KR102314579B1 - Structural element of a building structure - Google Patents

Abstract

The present invention relates to a structural member disposed between multiple columns vertically installed to transmit a load to the columns. The structural member of the present invention comprises: a main beam composed of a first part having a vertical portion extending long and a flange vertically formed to be perpendicular to both widthwise ends of the vertical portion, and a second part integrated with and extending from the first part in a longitudinal direction and having a vertical portion having a smaller width than the vertical portion of the first part and a flange vertically formed at one widthwise end of a horizontal portion; and an auxiliary beam having a vertical portion extending long and a flange vertically formed at a widthwise end of the vertical portion. The auxiliary beam extends from a longitudinal end of the first part of the main beam along the second part of the main beam to have a certain inclination to a longitudinal direction of the main beam, the flange of the auxiliary beam and the flange of the second part of the main beam are disposed to face each other with the vertical portions of the auxiliary and main beams interposed therebetween, and the vertical portion of the auxiliary beam and the vertical portion of the second part of the main beam lie on the same plane. The structural member further comprises a coupling panel that is combined to both the horizontal portion of the second part of the main beam and a horizontal portion of the auxiliary beam to couple the auxiliary beam to the main beam.

Description

Structural members of a building structure

The present invention relates to a structural member of a building structure, and more particularly, to a structural member disposed horizontally between columns or vertical walls of a building structure to support a roof, a floor, or a ceiling.

Buildings such as factories, hangars, warehouses, or indoor gymnasiums are built in long spans with a distance of several tens of meters between vertical side walls or columns to secure internal space.

Such a long-span building structure is generally formed by installing a horizontal member disposed to be inclined horizontally at the tip of a column fixed vertically, forming a rafter, and attaching a roof panel on the rafter. In addition, a horizontal member connected horizontally between the pillars is installed, and a panel is installed on the horizontal member or concrete is poured to form a floor surface on which an article or equipment is placed.

The rafters must withstand the load of the roof panel as well as the load of snow accumulating on the roof and must be composed of a member having sufficient strength to withstand wind pressure. In addition, the floor surface should be configured to have sufficient strength to withstand the load where the article or equipment is placed.

As a structural member arranged horizontally in such a long span building structure, a section steel having flanges at both ends in the width direction, such as an H-beam or an I-beam, is mainly used. Section steel is mainly manufactured and supplied by steel manufacturers according to specifications, and since it is formed through a rolling process, it has a constant cross-section throughout its length.

Since the load acting on the rafters or the floor in a building structure increases toward the column, the structural member supporting the rafter or the floor should select a section steel with a standard that can withstand the load acting on the part adjacent to the column.

However, a section steel of such a standard has a cross-section and weight that are too large compared to the load acting on the side close to the center of the roof or floor, and the weight again acts as a high load on the structural member itself. .

As one of the methods for solving this problem, in Korean Patent Application Laid-Open No. 10-2010-0130441 (Document 1), the structure of the welding beam used on the column side of the rafters, which has the name 'welding beam for assembled building structures', is disclosed. suggest

Document 1 The welding beam according to the invention constitutes a web of corrugated steel sheet having one end side in the longitudinal direction having a wider width than the other end, and welding flanges on both sides in the width direction of the web, and at both ends in the longitudinal direction of the web, a column and It is formed by combining fastening plates that engage with other parts of the rafters.

In the welding beam according to the invention of Document 1, as the width of the web increases toward the column, the strength increases, and the strength and rigidity can be increased by the corrugation of the web.

However, the corrugated steel plate has a high manufacturing cost, and since the flange and the fastening plate are separately manufactured and combined, the manufacturing process is complicated and the cost is high.

As another method, Korean Patent Publication No. 10-1289835 (Document 2) proposes an invention named 'beam structure'. The beam structure of the invention of Document 2 is to form a beam, which is a structural member, in a box shape, and to install a reinforcing plate for reinforcing rigidity in the box.

However, such a box-type beam can increase the rigidity and strength by variously configuring the cross-sectional shape, but since all the structural members must be separately manufactured and welded to each other, the manufacturing cost is high and the elements are welded to each other and combined with each other. There is a problem that it takes a lot of time and money.

Document 1: Republic of Korea Patent Publication No. 10-2010-0130441 Document 2: Korean Patent Publication No. 10-1289835

The present invention is intended to provide a structural member that is horizontally connected between the pillars of a building to support a load, and in consideration of the problems of the prior art, it is easy to manufacture, the manufacturing cost is low, and the pillar while taking a little time to manufacture An object of the present invention is to provide a structural member having a structure in which a portion adjacent to the ?

In particular, an object of the present invention is to provide a structural member having a structure that can be manufactured simply and inexpensively by mainly using a section steel manufactured according to specifications as elements constituting the structural member.

The problem to be solved by this invention described above is achieved by this invention, which relates to a structural member disposed between a plurality of vertically installed columns to transmit a load to the columns.

The structural member of this invention is

A first part having a longitudinally extending vertical part and flanges formed perpendicular to both ends of the vertical part in the width direction, the vertical part extending in the longitudinal direction from the first part and integrally formed, the vertical part having a smaller width than the vertical part of the first part and a main beam consisting of a second part having a flange formed vertically at one end in the width direction of the horizontal part; and an auxiliary beam having a flange formed vertically at one end in the width direction of the vertical portion extending long and the vertical portion,

The auxiliary beam is disposed extending from the end of the first portion of the main beam along the second portion of the main beam and having an angle of inclination with respect to the longitudinal direction of the main beam, the auxiliary beam being disposed to extend from the end of the first portion of the main beam and the flange of the auxiliary beam and the flange of the second portion of the main beam. are disposed opposite to each other with both vertical portions therebetween, the vertical portion of the auxiliary beam and the vertical portion of the second portion of the main beam are in the same plane,

and a coupling panel coupled together to the vertical portion of the second portion of the main beam and the vertical portion of the auxiliary beam to couple the auxiliary beam to the main beam.

According to this configuration, a first portion of the main beam is elongated with a constant cross-sectional size, a second portion of the main beam is elongated from the termination point and an auxiliary beam is obliquely elongated with respect to the second portion, wherein The joining panels are abutted and fastened to fasten the main beam and the auxiliary beam to each other.

Accordingly, the structural member has a structure in which the width gradually increases from the starting portion to the end portion of the second portion of the main beam and the auxiliary beam, so that the strength increases toward the end portion and it is possible to support a large load.

In addition, the main beam and the auxiliary beam can be manufactured by simply cutting the standardized H-type or I-type beam, and since the operation of combining them is also very simple, it is easy to manufacture and can be manufactured at low cost.

As an additional feature of the present invention, in the structural member of the present invention,

The second portion of the main beam may be formed by cutting a portion corresponding to the size and shape of the horizontal and vertical portions of the auxiliary beam by a predetermined length from one end of the main beam, and the remaining portion is cut from the main beam. It can be configured to be formed in one part.

Therefore, only a part of the main beam is cut to form the second part, and if the cut-out part is disposed at an angle with respect to the second part, it becomes an auxiliary beam, so manufacturing is very simple and the use of materials can be minimized.

As a further feature of this invention, in the structural member of this invention,

The joining panel may be configured to be formed and joined to abut the entire surface of the vertical portion of the second portion of the main beam and the vertical portion of the auxiliary beam and the vertical portion adjacent to the auxiliary beam in the first portion of the main beam.

The bonding panel having such a configuration can be manufactured simply by cutting a flat panel according to the shape of the vertical portion of the main beam and the auxiliary beam.

The bonding panel thus formed has a bonding panel disposed on both surfaces of the vertical portion of the second portion of the main beam and the vertical portion of the auxiliary beam, respectively, and includes the bonding panel, the vertical portion of the second portion of the main beam and the vertical portion of the auxiliary beam. They can be fastened to each other by a penetrating screw.

In addition, a spacer may be disposed between the vertical portion of the second portion of the main beam and the vertical portion of the auxiliary beam, and the coupling panel may be configured to be screwed to each other with the spacer interposed therebetween.

On the other hand, in the structural member of the present invention configured as described above, the second part of the main beam, the auxiliary beam, and the coupling panel are provided on both ends of the main beam in the longitudinal direction so that both ends are coupled to the column. .

The structural member of this configuration can be used when a high load is applied to both ends.

In addition, the structural member of the present invention configured as described above may have a configuration in which the second portion of the main beam, the auxiliary beam, and the joining panel are provided on one end side in the longitudinal direction of the main beam and disposed inclined with respect to the column. .

The structural member of this configuration is suitable for use when a high load is applied only to one end.

1 is a perspective view showing a frame of a building structure in which structural members according to an embodiment of the present invention are used.
2 is an exploded perspective view of a first structural member according to an embodiment of the present invention.
3 is a perspective view showing a state in which the first structural member is coupled according to an embodiment of the present invention.
Fig. 4 is a cross-sectional view taken along line AA of Fig. 3;
FIG. 5 is a cross-sectional view taken along line BB of FIG. 3 ;
6 is a perspective view illustrating a state before and a state in which elements constituting a second structural member are combined with each other according to an exemplary embodiment;

Hereinafter, the configuration and operation of preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1 shows a state in which a frame is erected before a wall or ceiling member is installed in a factory building.

The frame is provided with a main column (3) installed vertically upward from the ground side by side at both ends in the width direction of the building to support the load of the building, and auxiliary columns (4) standing in a line between the main columns to support the floor surface. have.

Between the upper ends of the main pillars 3, the first structural members 1 constituting the rafters are installed to extend obliquely upward from the main pillars 3 on both sides toward the center of the width direction of the building, and the two first structural members 1 ) ends in contact with each other to form rafters.

A second structural member 2 for supporting the bottom surface is provided between the middle of the main pillar 3 and the upper end of the auxiliary pillar 4 .

Hereinafter, the configuration and manufacturing method of the first structural member 1 will be described with reference to FIGS. 2 to 5 .

The first structural member 1 includes a main beam 10 extending over the entire length of the structural member and an auxiliary beam extending a predetermined length from an end coupled to the upper end of the upper column 1 and reinforcing the strength of the main beam. (20), the main beam 10 and the auxiliary beam 20 are coupled to each other and disposed between two bonding panels 30 and the bonding panel 30 for reinforcing the strength of the first structural member 1 It is configured to include a spacer (40).

The main beam 10 is provided using an H-type beam manufactured according to the standard, and the H-beam according to the standard is equipped with a longitudinally extending vertical portion 12 and a flange provided vertically at both ends of the vertical portion in the width direction. It is composed of (13).

On the other hand, the main beam 10, the structure of the H-beam is maintained as it is, the first portion 11 and the H-beam with the vertical portion 12 and the flange 13 formed vertically at both ends of the vertical portion as it is. A portion of the vertical portion and the second portion 15 of which the flange of one side is cut in the structure of the structure.

When the vertical portion 12 is cut along the longitudinal direction at the center of the width direction of the main beam 10 to a certain length from one end in the longitudinal direction of the main beam 10 to the other end, the vertical portion of the main beam is in the width direction. half of the remaining portion forms the vertical portion 16 of the second portion, and the flange 13 on one side remains.

As described above, the second portion 15 of the main beam is a portion remaining after cutting half of the width direction from the H-shaped beam, and has only a half-width vertical portion 16 and a flange 13 on one side.

A partial auxiliary beam (20) cut off from the main beam (10) is formed. The auxiliary beam 20 has a part of the vertical portion and a flange on one side by cutting the vertical portion from the center in the width direction to the length direction in the H-shaped beam.

Thus, the second portion 15 of the main beam 10 and the auxiliary beam have the same size and shape, only the second portion 15 of the main beam remains integral with the first portion 11, The auxiliary beam 20 differs only in that it is separated from the main beam.

Auxiliary beams 20 cut and formed from the main beam 10 face the second portion 15 of the main beam so that a vertical portion 21 of the auxiliary beam and a vertical portion 16 of the second portion of the main beam are formed. The flanges 22 of the auxiliary beam and the flanges 13 of the second part of the main beam are placed on the same plane and face each other with the vertical portions 21 and 16 therebetween.

Auxiliary beam 20 has one end abutting the end of first portion 11 from main beam 10 , ie at the interface where auxiliary beam 20 is cut, from there downward with respect to main beam 10 . placed in an inclined state. Accordingly, the distance between the auxiliary beam 20 and the second portion 15 of the main beam 10 increases as the distance from the first portion 11 of the main beam increases.

The two joining panels 30 have the entire vertical portion 16 of the second portion 15 of the main beam and a portion of the vertical portion 12 of the first portion adjacent to the vertical portion 16 of the second portion and the auxiliary It is provided so as to contact the entire vertical portion 21 of the beam 20 .

4 and 5, the two combining panels 30 are arranged with the vertical portions 12, 16 and 21 of the main and auxiliary beams interposed therebetween, and the combining panels 30 and the main beam 10 are interposed therebetween. ) and the auxiliary beam 20 are fastened to each other by bolts and nuts 33 and 34 fastened through the auxiliary beam 20 , and the auxiliary beam 20 is coupled to the main beam 10 .

As can be seen in FIG. 2 , the auxiliary beam 20 is disposed at an angle with respect to the main beam 10 , so that the vertical portion 21 of the auxiliary beam and the vertical portion 16 of the second portion of the main beam are spaced apart from each other and positioned between each other. space is formed in

In this space, a spacer 40 having the thickness of the vertical portion of the H-beam is placed, and in the portion where the spacer 40 is placed, the two coupling panels 30 are fastened to each other by bolts and nuts 33 and 34. have.

According to the configuration of each element of the first structural member 1 described above and the mutually fastened configuration, the first structural member cuts out a portion of the H-beam having a constant cross-section in the longitudinal direction from the center in the width direction, and cuts After arranging the auxiliary beam 20, which is the completed portion, at the cut position, it is constructed by attaching and fastening the coupling panel 30 thereto.

Accordingly, at the position where the auxiliary beam 20 and the coupling panel 30 are provided, the width of the first structural member 1 increases toward the end, so that it has higher strength and rigidity toward the end.

The rafter structure shown in FIG. 1 is completed by coupling the end to which the auxiliary beam 20 is attached to the first structural member 10 formed in this way to the upper end of the main column 3 and the opposite ends to each other.

On the other hand, in the above structure, by cutting the vertical portion 12 from the main beam 10 at the center in the width direction, the vertical portion of the cut auxiliary beam 20 and the second portion 15 of the main beam remaining after cutting have the same width, but the invention is not limited thereto.

That is, the part that cuts off the auxiliary beam 20 does not have to be the central position in the width direction of the vertical portion 12 of the main beam. The vertical portions of the second portion 15 of the beam have different widths.

In addition, although the spacers 40 are disposed between the bonding panels 30 in a portion, the spacers 40 are not essential, and the bonding panels 30 may be coupled to each other without disposing the spacers 40 .

Also, in this embodiment, the coupling panel 30 and the main beam 10 and the auxiliary beam 20 are fastened with bolts and nuts 33 and 34, but other types of screw coupling, riveting, or They can also be joined by welding.

Next, with reference to FIG. 6 , the second structural member disposed to support the floor surface in FIG. 1 will be described.

Since the second structural member 2 is installed between the auxiliary pillar 4 and the main pillar 3 provided between the main pillars 3 and is horizontally disposed to support the floor surface, one second structural member 2 ) is installed horizontally between the middle of the main column (3) and the upper end of the auxiliary column (4).

In the first structural member 1, the second part 15 is formed only at one end of the main beam 10 made of an H-shaped beam, and the auxiliary beam 20 and the fastening member 30 are installed there, but the second The structural member 2 has second parts 15' formed at both ends of the main beam 10' made of an H-shaped beam, and the auxiliary beam 20' and the fastening member 30' are installed there. It has a structural difference from the first structural member 1 in that respect.

According to the configuration of this second structural member 2, the second part 15' of the main beam 10' and the auxiliary beam 20', which are fastened to the main column 1 and the auxiliary column 2, and The end formed by the fastening member 30 ′ increases in width as it approaches the pillars 1 and 2 to increase strength and rigidity.

6, after cutting the auxiliary beam 20' by a certain distance from both ends of the main beam 10', and slanting the auxiliary beam 20', the bonding panel on both surfaces After arranging the spacers 40 by butting 30', the second structural member 2 was formed by fastening them with bolts and nuts.

In both the first structural member 1 and the second structural member 2 of the above-described embodiment, the auxiliary beam 20 was prepared by cutting one end of the H-shaped beam constituting the main beam 10, but the auxiliary beam is necessarily the main beam. It does not have to be formed by cutting, but may be provided by cutting a separate H-beam. As such a separate H-beam, one of a different standard from the H-beam constituting the main beam 10 may be used.

As above has been described the configuration of the structural member according to the embodiment of the present invention, this embodiment is only an example of the present invention, and the present invention is not limited to this embodiment and has various forms within the scope described in the claims. can be implemented, and such various forms fall within the scope of the present invention

1: first structural member 2: second structural member
3: main column 4: auxiliary column
10: main beam 20: auxiliary beam
30: fastening panel 40: spacer

Claims (7)

A structural member disposed between a plurality of vertically installed columns to transmit a load to the column,
A first part having a vertically extending vertical part and flanges formed vertically at both ends of the vertical part in the width direction, the vertical part extending in the longitudinal direction from the first part and integrally formed, the vertical part having a smaller width than the vertical part of the first part and a main beam consisting of a second part having a flange formed vertically at one end in the width direction of the horizontal part; and
Auxiliary beam having a longitudinally extending vertical portion and a flange formed vertically at one end in the width direction of the vertical portion
equipped with,
The auxiliary beam is disposed extending from the end of the first portion of the main beam along the second portion of the main beam and having an angle of inclination with respect to the longitudinal direction of the main beam, the auxiliary beam being disposed to extend from the end of the first portion of the main beam and the flange of the auxiliary beam and the flange of the second portion of the main beam. disposed opposite to each other with both vertical portions interposed therebetween, the vertical portion of the auxiliary beam and the vertical portion of the second portion of the main beam are in the same plane,
and a joining panel coupled together to the horizontal portion of the second portion of the primary beam and the horizontal portion of the auxiliary beam to couple the auxiliary beam to the primary beam. The method according to claim 1,
The second portion of the main beam is formed from a portion remaining after cutting a portion corresponding to the size and shape of the horizontal and vertical portions of the auxiliary beam by a predetermined length from one end of the main beam, and the auxiliary beam is a portion cut from the main beam which is formed of, a structural member. The method according to claim 1,
wherein the joining panel is formed and joined to abut the entire surface of the vertical portion of the second portion of the main beam and the vertical portion of the auxiliary beam and the vertical portion adjacent to the auxiliary beam in the first portion of the main beam. 4. The method according to claim 3,
Combining panels are respectively disposed on both surfaces of the vertical portion of the second portion of the main beam and the vertical portion of the auxiliary beam, and are fastened to each other by screws passing through the bonding panel, the vertical portion of the second portion of the main beam and the vertical portion of the auxiliary beam. which is a structural member. 5. The method according to claim 4,
wherein a spacer is disposed between the vertical portion of the second portion of the primary beam and the vertical portion of the auxiliary beam, and wherein the joining panels are screwed together with the spacer therebetween. 6. The method according to any one of claims 1 to 5,
and a second portion of the main beam and an auxiliary beam and a joining panel are provided on both longitudinal end sides of the main beam so that both ends are coupled to the column. 6. The method according to any one of claims 1 to 5,
wherein the second portion of the main beam and the auxiliary beam and the joining panel are provided on one longitudinal end side of the main beam and disposed inclined with respect to the column.

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