KR101194170B1 - Joint structure of modular building and method thereof - Google Patents

Abstract

The present invention provides a joint structure of the modular building and its construction method.
The joining structure of the modular building is connected to the core portion and the outer peripheral surface of the core portion, the connection panel having a truss member connected to the core portion, and is installed to be spaced apart from the core portion, pillars and floor beams and ceiling And a unit module stacked up and down with a beam and connected to the core part through bonding with the connection panel, wherein the connection panel is formed of a bottom panel installed at a height of the bottom beam of the unit module, and the truss The member may be provided as a horizontal truss in which the truss is disposed in the horizontal direction, and the load may be easily transmitted from the unit module to the core through the connection panel to be integrated with external force.
According to the embodiment of the present invention, a modular building is constructed using the core part, and the vertical displacement generated at the joint part between the unit modules stacked up and down by joining the unit module to the core part using the connection panel is minimized. can do. Accordingly, the resistance to the lateral force of the modular building can be increased.

Description

Joint Structure of Modular Building and Construction Method of It {JOINT STRUCTURE OF MODULAR BUILDING AND METHOD THEREOF}

The present invention relates to a joining structure of a modular building and a construction method thereof, and more particularly, to a joining structure and a construction method of the building to increase the resistance to the lateral force.

Modular building refers to a structure made by manufacturing a unit unit module made of box-shaped steel structure in advance and stacking them.

That is, the modular building can be configured by integrally manufacturing the main structural materials, equipment, materials, etc. in the factory, and laminated in the field. In addition, the unit of the modular building completes the building through the bolt coupling between the upper, lower and adjacent modules.

Conventional modular buildings have been used in low-level buildings such as schools and military facilities, but due to the development of high-strength materials and lightweight steel, convenience in construction and shortening of air due to factory production, it is not necessary to introduce modular buildings in high-rise buildings. It is emerging.

However, in the case of high-rise buildings, the lateral force, such as wind load or earthquake load, is the main design object. In the modular building, the unit unit module mainly resists the lateral force, which may cause a problem that the whole building cannot be integrated.

In order to solve such a problem, a method of increasing the stiffness for the lateral force by bolting the floor beam and the ceiling beam facing each other at the boundary of the unit unit module has been used.

However, even when the unit modules are connected to each other using bolt joints as described above, the entire building due to the vertical displacement generated in the bolt joints when the modular buildings (especially high-rise buildings) are subjected to lateral forces such as earthquake load or wind power. There is a problem in that the horizontal displacement of the usability and stability of the building is degraded.

That is, a high-rise building as shown in (a) of FIG. 1 is a case of a modular building in which unit modules 10 are stacked and constructed, as compared with the case of construction by a general construction method (see FIG. 1 (b)). 1 (c) is a problem because the horizontal displacement of the lateral force can be further increased.

The present invention has been proposed in order to solve the conventional problems as described above, the object of the aspect, the joint structure of the modular building to increase the resistance to the lateral force by minimizing the vertical displacement occurring at the junction between the unit modules stacked up and down and its To provide a construction method.

In addition, an object of the present invention is to provide a joint structure of a modular building and a construction method thereof that effectively cope with construction errors and smoothly transmit loads.

The present invention as a technical aspect for achieving the above object, the core portion; And a connection panel coupled to an outer circumferential surface of the core part and having a truss member connected to and connected to the core part. The connection panel is spaced apart from the core part and is stacked up and down with a pillar, a floor beam, and a ceiling beam. And a unit module connected to the core unit through bonding to a connection panel, wherein the connection panel is formed of a bottom panel installed at a height of the bottom beam of the unit module, and the truss member has a truss in a horizontal direction. It is provided with a horizontal truss disposed, and the load is easily transferred from the unit module to the core through the connection panel to provide a bonding structure of a modular building that is integrally acting on the external force.

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Preferably, the connection panel may include a truss connecting member for joining the truss member to the core unit or the unit module.

Preferably, the truss connecting member may be made of a plate member.

Preferably, the truss connecting member may be made of c-shaped steel or L-shaped steel.

Preferably, the connection panel may include a gusset plate welded to the truss connecting member and bonded to the truss member to mount the truss member to the truss connecting member.

Preferably, the connection member is made of a plate member bonded between the connection panel and the core or between the connection panel and the unit module, the bonding member for firmly coupling the connection panel and the core unit or the connection panel and the unit module. It may further include;

Preferably, the bonding member includes a connection plate provided between a unit module installed on the upper and a unit module installed on the lower of the unit modules stacked up and down, the connection plate, so as to support the connection panel from the bottom A protruding portion protruding from the unit module may be provided.

Preferably, the bonding member may include a fastening plate which is bolted between the connection panel and the unit module.

Preferably, the core portion is made of a reinforced concrete structure is provided with at least one horizontal reinforcement bent and embedded in concrete, the joining member, the joining plate is welded to the horizontal reinforcement and include a joining plate bonded to the connection panel Can be.

Preferably, the joining plate may be embedded in the concrete of the core portion.

Preferably, the support unit is bonded to one side of the core unit or the unit module, the support is formed with a bent portion to support the connection panel from the bottom.

On the other hand, the present invention as another aspect, the step of installing the core; And, the lower unit module installation step of installing the lower unit module spaced apart from the core; And, the upper unit module stacked on the lower unit module And connecting and installing a connection panel made of a truss member between the lower unit module and the upper unit module and the core unit so that a load can be easily transferred from the unit module to the core unit. The truss member is provided as a horizontal truss in which the truss is disposed in the horizontal direction, and absorbs construction errors when the core unit and the unit module are connected. Provide construction method of

Preferably, an additional lamination step of additionally stacking the unit module on the upper unit module, and installing a connection panel having a truss member in the spaced space between the further stacked unit module and the core portion; The additional lamination step may be repeated until the top layer unit module is stacked.

According to the bonded structure of the modular building according to the embodiment of the present invention and the construction method thereof, a modular building is constructed using a core part, and a unit is stacked up and down by bonding a unit module to the core part using a connection panel. The vertical displacement occurring at the junction between modules can be minimized. Accordingly, the resistance to the lateral force of the modular building can be increased.

In addition, according to an embodiment of the present invention, by connecting the core unit and the unit module using a connection panel, it provides an advantage that can effectively respond to the construction error compared to the case of directly connecting the unit module to the core unit.

In addition, according to an embodiment of the present invention, the load acting between the connection panel and the core portion or between the connection panel and the unit module can be effectively transmitted through the joining member composed of the plate.

In addition, according to an embodiment of the present invention, by providing a truss member in the connection panel it is possible to effectively transfer the load of the unit module to the core portion.

1 is a view showing the displacement according to the lateral force of a conventional modular building.
2 is a plan view schematically showing a bonding structure of a modular building according to an embodiment of the present invention.
FIG. 3 is a plan view showing details of the portion “A” of FIG. 2.
4 is a vertical cross-sectional view showing details of the "A" part of FIG.
FIG. 5 is a plan view illustrating the detail of a portion “B” of FIG. 2.
FIG. 6 is a vertical sectional view showing details of the "B" part of FIG.
7 is a view showing a construction method of a modular building according to an embodiment of the present invention.

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

First, the embodiments described below are embodiments suitable for understanding the technical features of the bonding structure and the construction method of the present invention modular building. However, the technical features of the present invention are not limited by the embodiments to which the present invention is applied or explained in the following embodiments, and various modifications are possible within the technical scope of the present invention.

Bonding structure 100 of the modular building according to an embodiment of the present invention, as shown in Figures 2 to 7, the core portion 110, the connection panel 130, the unit module 150 It may be configured to include.

The core unit 110 may be formed in a closed planar structure to serve as a shear wall to resist a horizontal load such as a lateral force.

That is, in recent years, especially in high-rise buildings, in addition to the pillars 151 on the outer side of the building, common parts such as elevators and stairs are installed at the center of the building to form cores that functionally connect the upper and lower parts of the building, and the core and each floor. The beams are connected to secure the stiffness and strength of the entire building. The core part 110 is configured to be connected up and down, and is configured in a closed type to resist lateral forces such as wind load or earthquake load acting on the building.

One embodiment of the present invention is based on increasing the rigidity of the lateral force of modular buildings (particularly skyscraper buildings) using such a core structure.

At this time, the configuration of the core portion 110 is not limited, but preferably may be composed of a reinforced concrete structure (RC core) consisting of a reinforcing steel and concrete integrally. In addition, the core part 110 may include a main reinforcing bar disposed in the vertical direction and a horizontal reinforcing bar 111 disposed in the horizontal direction. However, the configuration of the core unit 110 is not limited to the above, and as described below, various modifications are possible as long as the resistance to the lateral force can be increased in a high-rise building.

On the other hand, the connection panel 130 may be provided with a truss member coupled to the outer circumferential surface of the core portion 110 and connected to the core portion 110.

That is, as shown in the embodiment shown in FIG. 2, the connection panel 130 may be attached to a part or all of the outer circumferential surface of the core part 110. In this case, the connection panel 130 may be installed on each floor of the modular building, and may be configured to connect the core unit 110 and the unit module 150 of each floor to be described later.

At this time, preferably, the connection panel 130 is made of a bottom panel installed at the height of the bottom beam 153 of the unit module 150, the truss member 131 is a horizontal truss is arranged in a horizontal direction It can be provided as a truss.

Accordingly, the connection panel 130 may be disposed between the core part 110 and the unit module 150 to form a corridor for connecting the spaces. However, the connection panel 130 is not limited thereto.

On the other hand, the unit module 150 may be connected to the connection panel 130 and laminated vertically, and may have a column 151, a bottom beam 153 and a ceiling beam 155.

The unit module 150 may be a plurality of vertically stacked or connected in a horizontal direction to form the modular building. The unit module 150 may include a pillar 151, a floor beam 153, and a ceiling beam 155. The unit module 150 may be prefabricated at a factory and transported to a site to be assembled vertically and horizontally.

Bonding structure 100 of the modular building according to an embodiment of the present invention as described above, has a connection panel 130 for connecting it between the core unit 110 and the unit module 150, the connection panel 130 is characterized in that the transfer of the load of the unit module 150 to the core portion (110).

In addition, the connection panel 130 may be configured as a floor panel provided between the core unit 110 and the unit module 150 to serve as a corridor.

Accordingly, the bonding structure 100 of the modular building according to the embodiment of the present invention, by bonding the unit module 150 using the core unit 110, a modular building consisting of only the conventional unit module 150 In comparison, the resistance to lateral forces acting on the building can be increased.

In addition, by connecting the unit module 150 and the core unit 110 using the connection panel 130, compared to the case of directly connecting the unit module 150 and the core unit 110, each unit Since the horizontal shear force transmitted to the module 150 can be effectively transmitted to the core unit 110, the vertical displacement between the upper and lower unit modules 150 with respect to the lateral force can be minimized.

In addition, the connection panel 130 is composed of a bottom panel which is installed at the bottom plate position of each layer and the connection panel 130 is connected to the core portion 110 and the bolt joints, such that the unit module 150 is Compared to the case in which the core portion 110 is directly bonded, there is an advantage that can effectively correspond to the construction error.

That is, in the case where the unit module 150 is directly bonded to the core unit 110, a method of embedding connecting hardware in the core unit 110 and bolting the connecting hardware and the unit module 150 is provided. In this case, since there is a difference between the construction error (for example, 1.5mm-2mm) of the bolt hole of the connection hardware and the manufacturing error (for example, up to 10mm) of the unit module 150, the unit module 150 There is a problem in that the connection between the core portion 110 and the hard. On the other hand, the embodiment according to the present invention is made of a bottom panel and the core unit 110 and the core module 110 using the connection panel 130 coupled to the unit module 150 in a bolted connection type and Since the unit module 150 is connected, the construction error in the process of connecting the core unit 110 and the unit module 150 can be effectively absorbed.

On the other hand, the connection panel 130 may include a truss connecting member 133 for bonding the truss member 131 to the core unit 110 or the unit module 150.

That is, as in the embodiment shown in Figures 3 to 6, the truss connecting member 133 is bolted or welded to the core portion 110 or the unit module 150, the truss member 131 is It may be coupled to the truss connecting member 133. Accordingly, the truss connecting member 133 may bond the truss member 131 to the core unit 110 or the unit module 150.

On the other hand, the connection panel 130 is welded to the truss member 131 and bonded to the truss member 131, the gusset plate for mounting the truss member 131 to the truss connecting member 133 ( 135).

That is, as shown in the embodiment shown in Figures 3 to 6, the gusset plate 135 is disposed on the node portion of the truss member 131 disposed in the horizontal direction and welded to the truss connecting member 133 The truss member 131 may serve as a reinforcing plate to be joined to the truss connecting member 133.

On the other hand, the truss connecting member 133 may be made of a plate member or c-shaped steel or L-shaped steel.

That is, the truss connecting member 133 may be formed of a plate member or a c-shaped steel or an L-shaped steel so as to be bonded to the core portion 110 or the unit module 150 by welding or bolting. However, the gusset plate 135 is preferably made of c-shaped steel to secure a welding area with the gusset plate 135.

However, the truss connecting member 133 is joined to the core unit 110 or the unit module 150 and the gusset plate 135 is welded to the truss member 131 to the core unit 110 or If it can be connected to the unit module 150, various modifications are possible.

On the other hand, the joint structure 100 of the modular building according to an embodiment of the present invention, as shown in Figure 3 to Figure 6, the connection panel 130 and the core portion 110 or the connection panel It may further include a bonding member 170 for bonding the 130 and the unit module 150.

The bonding member 170 may be preferably configured as a plate member as described below, and the bonding between the connection panel 130 and the core unit 110 via the bonding member 170, or the The connection between the panel 130 and the unit module 150 may be performed to induce a smooth transfer of the load so that the modular building can be integrated with respect to the lateral force.

Hereinafter, specific embodiments of the bonding member 170 will be described.

The bonding member 170, as shown in the embodiment shown in Figure 4, is provided between the unit module 150 is installed on the upper and lower unit modules 150 of the unit modules 150 stacked up and down Including a connection plate 171, the connection plate 171 may include a protrusion 171a protruding from the unit module 150 to support the connection panel 130 from the bottom.

Here, the floor beam 153 and the ceiling beam 155 may be provided with a plate plate 157 on the upper and lower sides of the end portion that is adjacent to the pillar. In addition, the connection plate 171 may protrude toward the bottom beam side, and may be bolted through the flanges of the bottom beam 153 and the ceiling beam 155 and the plate plate 157. Accordingly, the coupling of the unit modules 150 stacked up and down can be firmly achieved.

Accordingly, the connection plate 171 is firmly coupled to the upper and lower portions of the unit module 150, and is coupled to the lower portion of the connection panel 130 by a bolt coupling to the connection panel 130 and the The coupling of the unit module 150 can be firmly.

The bonding member 170 may include a fastening plate 173 that is bolted between the connection panel 130 and the unit module 150.

That is, the fastening plate 173, as shown in the embodiment shown in Figures 3 and 4, between the pillar 151 of the unit module 150 and the truss connecting member 133 of the connection panel 130. Can be inserted. At this time, the fastening plate 173 may be fastened with bolts passing through the pillar 151 and the truss connecting member 133, and the inside of the pillar 151 may be made of C-shaped steel or the like so as to secure such bolt coupling. Joining auxiliary member 152 may be provided.

Accordingly, the fastening plate 173 effectively transmits the vertical or horizontal loads transmitted to the pillars 151 to the connection panel 130, thereby transmitting the load acting on the unit module 150 to the core part 110. ) Can serve as a

On the other hand, the core part 110 is made of a reinforced concrete structure having at least one horizontal reinforcement 111 is bent and formed in the concrete (C), the joining member 170, the horizontal reinforcement 111 It may include a bonding plate 175 that is welded to and bonded to the connection panel 130.

In addition, preferably, the joining plate 175 may be embedded in the concrete C of the core part 110.

That is, as shown in the embodiment shown in Figure 5 and 6, the core portion 110 may be made of a reinforced concrete structure in which the reinforcing bar and the concrete (C) is integrated, the reinforcing bar in the horizontal direction with the vertical reinforcement of the main reinforcement It may include a horizontal reinforcement 111 spaced apart.

At this time, the horizontal reinforcement 111 is reinforcement to the height (for example, the height of the bottom beam 153 of the unit module 150 is installed) the bottom panel is installed, the joining plate 175 is one surface The horizontal reinforcement 111 is provided with one or a plurality of welds, and may be embedded in the concrete (C) poured in the core portion (110). The truss connecting member 133 of the unit module 150 may be welded to the other surface of the bonding plate 175.

However, the installation of the bonding plate 175 is not necessarily limited to the above, and various modifications are possible.

The bonding plate 175 provided as described above may serve to effectively transfer the load of the connection panel 130 to the core unit 110. In addition, the bent horizontal reinforcement 111 may play a role of resisting the pulling force transmitted by the connection panel 130 when a lateral force is applied to the modular building.

Meanwhile, in the embodiment of the present invention, as shown in FIGS. 3 to 6, the core unit 110 or the unit module 150 is bonded to one surface thereof to support the connection panel 130 from below. It may further include a support hardware 190 formed with a bent portion.

That is, the support hardware 190 may be composed of, for example, a 'b'-shaped hardware, one surface of the joint plate 175 of the core portion 110 or the pillar 151 of the unit module 150 and Can be combined. The bent protrusion may support the lower portion of the connection panel 130. At this time, more preferably, the support hardware 190 may be configured to support the node by being located below the node of the truss member 131.

However, if the support hardware 190 can support the connection panel 130 from the bottom, the shape or the joining method can be applied without limitation, for example, the core portion 110 or the unit by bolting, etc. It may be combined with the module 150.

On the other hand, with reference to Figures 2 to 7, will be described the construction method of a modular building according to another aspect of the present invention.

Construction method of a modular building according to an embodiment of the present invention, as shown in Figure 7, the step of installing the core unit 110, the lower unit module 150 to be spaced apart from the core unit 110 Installing and installing the lower unit module 150, the upper unit module 150 stacked on the lower unit module 150, and spaced apart between the upper unit module 150 and the core unit 110 It may be configured to include a step of bonding the connection panel 130 having a truss member 131.

That is, as shown in FIG. 7A, the core unit 110 is installed, and as shown in FIG. 7B, the lowest unit module 150 is connected to the core unit 110. It can be installed at a predetermined interval apart.

Thereafter, as illustrated in FIG. 7C, the upper unit module 150 is stacked and installed on the lower unit module 150, and the upper unit module 150 and the core unit 110 are stacked. Connection panel 130 can be installed between. In this case, the connection panel 130 may be configured as a bottom panel having the truss member 131, and may be installed at the height of the bottom beam 153 of the upper unit module 150.

In addition, in the construction method according to an embodiment of the present invention, the unit module 150 is further stacked on the upper unit module 150, and the spaced apart between the additionally stacked unit module 150 and the core unit 110. And an additional stacking step of installing the connection panel 130 having the truss member 131 in the space, wherein the additional stacking step may be repeated until the top layer unit module 150 is stacked.

That is, as shown in the embodiment shown in Figure 7 (d), for example, after installing the two-layer unit module 150 and the connection panel 130 of the second floor, the unit module 150 of the third floor It can be installed and the connection panel 130 of the third floor. Then, this process may be repeated until the uppermost unit module is stacked.

When using the bonded structure of the modular building according to the embodiment of the present invention and the construction method thereof, the modular building is constructed using the core part, and the unit module is laminated up and down by bonding the unit module to the core part using the connection panel. The vertical displacement occurring at the junction between the unit modules can be minimized. Accordingly, the resistance to the lateral force of the modular building can be increased.

In addition, by connecting the core unit and the unit module by using a connection panel, it is possible to effectively cope with the construction error compared to the case of directly connecting the unit module to the core unit, between the connection panel and the core unit or between the connection panel and the unit module The load acting therebetween can be effectively transmitted through the joining member consisting of a plate.

While the invention has been shown and described in connection with specific embodiments so far, it will be appreciated that the invention can be varied and modified without departing from the spirit or scope of the invention as set forth in the claims below. It will be appreciated that those skilled in the art can easily know.

100: junction structure of the modular building 110: core portion
130: connection panel 131: truss member
133: truss connecting member 150: unit module
170: bonding member 171: connecting plate
173: fastening plate 175: bonding plate
190: support hardware

Claims (14)

A core portion;
A connection panel coupled to an outer circumferential surface of the core part and having a truss member connected to and connected to the core part;
A unit module installed spaced apart from the core part and having a column, a bottom beam, and a ceiling beam, stacked up and down, and connected to the core part through bonding with the connection panel;
The connection panel is composed of a bottom panel installed at the height of the bottom beam of the unit module, the truss member is provided as a horizontal truss truss is arranged in a horizontal direction,
Bonding structure of a modular building that the load is easily transferred from the unit module to the core through the connection panel and integrally acts on the external force.
delete The method of claim 1, wherein the connection panel
And a truss connecting member for joining the truss member to the core part or the unit module.
The method of claim 3,
The truss connecting member is a joining structure of a modular building, characterized in that consisting of a plate member.
The method of claim 4, wherein
The truss connecting member is a joint structure of a modular building, characterized in that consisting of c-shaped steel or L-shaped steel.
The method according to any one of claims 3 to 5, wherein the connection panel
And a gusset plate welded to the truss connecting member and joined to the truss member to mount the truss member to the truss connecting member.
The method of claim 1,
And a joining member formed between the connecting panel and the core unit or between the connecting panel and the unit module, for firmly coupling the connecting panel to the core unit or the connecting panel and the unit module. Bonding structure of a modular building comprising a.
The method of claim 7, wherein the bonding member
It includes a connection plate provided between the unit module installed in the upper and the unit module installed in the lower of the unit modules stacked up and down,
The connecting plate is a joining structure of a modular building, characterized in that it comprises a protrusion projecting from the unit module to support the connection panel from the bottom.
The method of claim 7, wherein the bonding member,
Bonding structure of a modular building comprising a fastening plate which is bolted between the connection panel and the unit module.
The method of claim 7, wherein
The core part is made of a reinforced concrete structure is embedded in the concrete is provided with at least one horizontal reinforcement bent,
The joining member is a joining structure of a modular building, characterized in that it comprises a joining plate welded to the horizontal reinforcing bar and bonded to the connection panel.
The method of claim 10,
The joining plate is a joining structure of a modular building, characterized in that the buried in the concrete of the core portion.
The method of claim 1,
Bonding structure of the modular building further comprising a; and the support unit is bonded to one side of the core unit or the unit module, the bent portion formed to support the connection panel from the bottom.
Installing a core unit;
A lower unit module installation step of installing a lower unit module spaced apart from the core unit; And,
An upper unit module is stacked and installed on the lower unit module, and a connection panel made of a truss member is installed between the lower unit module and the upper unit module and the core unit so that a load can be easily transferred from the unit module to the core unit. Including;
The connection panel is composed of a bottom panel installed at the height of the bottom beam of the upper unit module, the truss member is provided as a horizontal truss in which the truss is arranged in a horizontal direction construction error when connecting the core unit and the unit module Method of construction of modular buildings to absorb water.
The method of claim 13,
And further stacking unit modules on the upper unit module, and installing a connection panel including a truss member in a spaced space between the stacked unit modules and the core unit.
The additional lamination step is a construction method of a modular building, characterized in that repeated until the lamination of the uppermost unit module.

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