KR101194169B1 - Building module and joint structure thereof - Google Patents

Abstract

PURPOSE: A construction module and a joint structure thereof are provided to enable the re-use and re-alignment of the construction module by easily coupling and decoupling connection members. CONSTITUTION: A joint structure(200) of a construction module comprises an upper construction module(210), a lower construction module(230), and a connection member(250). A first insertion groove(111) is formed on the bottom surface of the upper construction module, and a first end plate(120) is coupled to the bottom end of the upper construction module. A second insertion groove(131) is formed on the top surface of the lower construction module, and a second end plate(140) is coupled to the top end of the lower construction module. The second end plate touches the first end plate. The first and second end plates are inserted into the connection member to connect the upper and lower construction modules to each other.

Description

Building module and joint structure of building module {BUILDING MODULE AND JOINT STRUCTURE THEREOF}

The present invention relates to a joint structure of the building module and the building module, and more particularly to a joint structure of the building module and the building module for joining the building module to facilitate reuse.

In general, modular construction (Modular Construction) is a method of assembling by transporting the three-dimensional box-shaped module unit manufactured and assembled in the factory to the field. The module unit includes electrical and mechanical equipment, interior and exterior materials including windows, floors, ceilings and the like. At this time, most of the building units are completed at the factory and assembled on site.

The modular construction using the modular construction method is completed by assembling each module unit manufactured at the factory on the site, up and down, back and forth, left and right. In addition, the module unit may be manufactured and assembled in the same shape and size.

Such modular buildings can be improved in quality through factory production, and can be dismantled, transported, and reinstalled through the recycling of module units, thereby reducing costs and reducing carbon emissions during the construction stage. It is widely applied to.

1 is a schematic perspective view showing a bonding structure of a conventional building modular unit, Figure 2 is a detailed view of the bonding portion of the modular unit of FIG.

As shown in the example shown in Figure 1, the modular unit 10 constituting the conventional modular building is basically composed of a beam 11 consisting of a web and a flange and a column 12 of the square tube, the beam is a slab (mido Is installed. At this time, as a method for connecting the upper and lower modular units, as shown in the example shown in Figure 2, the upper and lower end plates by welding the end plate 15, which is a joining iron plate separately to the joint of the upper and lower pillars 12 The bolt 15 can be fastened and assembled.

However, the bonding method of the upper and lower modular units using the separate end plate has a problem in that the production time of the unit in the factory is increased due to the increase of the welding point because the separate end plate must be welded to the pillar member.

On the other hand, although not shown in the prior art, as a method for connecting the lower modular unit, by forming a mouth hole which is a through hole penetrating through the inside, the outside in a portion adjacent to the junction of the pillar in the field by the operator in the field through the mouse hole There is a method of bolting the end plate of the upper and lower pillars by hand.

However, the method of using the mouse hole has a problem that the work hole in the field is inferior when the mouse hole is formed for bolting and the bolt hole is shielded when the bolt assembly is completed.

In addition, the modular unit joining method using the separate end plate, or the joining method using the mouse hole to adjust the position of the upper modular unit by using a crane during the site construction and to adjust the position of the upper and lower bolt holes However, there is a problem that precise construction is difficult by moving the module of weight.

In addition, when the upper and lower modular units are joined by the high-strength bolt coupling, it is difficult to separate the modular units and damage may occur to the structural members even when the high-strength bolts are coupled, thereby making it difficult to reuse the units or reposition the modular units.

The present invention has been proposed in order to solve the conventional problems as described above, the object of the aspect is to complete the joining process by fitting the connection member to facilitate the construction in the field and shorten the air, the coupling of the connection member or An object of the present invention is to provide a construction module and a joint structure of the building module, which are configured to be easily separated and easy to reuse or rearrange even after the building module is joined.

In another aspect, the present invention, by forming an inclined portion in the joint end of the upper and lower pillars to facilitate position adjustment between the upper and lower modules through self-centering of the upper and lower pillars, the position is maintained in the bonded state without bolt assembly To provide a building module and a joint structure of the building module.

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As a technical aspect for achieving the above object, the present invention, in the joint structure of the building module having a column coupled to a plurality of beams, the first insertion groove is formed on the lower side, the first having an inclined surface at the bottom An upper building module having an upper column coupled to an end plate, and a second insertion groove formed at an upper side thereof, and having a lower column coupled to a second end plate having an inclined surface formed to contact the first end plate at an upper end thereof. Undercarriage modules; And a connecting member connecting the upper building module and the lower building module by inserting and inserting the first end plate and the second end plate, wherein the connecting member includes: the first end plate and the first end plate; And a connecting groove into which a second end plate is inserted, wherein the upper pillar is seated on the lower pillar and is brought into the lower pillar by frictional force of a surface where the first end plate and the second end plate are in contact with each other. The compressive force is transmitted, the connection member provides a building module joint structure that is detachably coupled to facilitate disassembly of the building module.
Preferably, the connection member, the inclined surface of the shape corresponding to the inclined surface of the first end plate and the second end plate may be formed.

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More preferably, the upper column is formed with a coupling groove having an inclined surface at the lower end, the first end plate may be provided with an inclined portion corresponding to the inclined surface to be coupled to the coupling groove.

Also preferably, the lower pillar has a coupling protrusion having an inclined surface corresponding to the coupling groove at an upper end thereof, and the second end plate has an inclined portion corresponding to the inclined surface of the coupling protrusion to be coupled to the coupling protrusion. It can be provided.

On the other hand, preferably, the first end plate has a first fitting groove formed at one end corresponding to the first insertion groove so that the connection member is fitted, the second end plate is the first member so that the connection member is fitted A second fitting groove may be formed at one end corresponding to the fitting groove.

According to the joint structure of the building module and the building module according to an embodiment of the present invention, the joining process is completed by inserting the connecting member to the first end plate and the second end plate, so that the joining construction in the field is easy, The effect of shortening the air can be obtained.

In addition, according to an embodiment of the present invention, since the connection member is configured to facilitate not only coupling but also separation, an advantageous effect of reusing the building module constituting the modular building or repositioning the building module after bonding may be obtained.

In addition, according to an embodiment of the present invention, by the inclined portion of the first and second end plates, the self-centering of the upper and lower pillars can be made smoothly without the work of adjusting the position of the bolt hole, the bonding without the bolt assembly In this state, the position can be maintained.

1 is a schematic perspective view showing a bonding configuration of a conventional building modular unit.
FIG. 2 is a detailed view of the joint between the modular units of FIG. 1. FIG.
3 is a schematic perspective view showing a building module according to an embodiment of the present invention.
Figure 4 is an exploded perspective view showing the structure of the junction of the building module according to an embodiment of the present invention.
5 and 6 are cross-sectional views showing the junction structure of the building module according to an embodiment of the present invention.
7 is a perspective view showing a connecting member applied to the joint structure of the building module according to an embodiment of the present invention.

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

Firstly, the embodiments described below are suitable for understanding the technical features of the building module and the joint structure of the building module of the present invention. 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.

Building module 100 according to an embodiment of the present invention, as in the embodiment shown in Figure 3, includes a column 101 and the beam 103. Building module 100 according to an embodiment of the present invention can be laminated and bonded in a vertical direction or a horizontal direction to form a modular building.

The pillars 101 may be formed in plural, and the plurality of pillars 101 may have the same length as each other.

In addition, the pillar 101 may include end plates 120 and 140 having inclined portions at both ends thereof. In addition, fitting grooves 121 and 141 may be formed in the inclined portions of the end plates 120 and 140 to insert connection members (see reference numeral 250 of FIGS. 4 and 7) connecting upper and lower pillars.

That is, when the building module 100 is joined up and down, the upper and lower building modules 210 and 230 joined by the inclined portions of the end plates 120 and 140 coupled to both ends of the column 101. The center of the pillar 101 can be automatically adjusted. In this case, the inclined portions of the end plates 120 and 140 may be formed in the same direction as shown in FIG. 3A, but as shown in FIG. 3B, the inclined portions of the at least one pillar are formed in different directions to form left and right sides. Self-centering in the front and rear direction as well as the direction is possible, and can prevent the slippage between modules that can occur in the vertical direction in the inclined portion.

In addition, the upper and lower building modules 210 and 230 are connected to each other by using the detachable connecting member 250. In this case, the inclined portions of the end plates 120 and 140 may be fitted to the connecting members 250. Some of the fitting grooves 121 and 141 may be formed. Detailed description of the connection member 250 will be described later.

As shown in FIGS. 3 to 6, the end plates 120 and 140 may have an inverted 'V' shape having a high central portion and low both sides. In addition, the length of the fitting grooves (121, 141) is preferably formed in less than half of the end plate in order to maintain the strength of the end plates (120,140) and the connecting member (250). The thickness of the end plates 120 and 140 may be thickened to prevent a decrease in strength due to the formation of the fitting grooves.

However, the shape and angle of the inclined portion of the end plates (120, 140) and the shape of the fitting grooves (121, 141) is not limited to the case shown, the center of the pillar of the upper, lower building module (210, 230) If the connection member 250 can be fitted and fitted, various modifications are possible.

In addition, the pillars 101 may include insertion grooves 111 and 131 penetrating inside and outside of both ends corresponding to the fitting grooves 121 and 141 so that the connection members 250 connecting the upper and lower pillars are inserted. have.

That is, the insertion grooves 111 and 131 may be formed at side surfaces of the fitting grooves 121 and 141. The connecting member 250 is connected to the fitting grooves 121 and 141 and the insertion grooves 111 and 131 at the same time to connect the end plates 120 and 140 coupled to the ends of the pillars. Can be connected.

On the other hand, referring to Figure 3, the beam 103 is coupled to the pillar 101, it may be made of a plurality. In this case, the plurality of beams 103 may include long side beams and short side beams having different lengths, and the plurality of beams 103 may include four ceiling beams and the pillars disposed on top of the pillars 101. 101 may include four bottom beams disposed at the bottom.

In addition, FIG. 3 is shown a '''shaped beam formed of a web and a flange, the shape of the beam 103 is not limited to this, if it can be bonded to the pillar 101 to form a building module, Modified implementations are possible, for example 'H' section beams or 'I' section beams can be joined.

On the other hand, with reference to Figures 3 to 7, below, looks at with respect to the junction structure 200 of the building module according to another aspect of the present invention.

Junction structure 200 of the building module according to an embodiment of the present invention, as shown in Figures 4 to 6, the upper building module 210, the lower building module 230 and the connection member And 250.

The upper building module 210 may be configured to include a first insertion groove 111 is formed on the lower side, the upper column 110 coupled to the first end plate 120 at the bottom. The lower building module 230 has a second insertion groove 131 formed at an upper side thereof, and a lower column 130 having a second end plate 140 coupled to the first end plate 120 at an upper end thereof. It may be configured to include).

That is, the junction structure 200 of the building module according to an embodiment of the present invention is a structure for the junction of the upper pillar 110 constituting the upper building module 210 and the lower pillar constituting the lower building module. to be.

At this time, the first insertion groove 111 and the second insertion groove 131 is formed through the inner and outer ends of the upper pillar 110 and the lower pillar 130, and the upper pillar 110 and When the lower column 130 is bonded to form a hole into which the connection member 250 can be inserted.

In addition, the first end plate 120 and the second end plate 140 are coupled to the lower end of the upper column 110 and the upper end of the lower column 130, and the upper building module 210 and the When the lower building module 230 is bonded, the first end plate 120 and the second end plate 140 come into contact with each other. In addition, the vertical load of the upper building module 210 is transmitted to the lower building module 230 by the first and second end plates 140.

At this time, since the compressive force due to the vertical load is tolerated by the frictional force of the first and second end plates 140, the first and second end plates 120 and 140 may be formed relatively thick.

On the other hand, the connection member 250, as in the embodiment shown in Figures 5 to 7, the first end plate 120 and the second end plate 140 is inserted into the upper construction The module 210 and the lower building module 230 may be connected. In this case, the connection member 250 may be detachably coupled to facilitate disassembly of the building module.

Accordingly, the connecting member 250 is coupled to the first end plate 120 and the second end plate 140 by the tensile force is applied to the junction of the upper and lower building modules (210, 230) by the lateral force, etc. If so, it is configured to resist the tensile force.

In this case, the connection member 250 may include a connection groove 251 into which the first end plate 120 and the second end plate 140 are inserted.

That is, the connection groove 251 may be formed to open to one side of the connection member 250, the thickness of the connection groove 251 is the first end plate 120 and the second end plate 140. ) May be formed to have a size equal to the combined thickness so as to easily insert or detach the first and second end plates 120 and 140 joined together.

In the construction module joint structure 200 as described above, the joining process is completed by fitting the connecting members 250 to the first and second end plates 120 and 140, so that the construction of the joining part in the field is easy and the air is shortened. The effect can be obtained.

In addition, since the connection member 250 is configured to facilitate not only coupling but also separation, it is possible to reuse the building module constituting the modular building or to easily rearrange the building module after bonding.

On the other hand, the upper column 110 may be formed with a coupling groove 113 having an inclined surface at the bottom. In addition, the first end plate 120 may include an inclined portion having a shape corresponding to the inclined surface to be coupled to the coupling groove 113.

That is, the lower surface of the upper pillar 110 may be configured in a triangular shape having, for example, inclined surfaces on both sides, and the inclined surface is formed inward of the upper pillar 110 to form a coupling groove 113. can do. In addition, the first end plate 120 may be coupled to the lower end of the upper pillar 110 by having an inclined portion according to the shape of the lower surface of the upper pillar 110.

In addition, the lower column 130 may have a coupling protrusion 133 having an inclined surface having a shape corresponding to the coupling groove 113 at an upper end thereof. In addition, the second end plate 140 may include an inclined portion corresponding to the inclined surface of the coupling protrusion 133 to be coupled to the coupling protrusion 133.

That is, the lower column 130 may be inclined to both sides to form a triangular shape, for example, such as the upper column 110 on the upper surface, the inclined surface is formed to the outer side of the lower column 130 is coupled The protrusion 133 may be formed. At this time, the shape of the coupling protrusion 133 may be formed in the same shape as the coupling groove 113 to be fitted to the coupling groove 113 of the lower surface of the upper pillar (110). In addition, the second end plate 140 may include an inclined portion corresponding to the inclined surface of the coupling protrusion 133 to be coupled to the coupling protrusion 133.

As described above, the first end plate 120 and the second end plate 140 having the same inclined portion at the junction of the upper pillar 110 and the lower pillar 130 are coupled to each other, thereby forming the upper construction. The module 210 and the lower building module 230 can be smoothly self-centering without adjusting the position of the bolt hole, it is possible to obtain the effect that the position is fixed in the bonded state without the bolt assembly by the inclined portion. .

On the other hand, the first end plate 120 may be formed with a first fitting groove 121 at one end corresponding to the first insertion groove 111 so that the connection member 250 is fitted. In addition, the second end plate 140 may be formed with a second fitting groove 141 at one end corresponding to the first fitting groove 121 so that the connection member 250 is fitted.

In this case, the first fitting groove 121 and the second fitting groove 141 may be formed on the inclined portions of the first end plate 120 and the second end plate 140, preferably The first end plate 120 and the second end plate 140 may be formed at the middle edges of both inclined surfaces that are the center.

The first fitting groove 121 and the second fitting groove 141 may be formed to have the same width as that of the first insertion groove 111 and the second insertion groove 131. When the lower building module is joined, the connection member 250 may be formed together with the first insertion groove 111 and the second insertion groove 131. In this case, the first fitting groove 121 and the second fitting groove 141 may be fitted with the other side of the connection member 250 in which the connection groove 251 is not formed.

However, the shape, position, and size of the first fitting groove 121 and the second fitting groove 141 are not limited to those shown in the drawings, and the connection member 250 may be fitted into various shapes and shapes. Modifications can be made in size or the like.

According to the joint structure of the building module and the building module according to an embodiment of the present invention, the joining process is completed by inserting the connecting member to the first end plate and the second end plate, so that the joining construction in the field is easy, The effect of shortening the air can be obtained. In addition, the connection member is configured to facilitate as well as detachment as well as coupling, it is possible to reuse the building module constituting a modular building or to disassemble the building module after bonding can be obtained an advantageous effect that is easy to relocate.

And, by the inclined portion of the first and second end plate, the self-centering of the upper and lower pillars can be made smoothly without the work to match the position of the bolt hole, the effect of maintaining the position in the bonded state without the bolt assembly You can get it.

While the invention has been shown and described in connection with specific embodiments so far, it will be appreciated that the invention can be variously modified and varied 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: building module 110: upper pillar
111: first insertion groove 120: first end plate
121: first fitting groove 130: lower column
131: second insertion groove 140: second end plate
141: second fitting groove 200: construction module joint structure
210: upper building module 230: lower building module
250: connecting member 251: connecting groove

Claims (7)

delete delete In the joint structure of the building module having a column coupled to a plurality of beams,
An upper building module having a first insertion groove formed on a lower side thereof, and having an upper column coupled to a first end plate having an inclined surface at a lower end thereof;
A lower building module having a second pillar formed on an upper side thereof, and having a lower column coupled to a second end plate having an inclined surface formed thereon so as to contact the first end plate; And,
And a connecting member connecting the upper building module and the lower building module by inserting and inserting the first end plate and the second end plate.
The connecting member includes a connecting groove into which the first end plate and the second end plate are inserted.
The upper column is seated on the lower column, the compressive force is transmitted from the upper column to the lower column by the frictional force of the surface in contact with the first end plate and the second end plate, the connection member of the building module Construction module joint structure that is detachably coupled to facilitate disassembly. The method of claim 3,
The connecting member, the building module junction structure, characterized in that the inclined surface of the shape corresponding to the inclined surface of the first end plate and the second end plate. The method according to claim 3 or 4,
The upper column is formed with a coupling groove having an inclined surface at the bottom,
And the first end plate has an inclined portion corresponding to the inclined surface to be coupled to the coupling groove. The method of claim 5,
The lower column is formed with a coupling protrusion having an inclined surface corresponding to the coupling groove on the upper end,
And the second end plate has an inclined portion corresponding to an inclined surface of the engaging protrusion to engage with the engaging protrusion. The method according to claim 3 or 4,
The first end plate has a first fitting groove is formed at one end corresponding to the first insertion groove so that the connection member is fitted,
And the second end plate has a second fitting groove formed at one end corresponding to the first fitting groove so that the connection member is fitted therein.

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