KR100950460B1 - Dome style lightweight iron frame infrastructure - Google Patents

Abstract

PURPOSE: A dome type lightweight steel-frame structure is provided to disperse the heavy load and strong wind applies on a roof by forming the roof in dome shape. CONSTITUTION: A dome type lightweight steel-frame structure comprises a support beam(10) and a loop-frame. The support beam is vertically installed in two rows. The intensity of the support beam is reinforced by forming bead parts on one side in longitudinal direction. The loop-frame is installed on the support beam in dome shape. The loop-frame comprises a rafter beam(20) and a plurality of cross beams. The rafter beam is connected to the support beam in the dome shape. The cross beam is vertically installed on the rafter beam.

Description

Dome style lightweight iron frame infrastructure

The present invention relates to a domed lightweight steel structure, and more particularly, to a domed lightweight steel structure that is able to withstand load or wind pressure due to snowfall by constituting a structurally stable temporary structural structure.

In general, temporary construction is a structure that is installed to secure space inside, such as a warehouse or hangar, such as building a structure using wood, panels, or a tent made of synthetic resin fabric in a frame made of reinforced pipes, etc. To build the structure.

Such a building structure is typically formed in the shape of a "∧" shape of the roof, so that foreign matters such as rain or snow can flow down well.

However, when the roof of such a temporary structure is low in slope, the snow on the roof does not flow down and freezes as it is on the roof instead of under the wind pressure. Therefore, the snow accumulated on the roof is frozen on the entire surface of the roof. Since it acts as a load over the end of the roof was not able to withstand the snow load snowfall, there was a disadvantage that the building structure can collapse.

Therefore, in the above case, snow removal work is always required to remove snow accumulated on the roof, but this snow removal work takes a lot of labor and time, and in the snowy winter, frequent snow removal works may cause problems. there was.

In addition, when the slope of the roof is formed high, the snow falling on the roof flows well in the above-described forecasting stage, so that the snow is not damaged by snow, but the entire area of the roof vertically formed vertically is affected by the wind pressure. When a strong wind or momentary gusts act on the roof, the roof could shatter and collapse.

In addition, in the conventional temporary construction structure, a plurality of vertically installed posts and posts forming a loop frame are joined together to be welded to each other so that assembly and dismantling are inconvenient and cumbersome. Damage and breakage were added, so the material could hardly be reused or had a significantly low reuse rate.

Accordingly, the present invention has been made to solve the problems of the prior art as described above, by forming the roof of the temporary building structure in the form of a dome, not only the load applied to the roof is distributed but also the wind pressure acting on the roof to the periphery It is an object of the present invention to provide a domed lightweight steel structure having structural stability that can be firmly withstand load or wind pressure because it is dispersed.

Further, another object of the present invention, by assembling a plurality of pillars constituting the domed lightweight steel structure by bolt assembly through the bracket not only easy to assemble and dismantle, but also to prevent damage of the material during dismantling reuse of the entire amount of the material To provide a possible domed lightweight steel structure.

The above object is, in the domed lightweight steel structure, the holding beam is installed in two or more rows; And a roof frame installed in a dome shape on the strut beam.

The loop frame includes a plurality of rafter beams that are continuously connected and rounded on the support beam; And a plurality of purlin beams installed to connect between the plurality of rafter beams.

In addition, a plurality of intermediate holding beams are installed between both rows of the holding beams, and the intermediate holding beams are installed on the rafter beams through the bent fixed angles, between the holding beams and the rafter beams, and between the plurality of rafter beams. A bent bracket connecting two adjacent beams is installed, and the bracket is formed with a bead portion and a reinforcement panel portion for strength reinforcement.

A wire rope is connected between the adjacent beams of both beams and the beam beams, and a turnbuckle is provided between the beams and the wire ropes to adjust the length of the wire ropes.

According to the domed lightweight steel structure of the present invention, the roof of the temporary building structure is formed in the shape of a dome interconnected with each of the beams and purlin beams, so that not only the load acting on the roof is distributed but also the wind pressure flows through the roof. However, there is an advantage of having structural stability that can withstand strong wind pressure.

In addition, the domed lightweight steel structure of the present invention is not only easy to assemble and dismantle the temporary construction structure, but also breakage of materials during disassembly by connecting the plurality of strut beams, rafter beams, purlin beams, brackets, etc. Since it is prevented, all materials can be reused.

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

1 to 5 are views showing a domed lightweight steel structure according to the present invention.

As shown in FIG. 1, the domed lightweight steel structure of the present invention is composed of a prop beam 10 installed vertically in two or more rows and a loop frame installed in a dome shape on the prop beam 10. do.

The pillar beam 10 is a beam installed in two or more rows on a base plate (not shown) installed on the ground to form a bottom surface of a domed lightweight steel structure, and approximately "]" for strength reinforcement. The beam and the "[" shaped beam are formed in a "I" form or a "H" form, butt-coupled to each other.

In addition, a plurality of bead portions 10a are formed along one side of the strut beam 10 along the longitudinal direction of the strut beam 10 to reinforce the strength of the strut beam 10.

In addition, a plurality of horizontal supports 40 are installed between the strut beams 10 arranged as described above and vertically connected to the strut beams 10 to support the plurality of strut beams 10.

The loop frame includes a rafter beam 20 continuously connected to two rows of strut beams 10 and installed in a round shape in a dome shape, and is vertically installed on the plurality of rafter beams 20. It includes a plurality of purlin beams 21 to connect.

Here, the rafter beam 20 is formed in the form of "I" or "H" in which the "]" beam and the "[" ruler beam are butt-coupled to each other like the above-described post beam 10, thereby reinforcing strength. Meanwhile, at least one bead part 20a is formed along one side of the rafter beam 20 along the longitudinal direction of the rafter beam 20 to further reinforce the intensity of the rafter beam 10.

In addition, an eave bracket 50 is installed between the rafter beam 20 and the support beam 10 to connect both beams.

As shown in FIG. 3, the eave bracket 50 is bent to correspond to an angle formed by the holding beam 10 and the rafter beam 20 as a steel plate, and a plurality of bead portions 51 are formed on the surface thereof. Is formed to reinforce the strength of the eaves bracket (50). At this time, the bead portion 51 is formed along the longitudinal direction of the eaves bracket 50 is positioned perpendicular to the load acting on the domed lightweight steel structure, thereby having a strong strength against the load. In addition, the bending portion of the eaves bracket 50 is integrally formed with a reinforcing panel portion 52 connecting the two bending portions to reinforce the bending strength with respect to the load.

Meanwhile, although the eave bracket 50 formed as described above is illustrated as a pair of eave brackets 50 coupled to each other in FIG. 3, one eave bracket 50 may be used alone.

In addition, the ridge bracket 60 for connecting the rafters beams 20 of both sides is installed between the rafters beams 20 connected in a round, the ridge bracket 60 is the same as the eaves bracket 50 described above. Is formed, but the bent angle is formed more gently than the eaves bracket (50).

That is, as shown in FIG. 4, the ridged bracket 60 is formed to be bent to correspond to an angle formed by both the rafter beams 20 as a steel plate, similar to the eaves bracket 50 described above, and a plurality or more thereof are formed on the surface thereof. The bead portion 61 is formed along the longitudinal direction of the ridged bracket 60 to have a strong strength against the load, and the bent portion of the ridged bracket 60 is formed at both bent portions to reinforce the bending strength against the load. Reinforcing panel portion 62 for connecting the integrally formed.

Like the above-mentioned eave bracket 50, the ridged bracket 60 also shows a form in which a pair of ridged brackets 60 are combined in FIG. 4, but one ridged bracket 60 may be used alone.

On the other hand, the eaves bracket 50 and the ridged bracket 60 formed in this way are sandwiched between the "]" and "[" ruler beams, both ends of which constitute the prop beam 10 and the rafter beam 20, respectively. It is assembled and installed.

In addition, the unit area formed by the support beam 10 and the horizontal support 40 and the unit area formed by the rafter beam 20 and the purlin beam 21 are configured to prevent warpage to prevent deformation of the structure. 5 shows an example of the warp preventing means provided in the unit area formed by the rafter beam 20 and the purlin beam 21.

As shown in FIG. 5, the warp preventing means is installed between the two rafter beams 20 adjacent to each other back and forth in a substantially "와이어" shape, and the rafter beam 20 and the wire rope ( Between the 70 is a turnbuckle 71 is connected to be installed to adjust the length of the wire rope 70. Accordingly, as the turnbuckle 71 rotates, the wire rope 70 may be pulled or unrolled to adjust the tension of the wire rope 70 acting between the beam beams 20. On the other hand, the tension of the wire rope 70 is able to prevent the deformation of the rafter beam 20 against the load by steadily supporting the rafter beam 20 on both sides.

And, although not shown in the drawings, such warp preventing means is preferably installed between the two holding beams 10 as described above, it is preferable to function as described above.

Meanwhile, as shown in FIG. 2, a plurality of intermediate holding beams 30 are installed between two rows of holding beams 10, and an upper end of the intermediate holding beams 30 is bent through a fixed angle 31. Removably coupled to the rafter beam 20 as a bolt 80 and a nut 81 is installed.

In addition, a plurality of bead portions 30a are formed at one side of the intermediate support beam 30 along the longitudinal direction of the intermediate support beam 30 to reinforce the strength of the intermediate support beam 30 and the fixed angle. A bead portion for reinforcing the strength of the fixed angle 31 may also be formed on one side of the 31, and may be installed between the fixed angle 31 and the rafter beam 20 via a separate reinforcement plate 32. have.

In addition, between the support beam 10 and the intermediate support beam 30 is connected to the support beam 10 and the intermediate support beam 30 perpendicular to the zinc supporting the support beam 10 and the intermediate support beam 30. A plurality of horizontal support 40 formed of steel is installed. At this time, the horizontal support 40 is installed through the fixing bracket 41 of the "b" or "T" shape in the portion that is in contact with or intersecting the holding beam 10 and the intermediate holding beam 30, the fixed The brackets 41 are coupled to the beams 10 and 30 and the horizontal support 40 as bolts 80 and nuts 81, respectively. In addition, the fixing bracket 41 may be formed with a bead portion for reinforcing the strength of the fixing bracket (41).

It describes the installation process of the intermittent shaft structure of the present invention configured as described above.

First, the eaves bracket 50 and the fixed angle 31 are assembled to the upper ends of the prop beam 10 and the intermediate beam 30, respectively, and then the prop beam 10 and the intermediate beam 30 are placed on the ground. On each of the installed base plates (not shown), they are assembled and installed as bolts 80 and nuts 81, respectively.

At this time, the eaves bracket 50 is fitted between one end of the "]" beam and the "[" ruler beam constituting the support beam 10, while the other end "assembles the rafter beam 20 to be described later. ] Are assembled between the "[") beam and the "[" beam.

The horizontal support 40 is bolted and installed between the support beam 10 and the intermediate support beam 30 installed as described above through the fixing bracket 41.

Thereafter, the roof frame of the domed lightweight steel structure on the ground, that is to assemble the rafters beams 20 to form a roof using the ridge bracket 60, the both ends of the ridge bracket 60 constitutes the rafters beam 20, respectively. ] Are assembled between the "[") beam and the "[" beam.

One side of the rafter beam 20 assembled as described above is first assembled to the holding beam 10, and the other side of the rafter beam 20 is continuously assembled using the ridge bracket 60 as described above. Form round to form.

Thereafter, a plurality of rafter beams 20 rounded in a dome shape are assembled with a purlin beam 21 to vertically cross the rafter beam 20, and the assembling of the strut beam 10 and the rafter beam 20 is performed. After completion, the other reinforcing materials (not shown) are assembled, and the tents (not shown), plates (not shown), sandwich panels (not shown), etc., which are common on the inner and outer sides of the assembled domed lightweight steel structure are assembled. The installation of the domed lightweight steel structure is completed.

Therefore, the domed lightweight steel structure of the present invention installed as described above is not only to distribute the load acting on the roof by the roof is formed in the shape of the dome, but also the wind pressure is also distributed through the roof, a plurality of pillars constituting the domed lightweight steel structure Beam 10, rafter beam 20, purlin beam 21, eave bracket 50, ridge bracket 60, etc. are assembled as bolt 80 and nut 81 to assemble and dismantle the domed lightweight steel structure. Not only is it easy to use, but it also prevents material damage during disassembly, thereby improving the reuse rate of the material.

1 is a block diagram showing the structure of a domed lightweight steel structure according to the present invention.

FIG. 2 is a view showing the "A" part of FIG. 1, and is a structural diagram showing a connection state between the intermediate column beam and the rafter beam.

FIG. 3 is a view illustrating the “B” portion of FIG. 1 and illustrating the eave bracket connecting the prop beam and the rafter beam.

FIG. 4 is a view illustrating the "C" part of FIG. 1 and illustrating the ridged bracket connecting the rafter beams forming the loop frame.

5 is a view showing the bending prevention means of the domed lightweight steel structure according to the present invention.

<Description of the symbols for the main parts of the drawings>

10: prop beam 10a: bead part

20: rafter beam 20a: bead part

21: dori beam 30: intermediate pillar beam

30a: Bead portion 31: fixed angle

32: reinforcing plate 40: horizontal support

41: fixed bracket 50: eave bracket

51: bead portion 52: reinforcement panel portion

60: dragon floor bracket 61: bead

62: reinforcement panel part 70: wire rope

71: turnbuckle 80: bolt

81: nuts

Claims (7)

In the domed lightweight steel structure, For the strength reinforcement, the prop beam 10 is installed in two or more rows in an " I " shape or " H " ) Includes a roof frame installed in a dome shape, The loop frame has a plurality of rafters which are formed in a "I" form or a "H" form in which the "]" and "[") beams are butt-coupled to each other on the strut beam 10, and are continuously connected and rounded. And a plurality of purlin beams 21 installed to connect the beams 20 and the plurality of rafter beams 20, A plurality of intermediate holding beams 30 are installed between both rows of the support beams 10, and the intermediate holding beams 30 are installed on the rafter beams 20 through the bent fixed angles 31. Between the holding beam 10 and the rafter beam 20 and the plurality of rafter beams 20, the eave bracket 50 and the ridge bracket 60, which are bent to connect adjacent beams, are installed and the eave bracket ( 50) and the ridge bracket 60 are formed with bead portions 51 and 61 for strength reinforcement, respectively, and the bent portions of the eave bracket 50 and the ridge bracket 60 are for reinforcing bending strength against load. Reinforcement panel portions 52 and 62 are formed, respectively, and wire ropes 70 are connected to each other between the adjacent support beams 10 and the rafter beams 20, and the beams and the wire ropes 70 are provided. Domed lightweight steel structure, characterized in that the turnbuckle 71 is installed between the length of the wire rope 70 can be adjusted. delete delete delete delete delete delete

Images