KR101632681B1 - Joint structure of modular system using the plate, Construction method and Modular system thereby - Google Patents

Abstract

The present invention relates to a modular system joining structure using a joining plate, capable of effectively transmitting a lateral load such as a wind load or a seismic load applied to a module by joining a corridor panel with the module, and to a modular system constructing method using the same and a modular system. In the modular system joining structure using the joining plate, the corridor panel is seated on a top surface of an upper horizontal member of a lower module. An upper module is seated on top surfaces of the lower module and the corridor panel. A corridor panel insertion unit is formed in a lateral side coming in contact with the corridor panel of the upper module as a lower horizontal member protrudes from the outer lateral side of the vertical member for a predetermined distance at a position lifted from the bottom of the vertical member as much as the thickness of the corridor panel so that the corridor panel can be inserted into the corridor panel insertion unit. A lower connection unit and an upper connection unit are joined at angles enabling both legs to face outer lateral surfaces of the module between both legs of the upper module in the lower side of the vertical member and between both legs of the lower module in the upper side of the vertical member, respectively. The joining plate is inserted between the corridor panel and the lower connection unit of the upper module, thereby being coupled by a bolt inside a space unit formed inside the corridor panel. The joining plate protrudes from the underside of the corridor panel to a predetermined length, thereby being joined to the upper connection unit of the lower module by a bolt.

Description

Technical Field [0001] The present invention relates to a modular system joining structure using a joining plate, a modular system joining structure using the joining plate, a modular system joining structure using the joining plate,

The present invention relates to a modular system joining structure using joining plates that can effectively transfer a lateral load applied to a module such as a wind load or an earthquake load to a front wall of a core or a ground by joining a corridor panel with a module, will be.

The modular system is a steel structure building system that is completed by assembling the unit module as a unit from the factory to the top, bottom, left and right in the field.

Modular system is widely used due to the fact that most of the processes such as finishing, finishing, and facilities are carried out in factories, which can ensure the quality of the structure and shorten the construction time and reuse of the members after use.

The unit module of the modular system is composed of a vertical member provided at each of four corners, an upper horizontal member and a lower horizontal member connecting the upper end and the lower end of the adjacent vertical member, And the vertical members are connected to each other by bolting.

However, since the structure assembled by the bolt joint as described above is inferior in integrity and vulnerable to lateral force transmission, it is difficult to effectively support the lateral load applied to the module such as wind load or seismic load.

Accordingly, the upper and lower ends of the vertical members of the unit module are retracted from the outer side surfaces of the upper and lower horizontal members to form a horizontal gap, and a connecting shear plate is installed in the horizontal gap to tighten the vertical members of adjacent unit modules to increase rigidity and strength A description has been given of a bonding structure of a unit unit module (Patent No. 10-1031299).

However, since the adjacent unit modules form the pin connection, the above-mentioned patent has a problem that the lateral load can not be effectively supported.

In the conventional modular system, since the unit modules are stacked and the aisle panel is coupled to the side of the unit module, a support is provided on the side of the unit module under the aisle panel to transmit the load of the aisle panel to the lower part. There is a problem that the work of the refractory coating or the like is difficult because the bottom is protruded at the bottom and the appearance is poor.

KR 10-1031299 B1 KR 10-2014-0085719 A

SUMMARY OF THE INVENTION In order to solve the above problems, the present invention provides a modular system joining structure using an engaging plate that can effectively transfer a lateral load applied to a module to a front end wall of a core or a ground, and a modular system construction method and modular system.

According to a preferred embodiment of the present invention, an upper module and a lower module each including a vertical member provided at four corners of the vertical member and an upper horizontal member and a lower horizontal member connecting the upper and lower ends of the vertical member, A modular system joining structure for mutual joining wherein the corridor panel is seated on top of an upper horizontal member of a lower module and the upper module is seated on the lower module and the corridor panel, The side surface is coupled with the lower horizontal member so that the lower horizontal member protrudes from the vertical member at a position spaced upward from the lower end of the vertical member by a thickness of the corrugated panel by a predetermined length than the outer surface of the vertical member so that the corridor panel insertion portion is formed in the lower portion, Wherein the vertical member comprises a pair of legs arranged such that both legs face the outer surface of the module, A lower connection portion and an upper connection portion are respectively coupled between the vertical member lower legs of the upper module and between the upper leg portions of the vertical member of the lower module and a coupling plate is inserted between the corridor panel and the lower connection portion of the upper module, And the coupling plate is protruded to a predetermined length below the corridor panel and coupled with the upper connection part of the lower module with the bolt. Lt; / RTI >

According to another preferred embodiment of the present invention, a plurality of the upper module and the lower module are installed adjacent to each other in the right and left direction, and the lower plate of the adjacent upper module and the upper plate of the lower module are coupled to each other. To provide a modular system bonding structure.

According to another preferred embodiment of the present invention, the lower connection part of the upper module and the upper connection part of the lower module vertically penetrate through the bolts, and are mutually coupled to each other.

According to another preferred embodiment of the present invention, the coupling plate is a T-shape having an upper flange integrally formed at an upper end thereof, and the upper flange is bolted to an upper surface of the corridor panel and an upper portion of a lower connection portion of the upper module, Plate to provide a modular system bonding structure.

According to another preferred embodiment of the present invention, the upper flange on the upper module side of the coupling plate, the lower connection portion of the upper module, and the upper connection portion of the lower module vertically penetrate each other, System bonding structure.

According to another preferred embodiment of the present invention, the lower supporting member is further provided on the lower part of the lower horizontal member between the vertical members in the upper module, and the lower supporting member is provided so that the outer side thereof coincides with the outer end of the vertical member To provide a modular system bonding structure.

According to another preferred embodiment of the present invention, a plurality of vertical studs are spaced apart from each other between the upper horizontal member and the lower horizontal member, and a bracing member is further coupled to both side surfaces perpendicular to the surface to which the corridor panel is joined A modular system bonding structure using a coupling plate is provided.

According to another aspect of the present invention, there is provided a modular system construction method using a joining structure of a modular system using the coupling plate, comprising the steps of: (a) installing a lower module; (b) seating one end of the corridor panel on the upper surface of the upper horizontal member of the lower module; (c) installing an upper module on top of the lower module so that one end of the hallway panel is housed in the corridor panel insert; (d) inserting a coupling plate between the corridor panel and the lower connection of the upper module; And (e) bolting the corridor panel, the lower connection of the upper module, the upper connection of the lower module and the coupling plate; The method comprising the steps of:

According to another preferred embodiment of the present invention, there is provided a modular system using a joining structure of a modular system using the joining plate, comprising: a core front wall of a building; The corridor panel being fixedly coupled to one side of the core front end wall; And the upper module and the lower module fixedly coupled to one side of the corridor panel; The present invention provides a modular system.

The present invention has the following effects.

First, a coupling plate is installed between the corridor panel inserted in the corridor panel insertion portion of the upper module and the lower connection portion of the upper module, then bolts are fastened to pass through the lower connection portion of the corridor panel, the coupling plate and the upper module, And the bolt is fastened to penetrate the upper connection portion of the lower module, the corridor panel can be strongly bonded to the module.

Therefore, the lateral load applied to the module such as wind load or seismic load in the building can be effectively transmitted to the core shear wall or the ground through the corridor panel.

Second, since the corridor panel is mounted on the upper horizontal member of the lower module, it is easy to construct the module with the corridor panel.

Third, when the lower connection portion of the upper module and the upper connection portion of the lower module are connected through the elongated bolts, the coupling plate may be coupled to the upper module and the lower module from the front side,

Fourth, in the case of using a T-shaped coupling plate having an upper flange formed at its upper end, the upper flange is additionally fastened to the hallway panel and the upper module, so that the coupling can be firmly fixed and the position of the coupling plate can be fixed by the upper flange.

Fifth, the present invention is applicable to both a load bearing type modular system and a frame type modular system.

Sixth, since the load of the corridor panel is transmitted through the lower module, there is no need to provide a separate support for supporting the corridor panel under the corridor panel.

1 is a perspective view of a modular system joint structure using an inventive coupling plate;
2 is a perspective view showing an embodiment of a module;
3 is an enlarged view of the portion 'A' in FIG. 2;
Fig. 4 is a perspective view showing a combination of upper and lower modules and a corridor panel. Fig.
5 is a perspective view showing a coupling relationship of two upper and lower modules;
6 is a perspective view showing a coupling relationship of four upper and lower modules;
7 is a perspective view of four upper and lower module connections;
8 is a perspective view showing an embodiment of a coupling plate;
9 is a perspective view of an upper and lower module junction with an auxiliary coupling plate;
10 and 11 are perspective views showing steps of a modular system construction method according to the present invention.
12-14 are schematic diagrams illustrating a lateral load transfer mechanism by the modular system of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings and preferred embodiments.

FIG. 1 is a perspective view of a modular system joint structure using an inventive coupling plate, FIG. 2 is a perspective view illustrating an embodiment of a module, and FIG. 3 is an enlarged view of a portion 'A' of FIG. FIG. 5 is a perspective view showing the coupling relationship between the upper and lower modules, and FIG. 6 is a perspective view showing the coupling relationship of the upper and lower modules.

As shown in FIGS. 1 and 4, the modular system bonding structure using the bonding plate of the present invention includes a vertical member 21 spaced apart from each other at four corners, and an upper and a lower ends of the vertical member 21, The upper module 2a and the lower module 2b, which are composed of an upper horizontal member 22 and a lower horizontal member 23, are connected to the corridor panel 3, respectively.

The upper module 2a and the lower module 2b are connected to each other by a vertical member 21, an upper horizontal member 22 connecting the upper ends of the adjacent vertical members 21, And a lower horizontal member (23).

In the present invention, the upper module 2a and the lower module 2b are bonded to the corridor panel 3 so that the lateral load acting on the module 2 is transmitted to the core front wall 1 of the building via the corridor panel 3 Can be effectively transmitted.

4 to 6, 7 and so on, in the modular system bonding structure using the coupling plate of the present invention, the corridor panel 3 is seated on the upper horizontal member 22 of the lower module 2b The upper module 2a is seated on the lower module 2b and the upper part of the corridor panel 3. The side surface of the upper module 2a contacting with the corridor panel 3 is perpendicular to the vertical A corridor panel insertion portion 24 is formed at a lower portion thereof so as to be protruded from the lower end of the member 21 by a predetermined length longer than the outer surface of the vertical member 21 at a position spaced upward by a thickness of the corridor panel 3, The vertical member 21 is inserted into the vertical member 21 of the upper module 2a as an angle which is arranged such that both legs face the outer side of the module 2, Between the lower two legs and between the upper legs of the vertical member 21 of the lower module 2b, The connecting plate 25 and the upper connecting portion 26 are coupled to each other and the coupling plate 4 is inserted between the hallway panel 3 and the lower connecting portion 25 of the upper module 2a, The coupling plate 4 is protruded to a lower portion of the hall panel 3 by a predetermined length so as to be connected to the upper connecting portion 26 of the lower module 2b and the bolt B B). ≪ / RTI >

The corridor panel 3 is mounted on the upper horizontal member 22 of the lower module 2b and the upper module 2a is inserted into the corridor panel insertion portion 24 of the upper module 2a so that the corridor panel 3 is inserted. So that the corridor panel 3 can be easily installed while being joined to the module 2.

1 and 4, the corrugated panel 3 is constructed by connecting the four corners of the corrugated panel to each other at four corners. However, the corrugated panel 3 is not limited to this, ) Member.

At this time, a part of the part where the corridor panel 3 is joined to the module 2 forms a predetermined empty space without pouring concrete, so that it can be utilized as a work ball when fastening the bolt (B).

The corridor panel insertion section 24 is a space formed below the lower horizontal member 23 of the upper module 2a and the corridor panel 3 is a space formed in the module 2 by the corridor panel insertion section 24, . Thus, the upper horizontal member 22 of the lower module 2b, the end of the corridor panel 3, and the lower horizontal member 23 of the upper module 2a are positioned on the same vertical line so that the upper and lower modules 2a and 2b They can be stacked at the same position.

The vertical load of the upper module 2a is transmitted to the lower module 2b through the corridor panel 3. [

The vertical member 21 is connected to the lower connecting portion 25 and the upper connecting portion 26 between the both legs of the a-shaped steel respectively on the lower portion of the upper module 2a and the upper portion of the lower module 2b.

2, the upper and lower modules 2a and 2b are coupled to the upper and lower connecting portions 26 and 25, respectively, at upper and lower portions of the vertical member 21, respectively.

As shown in the enlarged view of FIG. 3, the lower connecting portion 25 and the upper connecting portion 26 may be hollow hexahedrons having bolt connecting holes formed on the front surface and the upper and lower surfaces.

The upper and lower surfaces of the lower connection portion 25 are preferably aligned with the upper and lower surfaces of the corridor panel 3 for coupling with the T-shaped coupling plate 4 to be described later.

The coupling plate 4 is a member that joins the module 2 and the hallway panel 3 to integrate them. As shown in FIG. 7, which will be described later, the hallway panel 3, the coupling plate 4, And the lower connection part 25 of the side wall 2a can be coupled by a one-side bolt which can be fastened at the front side.

The one-side bolt is a special special bolt developed to be used when joining a closed end member such as a rectangular steel pipe. Therefore, when the one side bolt is used, the bolt can be fastened on the front surface of the corridor panel 3, so that the workability can be improved and the air shortening can be achieved.

Likewise, the upper coupling portion 26 of the coupling plate 4 and the lower module 2b can also be coupled with a front side bolt at the front side.

Therefore, since the module 2 and the corridor panel 3 can be joined by bolt connection, a field welding process is unnecessary.

The modular system bonding structure using the coupling plate of the present invention is usable in both a wall-wise modular system and a frame-wise modular system.

In the case of the load cell type modular system, a bearing wall constituted by the upper horizontal member 22, the lower horizontal member 23 and the vertical stud 28 coupled between the upper and lower horizontal members 22 and 23 is disposed inside the lower support member 27 The module 2 is formed by connecting the bottom member composed of the concrete to be poured and the vertical member 21, and the load is resisted by the bearing wall.

In the case of the frame modular system, the beams and pillars of the module (2) can be made of a relatively thick hot-rolled steel having a high rigidity and resist the load by the frame behavior of the beam and the column.

The modular system bonding structure using the coupling plate of the present invention can be applied to the coupling of one upper module 2a and one lower module 2b as shown in FIG. 5, 2a and the two lower modules 2b.

That is, a plurality of the upper module 2a and the lower module 2b are installed adjacent to each other, and the coupling plate 4 is connected to the lower connection portion 25 of the adjacent upper module 2a and the lower module 2b May be configured to be coupled to each other.

Therefore, the coupling plate 4 joins the four modules 2 and the hallway panel 3 in the upper, lower, left, and right directions.

The lower connecting part 25 of the upper module 2a and the upper connecting part 26 of the lower module 2b may vertically penetrate the long bolt LB and may be coupled to each other.

This allows the coupling plate 4 to vertically couple the upper module 2a and the lower module 2b in addition to coupling the upper module 2a and the lower module 2b from the front, 2 can be more firmly coupled.

As shown in FIGS. 3, 5, 6, and the like, a lower support member 27 is further provided below the lower horizontal member 23 between the vertical members 21 in the upper module 2a, 27 may be provided so that the outer surface thereof coincides with the outer end of the vertical member 21.

The lower support member 27 supports the load of the lower horizontal member 23 and may be filled with concrete or the like inside the lower support member 27 to form a bottom member of each module 2. [

The bottom member serves as a diaphragm.

1 to 3, a plurality of vertical studs 28 are spaced apart from each other between the upper horizontal member 22 and the lower horizontal member 23, and the corrugated panel 3 is joined A bracing member 29 may be further coupled to both sides of the side wall 20 perpendicular to the plane.

The vertical stud 28 and the bracing member 29 are configured to form a load-bearing modular system, so that the load bearing wall transfers the lateral load acting on the building. That is, the lateral load is transmitted in the order of module 2 → corridor panel 3 → core front wall 1.

Here, the vertical member 21 connects the load bearing wall composed of the upper horizontal member 22, the lower horizontal member 23, the vertical stud 28 and the bracing member 29 to the adjacent load bearing wall.

FIG. 7 is a perspective view of four upper and lower module joints, FIG. 8 is a perspective view showing an embodiment of a coupling plate, and FIG. 9 is a perspective view of an upper and lower module joint with an auxiliary coupling plate.

7 and 8, the coupling plate 4 is a T-shape having an upper flange 41 integrally formed at an upper end thereof. The upper flange 41 is connected to the upper surface of the corridor panel 3, 2a by a bolt (B) on the lower connecting portion (25).

Therefore, the corridor panel 3, the coupling plate 4, and the lower connection portion 25 of the upper module 2a are bolted together and the coupling plate 4 and the upper connection portion 26 of the lower module 2b are bolted together In addition, since both sides of the upper flange 41 are fastened to the corridor panel 3 and the upper module 2a, more rigid coupling is possible.

Since the upper flange 41 is caught on the lower connecting portion 25 of the corridor panel 3 and the upper module 2a on both sides, the upper flange 41 can also fix the position of the coupling plate 4.

7 and 9, the upper flange 41 of the upper module 2a, the lower connection portion 25 of the upper module 2a, and the upper connection portion 26 of the lower module 2b of the coupling plate 4 May vertically penetrate the long bolt (LB) and be coupled to each other.

Thereby, the upper flange 41 of the coupling plate 4 can be coupled with the lower module 2b at the same time as the upper module 2a, so that the coupling can be made more robust.

9, when the upper, lower, right, and left four modules 2 are coupled at one point, the auxiliary coupling plate 6 is coupled to the lower connection part 26 of the lower module 2b, 4 by the upper flange 41 and the left and right modules 2 by the auxiliary coupling plate 6 in the lower part.

FIGS. 10 and 11 are perspective views showing steps of the modular system construction method according to the present invention.

10 and 11, a modular system construction method using a joining structure of a modular system using the joining plate of the present invention will be described.

In the modular system construction method of the present invention, (a) a lower module 2b composed of a vertical member 21 and upper and lower horizontal members 22 and 23 is installed (FIGS. 10 (a) and 10 (b)).

At this time, an upper connection part 26 is coupled to the upper part of the vertical member 21 of the lower module 2b, and a plurality of lower modules 2b are installed adjacent to the left and right when there are a plurality of lower modules 2b.

Next, (b) one end of the corridor panel 3 is seated on the upper surface of the upper horizontal member 22 on one side of the lower module 2b (Fig. 10 (c)).

The corridor panel 3 has an end joined to the upper portion of the upper horizontal member 22 and a frame portion located at one end of the corridor panel 3 as shown in Figure 10 (c) And may be installed on the upper surface of the upper horizontal member 22.

Thereafter, (c) the upper module 2a is installed on the lower module 2b so that one end of the corridor panel 3 is housed in the corridor panel insertion portion 24 (FIG. 10 (d)).

The lower horizontal member 23 of the upper module 2a and the frame located at one end of the corridor panel 3 and the lower module 2b of the lower module 2b are disposed in the corridor panel insertion portion 24, The upper horizontal member 22 is positioned on the same vertical line.

And (d) the coupling plate 4 is inserted between the corridor panel 3 and the lower connecting portion 25 of the upper module 2a (Fig. 11 (a)).

The coupling plate 4 may be a vertical plate or a T-shaped coupling plate 4 shown in FIG.

Finally, (e) Bolt B is joined to the corridor panel 3, the lower connecting portion 25 of the upper module 2a, the upper connecting portion 26 of the lower module 2b, and the engaging plate 4 (B) of FIG.

As described above, in the present invention, the lower module 2b, the corridor panel 3 and the upper module 2a are all installed at predetermined positions and then the coupling plate 4 is installed. Then, the lower module 2b, The corridor panel 3, the coupling plate 4 and the lower connecting portion 25 of the upper module 2a are fastened with the bolts B while the panel 3 and the upper module 2a are being worn, 4 and the upper connecting portion 26 of the lower module 2b with the bolts B. [

As described above, the corridor panel 3 may be formed of a frame and concrete placed inside the frame. At this time, a space 31 may be formed in a part of the inside of the corridor panel 3.

In the step (e), the space portion 31 may be used as a work hole during the bolt fastening operation, and the concrete is poured into the space portion 31 of the corridor panel 3 after the step (e).

12 to 14 are schematic views showing a lateral load transfer mechanism by the modular system of the present invention.

The modular system of the present invention relates to a modular system using a modular system joining structure using the coupling plate as described above, comprising: a core front wall 1 of a building; The corridor panel (3) fixedly coupled to one side of the core front end wall (1); And the upper module (2a) and the lower module (2b) fixedly coupled to one side of the corridor panel (3); . ≪ / RTI >

In FIG. 12, the corridor panel 3 serves as a horizontal diaphragm, and both the short side direction and the long side lateral load are transferred to the core front wall 1.

In particular, the lateral load F1 in the long-side direction is transmitted to the core front wall 1 via the corridor panel 3 connected to the module 2, and the lateral load F2 in the short-side direction is transmitted to the short- Is directly transmitted to the core shear wall (1) through the corridor panel (3) by tensile or compressive forces.

13, the moments may be transmitted directly to the ground through the bracing panel 3 and the bracing member 29 in the walls of a plurality of vertically adjoining modules 2.

When the bending moment transmission performance of the corridor panel 3 is insufficient, the bottom plate of the module 2 adjacent to the core front end wall 1 is formed of the diaphragm 5, It is also possible to transmit the bending moment through the bottom plate of the base 2.

1: core shear wall 2: module
2a: upper module 2b: lower module
21: vertical member 22: upper horizontal member
23: lower horizontal member 24: corridor panel insertion portion
25: lower connection part 26: upper connection part
27: lower support member 28: vertical stud
29: bracing member 3: corridor panel
31: space part 4: engaging plate
41: upper flange 5: diaphragm
6: Auxiliary coupling plate B: Bolt
LB: Long bolt

Claims (9)

An upper module 2a constituted by an upper horizontal member 22 and a lower horizontal member 23 connecting upper and lower ends of the vertical member 21 and a vertical member 21 provided at four corners, And a joining plate for joining the lower module 2b and the corridor panel 3 to each other,
The corridor panel 3 is seated on the upper horizontal member 22 of the lower module 2b and the upper module 2a is seated on the lower module 2b and the corridor panel 3, The side surface of the module 2a contacting the corridor panel 3 is located at a position spaced upward from the lower end of the vertical member 21 by the thickness of the corridor panel 3 The hallway panel 3 is inserted into the hallway panel inserting portion 24 by forming a hallway panel inserting portion 24 at a lower portion so as to protrude to a predetermined length,
The vertical member 21 is an angle between two legs of the vertical member 21 of the upper module 2a and between the lower legs of the lower module 2b, A lower connection portion 25 and an upper connection portion 26 are coupled between the upper and lower legs 21, respectively,
A coupling plate 4 is inserted between the hallway panel 3 and the lower connecting portion 25 of the upper module 2a and is inserted into the space 31 formed in the inside of the hallway panel 3 with bolts B Wherein the coupling plate 4 is protruded to a predetermined length below the corridor panel 3 and is coupled to the upper connecting portion 26 of the lower module 2b with the bolt B. Modular system bonding structure.
The method of claim 1,
A plurality of the upper module 2a and the lower module 2b are installed adjacent to each other on the right and left sides and the coupling plate 4 is connected to the lower connecting portion 25 of the adjacent upper module 2a and the lower connecting portion 25 of the lower module 2b And the upper connection part (26) are coupled to each other.
The method of claim 1,
Wherein the lower connecting portion 25 of the upper module 2a and the upper connecting portion 26 of the lower module 2b vertically penetrate through the elongated bolts LB and are coupled to each other. .
The method of claim 1,
The upper flange 41 is formed on the upper surface of the corridor panel 3 and the lower connecting portion 25 of the upper module 2a, Bolts (B). ≪ RTI ID = 0.0 > A < / RTI >
5. The method of claim 4,
The upper flange 41 of the upper plate 2a of the coupling plate 4, the lower connecting portion 25 of the upper module 2a and the upper connecting portion 26 of the lower module 2b are arranged to vertically align the long bolt LB And the coupling plates are coupled to each other through the through holes.
The method of claim 1,
A lower support member 27 is further provided below the lower horizontal member 23 between the vertical members 21 in the upper module 2a, And an outer end of the coupling plate.
The method of claim 1,
Between the upper horizontal member 22 and the lower horizontal member 23 a plurality of vertical studs 28 are provided so as to be spaced apart from each other and both side surfaces perpendicular to the surface to which the corridor panel 3 is bonded are provided with a bracing member 29 ) Is further coupled to the coupling plate (20).
A modular system joining structure using a joining plate according to any one of claims 1 to 7,
(a) installing a lower module (2b);
(b) placing one end of the corridor panel (3) on the upper surface of the upper horizontal member (22) on one side of the lower module (2b);
(c) installing the upper module (2a) on the lower module (2b) so that one end of the corridor panel (3) is housed in the corridor panel insert (24);
(d) inserting a coupling plate (4) between the corridor panel (3) and the lower connection portion (25) of the upper module (2a); And
(e) bolting the corridor panel 3, the lower connection 25 of the upper module 2a, the upper connection 26 of the lower module 2b and the coupling plate 4; Wherein the modular system construction method comprises the steps of:
A modular system using a modular system joining structure using the joining plate of any one of claims 1 to 7,
A core shear wall 1 of the building; The corridor panel (3) fixedly coupled to one side of the core front end wall (1); And the upper module (2a) and the lower module (2b) fixedly coupled to one side of the corridor panel (3); ≪ / RTI >

Images