KR20130013527A - Beam installation structure for reinforcement of self assembly tent - Google Patents

Abstract

PURPOSE: An installation structure of beam for reinforcing bearing capacity of a prefabricated pavilion construction is provided to reinforce a supporting force by a truss structure connection of a first beam and a second beam, to firmly support the prefabricated pavilion construction even in an unable situation. CONSTITUTION: An installation structure of beam for reinforcing bearing capacity of a prefabricated pavilion construction comprises a first beam(10), a second beam(20), a v-shaped connector(30), and a support pipe(40). The first beam is installed in a dome-shaped at the outside. The second beam is installed in a dome-shaped which is separated from the inner side of the first beam. A v-shaped connector is connected between the bottom of the first beam and the upper side of the second beam, and a prominent projecting piece which is protruded to a diagonal direction. A support pipe is coupled between the prominent projecting piece of the v-shaped connector.

Description

Beam installation structure for reinforcement of self assembly tent}

The present invention relates to a prefabricated tent structure, and more particularly, the beam is installed in the inner and outer double is connected to the truss structure through the combination of the 'V' type connector and the support pipe so that the support force can be reinforced without the installation of the pillar It relates to a beam installation structure for reinforcing the bearing capacity of the prefabricated tent structure.

Recently, there has been an increase in the installation of structures made of prefabricated tents with membranes to maintain tension between beams.

Structures made of such prefabricated tents have a lower material cost than ordinary structures, which not only lowers the construction cost, but also facilitate the operation, which shortens the construction period, and the appearance is unique, resulting in a unique aesthetic and durability. Excellent weather can be prepared for bad weather, easy to change size and shape, free from restrictions on installation space, and easy to remove and transfer after installation, exhibit facilities, airport facilities, factories It is widely applied to facilities, military facilities, port facilities, sports facilities, and shopping malls.

On the other hand, in the case of a very large prefabricated tent structure requires a considerable support, in the case of a prefabricated tent structure for any purpose that can be installed in the interior space can be secured by supporting the beam by installing a pillar, but the use of gymnasium, etc. In the case of the prefabricated tent structure, there is a problem that it is difficult to secure the bearing capacity of the beam because it can not be installed in the interior space.

For this reason, in the relevant field, the beam installation structure for reinforcing bearing capacity can be obtained without the installation of pillars in the construction process of the large prefabricated tent structure, but until now, the situation has not been satisfactory.

The present invention has been proposed in view of the above circumstances, to provide a beam installation structure for reinforcing the support capacity of the prefabricated tent structure to be able to reinforce the support force without the installation of the pillar in the construction process of the super-sized prefab tent structure. Is there.

Beam installation structure for reinforcing bearing capacity of the prefabricated tent structure according to the present invention for achieving the above object,

A first beam having an intermediate portion leading from both ends fixed in contact with the ground and positioned above the both ends is provided;

A second beam is provided inside the first beam, the middle portion of which is extended from both ends fixed to the ground and positioned above the both ends, the second beam having a constant distance from the inner surface of the first beam;

'V' type connectors having protrusions protruding obliquely toward the lower sides of the first beams on the bottom of the first beam are continuously provided at intervals along the longitudinal direction of the first beam;

The 'V' connector having the protruding pieces protruding obliquely toward the upper sides of the second beam on the upper surface of the second beam is continuously spaced along the longitudinal direction of the second beam between the 'V' connector of the first beam. Prepared;

The protrusion of the 'V' connector is inserted through the openings at both ends between the protrusion of the 'V' connector provided in the first beam and the protrusion of the 'V' connector provided in the second beam adjacent thereto. It is characterized in that the support pipe is provided.

The beam installation structure for reinforcing the bearing capacity of the prefabricated tent structure according to the present invention is provided with a 'V' type connector having a protruding piece formed on the bottom surface of the first beam located outside and the top surface of the second beam located inside the first beam. Since the support pipe is zigzag-connected between the 'V' type connector protrusion of the first beam and the 'V' type connector protrusion of the second beam to be connected in a truss structure, the truss structure of the first beam and the second beam is connected. By the reinforcement of the bearing force can be made by the situation that can not be installed in the interior of the prefab tent structure there is an effect that the support of the prefab tent structure can be made solid.

1 is a schematic view showing a beam installation to which the beam mounting structure for reinforcing bearing capacity of the prefabricated tent structure according to the present invention
Figure 2 is a cross-sectional view for explaining the structure of the first beam and the second beam in the beam installation structure for reinforcing the bearing capacity of the assembled tent structure according to the present invention
3 is a cross-sectional view showing a 'V' type connector in the beam installation structure for reinforcing bearing capacity of the prefabricated tent structure according to the present invention.
Figure 4 is a cross-sectional view showing a support pipe in the beam installation structure for reinforcing the bearing capacity of the prefabricated tent structure according to the present invention.
5 is a cross-sectional view of the support pipe is installed using the 'V' type connector to the first beam in the beam installation structure for reinforcing the supporting force of the prefabricated tent structure according to the present invention.
Figure 6 is a cross-sectional view of the installation of the bellows pipe using the 'V' type connector to the second beam in the beam installation structure for reinforcing the supporting force of the prefabricated tent structure according to the present invention.
Figure 7 is a cross-sectional view for explaining the coupling of the support pipe to the 'V' type connector protrusion in the beam installation structure for reinforcing the supporting force of the prefabricated tent structure according to the present invention

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

As shown in FIG. 1, the beam installation structure for reinforcing the supporting force of the assembled tent structure according to the present invention includes a first beam 10, a second beam 20, a 'V' type connector 30, and a support. It consists of a pipe 40.

The first beam 10 has a dome shape in which an intermediate portion leading from both ends fixed in contact with the ground is positioned above the both ends.

As shown in FIG. 1, the first beam is installed in a dome shape from the outside, and the second beam is installed in a dome shape while being spaced apart from the inside of the first beam.

The support pipe 40 is installed like a truss using the 'V' type connector 30 between the first beam and the second beam.

As shown in FIG. 2, the first beam 10 is a rope insertion hole 11a for insertion of a rope 51 provided along both longitudinal edges of the membrane 50 on both sides of the inner and outer flanges 11. Is formed, and the rope insertion holes 11a formed on both inner and outer flanges 11 of the first beam 10 and the rope insertion holes formed on both sides of the inner and outer flanges 11 of the other first beam 10 adjacent thereto ( Both ropes 51 of the membrane 50 are inserted between 11a) so that the membrane 50 is in tension between the first beam 10 and the other first beam 10 adjacent thereto. .

The second beam 20 is located inside the first beam 10, and the intermediate part leading from both ends fixed in contact with the ground is positioned above the both ends to form a dome shape as a whole, and the outer surface thereof is the first beam. It maintains a constant space | interval from the inner surface of (10).

As shown in FIG. 2, the second beam 20 is a rope insertion hole 21a for inserting the rope 51 provided along the longitudinal edge of the membrane 50 on both sides of the flange 21 on the inner and outer sides. Is formed, and the rope insertion ports 21a formed at both sides of the inner and outer flanges 21 of the second beam 20 and the rope insertion holes formed at both sides of the inner and outer flanges 21 of the other second beam 20 adjacent thereto ( Both ropes 51 of the membrane 50 are inserted between 21a) so that the membrane 50 is in tension between the second beam 20 and the other second beam 20 adjacent thereto. .

The 'V' type connector 30 is coupled to the bottom surface of the first beam 10 and the upper surface of the second beam 20, a plurality of protruding pieces 31 protruding in the diagonal direction is formed on both sides.

The 'V' type connector 30 is the protrusion piece 31 is directed downward when the continuous coupling at the bottom surface of the first beam 10, the gap on the upper surface of the second beam (20) When the projection pieces 31 are continuously coupled to the upper portion, the 'V' type connector 30 of the second beam 20 is interposed between the 'V' type connector 30 of the first beam 10. It is located in.

When the 'V' type connector 30 is coupled to the bottom surface of the first beam 10, the projection piece 31 is directed downward, when the projection piece 31 is coupled to the top surface of the second beam 20 Facing upward, the 'V' connector 30 of the second beam 20 is positioned between the 'V' connector 30 of the first beam 10 so that one 'V of the first beam 10 is located. The support pipe 40 has a zigzag shape between the protrusion 31 formed in the 'type connector 30 and the protrusion piece 31 formed in the' V 'type connector 30 of the second beam 20 adjacent thereto. Can be combined to form a truss structure.

On the other hand, it is preferable that a pair of reinforcement teeth 32 are provided on the inner side surfaces of both protruding pieces 31 on the inner surfaces of both protruding pieces 31 of the 'V' type connector 30, It is preferable that a through hole 33 is provided at the center between the two protruding pieces 31 of the 'V' type connector 30.

The reinforcement teeth formed on both side protruding pieces 31 of the 'V' type connector 30 are formed in pairs on the inside of the protruding piece and the reinforcing bar is not formed on the bottom surface on which the through hole 33 is formed.

Protruding piece is provided by a pair of reinforcing bar 32 formed on one inner side of the protrusion 31 and the inner side of the other protrusion piece 31 on the inner surface of the both sides of the protrusion (31) of the 'V' type connector (30). It is possible to prevent the 31 to be bent or bent, and the through-hole 33 is provided in the center between the two protruding pieces 31 of the 'V' type connector 30 directly through the through-hole 33 Binding of the 'V' type connector 30 to the first beam 10 and the second beam 20 can be achieved.

In addition, the support pipe 40 shown in FIG. 4 has a protrusion V 31 of the 'V' type connector 30 provided in the first beam 10 and a 'V' provided in the second beam 20 adjacent thereto. It is coupled between the protruding pieces 31 of the type connector 30, the protruding piece 31 of the 'V' type connector 30 is inserted through the opening 41 of both ends is coupled as shown in FIG.

It is preferable that through holes 42 are provided at both ends of the support pipe 40 as shown in FIGS. 5 and 6, respectively, and protruding pieces of the 'V' type connector 30 inside the opening 41. It is preferable that the insertion groove 41a is provided close to the 31.

Through holes 42 are provided at both ends of the support pipe 40, respectively, through the through holes 42 in the state in which the protruding pieces 31 of the 'V' type connector 30 are inserted at both ends of the support pipe 40. By fastening the direct screw 43, the support pipe 40 can be bound on the protruding piece 31 of the 'V' type connector 30, and inside the opening 41 of the support pipe 40. Since the insertion groove 41a is provided in close contact with the protruding piece 31 of the 'V' type connector 30, the protruding piece of the 'V' type connector 30 is formed in the opening 41 of both ends of the support pipe 40. 31) it is possible to prevent the flow of the support pipe 40 in the inserted state.

Referring to the beam installation according to the beam installation structure for reinforcing the bearing capacity of the prefabricated tent structure as described above in detail as follows.

First, the second beam 20 is generally installed in a dome shape inside the first beam 10 fixed to the ground in an upright state.

At this time, the installation form of the first beam and the second beam of the present invention is not necessarily limited to the dome shape, and may be installed in a quadrangular, triangular, dome shape or the like according to the installation form.

In the present invention, the inner side of the first beam 10 fixed to the ground in an upright state is in an open state, and then moves the second beam 20 to the inner side of the first beam 10 and then the second beam 20 of the second beam 20. When the upper surface is maintained at a constant distance from the bottom of the first beam 10, and then fixed to the ground both ends of the second beam 20, the second beam 20 in the dome-shaped upright inside the first beam 10 It can be fixed in a state.

Next, the 'V' type connector is coupled along the bottom surface of the first beam 10.

In the present invention, the 'V' type connector 30 is provided with a through hole 33 in the center between the projection pieces 31, as shown in FIG. 5, the projection piece 31 is lower on the bottom surface of the first beam 10. When the direct connection screw 34 is fastened through the through hole 33 after closely connecting the 'V' type connector 30 toward the 'V' type connector 30 along the bottom of the first beam 10, the coupling is made. It becomes possible.

Next, the 'V' type connector 30 is coupled along the upper surface of the second beam 20.

In the present invention, the 'V' type connector 30 is provided with a through hole 33 in the center between the protruding pieces 31 as described above, so as to be constant on the upper surface of the second beam 20 as shown in FIG. 6. When the protruding piece 31 closely connects the 'V' type connector 30 facing upwards and then fastens the direct screw 34 through the through hole 33, the 'V' along the upper surface of the second beam 20 The coupling of the 'type connector 30 can be made.

At this time, the 'V' type connector 30 coupled to the upper surface of the second beam 20 is continuous at intervals, between the 'V' type connector 30 coupled to the first beam 10. By being located in the 'V' type connector 30 of the first beam 10 and the 'V' type connector 30 of the second beam 20 it is possible to be alternately positioned.

Next, between the protruding piece 31 formed in the 'V' type connector 30 of the first beam 10 and the protruding piece 31 formed in the 'V' type connector 30 of the second beam 20. The support pipe 40 is coupled.

In the present invention, the opening 41 of both ends of the support pipe 40 is provided with an insertion groove 41a which is in close contact with the protruding piece 31 of the 'V' type connector 30, and both ends of the support pipe 40. Each is provided with a through-hole 42, so as shown in Figure 7 'V' type coupler coupled to the first beam 10 in the insertion groove (41a) provided in the upper opening 41 of the support pipe 40 The 'V' type connector 30 coupled to the second beam 20 in the insertion groove 41a provided in the lower opening 41 of the support pipe 40 by inserting the protruding piece 31 of the support pipe 40 therein. After inserting the protruding piece 31 and fastening the direct screw 43 to each of the through-holes 42 at both ends of the support pipe 40, the protruding piece formed on the 'V' type connector 30 of the first beam 10. The support pipe 40 can be coupled between the protrusion 31 formed in the '31' and the 'V' type connector 30 of the second beam 20.

By the above process, the second beam 20 maintains a constant distance from the first beam 10 inside the first beam 10 and is connected to the first beam 10 by the support pipe 40. As shown in FIG. 1, the support pipe 40 is coupled in a zigzag form between the first beam 10 and the second beam 20 to form a dome-shaped truss structure, so that the first beam 10 is Compared with the single installation, the supporting force can be reinforced, so that the support of the prefabricated tent structure can be firmly made without the installation of the pillar by being applied to the construction of the large prefabricated tent structure, which is difficult to install the pillar in the interior space such as a gymnasium.

Meanwhile, in the above description, after coupling the 'V' type connector 30 to the first beam 10 and the second beam 20 while the first beam 10 and the second beam 20 are fixed upright. Although the support pipe 40 has been described in the order of coupling the support pipe 40 to the protruding piece 31 of the 'V' type connector 30 coupled to the first beam 10 and the second beam 20, For example, the 'V' type connector 30 is coupled to the first beam 10 and the second beam 20 lying down, and the 'V' type connector is coupled to the first beam 10 and the second beam 20. After coupling the support pipe 40 to the protruding piece 31 of the 30 and the fixing of the first beam 10 and the second beam 20 in the upright state by the support pipe 40 and Likewise, the beams may be installed in a different order.

According to the present invention as described above, an army barrack, a warehouse, an aircraft hangar, an auditorium, a gymnasium, and the like can be installed as a prefab tent.

The present invention as described above is not limited to the above-described embodiments, and can be changed within the scope without departing from the gist of the present invention claimed in the claims, such changes are within the scope of the claims.

10: first beam 11: flange
11a: rope insertion hole 20: the second beam
21: flange 21a: rope insertion opening
30: 'V' type connector 31: protrusion
32: reinforcement 33: through
34: Direct connection thread 40: Support pipe
41: opening 41a: insertion groove
42: through hole 43: direct screw
50: membrane 51: rope

Claims (3)

A dome-shaped first beam 10 having an intermediate portion leading from both ends fixed in contact with the ground and positioned above both ends is provided;
The second beam 20 having an intermediate portion leading from both ends fixed in contact with the ground inside the first beam 10 above the both ends and maintaining a constant distance from the inner surface of the first beam 10. Is prepared;
'V' type connector 30 having protrusions 31 protruding obliquely toward the lower sides of the first beam 10 on the bottom of the first beam 10 is spaced along the length direction of the first beam 10. Provided continuously;
The 'V' type connector 30 of the first beam 10 has a 'V' type connector 30 having a protruding piece 31 protruding obliquely toward the upper sides of the second beam 20. Are continuously provided at intervals along the longitudinal direction of the second beam 20 between the gaps;
The protruding piece 3 of the 'V' type connector 30 provided in the first beam 10 and the protruding piece 31 of the 'V' type connector 30 provided in the second beam 20 adjacent thereto. Beam support for reinforcing the bearing capacity of the prefabricated tent structure, characterized in that the support pipe 40 is provided between the protrusion 41 of the 'V' type connector 30 is inserted through the opening 41 of both ends. rescue. The method of claim 1,
A pair of reinforcement teeth 32 are provided on the inclined surfaces of the both side protruding pieces 31 of the 'V' type connector 30, and directly connected to the center between the both side protruding pieces 31 of the 'V' type connector 30. Beam installation structure for reinforcing the bearing capacity of the prefabricated tent structure, characterized in that the through hole 33 is fastened to the screw 34 is provided. The method of claim 1,
Both ends of the support pipe 40 are provided with through holes 42 to which the direct screw 43 is fastened, respectively, and the opening 41 is in close contact with the protruding pieces 31 of the 'V' type connector 30. Beam installation structure for reinforcing the bearing capacity of the prefabricated tent structure, characterized in that the insertion groove (41a) is provided.

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