columns 221b fixed to the left wall W11 of the existing left building SB1, and an upper end of the left lower left column 221a. Left lower floor left side vertical robo (222a) coupled to the upper left side of the lower left column right (221b) and coupled to the upper left lower left right side vertical beam (222b) and fixed to the left wall (W11) of the building (SB1), And a plurality of lower left floor robos 223 connecting the left lower floor left robo 222a and the left lower floor right robo 222b at predetermined intervals in a direction.

The left mezzanine reinforcement unit 230 has a plurality of left mezzanine left columns 231a coupled to a lower end on an upper surface of the left lower left vertical longitudinal beam 222a at a predetermined interval in the vertical direction, and at a predetermined distance in the vertical direction. It is coupled to the upper surface of the lower left right side vertical robo (222b) and coupled to a plurality of left middle right pillars (231b) fixed to the left wall (W11) of the existing left building (SB1) and the upper left of the left middle left column (231a). The left mezzanine left side vertical beam 232a and the left mezzanine right side vertical beam 232b coupled to the upper end of the left mezzanine right column 231b and fixed to the left wall W11 of the existing left building SB1, and in a vertical direction. It includes a plurality of left-middle street robo (233) connecting the left-middle left side vertical robo (232a) and the left-middle right side vertical (232b) at regular intervals.

The upper left layer reinforcement part 240 has a left upper left column 241a coupled with a lower end to an upper surface of the left middle left vertical longitudinal beam 232a at regular intervals in a vertical direction, and the left middle layer at regular intervals in a vertical direction. A lower end is coupled to the upper surface of the right vertical beam 232b and a plurality of upper left pillars 241b fixed to the left wall W11 of the existing left building SB1, and coupled to an upper end of the upper left column 241a. The left upper left vertical robo 242a and the left upper right vertical robo 242b coupled to the upper end of the left upper right column 241b and fixed to the left wall W11 of the existing left building SB1, and vertically It includes a plurality of left upper floor robo 243 connecting the left upper left vertical robo 242a and the left upper right vertical robo 242b at a predetermined interval.

The left basic left column 211a, the left basic right column 211b, the left lower left column 221a, the left lower right column 221b, the left middle left column 231a, the left middle right column 231b, the left side The upper left column 241a, the upper left column 241b, the left base girder 213, the lower left girder 223, the left middle girder 233, and the left upper girder 243 are existing left buildings (SB1). ) And the number of installations can be varied corresponding to the vertical width of the existing right building (SB2).

The left basic left column 211a, the left basic right column 211b, the left basic left vertical robot 212a, the left basic right vertical beam 212b, the left basic horizontal robot 213, and the left lower left column 221a, Left lower floor right column (221b), Left lower floor left vertical robo (222a), Left lower floor right vertical robo (222b), Left lower floor horizontal robo (223), Left middle floor left column (231a), Left middle floor right column (231b), Left middle floor Left vertical robo (232a), left middle right robo (232b), left middle floor robo (233), left upper left column (241a), left upper right column (241b), left upper left vertical robo (242a), left upper right vertical robo 242b, the upper left gabor 243 is composed of a conventional H-shaped steel having a web and a pair of flanges.

Upper and lower coupling pieces 211c and 211e and lower coupling pieces 211d and 211f are fixed to upper and lower ends of the left foundation left column 211a and the left foundation right column 211b by welding, and the left lower layer left column 221a. ) And the upper and lower ends of the left lower layer right column 221b and the upper coupling pieces 221c and 221e and the lower coupling pieces 221d and 211f are fixed by welding, and the left middle layer left column 231a and the left middle layer right column ( The upper and lower ends of the upper and lower ends 231c and 231e and the lower and lower coupling pieces 231d and 231f are fixed by welding, and upper and lower ends of the upper left column 241a and the upper left column 241b are welded. The pieces 241c and 241e and the lower coupling pieces 241d and 241f are fixed by welding.

The upper coupling piece and the lower coupling piece are formed in an elongated rectangular shape in the transverse direction.

The left base pillar 211a and the left base pillar 211b can be fixed only by embedding in the left base portion F21, but are embedded together in the left base portion F21 by welding a plurality of rebars or steel bars. By doing so, it can be fixed more firmly.

The left lower layer right pillar 221b, the left middle layer right pillar 231b, and the left upper layer right pillar 241b are formed of a high strength polymer mortar 224, 234, between the web and the flange and the left wall W11 of the existing left building SB1. 244 may be fixed to the left wall W11 of the existing left building SB1.

In addition, the left lower layer right column 221b, the left middle layer right column 231b, and the left upper layer right column 241b penetrate the anchor bolt which is buried in the left wall W11 of the existing left building SB1 through the web, and nuts. It can also be fixed to the left wall W11 of the existing left building SB1 by fastening.

In addition, the left lower layer right pillar 221b, the left middle layer right pillar 231b, and the left upper layer right pillar 241b may be double fixed by the high-strength polymer mortar and the anchor bolt / nut.

The left basic right vertical robot 212b, the left lower right vertical robo 222b, the left middle right vertical robo 232b, and the left upper right vertical robo 242b are anchor bolts projected to the left wall W11 of the existing left building SB1. It can be fixed to the left wall (W11) of the existing left building (SB1) by passing through the web and fastening the nut.

At this time, the web and the flange of the left basic right side robo 212b, the left lower right side robo 222b, the left middle right side robo 232b, the left upper right side robo 242b, and the left wall of the existing left building SB1 (W11) By filling the high-strength polymer mortar (215, 225, 235, 245) in between to fix the double with the anchor bolt / nut can be made to secure the fixed to the left wall (W11) of the existing left building (SB1). .

The left basic left longitudinal robot 212a seats the lower flange on the upper coupling piece 211c of the left basic left pillar 211a, and passes the bolt through the lower flange and the upper coupling piece 211c to fasten the nut. It can be coupled to the upper end of the left foundation left column (211a), the left basic right vertical beam (212b) seats the lower flange on the upper coupling piece (211e) of the left foundation right pillar (211b), and the lower flange and It can be coupled to the upper end of the left basic right pillar (211b) by fastening the nut through the upper coupling piece (211e).

The left lower layer left column 221a seats the lower engaging piece 221d on the upper flange of the left basic left longitudinal robot 212a, and the bolt is passed through the upper flange and the lower engaging piece 221d to fasten the nut. It can be coupled to the upper surface of the left basic left longitudinal robot (212a), the left basic right column (211b) is seated on the upper flange of the left base right longitudinal robot (212b), and the upper flange and the upper flange It can be coupled to the upper surface of the left basic right side vertical beam (212b) by fastening the nut through the bolt through the lower coupling piece (211f).

The left lower floor left vertical robo (222a) seats the lower flange on the upper engaging piece (221c) of the lower left floor column (221a), and passes the bolt through the lower flange and the upper engaging piece (221c) to fasten the nut. It can be coupled to the upper left of the lower left column left 221a, the left lower layer right vertical robo 222b seats the lower flange on the upper coupling piece 221e of the lower left layer right column 221b, and the lower flange and It can be coupled to the upper end of the lower left column right pillar (221b) by fastening the nut through the bolt through the upper coupling piece (221e).

The left mezzanine left column 231a seats the lower engaging piece 231d on the upper flange of the lower left vertical servo 222a, and passes the bolt through the upper flange and the lower engaging piece 231d to fasten the nut. It can be coupled to the upper surface of the lower left floor left vertical robo (222a), the left middle layer right column (231b) seats the lower coupling piece (231f) on the upper flange of the lower left floor right vertical robo (222b), and the upper flange and By fastening the nut through the lower coupling piece 231f, it can be coupled to the upper surface of the left lower layer right vertical beam 222b.

The left mezzanine left longitudinal robot 232a seats the lower flange on the upper engaging piece 231c of the left mezzanine left column 231a, and passes the bolt through the lower flange and the upper engaging piece 231c to fasten the nut. It can be coupled to the upper end of the left mezzanine left column (231a), the left mezzanine right vertical robo (232b) to seat the lower flange on the upper coupling piece (231e) of the left mezzanine right column (231b), It can be coupled to the upper end of the left middle layer right column (231b) by fastening the nut through the upper coupling piece (231e).

The left upper left column 241a seats the lower engaging piece 241d on the upper flange of the left middle left vertical beam 232a, and passes the bolt through the upper flange and the lower engaging piece 241d to fasten the nut. It can be coupled to the upper surface of the left middle left vertical robo (232a), the left upper right column (241b) seats the lower coupling piece (241f) on the upper flange of the left middle right vertical robo (232b), It can be coupled to the upper surface of the left middle layer right vertical beam 232b by fastening a nut through the lower coupling piece 241f.

The upper left upper left vertical robo 242a seats the lower flange on the upper engaging piece 241c of the upper left upper pillar 241a, and passes the bolt through the lower flange and the upper engaging piece 241c to fasten the nut. It can be coupled to the upper end of the left upper left column (241a), the left upper right vertical robo (242b) to seat the lower flange on the upper coupling piece (241e) of the upper left upper column (241b), It can be coupled to the upper end of the upper left column right 241b by fastening the nut through the upper coupling piece 241e.

The left foundation crossbeam 213 is inserted into the left end between the upper coupling piece (211c) of the left foundation left column (211a) and the lower coupling piece (221d) of the lower left column left pillar (221a), the lower flange and the upper coupling Through the bolt through the piece 211c to fasten the nut, and through the bolt through the upper flange and the lower coupling piece (221d) to fasten the nut, the upper end of the upper base piece (211e) of the left base right column (211b) Is inserted between the lower coupling piece 221f of the lower left column right column 221b, and the nut is screwed through the lower flange and the lower coupling piece 211e to the upper flange and the lower coupling piece 221f. The left basic left vertical beam 212a and the left basic right vertical beam 212b are connected to each other by fastening the nut through the bolt, and the left basic left column 211a, the lower left column left column 221a, and the left basic right column. 211b and the lower left column right column 221b.

The lower left floor gabor 223 is inserted into the lower end between the upper coupling piece 221c of the left lower left column 221a and the lower coupling piece 231d of the left middle left column 231a, and the lower flange and the upper coupling piece. 221c through the bolt to fasten the nut, and through the bolt through the upper flange and the lower coupling piece (231d) to fasten the nut, the right end of the upper coupling piece (221e) of the lower left column right column (221b) It is inserted between the lower coupling piece 231f of the left middle layer right column 231b, and the nut passes through the lower flange and the upper coupling piece 221e to tighten the nut, and the bolt is attached to the upper flange and the lower coupling piece 231f. The left lower layer left vertical robo 222a and the left lower layer right vertical robo 222b are connected to each other by fastening the nut, and the lower left layer left column 221a, the left middle layer left column 231a, and the left lower layer right column ( 221b) and the left middle layer right column 231b.

The left middle floor robo 233 inserts the left end between the upper engaging piece 231c of the left middle left column 231a and the lower engaging piece 241d of the left upper left column 241a, and the lower flange and the upper engaging piece. The nut is passed through the bolt through the bolt 231c, and the nut is fastened by passing the bolt through the upper flange and the lower coupling piece 241d, and the upper end is coupled with the upper coupling piece 231e of the left middle layer right column 231b. It is inserted between the lower coupling piece 241f of the upper left column 241b, the bolt is passed through the lower flange and the upper coupling piece 231e, and the nut is tightened, and the bolt is attached to the upper flange and the lower coupling piece 241f. The left mezzanine left longitudinal robo (232a) and the left mezzanine right vertical robo (232b) are connected to each other by tightening the nut, and the left mezzanine left column (231a), the left upper left column (241a), and the left mezzanine right column ( 231b) and the upper left column 241b.

The left upper floor robo 243 inserts a left end between the upper engaging piece 241c of the left upper left column 241a and the engaging piece 241g welded and fixed to the upper surface of the left upper left longitudinal robo 242a, and has a lower flange. And the nut through the bolt through the upper coupling piece 241c and the nut through the bolt through the upper flange and the coupling piece 241g, and the upper end of the upper coupling piece 241b of the upper left column 241b. 241f) is inserted between the coupling pieces 241h welded and fixed to the upper surface of the upper left right vertical robo 242b, and through the bolts through the lower flange and the upper coupling piece 241e, the nut is tightened and the upper flange is engaged with the upper flange. The left upper left vertical robo 242a and the left upper right vertical robo 242b are connected to each other through the bolt through the bolt 241h, and the left upper left column 241a and the left upper right column 241b. Can be combined.

The right reinforcement part 300 includes a right basic reinforcement part 310, a right lower reinforcement part 320, a right middle reinforcement part 330, and a right upper reinforcement part 340.

The right foundation reinforcement part 310 is formed of a reinforced concrete structure that excavates the right ground of the existing right foundation part (FD2) and is placed in the ground and is connected to the existing right foundation part (FD2). A plurality of right base pillars 311a buried in the right base portion F31 at regular intervals in the longitudinal direction, and a plurality of left base pillars 331a buried in the right base portion F31 at regular intervals in the vertical direction; The right base left side vertical beam 312a and the right base left column 311b coupled to the upper end of the right base left column 311a and fixed to the right wall W22 of the existing right building SB1, and the right base right side A plurality of right basic crossbeams connecting the right basic left vertical beam 312b to which the pillar 311b is coupled to the top, and connecting the right basic left vertical beam 312a and the right basic right vertical beam 312b at regular intervals in the vertical direction. 313.

The lower right floor reinforcement part 320 is coupled to the bottom of the upper right side of the left side vertical beam 312a at regular intervals in the vertical direction and a plurality of lower right floors fixed to the right wall W22 of the existing right building SB1. A left column 321a, a plurality of right lower layer right pillars 321b coupled to a lower end on an upper surface of the right basic right vertical beam 312b at regular intervals in the vertical direction, and an upper end of the right lower layer left column 321a. Coupled to the lower right side left vertical robot 322a fixed to the right wall (W22) of the existing right building (SB1), and the lower right right side vertical beam (322b) coupled to the upper end of the right lower right column (321b), vertically And a plurality of right lower floor robos 323 connecting the right lower floor left vertical robo 322a and the right lower floor right vertical robo 322b at predetermined intervals in a direction.

The right middle reinforcement part 330 has a lower end coupled to an upper surface of the right lower floor left vertical beam 322a at a predetermined interval in the vertical direction, and a plurality of right middle floors fixed to the right wall W22 of the existing right building SB1. The left column 331a, a plurality of right middle layer right pillars 331b coupled to a lower end on an upper surface of the right lower layer right vertical beam 322b at a predetermined interval in the vertical direction, and the right layer middle left column 331a Coupled to the right and the right middle left vertical robo (332a) fixed to the right wall (W22) of the existing right building (SB1), the right middle right vertical robo (332b) coupled to the upper end of the right middle right column (331b), and vertical It includes a plurality of right-middle side street robo 333 connecting the right-middle left side vertical robo (332a) and the right-middle right side vertical robo (332b) at regular intervals in the direction.

The right upper floor reinforcing part 340 is coupled to the bottom of the upper right side of the left vertical longitudinal beam 332a at a predetermined interval in the vertical direction, and a plurality of upper right floors fixed to the right wall W22 of the existing right building SB1. A left column 341a, a plurality of right upper layer right pillars 341b having a lower end coupled to an upper surface of the right middle layer right vertical beam 332b at regular intervals in a vertical direction, and an upper end of the right upper layer left column 341a Coupled to the upper right upper left vertical robot (342a) and fixed to the upper right wall (W22) of the existing right building (SB1), the upper right upper vertical vertical beam (342b) coupled to the upper end of the right upper pillar (341b), and vertical And a plurality of upper right floor robos 343 connecting the upper right floor left robo 342a and the right upper floor right robo 342b at a predetermined interval in a direction.

The right base left column 311a, right base right column 311b, right lower left column 321a, right lower right column 321b, right middle left column 331a, right middle right column 331b, right The upper left column 341a, the upper right column 341b, the right base girder 313, the lower right girder 323, the right middle girder 333, and the right upper girder 343 are the existing left buildings (SB1). ) And the number of installations can be varied corresponding to the vertical width of the existing right building (SB2). In the illustrated example, only one of the front and rear ends is shown for convenience.

The right base left column 311a, right base right column 311b, right base left vertical robot 312a, right base right vertical robot 312b, right base horizontal robot 313, and right lower left column 321a, Right lower floor right column 321b, right lower floor left longitudinal robo 322a, right lower floor right side robo 322b, right lower floor right robo 323, right middle left column 331a, right middle right column 331b, right middle floor Left side vertical robo (332a), right middle layer right robo (332b), right middle layer robo (333), right upper left column (341a), right upper left column (341b), right upper left vertical robo (342a), right upper right vertical robo 342b, the upper right side giraffe 343 is composed of a conventional H-shaped steel having a web and a pair of flanges.

Upper and lower engaging pieces 311c and 311e and lower engaging pieces 311d and 311f are welded and fixed to upper and lower ends of the right base left column 311a and the right base right column 311b, and the right lower layer left column 321a and The upper and lower ends of the right lower layer right column 321b are welded and fixed to the upper engaging pieces 321c and 321e and the lower engaging pieces 321d and 321f, and the upper and lower ends of the right middle left column 331a and the right middle layer right column 331b. The upper coupling pieces 331c and 331e and the lower coupling pieces 331d and 331f are welded and fixed, and upper and lower coupling pieces 341c and 341e at the upper and lower ends of the right upper left column 341a and the right upper right column 341b. And the lower coupling pieces 341d and 341f are welded and fixed.

The upper coupling piece and the lower coupling piece are formed in an elongated rectangle in the transverse direction.

The right foundation left column 311a and the right foundation right pillar 311b can be fixed only by embedding in the right foundation part F31, but are embedded together in the left foundation part F31 by welding a plurality of rebars or steel bars. By doing so, it can be fixed more firmly.

The right lower left column 321a, the right middle left column 331a, and the right upper left column 341a are a high strength polymer mortar 324, 334, between the web and the flange and the right wall W22 of the existing right building (SB1). 344 can be fixed to the right wall W22 of the existing right building SB1.

In addition, the lower right column left 321a, the right middle left column 331a, the right upper left column 341a penetrates the anchor bolts embedded in the right wall W22 of the existing right building SB1 through the web and tightens the nut. It can also be fixed to the right wall (W22) of the existing right building (SB1).

In addition, the right lower left column 321a, the right middle left column 331a, and the right upper left column 341a may be double fixed by the high-strength polymer mortar and the anchor bolt / nut.

The right basic left vertical robot 312a, the right lower left vertical robot 322a, the right middle left vertical robot 332a, and the right upper left vertical robot 342a are anchor bolts projected to the right wall W22 of the existing right building SB1. It can be fixed to the right wall (W22) of the existing right building (SB1) by passing through the web and fastening the nut.

At this time, the web and the flange of the right basic left vertical robot (312a), the right lower left vertical robot (322a), the right middle left vertical robot (332a), the right upper left vertical robot (342a), and the right wall (W22) of the existing right building (SB1). By filling the high-strength polymer mortar (315, 325, 335, 345) in between to secure the double with the anchor bolt / nut can be made to secure the fixed to the right wall (W22) of the existing right building (SB1). .

The right base left vertical crossbeam 312a seats the lower flange on the upper engaging piece 311c of the right basic left pillar 311a, and passes the bolt through the lower flange and the upper engaging piece 311c to fasten the nut. It can be coupled to the upper end of the right base left column (311a), the right base right vertical beam 312b is seated on the upper coupling piece (311e) of the right base right column (311b), and the lower flange and The right foundation right pillar 311b may be coupled to the upper end by fastening the nut through the upper coupling piece 311e.

The lower right lower left column 321a seats the lower engaging piece 321d on the upper flange of the right basic left longitudinal robot 312a, and fastens the nut by passing a bolt through the upper flange and the lower engaging piece 321d. It can be coupled to the upper surface of the right basic left longitudinal robot (312a), the right lower layer right column (321b) seats the lower coupling piece (321f) on the upper flange of the right basic right longitudinal robot (312b), and the upper flange and It can be coupled to the upper surface of the right basic right side vertical beam 312b by fastening the nut through the lower coupling piece 321f.

The lower right lower left vertical robot 322a seats the lower flange on the upper engaging piece 321c of the lower right lower left column 321a, and passes the bolt through the lower flange and the upper engaging piece 321c to fasten the nut. It can be coupled to the upper end of the lower right floor left column (321a), the right lower floor right vertical beam (322b) is seated on the upper coupling piece (321e) of the lower right floor right column (321b), and the lower flange and It can be coupled to the upper end of the lower right side pillar 321b by fastening the nut through the upper coupling piece 321e.

The right mezzanine left column 331a seats the lower engaging piece 331d on the upper flange of the lower right lower left vertical beam 322a, and passes the bolt through the upper flange and the lower engaging piece 331d to fasten the nut. It can be coupled to the upper surface of the lower right lower left vertical robo (322a), the right middle layer right column (331b) is the lower engaging right side robo (322b) is seated on the upper flange, the upper right flange, It is possible to couple to the upper surface of the right lower layer right vertical beam 322b by fastening the nut through the lower coupling piece 331f.

The right middle left vertical robo 332a seats the lower flange on the upper coupling piece 331c of the right middle left column 331a, and fastens the nut by passing a bolt through the lower flange and the upper coupling piece 331c. It can be coupled to the upper end of the right mezzanine left column 331a, the right mezzanine right vertical robo 332b seats the lower flange on the upper coupling piece 331e of the right mezzanine right column 331b, and It can be coupled to the upper end of the right middle layer right pillar 331b by fastening the nut through the upper coupling piece 331e.

The upper right column left column 341a seats the upper coupling piece 331d on the upper flange of the right middle left longitudinal robo 332a, and fastens the nut by passing a bolt through the upper flange and the upper coupling piece 331d. It can be coupled to the upper surface of the right middle layer left vertical robo 332a, the right upper layer right column 341b seats the upper coupling piece 341e on the upper flange of the right middle layer right longitudinal robo 332b, and the upper flange and The upper coupling piece 331e may be coupled to the upper surface of the right middle layer right vertical beam 332b by fastening a nut.

The upper right upper left vertical robot 342a seats the lower flange on the upper engaging piece 341c of the upper upper left column 341a, and passes the bolt through the lower flange and the upper engaging piece 341c to fasten the nut. It can be coupled to the upper end of the right upper left column (341a), the right upper right side vertical beam (342b) is seated on the upper coupling piece (341e) of the upper right upper pillar (341b), and the lower flange The upper coupling piece 341e can be coupled to the upper end of the upper right pillar 341b by fastening a nut.

The upper right floor giraffe 343 is inserted between the upper end piece 341c of the upper right column left column 341a and the coupling piece 341g welded to the upper surface of the right upper left column 342a, and the lower flange. And the nut by fastening the nut through the upper coupling piece 341c and fastening the nut by passing the bolt through the upper flange and the coupling piece 341g, and the right end of the upper coupling piece of the upper right column 341b ( 341e) and a coupling piece 341h welded and fixed to the upper surface of the right upper layer right vertical beam 342b, and through a bolt through the lower flange and the upper coupling piece 341e to fasten the nut and to engage with the upper flange. The upper right upper left vertical robo 342a and the upper right upper vertical robo 342b are connected to each other by passing the bolt through the piece 341g, and the upper right upper column 341a and the upper right upper pillar 341b. Can be combined.

The central basic girder 113, the central lower tier robo 123, the central middle tier robo 133, the central upper tier robo 143, the left basic girder 213, the left lower tier robo 223, the left middle tier robo 233 ), The upper left side robo 243, the right base side robo 313, the lower right side girder 323, the right middle side robo 333, the upper right side robo 343, both ends of the closing plate (113a, 123a, 133a, 134a) , 213a, 223a, 233a, 234a, 313a, 323a, 333a, and 343a can be attached by welding.

On the other hand, since the central lower floor reinforcement unit 120, the lower floor reinforcement part 220 and the right lower floor reinforcement part 320 is located on the parking spaces (P11, P21, P31), the front and rear surfaces are opened for access of the vehicle. It should be installed in the state, but the middle layer reinforcement unit 130 and the center upper layer reinforcement unit 140, the left middle layer reinforcement unit 230 and the upper left layer reinforcement unit 240, the right middle layer reinforcement unit 330 and the upper right layer reinforcement unit 340 is installed at a height irrelevant to the entrance and exit of the vehicle may utilize the internal space as a storage space.

To this end, the central middle reinforcement unit 130 and the central upper layer reinforcement unit 140, the left middle layer reinforcement unit 230, the left upper layer reinforcement unit 240, the right middle layer reinforcement unit 330, and the upper right layer reinforcement unit 340. The bottom panel (136, 146, 236, 246, 336, 346) attached to the bottom, the front panel (137, 147, 237, 247, 337, 347) and the rear panel (138, 148, 238) attached to the front , 248, 338, 348).

The bottom panels 136, 146, 236, 246, 336, and 346 may include a lower middle left vertical robot 122a, a lower middle right vertical robot 122b, a lower middle horizontal robo 123, and a middle middle left vertical robot 132a. Middle right vertical robo (132b), the middle middle floor robo (133), the middle upper left vertical robo (142a), the middle upper left vertical bot (142b), the middle upper floor robo (143), the lower left left vertical robo (222a), the lower left floor Right vertical robo (222b), left lower floor robo (223), left middle left vertical robo (232a), middle middle right vertical robo (132b), middle middle floor robo (133), left upper left vertical robo (242a), left upper left vertical robo 242b, the upper middle floor robo 143, the lower right left vertical robo 322a, the lower right right lateral robo 322b, the lower right lower lateral robo 323, the right middle left lateral robo 332a, the right middle left lateral robo 332b ), And may be attached to the upper surface of the right middle floor robo 333, the upper right floor left robo 342a, the right upper floor right robo 342b, and the right upper floor robo 343.

The bottom panels 136, 146, 236, 246, 336, and 346 have a central middle left column 131a, a middle middle right column 131b, a left middle left column 231a, and a left middle right column 231b. The cutouts corresponding to the right middle left column 331a and the right middle right column 331b may be formed.

The front panels 137, 147, 237, 247, 337, and 347 have a central middle left column 131a, a central middle right column 131b, a central middle girder 133, and a central upper left column ( 141a), the center upper right column 141b, the center upper floor robo 143, the left middle left column 231a, the left middle right column 231b, the left middle floor robo 233, and the left upper left column 241a. , The left middle right column 241b, the left upper layer robo 243, the right middle left column 331a, the right middle right column 331b, the right middle layer robo 333, and the right upper left column 341a, right It can be attached to the front surface of the upper right pillar 341b and the upper right girder 343.

The rear panels 138, 148, 238, 248, 338, and 348 have a central middle left column 131a, a middle middle right column 131b, a central middle girder 133, and a central upper left column ( 141a), the center upper right column 141b, the center upper floor robo 143, the left middle left column 231a, the left middle right column 231b, the left middle floor robo 233, and the left upper left column 241a. , The left middle right column 241b, the left upper layer robo 243, the right middle left column 331a, the right middle right column 331b, the right middle layer robo 333, and the right upper left column 341a, right The upper right pillar 341b and the right upper layer gabor 343 may be attached to the rear.

In addition, left panels 239 and 249 are attached to the left side of the left middle reinforcement part 230 and the left upper left side reinforcement part 240, and the right side and the right upper part reinforcement part 340 of the right middle reinforcement part 330. The right side panels 339 and 349 are attached to the right side.

The left panel 239 is attached to the left surface of the left middle left column 231a and the left middle left vertical robo 232a, and the left panel 249 is formed of the left upper left column 241a and the left upper left vertical beam 242a. It is attached to the left side, the right panel 339 is attached to the right side of the right middle layer right column 331b and the right middle layer right vertical robo 332b, and the left panel 349 is the right upper layer right column 341b and the upper right layer It is attached to the right side of the stringer 342b.

In addition, a ceiling panel 250 is attached to an upper end of the left upper reinforcement part 240, and a ceiling panel 350 is attached to an upper end of the right upper reinforcement part 340.

The ceiling panel 250 is attached to an upper surface of a left upper left vertical robo 242a, a left upper right vertical robo 242b, and a left upper floor robo 243, and the ceiling panel 350 is connected to a right upper left vertical robo 342a. It is attached to the upper surface of the right upper layer right robo 342b and the right upper layer robo 343.

In addition, the central roof reinforcement unit 150 may utilize its internal space as a storage space.

Accordingly, the central roof reinforcement part 150 includes a bottom panel 156 attached to the bottom, a front panel 157 attached to the front side, a rear panel 158 attached to the rear side, and a left side panel attached to the left side. 159, a right side panel 160 attached to the right side, and a ceiling panel 161 may be included.

The bottom panel 156 may be attached to an upper surface of the central upper left vertical beam 142a and the central upper right vertical part 142b, and the front panel 157 may have a rooftop left pillar 151a and a rooftop right side. The pillar 151b may be attached to the front of the rooftop robo 153, and the rear panel 158 may be attached to the rear of the rooftop left pillar 151a, the rooftop right pillar 151b, and the rooftop robo 153 located at the rear. I can attach it.

The bottom panels 136, 146, 156, 236, 246, 336, 346, and front panels 137, 147, 157, 237, 247, 337, and 347. The rear panels 138, 148, 158, 238, 248, 338, and 348, the left panel 159, the right panel 160, and the ceiling panel 161 are provided with insulation, elasticity, and The conventional sandwich panel which superposed the intrinsic filler can be used.

In addition, the bottom panel (136, 146, 156, 236, 246, 336, 346), the front panel (137, 147, 157, 237, 247, 337, 347). The rear panels 138, 148, 158, 238, 248, 338, and 348, the left panel 159, the right panel 160, and the ceiling panel 161 can be directly attached to each column and beam by screws. Since it can be attached using a bracket (not shown) fixed by welding or screwing to each column and beam, detailed illustration and description thereof will be omitted.

In addition, the door panel and the door panel 159 and the right panel 160 of the central roof reinforcement unit 150 are provided with an entrance and a door, and the bottom panel 156 of the central upper layer reinforcement unit 140 and the central roof reinforcement unit 150. Install the connecting hole and the door to connect the inside, and install the ladder inside the central upper reinforcement unit 140 to move between the inner space of the central roof reinforcement unit 150 and the inner space of the central upper reinforcement unit 140 It is configured to allow, and the bottom panel 146 of the central upper reinforcement unit 140 is installed through the connection hole and the door that can communicate with the internal space of the central middle reinforcement unit 130 and inside the central layer reinforcement unit 130 By installing a ladder may be configured to move between the internal space of the central upper reinforcement unit 140 and the internal space of the central middle reinforcement unit 130.

Doors and doors are installed on the front panels 236, 246, 336, and 346 of the left middle reinforcement part 230, the left upper reinforcement part 240, the right middle reinforcement part 330, and the right upper reinforcement part 340. And, it can be configured to enter and exit the interior space by using an external ladder.

The middle layer reinforcement unit 130, the center upper layer reinforcement unit 140, the central roof reinforcement unit 150, the left middle layer reinforcement unit 230, the upper left layer reinforcement unit 240, the right layer reinforcement unit 330, right The internal space of the upper reinforcement unit 340 may allow the manager of the existing left building (SB1) and the existing right building (SB2) to store and manage common equipment or common materials.

As described above, the existing left building (SB1) and the existing right building (SB2) are connected and reinforced by the central reinforcing means 100 and are separately reinforced by the left and right reinforcing parts 200 and 300. Seismic reinforcement of existing buildings adjacent to two buildings can be more effectively performed.

In addition, the central reinforcement means 100, the left reinforcement portion 200 and the right side reinforcement portion 300, the central basic left pillar (111a), the central basic right pillar (111b), the central basic left longitudinal crossbeam (112a), the central foundation Right vertical beam 112b, center lower left column 121a, center lower layer right column 121b, center lower layer left vertical beam 122a, center lower layer right vertical beam 122b, center middle left column 131a, center middle right column 131b, the center middle left vertical robo 132a, the center upper left column 141a, the center upper right column 141b, the middle middle right vertical section 132b, the center upper left vertical robo 142a, and the middle upper right vertical section 142b and the like are fixed by anchor bolts / nuts with respect to the existing left building (SB1) and the existing right building (SB2), and are also fixed by high-strength polymer mortar so that the seismic reinforcement effect is increased.

In addition, according to the installation of the central reinforcing means 100, the left reinforcing part 200 and the right reinforcing part 300, the central middle reinforcement portion 130, the central upper reinforcement portion 140, the central roof reinforcement portion 150, The internal spaces formed in the left middle reinforcement part 230, the left upper reinforcement part 240, the right middle reinforcement part 330, and the right upper reinforcement part 340 can be managed by storing common supplies or common materials. As it can be used as a storage space, a space expansion effect can be obtained.

In addition, after the construction is completed, the bottom of the central parking space (P11), the left parking space (P21) and the right parking space (P31) is finished by pavement (FV1, FV2, FV3) by the central foundation left side robot 112a, the center The basic right side crossbeam 112b, the center basic crossbeam 113, the left basic left crossbeam 212a, the left basic right crossbeam 212b, the right basic left crossbeam 312a, and the right basic right crossbeam 312b are not exposed. Do not.

The embodiments described above are not intended to limit the technical spirit and scope of the present invention but to describe the scope of the present invention by the above-described embodiments, which are not intended to limit the scope of the present invention. Those skilled in the art will be able to various modifications and variations without departing from the spirit and scope of the present invention, these modifications and variations will be construed as belonging to the scope of the invention.

SB1: Existing left building SB2: Existing left building
W11, W21: left wall W12, W22: right wall
P11: center parking space P21: left parking space
P31: Right parking space 100: Central reinforcement means
110: center basic reinforcement unit 120: central lower layer reinforcement unit
130: central middle reinforcement unit 140: central upper layer reinforcement unit
150: central roof reinforcement part 200: left reinforcement part
210: left base reinforcement unit 220: left lower layer reinforcement unit
230: left layer reinforcement unit 240: left upper layer reinforcement unit
300: right reinforcement unit 310: right base reinforcement unit
320: lower right layer reinforcement unit 330: right middle layer reinforcement unit
340: upper right reinforcement part

Claims (1)

Existing left building with existing left foundation (FD1), left wall (W11) and right wall (W12), lower floor slab (S11), middle floor slab (S12), upper floor slab (S13) and rooftop slab (S14) SB1); Existing right building (FD2), left wall (W21) and right wall (W22), lower floor slab (S21), middle floor slab (S22), upper floor slab (S23) and rooftop slab (S24) SB2); A central parking lot (P11) formed between the existing left building (SB1) and the existing right building (SB2); A left parking lot P21 formed on the left side of the existing left building SB1; In the seismic reinforcement structure using a high-strength polymer mortar and steel structure to seismic-reinforce the existing building, including; a right parking lot (P22) formed on the right side of the existing right building (SB2),
A central reinforcing part 100 installed between the existing left building SB1 and the existing right building SB2; A left reinforcement part 200 installed on the left side of the existing left building SB1; And a right reinforcing part 300 installed on the right side of the existing right building SB2.
The central reinforcement part 100 includes a central basic reinforcement part 110, a central lower reinforcement part 120, a central middle reinforcement part 130, a central upper reinforcement part 140, and a central roof reinforcement part 150. ,
The central foundation reinforcement unit 110 is formed of a reinforced concrete structure that excavates the ground between the existing left foundation (FD1) and the existing right foundation (FD2) and is placed in the ground so that the existing left foundation (FD1) and existing The central foundation portion F11 connected to the right foundation portion FD2, the plurality of central foundation left pillars 111a fixed to the central foundation portion F11 at regular intervals in the longitudinal direction, and in the longitudinal direction. A plurality of central foundation right pillars 111b fixed to the central foundation part F11 at regular intervals and coupled to the upper ends of the central foundation left pillars 111a and the right wall W12 of the existing left building SB1. ) Is coupled to a plurality of central foundation left side robot 112a fixed by anchor bolt / nut fastening and filling of high strength polymer mortar, and coupled to the upper end of the central foundation right pillar 111b and the left wall of the existing right building SB2. Anchor bolt / nut tightening to (W21) And a plurality of centers connecting the central basic left longitudinal robot 112b and the central basic right longitudinal robot 112b at regular intervals in the longitudinal direction to be fixed by the filling of the high strength polymer mortar. Including the base crossbeam 113,
The lower middle reinforcement part 120 is coupled to the bottom of the central foundation left vertical beam 112a at a predetermined interval in the vertical direction, and the anchor bolt / nut fastening to the right wall (W12) of the existing left building (SB1) The lower left side wall of the existing lower building (SB2) is coupled to the lower end of the central lower left column (121a) fixed by the filling of high-strength polymer mortar and the upper surface of the central basic right longitudinal crossbeam (112b) at regular intervals in the longitudinal direction ( W21) is coupled to the upper middle pillar 120b fixed by the anchor bolt / nut fastening and the filling of high-strength polymer mortar, and the upper wall of the existing left building (SB1) and coupled to the upper end of the lower pillar (121a) W12) is coupled to the upper center lower left vertical robot 122a fixed by anchor bolt / nut fastening and high-strength polymer mortar filling, and the upper right side of the lower middle middle pillar 121b, and the left side of the existing right building SB2. The central lower layer right vertical robot 122b fixed to the wall W21 by anchor bolt / nut fastening and the filling of high-strength polymer mortar, and the central lower layer left vertical robot 122a and the central lower layer right vertical beam at regular intervals in the vertical direction ( It comprises a plurality of central lower floor girder 123 connecting 122b),
The central stratified reinforcement unit 130 is coupled to the upper surface of the central lower left vertical beam 122a at a predetermined interval in the vertical direction, and anchor bolt / nut fastening and high strength polymer to the right wall W12 of the existing left building SB1. A plurality of central mezzanine left pillars 131a fixed by the filling of mortar and the upper wall of the central lower layer right vertical crossbeam 122b at a predetermined interval in a clockwise direction, and the left wall W21 of the existing right building SB2. It is coupled to a plurality of central middle layer right pillar (131b) fixed by anchor bolt / nut fastening and the filling of high-strength polymer mortar, and the upper wall of the existing left building (SB1) and coupled to the upper end of the middle layer left column (131a) W12) is coupled to the top of the middle-middle left side vertical beam (132a), which is fixed by anchor bolt / nut fastening and the filling of high-strength polymer mortar, and coupled to the upper end of the middle-middle right column (131b) and the existing right building (SB2) A central middle right vertical robot 132b fixed to the left wall W21 by fastening anchor bolts / nuts and filling with high-strength polymer mortar, and the central lower left vertical robot 122a and the central lower right vertical robot at regular intervals in a vertical direction ( 122b) includes a plurality of central strata crossbeam 133,
The upper middle reinforcement portion 140 is coupled to the upper surface of the central middle left longitudinal beam 132a at a predetermined interval in the longitudinal direction, and anchor bolt / nut fastening and high-strength polymer to the right wall (W12) of the existing left building (SB1) A plurality of central upper left pillars 141a fixed by the filling of mortar and the upper wall of the central middle right vertical beam 132b at regular intervals in the vertical direction, and the left wall W21 of the existing right building SB2. A plurality of central upper right pillars 141b fixed by anchor bolt / nut fastening and high-strength polymer mortar filling, and coupled to an upper end of the central upper left pillar 141a and the right wall of the existing left building SB1 ( W12) is coupled to the top of the central upper left vertical robo (142a) fixed by the anchor bolt / nut fastening and the filling of high-strength polymer mortar, and the existing right building (SB2) A central upper right vertical portion 142b fixed to the left wall W21 by fastening anchor bolts / nuts and filling of high strength polymer mortar, and the central upper left vertical robo 142a and the central upper right vertically spaced at regular intervals. It includes a plurality of central upper floor robo 143 for connecting the portion (142b),
The central rooftop reinforcement part 150 has a plurality of rooftop left pillars 151a coupled to a lower end on an upper surface of the central upper left vertical beam 142a at a predetermined interval in the vertical direction, and at a predetermined interval in the vertical direction. A plurality of rooftop right pillars 151b having a lower end fixed to an upper surface of an upper right vertical part 142b, a rooftop left vertical beam 152a coupled to an upper end of the rooftop left pillar 151a, and the rooftop right pillar 151b. Rooftop right side robo (152b) coupled to the upper end of the; and a plurality of rooftop robo (153) for connecting the rooftop left side robo (152a) and the rooftop right side helical (152b) at regular intervals in the vertical direction,
The left reinforcement part 200 includes a left basic reinforcement part 210, a lower left reinforcement part 220, a left middle reinforcement part 230, and a left upper reinforcement part 240.
The left foundation reinforcement portion 210 is formed of a reinforced concrete structure that excavates the left ground of the existing left foundation portion (FD1) and is placed in the ground and left foundation portion (F21) connected to the existing left foundation portion (FD1) and A plurality of left foundation pillars 211a buried in the left base portion F21 at regular intervals in the longitudinal direction, and a plurality of left foundation pillars 211a buried in the left foundation portion F21 at regular intervals in the longitudinal direction; The left foundation right column 211b, the left base left vertical crossbeam 212a coupled to the top of the left base left column 211a, and the left base building pillar 211b, and the existing left building (SB1) The left basic right vertical robot (212b) fixed to the left wall (W11) by the anchor bolt / nut fastening and the filling of high-strength polymer mortar, and the left basic left vertical robot (212a) and the left basic right at regular intervals in the vertical direction Stringer 212b It includes a plurality of left foundation girbo 213 to connect,
The lower left layer reinforcing part 220 has a plurality of lower left column left pillars 221a coupled to a lower end on an upper surface of the left basic left vertical beam 212a at a predetermined interval in the vertical direction, and at a predetermined distance in the vertical direction. A plurality of lower left pillars coupled to the upper surface of the left basic right longitudinal robot 212b and fixed by anchor bolt / nut fastening to the left wall W11 of the existing left building SB1 and filling of high-strength polymer mortar (221b). ), The left lower floor left vertical beam 222a coupled to the upper left lower left column 221a, and the upper left side of the left lower floor right pillar 221b, as well as the left wall W11 of the existing left building SB1. The left lower layer right vertical robo (222b) secured by anchor bolt / nut fastening and high-strength polymer mortar filling, and the lower left layer left vertical robo (222a) and the left lower layer right vertical robo (222b) at regular intervals in the longitudinal direction. The bottom includes a plurality of lower left floor robo 223,
The left mezzanine reinforcement unit 230 has a plurality of left mezzanine left columns 231a coupled to a lower end on an upper surface of the left lower left vertical longitudinal beam 222a at a predetermined interval in the vertical direction, and at a predetermined distance in the vertical direction. A plurality of left middle layer right pillars 231b coupled to the upper surface of the left lower layer right side robo 222b and fixed by anchor bolt / nut fastening and high strength polymer mortar filling to the left wall W11 of the existing left building SB1; Anchors on the left side wall (W11) of the existing left building (SB1) and coupled to the left side left side vertical beam (232a) coupled to the upper end of the left middle left column (231a), and the left middle right column (231b). The left middle layer right vertical robo (232b) fixed by bolt / nut fastening and the filling of high strength polymer mortar, and the left middle layer left vertical robo (232a) and the left middle layer right vertical robo (232b) connected at regular intervals in the vertical direction It includes a plurality of left middle floor robo,
The upper left layer reinforcement part 240 has a left upper left column 241a coupled with a lower end to an upper surface of the left middle left vertical longitudinal beam 232a at regular intervals in a vertical direction, and the left middle layer at regular intervals in a vertical direction. A plurality of upper left pillars 241b coupled to the upper surface of the right vertical beam 232b and fixed by anchor bolt / nut fastening and high-strength polymer mortar filling to the left wall W11 of the existing left building SB1. Anchor is coupled to the left upper left vertical robo 242a coupled to the upper end of the left upper left column 241a and the left upper right column 241b and is anchored to the left wall W11 of the existing left building SB1. The upper left right vertical robo 242b fixed by bolt / nut fastening and the filling of high strength polymer mortar, and the upper left right vertical robo 242a and the left upper right vertical robo 242b at regular intervals in the vertical direction are connected. It includes several left upper street robo 243,
The right reinforcement part 300 includes a right base reinforcement part 310, a right lower reinforcement part 320, a right middle reinforcement part 330, and a right upper reinforcement part 340.
The right foundation reinforcement part 310 is formed of a reinforced concrete structure that excavates the right ground of the existing right foundation part (FD2) and is placed in the ground and is connected to the existing right foundation part (FD2). A plurality of right base pillars 311a buried in the right base portion F31 at regular intervals in the longitudinal direction, and a plurality of left base pillars 331a buried in the right base portion F31 at regular intervals in the vertical direction; The right base pillar 311b and the right base pillar 311a are coupled to the upper end and fixed by anchor bolt / nut fastening and high strength polymer mortar to the right wall W22 of the existing right building SB1. The right basic left longitudinal robot 312a, the right basic right vertical beam 311b coupled to the top, and the right basic right vertical beam 312b, and the right basic left longitudinal robot 312a and the right basic right side at regular intervals. Stringer 312b It includes a plurality of right foundation girbo 313 to connect,
The lower right floor reinforcement part 320 is coupled to an anchor bolt / nut on the right side wall W22 of the existing right side building (SB1) as well as the bottom is coupled to the upper surface of the right basic left vertical beam 312a at a predetermined interval in the vertical direction. A plurality of right lower layer left pillars 321a fixed by the filling of high strength polymer mortar, and a plurality of right lower layer right pillars 321b having a lower end coupled to an upper surface of the right basic right vertical beam 312b at a predetermined interval in the vertical direction. ) And the lower right floor left vertical beam 322a coupled to the upper end of the lower right floor left column 321a and fixed by anchor bolt / nut fastening and high-strength polymer mortar filling to the right wall W22 of the existing right building SB1. ), The right lower layer right vertical beam 322b coupled to the upper end of the right lower layer right column 321b, and the right lower layer left vertical beam 322a and the right lower layer right vertical beam 322b at regular intervals in the vertical direction. The defect includes a plurality of lower right horizontal robo 323,
The right middle reinforcement part 330 is coupled with an anchor bolt / nut on the right side wall W22 of the existing right side building (SB1) as well as the bottom is coupled to the upper surface of the right lower left vertical length 322a at a predetermined interval in the longitudinal direction. A plurality of right multilayer left pillars 331a fixed by the filling of high-strength polymer mortar, and a plurality of right multilayer right pillars 331b having a lower end coupled to an upper surface of the right lower layer right vertical beam 322b at regular intervals in the vertical direction. ), And the right middle left column 331a is coupled to the top and the right middle left side vertical beam 332a fixed by anchor bolt / nut fastening and high strength polymer mortar filling to the right wall W22 of the existing right building SB1. ), The right middle right vertical robo 332b coupled to the upper end of the right middle right column 331b, and the right middle left vertical robo 332a and the right middle right vertical robo 332b at regular intervals in the vertical direction. The defect includes a plurality of right-middle gyro 333,
The upper right layer reinforcement part 340 is coupled to the anchor bolt / nut on the right side wall of the existing right building (SB1) and the lower end is coupled to the upper surface of the right middle left vertical length 332a at regular intervals in the longitudinal direction. A plurality of upper right column left pillars 341a fixed by the filling of high-strength polymer mortar, and a plurality of upper right right pillars 341b having a lower end coupled to an upper surface of the right middle layer right vertical beam 332b at regular intervals in the vertical direction. ) And the upper right side left side vertical beam (342a) coupled to the upper end of the upper right side left column (341a) and fixed by anchor bolt / nut fastening and high-strength polymer mortar filling to the right wall (W22) of the existing right building (SB1). ), The upper right upper right vertical beam 342b coupled to the upper end of the upper right upper pillar 341b, and the upper right upper left vertical beam 342a and the upper right upper vertical beam 342b at a predetermined interval in the vertical direction. The defect includes a plurality of upper right floor robo 343,
Since the center lower floor reinforcement part 120, the lower floor reinforcement part 220, and the right lower floor reinforcement part 320 are located on the parking spaces P11, P21, and P31, the front and rear surfaces are opened to access the vehicle. Although it should be installed, the middle layer reinforcement unit 130 and the center upper layer reinforcement unit 140, the left middle layer reinforcement unit 230 and the upper left layer reinforcement unit 240, the right middle layer reinforcement unit 330 and the upper right layer reinforcement unit 340 ) Is a seismic reinforcement structure using high-strength polymer mortar and steel structure, which is installed at a height irrelevant to the entrance and exit of the vehicle.

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