KR20140026913A - Unit moduler structure for extension and bracket and connecting method therof - Google Patents

Abstract

According to one side surface of the present invention, a unit modular structure for extension includes: a column made of C-shaped steel; a binding unit formed in the upper part and the lower part of the column and having an end plate; and a beam which is made of C-shaped steel and has a fixing plate bound to the binding unit and having a fixing hole into which a bolt is inserted.

Description

Unit Moduler Structure For extension and Bracket and Connecting Method Therof}

The present invention relates to an expansion unit modular structure and bracket, and more particularly to an expansion unit modular structure and bracket that can be easily expanded while securing a workspace in an existing building.

The modular construction method is an advanced construction method that pre-fabricates more than 80% of the basic frame made of weathering steel and installs it on site.

It is a way to build a building like a container by prefabricating a steel frame structure at a factory. This construction method is regarded as more competitive in terms of construction quality, economics and environmental friendliness than previous construction methods because it can secure the quality of buildings and shorten the air and can be easily moved or reused.

The greatest strength of modular construction method is construction period and economical efficiency. The construction period can be reduced to one-third, and the cost of construction can be dramatically reduced, and reuse is possible, which is excellent in economy.

In addition, it minimizes waste generation by minimizing field work and minimizes noise and dust on site.

In the modular method, a steel pipe column and a C-shaped steel beam are rigidly joined and a composite or PC bottom plate is inserted into a C-shaped steel web.

However, the existing modular construction method has been developed for new construction, so the vertical expansion is limited to two floors under current law. Existing modular modulars have long one-sided structural forms that are longer than short sides to cope with design modules of existing buildings. In this case, the structural efficiency of the square steel pipe column is lowered, there is a problem that the steel joint treatment in the short side direction is not significant.

In addition, when installing the modular on the roof of the existing building there is a problem that can not secure the working space between the floor and the modular.

The present invention has been made to solve the above problems, the object of the present invention is to ensure the expansion of the working space on the upper part of the existing building.

Still another object of the present invention is to be able to form various planes by simple joining.

Expansion unit modular structure according to an aspect of the present invention for achieving the above object is a column formed of a C-shaped steel, the joint formed on the top and bottom of the column having an end plate, and bonded to the junction It may include a beam formed of C-shaped steel having a fixing plate is formed with a fixing hole for inserting the bolt therein.

When the load acts on the slab, the beam may be provided with a long side beam receiving the load and supporting the long side of the slab, and a short side beam supporting the short side of the slab.

The fixing plate is located on the upper side of both ends of the beam and can be welded to the side of the pillar.

The pillar may have the flange face inward to serve as an opening when joining the beam.

The bore slab may be directed inwardly with a flange surface to allow insertion of the slab into the beam.

In addition, the bracket on the other side of the present invention for achieving the above object is a rectangular base plate to be installed on the concrete, the fixing hardware for fixing the base plate to the concrete, each of the center of the base plate It may include a plurality of stiffeners extending to the upper end by connecting to the end center.

The base plate may be installed on the concrete plinth.

The stiffener may have a support hole for supporting the expansion unit modular structure.

The quantity of the stiffener can be adjusted according to the quantity of the expansion unit modular structure bonded to the bracket.

In addition, the expansion unit modular structure and the bracket in one aspect of the present invention for achieving the above object (a) combining a plurality of stiffeners so as to extend from the center of the base plate to the upper end of each connection; ; (b) installing the base plate on an upper portion of the concrete plinth to fix the fixed iron; (c) inserting an extension unit modular structure between each said stiffener; (d) matching the positions of the fixing holes of the fixing plate provided in the beam of the expansion unit modular structure with the support holes provided on the upper part of the stiffener; (e) fastening the support hole and the fixing hole with a bolt.

The column and the flange face of the expansion unit modular structure may be formed of C-shaped steel facing inward.

The quantity of the stiffener can be adjusted according to the quantity of the expansion unit modular structure bonded to the bracket.

According to the expansion unit modular structure and the bracket and the joining method according to the present invention, by installing a bracket on the upper portion of the plinth to install the expansion unit modular structure it is possible to secure a work space in the lower portion of the expansion unit modular structure.

In addition, since the fixing unit of the bracket's spinner and the expansion unit modular structure can be bonded to each other, the expansion unit modular structure can be joined and thus the construction can be easily performed.

1 is a perspective view showing an expansion unit modular structure according to an embodiment of the present invention.
Figure 2 is a perspective view showing a junction according to an embodiment of the present invention.
3 is a perspective view showing a bracket according to another embodiment of the present invention.
4 is a cross-sectional view showing a state in which a bracket according to another embodiment of the present invention is installed.
Figure 5 is a perspective view of the bracket according to the number of stiffeners according to another embodiment of the present invention.
6 is a perspective view showing a state in which the expansion unit modular structure and the bracket is installed according to an embodiment of the present invention.
Figure 7 is a perspective view showing a process of installing the expansion unit modular structure to the bracket according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail for the expansion unit modular structure and bracket according to an embodiment of the present invention.

1 is a perspective view showing an expansion unit modular structure according to an embodiment of the present invention, Figure 2 is a perspective view showing a joint according to an embodiment of the present invention.

1 to 2, the expansion unit modular structure 10 according to an embodiment of the present invention is a column 100 formed of C-shaped steel, and joined to the top and bottom of the column 100 and C A beam 200 formed of a shape steel and the connection part 300 having an end plate 310 may be directly connected to the pillar 100.

The pillar 100 is formed of C-shaped steel in consideration of the ease of joining the existing building and the joining with the plinth 1000 part. The pillar 100 formed of the C-shaped steel is formed of a web 600 and a flange 500 extending vertically from both sides of the web 600. In addition, the pillar 100 faces the flange 500 surface inward to facilitate joining with the beam 200 or the plinth 1000.

For example, the conventional unit modular method forms the column 100 with a square steel pipe. Conventional unit modular method is to build a unit by stacking the unit modular in the upper unit modular method for expansion rather than expansion. Therefore, the column 100 is formed of a square steel pipe to support the load of the unit module stacked on the top. On the contrary, in the case of the expansion that is not the expansion that can increase the floor, the role of the pillar 100 supporting the load of the upper part is reduced because two floors are limited by the current law. Therefore, the C-shaped steel, not the square steel pipe, can support the unit module of the upper layer.

In addition, when the pillar 100 is formed of a square steel tube, when the beam 200 and the pillar 100 of the upper layer are joined to the pillar 100, a work space is not formed when using a pin joint instead of welding. Therefore, in the conventional unit modular method, an opening is formed in the junction 300 to perform pin joining with the beam 200 or the pillar 100 of the upper layer, which consumes time and money by forming an opening in the square steel pipe. The load transmitted from the upper part is hindered by the opening part from the lower part. However, in the present invention, since the pillar 100 is formed of C-shaped steel with one side open, the load of the upper portion is evenly transmitted to the lower side, and the flange 100 of the C-shaped steel is opened toward the inner side of the pillar 100. The formed surface is formed inside the unit module to form a working space for joining the beam 200 and the upper pillar 100. In addition, since the flange 500 surface of the C-shaped steel faces inward, the work of joining the pillar 100 and the beam 200 or the upper pillar 100 from the inside of the unit module reduces the risk of falling to the outside. You can prevent it.

The beam 200 has an upper beam 220 that is joined to the upper portion of the pillar 100 to form a ceiling and a lower beam 210 that is bonded to the lower portion of the pillar 100 to form a floor. The beam 200 faces the flange 500 surface inwardly to allow the bottom slab to be inserted into the beam 200 dance.

The upper beam 220 is bonded to the upper portion of the pillar 100 to form a ceiling. When the ceiling is formed on the upper beams 220 without raising the unit modular to the upper beams 220, the flange 500 faces the inner side so that the ceiling slab can be inserted into the upper beams 220.

The lower beam 210 is bonded to the lower portion of the pillar 100 and the bottom slab is inserted into the beam 200 dance to form a floor. The upper portion of the lower beam 210 is provided with a fixing plate 400 at both ends in contact with the pillar (100). The fixing plate 400 has a fixing hole 410 for inserting the bolt 1100 for fixing between the unit modular structure 10 when the unit modular structure 10 is horizontally bonded. The lower beam 210 faces the flange 500 surface inwardly so that the bottom slab can be inserted into the beam 200.

Since the fixing plate 400 is located at the upper portion of the lower beam 210, even if the bottom slab is installed in the lower portion can work.

For example, when the expansion unit modular structure 10 is manufactured at a factory and then moved to a site, the expansion unit modular structure 10 should be joined to a plurality of plane expansion units. At this time, when the floor slab is installed in the factory and moved to the site, it may be inconvenient to join a plurality of the unit modular structures 10 for expansion according to a plane. Therefore, after the bottom slab is installed, the plurality of expansion unit modular structures 10 may be joined to the plane by the fixing plate 400 provided on the lower beam 210.

In addition, the beam 200 is a long side beam 211 for receiving a load when the load is applied to the floor slab and the long side of the slab and a short side beam 212 supporting the side of the short length of the slab. It is provided.

The joint 300 has an end plate 310 to weld the beam 200 to the pillar 100. The joint part 300 is formed at a position where the pillar 100 and the beam 200 are joined, and the beam 200 cannot be joined to an open surface between the flange 500 of the pillar 100. The plate 310 is installed and bonded.

For example, the long side beams 211 may be joined by welding the pillars 100 at the joint 300. However, since the short side beams 212 are formed with the flange 500 of the pillar 100 facing inward, the short side beams 212 may have insufficient space for joining the short side beams 212 and the pillars 100. Therefore, the end plate 310 is installed at the same position as the flange 500 of the short side beams 212 in the space formed between the flanges 500 of the joint portion 300 to join the upper side short side beams 212. It can be secured (200).

In addition, since the long side beams 211 are subjected to the load of the slab can be joined by a steel joint directly welding the beams 200 to the column 100, the short side beams 212 is installed to support the slab Since the beam 200 receives less load, it can be joined to the pillar 100 by pin bonding using the bolt 1100.

For example, in the case of a two-way slab, the load mainly acts as the long side beams 211 and the short side beams 212 act as a small load, so the short side beams 212 only serve to support the slab. Therefore, the welding beam 200 may not be subjected to a lot of load at the site where the short side beams 212 and the pillars 100 are joined, but a simple pin joint may be used.

Hereinafter, in describing the bracket according to another embodiment of the present invention, the same reference numerals are used for the same configuration as the expansion unit modular structure according to the above-described embodiment, and a detailed description thereof will be omitted.

3 is a perspective view showing the bracket 20 according to another embodiment of the present invention, Figure 4 is a cross-sectional view showing a state in which the bracket 20 according to another embodiment of the present invention is installed.

As shown in FIGS. 3 to 4, the bracket 20 according to another embodiment of the present invention has a rectangular base plate 700 installed on an upper portion of the concrete and a fixing for fixing the base plate 700 to concrete. The hardware 900 may include a plurality of stiffeners 800 that extend from the center of the base plate 700 to the upper ends of the respective ends.

The base plate 700 may be installed on an upper portion of the concrete plinth 1000 of an existing building to install the extension unit modular structure 10. In addition, the coupling hole 710 for inserting the fixing hardware 900 in close proximity to the position where the side of the base plate 700 is provided.

The fixing hardware 900 allows the base plate 700 to be fixed to an upper portion of a rooftop or plinth 1000 of an existing building. The fixing hardware 900 may be a bolt or the like, and after placing the base plate 700 in a position to install the bracket 20 to fix the base plate 700 using the fixing hardware 900, The fixing hardware 900 is inserted by forming a space for inserting the fixing hardware 900 at the same position as the coupling hole 710 formed in the base plate 700.

The stiffeners 800 extend from the center of the base plate 700 to the center of each side thereof and extend upward. Each of the stiffeners 800 may be formed in a cross shape by joining at the center of the base plate 700 by welding or the like. In addition, the stiffener 800 may extend upward to the same height as the fixing plate 400 provided in the lower beam 210 of the expansion unit modular structure 10. In addition, the upper portion of the stiffener 800 may be provided with a support hole 810 at the same position as the fixing hole 410 when bonded to the fixing plate 400.

The bracket 20 may be installed on the floor of the building to be expanded as shown in FIG. 4A, and then the unit modular structure 10 for extension may be installed between the stiffeners 800.

And, when it is difficult to install the unit modular structure 10 on the floor of the building to be expanded, as shown in Figure 4 (b) by fixing the concrete plinth 1000 on the floor to the bracket 1000 above the bracket 20 can be fixed.

5 is a perspective view of the bracket according to the number of stiffeners according to another embodiment of the present invention.

As shown in FIG. 5, the quantity of the stiffener 800 of the bracket 20 according to another embodiment of the present invention may be adjusted according to the quantity of the expansion unit modular structure 10 bonded to the bracket 20. have.

When the bracket 20 is installed on the floor or plinth 1000 of the building to be expanded, when the extension unit modular structure 10 is installed on the bracket 20, according to the quantity of the unit modular structure 10. The number of stiffeners 800 and the size of the base plate 700 can be adjusted.

For example, when only one unit modular structure 10 is installed at the top as shown in FIG. 5A, only two stiffeners 800 may be installed perpendicularly to the end of the base plate 700. In addition, in the case where two unit modular structures 10 are installed at the upper part as shown in FIG. 5 (b), the stiffener 800 is installed at one long side of the base plate 700, and then, at the center of the stiffener 800. Three other stiffeners 800 may be installed on one base plate 700 by installing one more on the other long side. In addition, in the case where three or four unit modular structures 10 are installed on the upper part as shown in FIG. 5 (b), one stiffener 800 is installed from the center of the base plate 700 to the center of each end. Four stiffeners 800 may be installed at 700.

When fixing the extension unit modular structure 10 to the bracket 20, the fixing plate 400 provided on the stiffener 800 of the bracket 20 and the lower beam 210 of the extension unit modular structure 10. ) Back to the support bolt 810 formed in the stiffener 800 of the bracket 20 and the fixing hole 410 of the fixing plate 400 formed in the expansion unit modular structure 10 to equal the bolt Fixed to (1100). In addition, when bonding between the same expansion unit modular structure 10, after adjusting the position so that the stiffener 800 of the bracket 20 is inserted between the fixing plate 400 provided in each of them fixed with a bolt (1100) do. At this time, a gap may be generated between the expansion unit modular structure 10 by the stiffener 800, and the gap may be filled with concrete, silicon, or the like.

6 is a perspective view showing a state in which the expansion unit modular structure and the bracket is installed according to an embodiment of the present invention.

As illustrated in FIG. 6, the expansion unit modular structure 10 according to the exemplary embodiment of the present invention may be bonded in various forms using the bracket 20.

A plurality of unit modular structures 10 for expansion may be joined to form various planes.

For example, the 'U', 'B' shape, etc. may be used in the extension unit modular structure 10 by joining the long side beams 211 and the long side beams 211 or the short side and the short side beams 212. It is possible to form a variety of planes.

When joining the expansion unit modular structure 10 may be formed a base such as a base (1000) at the bottom, and after fixing the bracket 20 to the base and the expansion unit modular to the bracket 20 The structure 10 can be fixed and joined.

When the extension unit modular structure 10 is formed by forming a base such as the plinth 1000, the extension unit modular structure 10 is installed to rise upward by the height of the plinth 1000. Separate work spaces can be created, such as installation, and work can be performed regardless of the condition of the rooftop side of the existing building.

The shape of the bracket 20 may vary depending on the quantity of the extension unit modular structure 10 at the junction 300 of the extension unit modular structure 10.

7 is a perspective view illustrating a process of installing an expansion unit modular structure on a bracket according to an embodiment of the present invention.

As illustrated in FIG. 7, an expansion unit modular structure 10 according to an embodiment of the present invention may be installed on a bracket 20 to be extended to an existing building.

As shown in (a) and (b) of FIG. 7, the plurality of stiffeners 800 of the bracket 20 are coupled before the extension unit modular structure 10 is installed on the bracket 20, and the bracket 20 It is combined with the base plate 700 of the). When the stiffener 800 and the base plate 700 are coupled to each other, welding may be performed, and a support hole 810 is provided on an opposite side to which the stiffener 800 is coupled to an upper portion of each stiffener 800. can do.

In addition, the base plate 700 is provided with a coupling hole 710 into which the fixed hardware 900 can be inserted close to the position where the side of the base plate 700 is in contact. The coupling hole 710 is a fixed hardware 900 that is inserted into the coupling hole 710 when the extension unit modular structure 10 and the bracket 20 is coupled to the extension unit modular structure 10 The side of the base plate 700 is formed close to the contact position so that it can be formed under the slab without being disturbed.

As shown in FIG. 7C, the bracket 20 may be installed at an upper portion of the plinth 1000 or the like. The plinth 1000 allows the extension unit modular structure 10 to be installed without being disturbed by the floor of the existing building.

The bracket 20 is installed on the upper part of the plinth 1000, etc., and then a space for inserting the fixed hardware 900 into the equipment, such as a drill, is formed at the position where the coupling hole 710 provided in the bracket 20 is formed. It can be fixed to the fixed iron 900 by forming a.

As shown in (d) and (e) of FIG. 7, the extension unit modular structure 10 may be inserted into and installed on the bracket 20 fixed to the pedestal 1000. The fixing plate 400 formed in the lower beam 210 of the expansion unit modular structure 10 and the support hole 810 formed in the stiffener 800 of the bracket 20 may be fixed using the bolt 1100. have.

In the above described the axis detection sensor and method according to an embodiment of the present invention, the spirit of the present invention is not limited to the embodiments presented herein. Those skilled in the art, who understands the spirit of the present invention, can readily suggest other embodiments by adding, changing, deleting, adding, or the like of components within the scope of the same idea, I would say.

10: expansion unit modular structure 20: bracket
100: pillar 200: beam
210: lower beam 211: long side beam
212: short side beam 220: upper beam
300: junction 310: end plate
400: fixing plate 410: fixing hole
500: flange 600: web
700: base plate 710: coupling hole
800: stiffener 810: support hole
900: fixed hardware 1000: plinth
1100: bolt

Claims (12)

A column formed of C-shaped steel,
A joint formed at an upper portion and a lower portion of the pillar and having an end plate;
An expansion unit modular structure comprising a beam formed of C-shaped steel having a fixing plate is joined to the junction and a fixing hole for inserting a bolt therein.
The method of claim 1,
When the load is applied to the slab of the beam receives a load and the long side beam for supporting the long side of the slab,
And a short side beam supporting the short side of the slab.
The method of claim 1,
The fixing plate is located on the upper side of both ends of the beam and the expansion unit modular structure, characterized in that welding on the side of the pillar.
The method of claim 1,
And the pillar has a flange surface facing inward to serve as an opening when joining the beam.
The method of claim 1,
And the flange slab faces inwardly to allow the beam slab to be inserted into the beam.
A square base plate installed on the concrete top,
Fixing hardware for fixing the base plate to the concrete,
Brackets comprising a plurality of stiffeners extending from the center of the base plate to the upper end of each end.
The method according to claim 6,
The base plate is a bracket, characterized in that installed on the concrete plinth.
The method according to claim 6,
The stiffener is a bracket having a support hole for supporting the expansion unit modular structure at the top
The method according to claim 6,
The amount of the stiffener is bracket according to the number of the expansion unit modular structure to be bonded to the bracket.
(a) coupling a plurality of stiffeners to connect from the center of the base plate to the center of each end and extend upwards;
(b) installing the base plate on an upper portion of the concrete plinth to fix the fixed iron;
(c) inserting an extension unit modular structure between each said stiffener;
(d) matching the positions of the fixing holes of the fixing plate provided in the beam of the expansion unit modular structure with the support holes provided on the upper part of the stiffener;
and (e) fastening the support hole and the fixing hole with bolts.
The method of claim 10,
The method of joining the expansion unit modular structure and the bracket, characterized in that the column and the flange surface of the expansion unit modular structure is formed of C-shaped steel toward the inside.
The method of claim 10,
The amount of the stiffener is adjusted according to the quantity of the expansion unit modular structure to be bonded to the bracket, the expansion unit modular structure and the bonding method of the bracket.

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