KR102206844B1 - Structure and method for jointing two unit module of modular building - Google Patents

Abstract

According to the present invention, as a combined structure for coupling the plurality of unit modules in a modular building completed by combining a plurality of unit modules, the plurality of unit modules are a lower unit module and an upper unit disposed above the lower unit module. A module, wherein the lower unit module includes a plurality of lower module pillars and a plurality of lower module ceiling beams connecting upper portions of the lower module pillars, and the upper unit module includes a plurality of upper module pillars, A plurality of upper module floor beams connecting the lower portions of the upper module pillars are provided, and the plurality of upper module floor beams are spaced apart to secure a predetermined space on the plurality of lower module ceiling beams, and the upper module floor beam And, a connection hardware for connecting the lower module ceiling beams located under the upper module floor beams, wherein the connection hardware includes a flat connection plate portion to have a T shape, and a flange portion located at one end of the connection plate portion, , The connection plate part is coupled to the side surface of the upper module floor beam and the side surface of the lower module ceiling beam, and the flange part is coupled to the upper surface of the upper module floor beam or the lower surface of the lower module ceiling beam. A coupling structure between unit modules is provided.

Description

Structure and method of coupling between unit modules of modular building {STRUCTURE AND METHOD FOR JOINTING TWO UNIT MODULE OF MODULAR BUILDING}

The present invention relates to a modular building, and more particularly, to a technology for combining unit modules of a modular building.

Modular buildings include structural members, floor plates, ceiling materials, interior and exterior finishing materials and equipment, and are completed by transporting a plurality of unit modules manufactured in the factory and assembling them on site.

FIG. 1 shows a state in which an upper unit module 10b is coupled on a lower unit module 10a in a conventional modular building 10. Referring to Figure 1, each of the upper unit module (10b) coupled to the upper unit module (10a) and the lower unit module (10a), pillars (13a, 13b), the bottom long side beams (11a, 11b), It is provided with a ceiling long side beam (12a, 12b). The floor long side beam 11b of the upper unit module 10b is disposed on the ceiling long side beam 12a of the lower unit module 10a, and the floor long side beam 11b of the upper unit module 10b is sagging by the load. In consideration of this, the floor long side beams 11b of the upper unit module 10b are positioned slightly spaced apart from the ceiling long side beams 12a of the lower unit module 10a. In the conventional modular building 10, since the floor length 11b of the upper unit module 10b and the ceiling length 12a of the lower unit module 10a are installed without structural bonding, most design loads are It is designed so that the bottom long side beams 11b of the unit module 10b can resist all of them.

Recently, as the application of modular buildings is gradually expanding, the spacing of the pillars 13a and 13b of the unit modules 10a and 10b is increasing in order to increase the space utilization, and the spacing of the pillars 13a and 13b is increased from 6m to 12m. In case of double increase, the required moment increases 4 times in proportion to the square of the spacing of the columns 13a and 13b, and the amount of deflection increases 16 times in proportion to the 4th of the spacing of the columns 13a and 13b. The dance of the whole beam increases excessively, and accordingly the dance of the whole beam (t) increases. This causes problems such as difficulty in securing a ceiling height and limiting the height of transportation, and leads to an increase in the amount of structures, which requires improvement.

Republic of Korea Patent Publication Registration No. 10-0694479 (2007.03.12.)

It is an object of the present invention to provide a combined structure and method between unit modules of a modular building that is advantageous in securing floor height and transportation by reducing the dance of the floor in a long-span modular building, and minimizing the amount of structure to ensure economic efficiency. .

In order to achieve the above object of the present invention, according to an aspect of the present invention, as a combined structure for coupling the plurality of unit modules in a modular building completed by combining a plurality of unit modules, the plurality of unit modules A unit module and an upper unit module disposed above the lower unit module, the lower unit module having a plurality of lower module pillars and a plurality of lower module ceiling beams connecting upper portions of the lower module pillars, , The upper unit module includes a plurality of upper module pillars and a plurality of upper module floor beams connecting lower portions of the upper module pillars, and the plurality of upper module floor beams are constant above the plurality of lower module ceiling beams. It is spaced apart so that a space can be secured, and includes a connection hardware installed between the upper module floor beams and a lower module ceiling beams spaced apart from the upper module floor by a predetermined space, and the connection hardware is A flat connection plate portion to have a T shape and a flange portion positioned at one end of the connection plate portion, and the connection plate portion is coupled to a side surface of the upper module floor beam and a side surface of the lower module ceiling beam, and the flange portion A coupling structure between unit modules of a modular building is provided, which is coupled to an upper surface of the upper module floor beam or a lower surface of the lower module ceiling beam.

In order to achieve the above object of the present invention, according to another aspect of the present invention, a lower module installation step of arranging a plurality of lower unit modules adjacent to each other; An upper module installation step of adjacently disposing a plurality of upper unit modules corresponding to each of the plurality of lower unit modules on the plurality of lower unit modules; And a connection hardware fastening step of coupling the plurality of unit modules using a connection hardware, wherein each of the plurality of lower unit modules connects a plurality of lower module pillars and the plurality of lower module pillars from an upper portion. A plurality of lower module ceiling beams are provided, and each of the plurality of upper unit modules includes a plurality of upper module pillars and a plurality of upper module floor beams connecting the plurality of upper module pillars from a lower side, and the plurality of The upper module floor beams are spaced apart to secure a certain space on the plurality of lower module ceiling beams, and the connection hardware has a flat connection plate part to have a T shape, and a flange part located at one end of the connection plate part. In the step of fastening the connection hardware, the connection hardware is disposed between the two adjacent upper module floor beams and between the two adjacent lower module ceiling beams from above in a state in which the flange part is located above and the connection plate part is located below. It is inserted, the connecting plate portion is positioned and coupled between the two adjacent upper module floor beams and the two adjacent lower module ceiling beams, and the flange portion is positioned and coupled to the upper surface of each of the two adjacent upper module floor beams, A method of combining unit modules of a modular building is provided.

In order to achieve the object of the present invention, a lower module installation step of arranging a plurality of lower unit modules adjacent to each other; A first connection hardware fastening step of coupling the plurality of lower unit modules using a connection hardware; An upper module installation step of adjacently disposing a plurality of upper unit modules corresponding to each of the plurality of lower unit modules on the plurality of lower unit modules; And a second connection hardware fastening step of coupling the plurality of upper unit modules using the connection hardware, wherein each of the plurality of lower unit modules includes a plurality of lower module columns and the plurality of lower module columns. A plurality of lower module ceiling beams connected from the top are provided, and each of the plurality of upper unit modules includes a plurality of upper module pillars and a plurality of upper module floor beams connecting the plurality of upper module pillars from the bottom. The plurality of upper module floor beams are spaced apart to secure a certain space on the plurality of lower module ceiling beams, and the connection hardware has a flat connection plate portion to have a T shape, and a plan located at one end of the connection plate portion. Having a branch, and in the step of fastening the first connection hardware, the connection hardware is inserted between the two adjacent lower module ceiling beams from below while the flange part is located below and the connection plate part is located above, The connection plate portion is positioned and coupled between the two adjacent lower module ceiling beams, the flange portion is positioned and coupled to the lower surface of each of the two adjacent lower module ceiling beams, and in the second connection hardware fastening step, the connection plate portion There is provided a method of combining unit modules of a modular building, which is located and coupled between the two adjacent upper module floor beams.

According to the present invention, all the objects of the present invention described above can be achieved. Specifically, in a long-span modular building, the lower module ceiling beams and the upper module floor beams separated from each other are connected by connecting hardware, so that the lower module ceiling beams, the upper module floor beams, and the connecting hardware show the behavior of a Virendeel truss. In addition, the lower module ceiling beam can resist design loads together with the upper module floor beam. Accordingly, it is possible to reduce the dance of the upper module floor beam, so that the dance of the entire beam including the lower module ceiling beam and the upper module floor beam is also reduced, and transportation is facilitated while minimizing the amount of parts.

1 schematically shows the configuration of a conventional modular building, and is a side view showing a long side beam.
2 is a perspective view schematically showing a structure of a modular building combined by a combined structure between unit modules of a modular building according to an embodiment of the present invention.
3 is a diagram showing a coupling structure between unit modules shown in FIG. 2.
4 is a perspective view of the connection hardware shown in FIG. 2.
5 is a flowchart illustrating a method of combining unit modules of a modular building according to an embodiment of the present invention.
6 is a perspective view schematically showing a structure of a modular building combined by a combined structure between unit modules of a modular building according to another embodiment of the present invention.
7 is a diagram showing a coupling structure between unit modules shown in FIG. 6.
8 is a flowchart illustrating a method of combining unit modules of a modular building according to another embodiment of the present invention.

Hereinafter, the configuration and operation of an embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 2 schematically shows a structure of a modular building joined by a coupling structure between unit modules of a modular building according to an embodiment of the present invention. Referring to FIG. 2, the modular building 100 includes a lower unit module 100a, an upper unit module 100b positioned above the lower unit module 100a, and a lower unit module 100a and an upper unit module 100b. ) And a coupling structure 140 between unit modules to couple.

The lower unit module 100a is manufactured in a factory including structural members, floor plates, ceiling materials, interior and exterior finishing materials, and facilities, and includes a plurality of lower module columns 111a, 112a, 113a, 114a, and a plurality of lower modules. It includes a lower module steel structure including floor beams 121a, 122a, 123a, 124a and a plurality of lower module ceiling beams 131a, 132a, 133a, 134a. In the drawings, only a steel structure is shown for convenience of description. In this embodiment, the floor of the lower unit module 100a will be described as being constructed in a dry manner such as the deck finish.

The plurality of lower module pillars 111a, 112a, 113a, and 114a are all four, and the first lower module pillar 111a and the second lower module pillar 112a positioned at points corresponding to each of the four rectangular vertices , A third lower module post 113a and a fourth lower module post 114a. In this embodiment, the distance between the first lower module post 111a and the second lower module post 112a and the distance between the third lower module post 113a and the fourth lower module post 114a are the first lower module It is arranged to be formed to be longer than the distance between the pillar 111a and the fourth lower module pillar 114a and the distance between the second lower module pillar 112a and the third lower module pillar 113a, and the present invention is limited thereto. It is not. Between the plurality of lower module columns 111a, 112a, 113a, 114a, a plurality of lower module floor beams 121a, 122a, 123a, 124a and a plurality of lower module ceiling beams 131a, 132a, 133a, 134a are Are combined. In the present embodiment, the lower module pillars 111a, 112a, 113a, and 114a are described as being made of square pipe steel, but the present invention is not limited thereto.

The plurality of lower module floor beams 121a, 122a, 123a, 124a are all four, and the first lower module floor beam 121a, the second lower module floor beam 122a, and the third lower module floor beam ( 123a) and the fourth lower module floor beam 124a, and all have the same dance.

The first lower module floor beam 121a is disposed to extend horizontally between the first lower module pillar 111a and the second lower module pillar 112a at the bottom of the lower unit module 100a, so that the first lower module The pillar 111a and the second lower module pillar 112a are connected. The first lower module floor beam 121a becomes a long side beam connecting the two lower module pillars 111a and 112a having a relatively distant distance. The first lower module floor beam 121a and the two lower module columns 111a and 112a are coupled through means such as welding and bolting. The first lower module floor beam 121a is disposed above the lower ends of the two lower module columns 111a and 112a, and is spaced apart from the lower end of the lower unit module 100a to secure a predetermined space. The first lower module floor beam 121a is a C-shaped steel having a sectional shape of'C', and is disposed so that the opening faces the inner side of the lower unit module 100a.

The second lower module floor beam 122a is disposed to extend horizontally between the third lower module pillar 113a and the fourth lower module pillar 114a at the bottom of the lower unit module 100a, so that the third lower module The pillar 113a and the fourth lower module pillar 114a are connected. The second lower module floor beam 122a becomes a long side beam that connects the two lower module pillars 113a and 114a having a relatively distant distance. The second lower module floor beams 122a and the two lower module columns 113a and 114a are coupled through means such as welding and bolting. The second lower module floor beams 122a are disposed above the lower ends of the two lower module columns 113a and 114a, and are spaced apart from the lower end of the lower unit module 100a to secure a predetermined space, and the first lower module floor beams 121a It is located at the same height as ). The second lower module floor beam 122a is a C-shaped steel having a cross-sectional shape of'C' and is disposed so that the opening faces the inner side of the lower unit module 100a.

The third lower module floor beam 123a is disposed to extend horizontally between the second lower module pillar 112a and the third lower module pillar 113a at the bottom of the lower unit module 100a, so that the second lower module The pillar 112a and the third lower module pillar 113a are connected. The third lower module floor beam 123a becomes a short side beam connecting the two lower module columns 112a and 113a having a relatively short distance. The third lower module floor beam 123a and the two lower module columns 112a and 113a are coupled through means such as welding and bolting. The third lower module floor beams 123a are disposed above the lower ends of the two lower module columns 112a and 113a, and are spaced apart from the lower end of the lower unit modules 100a to secure a certain space, and are separated from the bottom of the first and second lower modules. It is located at the same height as the beams 121a and 122a. The third lower module floor beam 123a is a c-shaped steel having a sectional shape of'c', and is disposed so that the opening faces the inner side of the lower unit module 100a.

The fourth lower module floor beam 124a is disposed to extend horizontally between the first lower module pillar 111a and the fourth lower module pillar 114a at the bottom of the lower unit module 100a, so that the first lower module The pillar 111a and the fourth lower module pillar 114a are connected. The fourth lower module floor beam 124a becomes a short side beam connecting the two lower module columns 111a and 114a having a relatively short distance. The fourth lower module floor beam 124a and the two lower module columns 111a and 114a are coupled through means such as welding and bolting. The fourth lower module floor beams 124a are disposed above the lower ends of the two lower module pillars 111a and 114a, and are spaced apart from the lower end of the lower unit module 100a to secure a predetermined space, and the first, second, and third It is located at the same height as the lower module floor beams 121a, 122a, 123a. The fourth lower module floor beam 124a is a C-shaped steel having a cross-sectional shape of'C' and is disposed so that the opening faces the inner side of the lower unit module 100a.

The plurality of lower module ceiling beams (131a, 132a, 133a, 134a) are all four, and the first lower module ceiling beam (131a), the second lower module ceiling beam (132a), and the third lower module ceiling beam ( 133a) and the fourth lower module ceiling beam 134a, and all have the same dance. In this embodiment, it will be described that the dance of the lower module ceiling beams 131a, 132a, 133a, 134a is the same as the dance of the lower module floor beams 121a, 122a, 123a, 124a.

The first lower module ceiling beam 131a is disposed to extend horizontally between the first lower module pillar 111a and the second lower module pillar 112a in the ceiling portion of the lower unit module 100a. The pillar 111a and the second lower module pillar 112a are connected. The first lower module ceiling beam 131a becomes a long side beam that connects the two lower module pillars 111a and 112a that are relatively far apart. The first lower module ceiling beam 131a and the two lower module columns 111a and 112a are coupled through means such as welding and bolting. The first lower module ceiling beam 131a is disposed to correspond to the upper ends of the two lower module pillars 111a and 112a. The first lower module ceiling beam 121a has a cross-sectional shape including a web 1311a and two flanges 1312a extending from both ends of the web 1311a in the width direction (height direction in the drawing) as shown in FIG. As this'c'-shaped c-beam, the opening 1313a is disposed to face the inner side of the lower unit module 100a.

The second lower module ceiling beam 132a is disposed to extend horizontally between the third lower module pillar 113a and the fourth lower module pillar 114a at the ceiling portion of the lower unit module 100a. The pillar 113a and the fourth lower module pillar 114a are connected. The second lower module ceiling beam 132a becomes a long side beam that connects the two lower module pillars 113a and 114a that are relatively far apart. The second lower module ceiling beams 132a and the two lower module posts 113a and 114a are coupled through means such as welding and bolting. The second lower module ceiling beams 132a are disposed to correspond to the upper ends of the two lower module pillars 113a and 114a. The second lower module ceiling beam 122a is a C-shaped steel having a cross-sectional shape of'C' and is disposed so that the opening faces the inner side of the lower unit module 100a.

The third lower module ceiling beam 133a is disposed to extend horizontally between the second lower module pillar 112a and the third lower module pillar 113a in the ceiling portion of the lower unit module 100a, so that the second lower module The pillar 112a and the third lower module pillar 113a are connected. The third lower module ceiling beam 133a becomes a short side beam connecting the two lower module pillars 112a and 113a having a relatively short distance. The third lower module ceiling beam 133a and the two lower module columns 112a and 113a are coupled through means such as welding and bolting. The third lower module ceiling beam 133a is disposed to correspond to the upper ends of the two lower module pillars 112a and 113a. The third lower module ceiling beam 133a is a C-shaped steel having a sectional shape of'C', and is disposed so that the opening faces the inner side of the lower unit module 100a.

The fourth lower module ceiling beam 134a is disposed to extend horizontally between the first lower module pillar 111a and the fourth lower module pillar 114a at the ceiling portion of the lower unit module 100a, so that the first lower module The pillar 111a and the fourth lower module pillar 114a are connected. The fourth lower module ceiling beam 134a becomes a short side beam connecting the two lower module pillars 111a and 114a having a relatively short distance. The fourth lower module ceiling beams 134a and the two lower module columns 111a and 114a are coupled through means such as welding and bolting. The fourth lower module ceiling beam 134a is disposed to correspond to the upper ends of the two lower module pillars 111a and 114a. The fourth lower module ceiling beam 134a is a C-shaped steel having a sectional shape of'C', and is disposed so that the opening faces the inner side of the lower unit module 100a.

The upper unit module 100b is manufactured in a factory including structural members, floor plates, ceiling materials, interior and exterior finishing materials, and equipment, like the lower unit module 100a, and includes a plurality of upper module columns 111b, 112b, 113b, and 114b. ), and a plurality of upper module floor beams 121b, 122b, 123b, 124b, and an upper module steel structure having a plurality of upper module ceiling beams 131b, 132b, 133b, 134b. In the drawings, only a steel structure is shown for convenience of description. In this embodiment, the bottom of the upper unit module 100b will be described as having a dry finish such as a deck finish like the upper unit module 100a.

A plurality of upper module columns 111b, 112b, 113b, 114b of the upper unit module 100b, a plurality of upper module floor beams 121b, 122b, 123b, 124b, and a plurality of upper module ceiling beams 131b , 132b, 133b, 134b, a plurality of lower module columns 111a, 112a, 113a, 114a of the lower unit module 100a, and a plurality of lower module floor beams 121a, 122a , 123a, 124a), and a plurality of lower module ceiling beams 131a, 132a, 133a, 134a, and thus a detailed description thereof will be omitted.

The upper unit module 100b is located above the lower unit module 100a, the first lower module pillar 111a and the first upper module pillar 111b are connected, and the second lower module pillar 112a and the second The upper module post 112b is connected, the third lower module post 113a and the third upper module post 113b are connected, and the fourth lower module post 114a and the fourth upper module post 114b are connected. Arranged so that the first upper module floor beams 121b are spaced apart from each other and in parallel on the first lower module ceiling beams 131a, and the second upper module floor beams on the second lower module ceiling beams 132a ( 122b) are spaced apart and arranged in parallel, and the third upper module floor beams 123b are spaced apart from the third lower module ceiling beams 133a and are arranged in parallel, and the fourth lower module ceiling beams 134a The fourth upper module floor beams 124b are spaced apart from each other and disposed in parallel.

The coupling structure 140 between unit modules couples the lower unit module 100a and the upper unit module 100b positioned above the lower unit module 100a. The coupling structure 140 between unit modules includes a plurality of connection hardware 170 fastened to each of the lower unit module 100a and the upper unit module 100b.

3 and 4, the connection hardware 170 has a T-shape, and includes a connection plate part 171 and a flange part 175 positioned at one end of the connection plate part 171. The first lower module ceiling beam (131a) that is long side and the first upper module floor beam (121b) that is long side is connected by the connection hardware 170, and the second lower module ceiling beam (132a) that is long side and the second, which is long side The upper module floor beam 122b is connected. In this embodiment, the first lower module ceiling beams 131a, the first upper module floor beams 121b, and the second lower module ceiling beams 132a and the second upper module floor beams 122b are respectively provided with four connecting hardware ( 170), but unlike this, it may be connected by three or less or five or more connecting hardware 170, which is also within the scope of the present invention. In addition, in this embodiment, between the third lower module ceiling beam (133a) that is a short side and the third upper module bottom beam (123b) that is a short side, and the fourth lower module ceiling beam (134a) that is a short side, and a fourth upper module floor that is short side It is described that the beams 124b are not connected by the connection hardware 170, but unlike this, between the third lower module ceiling beams 133a and the third upper module floor beams 123b and the fourth lower module ceiling beams ( 134a) and the fourth upper module floor beam 124b may also be connected by one or more connecting hardware 170, which is also within the scope of the present invention.

The connection plate part 171 has a generally flat plate shape, and includes a plurality of first bolt holes 172 and a plurality of second bolt holes 173. The plurality of first bolt holes 172 are spaced apart from the flange portion 175 by a predetermined distance and are arranged in a line parallel to the flange portion 175. The plurality of second bolt holes 173 are arranged in a line parallel to the flange portion 175 between the first bolt holes 172 and the flange portion 175.

The flange portion 175 is a balanced plate shape positioned at one end (top in the drawing) of the connection plate portion 171, forms a right angle with the connection plate portion 171, and extends to both sides of the connection plate portion 171. A plurality of third bolt holes 176 are disposed on both sides of the flange portion 175 with the connecting plate portion 171 therebetween.

3 shows a state in which the connection hardware 170 is coupled to the first lower module ceiling beam 131a and the first upper module floor beam 121b. The connection hardware 170 includes not only the first lower module ceiling beams 131a and the first upper module floor beams 121b, which are arranged vertically, but also a side lower unit module (not shown) disposed on the side of the lower unit module 100a. ) Of the lower module ceiling beam (231a) and the upper module floor beam (221b) of the side upper unit module (not shown) located on the upper side of the lower unit module (not shown) and disposed on the side of the upper unit module (100b) Are combined. Referring to Figure 3, the connection hardware 170, one side of the flange portion 175 covers the top surface of the bottom beam 121b of the first upper module and the bottom beam 221b of the other upper module disposed adjacent to the side In contact, the connection plate part 171 is between the first upper module floor beams 121b and the other upper module floor beams 221b, and between the first lower module ceiling beams 131a and the other lower module ceiling beams 231a. It is placed in place. The flange portion 175 is bolt-nut-fastened to the first upper module floor beam 121b and the other upper module floor beam 221b adjacent to the side through the third bolt hole 176. Another lower module adjacent to the first lower module ceiling beam (131a) by bolt-nut fastening means (181, 185) through the first bolt hole 172 and the second bolt hole 173 formed in the connection plate part 171 The ceiling beam 231a and the first upper module floor beam 121b and the adjacent upper module floor beam 221b are coupled.

As shown in FIG. 2, the lower module ceiling beams 131a and 133a spaced apart from each other by a plurality of connection hardware 170 and the upper module floor beams 121b and 123b are connected, so that the lower module ceiling beams 131a and 133a ), the upper module floor beams 121b and 123b and the plurality of connecting hardware 170 show the behavior of the Virendeel truss, and the lower module ceiling beams 131a and 133a are also the upper module floor beams 121b and 123b. Together with it, it can resist design load. Accordingly, it is possible to reduce the dance of the upper module floor beams 121b and 123b, so that the dance of the entire beam including the lower module ceiling beams 131a and 133a and the upper module floor beams 121b and 123b is also reduced. It becomes easy to transport while minimizing the amount of parts.

FIG. 5 is a flowchart illustrating a method of combining unit modules of a modular building according to an embodiment of the present invention. The method shown in FIG. 5 is a method suitable for the structure shown in FIG. 2 (that is, when the floor of the unit module is constructed in a dry manner). Referring to FIG. 5, a method for combining unit modules of a modular building according to an embodiment of the present invention includes a lower module installation step (S10), an upper module installation step (S20), and a connection hardware fastening step (S30). do. Referring to FIGS. 2 and 3 together, each step will be described in more detail as follows.

In the lower module installation step S10, the lower unit module 100a is installed. In the lower module installation step S10, a plurality of lower unit modules 100a may be installed adjacent to each other. After the one or more lower unit modules 100a are installed through the lower module installation step S10, the upper module installation step S20 is performed.

In the upper module installation step S20, the upper unit module 100b is placed on the lower unit module 100a and installed. In the upper module installation step S20, a plurality of upper unit modules 100b may be installed adjacent to each other. After the one or more upper unit modules 100b are installed on the one or more lower unit modules 100a through the upper module installation step S20, the connection hardware fastening step S30 is performed.

In the connection hardware fastening step (S30), the connection hardware 170 is fastened in the form as shown in FIGS. 2 and 3 to connect the lower module ceiling beam 131a and the upper module floor beam 121b.

6 schematically shows a structure of a modular building joined by a coupling structure between unit modules of a modular building according to another embodiment of the present invention. 6, the modular building 200 includes a lower unit module 100a, an upper unit module 100b positioned above the lower unit module 100a, a lower unit module 100a, and an upper unit module 100b. ) And a coupling structure 240 between the unit modules for coupling. The lower unit module 100a and the upper unit module 100b are the same as the embodiment shown in FIG. 2 except that the floor is a concrete slab and wet finish. Compared with the embodiment shown in Fig. 2, the same reference numerals denote the same configuration.

Referring to FIG. 7 to describe the coupling structure between unit modules of the embodiment shown in FIG. 6, as compared to the embodiment shown in FIG. 3, the arrangement direction of the connection hardware 170 is different, and the connection hardware 170 The silver flange portion 175 is disposed in contact with the lower surface of the first lower module ceiling beam 131a. When comparing Fig. 7 and Fig. 3, the same reference numerals denote the same configuration.

8 is a flowchart illustrating a method of combining unit modules of a modular building according to another embodiment of the present invention. The method shown in FIG. 8 is a method suitable for the structure shown in FIG. 6 (that is, when the floor of the unit module is constructed in a wet manner such as a concrete slab). Referring to FIG. 8, a method for combining unit modules of a modular building according to another embodiment of the present invention includes a lower module installation step (S10`), a first connection hardware fastening step (S15), and an upper module installation step (S20). `) and the second connection hardware fastening step (S25). Referring to FIGS. 6 and 7 together, each step will be described in more detail as follows.

In the lower module installation step S10`, the lower unit module 100a is installed. In the lower module installation step S10', a plurality of lower unit modules 100a may be installed adjacent to each other. After the at least one lower unit module 100a is installed through the lower module installation step S10`, the first connection hardware fastening step S15 is performed.

In the first connection hardware fastening step (S15), the connecting hardware 170 is shown between the two adjacent lower module ceiling beams (131a, 231a in FIG. 7) of each of the two adjacent lower unit modules installed through the lower module installation step (S10`). As shown in Figure 7, after being inserted from the bottom, it is bolted. Since the floors of the unit modules 100 and 100b are wet-finished like a concrete slab, the connection hardware 170 cannot be inserted from above, as in the embodiment shown in FIGS. 2 and 3, so in this embodiment, the connection hardware ( 170) is inserted from below and combined. After the connection hardware 170 is inserted between the two adjacent lower module ceiling beams (131a and 231a in FIG. 7) through the first connection hardware fastening step (S15) and bolted, the upper module installation step (S20`) is performed. .

In the upper module installation step (S20`), the upper unit module 100b is lowered while the connection hardware 170 is fastened to the lower module ceiling (131a, 231a in FIG. 7) through the first connection hardware fastening step (S15). It is placed and installed on the unit module 100a. In the upper module installation step S20', a plurality of upper unit modules 100b may be installed adjacent to each other. After the one or more upper unit modules 100b are installed on the one or more lower unit modules 100a through the upper module installation step S20`, the second connection hardware fastening step S25 is performed.

In the second connection hardware fastening step (S25), the connection hardware 170 is bolted between the two adjacent upper module bottom beams 121b and 221b of the two upper modules, as shown in FIG. 7.

Although the present invention has been described through the above embodiments, the present invention is not limited thereto. The above embodiments may be modified or changed without departing from the spirit and scope of the present invention, and those skilled in the art will recognize that such modifications and changes also belong to the present invention.

100, 200: modular building
100a: lower unit module
111a, 112a, 113a, 114a: lower module column
121a, 122a, 123a, 124a: lower module floor beams
131a, 132a, 133a, 134a: lower module ceiling beam
100b: upper unit module
111b, 112b, 113b, 114b: upper module column
121b, 122b, 123b, 124b: upper module floor beam
131b, 132b, 133b, 134b: upper module ceiling beam
140, 240: Combined structure between unit modules
170: connecting hardware

Claims (10)

As a combined structure that combines the plurality of unit modules in a modular building completed by combining a plurality of unit modules,
The plurality of unit modules includes a lower unit module and an upper unit module disposed above the lower unit module,
The lower unit module includes a plurality of lower module pillars and a plurality of lower module ceiling beams connecting upper portions of the lower module pillars,
The upper unit module includes a plurality of upper module pillars and a plurality of upper module bottom beams connecting lower portions of the upper module pillars,
The plurality of upper module floor beams are positioned to be spaced apart to secure a predetermined space on the plurality of lower module ceiling beams,
And a plurality of connecting hardware installed in a spaced apart space between the upper module floor beam and the lower module ceiling beam located under the upper module floor beam,
The connection hardware has a flat connection plate portion to have a T shape, and a flange portion positioned at one end of the connection plate portion,
The connection plate portion is coupled together to the side of the upper module floor beam and the side of the lower module ceiling beam,
The flange portion is coupled to an upper surface of the upper module floor beam or a lower surface of the lower module ceiling beam,
The upper module floor beam, the lower module ceiling beam, and the plurality of connecting hardware form a Virendil truss structure,
A plurality of lower unit modules are disposed adjacent to each other, and a plurality of upper unit modules are disposed adjacent to each other in correspondence to the plurality of lower unit modules, so that two lower module ceiling beams are adjacent between the two adjacent lower unit modules, Two upper module floor beams are located adjacent to each other between the two adjacent upper unit modules,
The connecting plate portion is located and coupled between the two adjacent upper module floor beams and between the two adjacent lower module ceiling beams,
The flange portion is located and coupled to the upper surface of each of the two adjacent upper module floor beams or the lower surface of each of the two adjacent lower module ceiling beams,
The two adjacent upper module floor beams are bolted together to the connection plate part positioned between the two adjacent upper module floor beams,
The two adjacent lower module ceiling beams are bolted together to the connection plate portion positioned between the two adjacent lower module ceiling beams,
Combined structure between unit modules of a modular building. The method according to claim 1,
A plurality of connection hardware is coupled between the upper module floor beam and the lower module ceiling beam, the coupling structure between unit modules of a modular building. delete delete A lower module installation step of adjacently disposing a plurality of lower unit modules;
An upper module installation step of adjacently disposing a plurality of upper unit modules corresponding to each of the plurality of lower unit modules on the plurality of lower unit modules; And
A connection hardware fastening step of coupling the plurality of unit modules using a connection hardware,
Each of the plurality of lower unit modules includes a plurality of lower module pillars and a plurality of lower module ceiling beams connecting the plurality of lower module pillars from above,
Each of the plurality of upper unit modules includes a plurality of upper module pillars and a plurality of upper module bottom beams connecting the plurality of upper module pillars from a lower side,
The plurality of upper module floor beams are positioned to be spaced apart to secure a predetermined space on the plurality of lower module ceiling beams,
The connection hardware has a flat connection plate portion to have a T shape, and a flange portion positioned at one end of the connection plate portion,
In the step of fastening the connection hardware, the connection hardware is inserted between the two adjacent upper module floor beams and between the two adjacent lower module ceiling beams from above while the flange part is located above and the connection plate part is located below. Thus, the connecting plate portion is located and coupled between the two adjacent upper module floor beams and between the two adjacent lower module ceiling beams, and the flange portion is positioned and coupled to the upper surface of each of the two adjacent upper module floor beams. How to combine unit modules of a building. The method of claim 5,
The connection hardware is bolted to the two adjacent upper module floor beams and the two adjacent lower module ceiling beams, the coupling method between unit modules of a modular building. The method of claim 5,
A plurality of connection hardware is coupled to the two adjacent upper module floor beams and the two adjacent lower module ceiling beams. A lower module installation step of adjacently disposing a plurality of lower unit modules;
A first connection hardware fastening step of coupling the plurality of lower unit modules using a connection hardware;
An upper module installation step of adjacently disposing a plurality of upper unit modules corresponding to each of the plurality of lower unit modules on the plurality of lower unit modules; And
A second connection hardware fastening step of coupling the plurality of upper unit modules using the connection hardware,
Each of the plurality of lower unit modules includes a plurality of lower module pillars and a plurality of lower module ceiling beams connecting the plurality of lower module pillars from above,
Each of the plurality of upper unit modules includes a plurality of upper module pillars and a plurality of upper module bottom beams connecting the plurality of upper module pillars from a lower side,
The plurality of upper module floor beams are positioned to be spaced apart to secure a predetermined space on the plurality of lower module ceiling beams,
The connection hardware has a flat connection plate portion to have a T shape, and a flange portion positioned at one end of the connection plate portion,
In the step of fastening the first connection hardware, the connection plate part is inserted between the two adjacent lower module ceiling beams from below while the flange part is located below and the connection plate part is located above, so that the connection plate part It is positioned and coupled between two adjacent lower module ceiling beams, and the flange portion is positioned and coupled to the lower surface of each of the two adjacent lower module ceiling beams,
In the step of fastening the second connection hardware, the connection plate portion is positioned and coupled between the two adjacent upper module floor beams. The method of claim 8,
The connection hardware is bolted to the two adjacent upper module floor beams and the two adjacent lower module ceiling beams, the coupling method between unit modules of a modular building. The method of claim 8,
A plurality of connection hardware is coupled to the two adjacent upper module floor beams and the two adjacent lower module ceiling beams.

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