KR20190115814A - composite beam assembly for field installation - Google Patents

Abstract

The present invention relates to a composite beam which can be easily installed at a site by providing a structure where a stud bolt for shear connection couples a previously installed auxiliary flange to a composite beam. The assemblable composite beam comprises: a first web plate including an upper flange horizontally bent outwards from an upper end thereof and a lower flange horizontally bent inwards from a lower end thereof, and forming one side plate of the composite beam; a second web plate having a shape symmetric to the first web plate, and forming another side plate of the composite beam; a lower plate coupled to the lower flange of the first web plate and the lower flange of the second web plate to form a bottom of the composite beam; a first auxiliary flange coupled into an upper end of the first web plate; and a second auxiliary flange having a shape symmetric to the first auxiliary flange to be coupled into an upper end of the second web plate.

Description

Composite beam assembly for field installation

The present invention relates to a prefabricated composite beam, to a composite beam that can be easily installed in the field by providing a structure for coupling the auxiliary flange pre-installed with a stud bolt for shear connection to the composite beam.

Currently, the production of synthetic beams used at home and abroad is almost dependent on cold forming. This method is a method of producing a product by inserting a coil wound on a steel sheet, which is a material for injection, which is widely used to minimize the loss of materials and to produce quickly.

However, this method uses non-standard sized materials rather than standard sized products, which leads to higher costs due to stock acquisition and higher production and financial costs due to excessive investment of machinery.

In addition, most of the products are in the form of large companies have exclusive production rights for the above reasons, the price of the product is relatively high due to the profit application without competition.

In addition, since a product from a conventional single molding machine has a limitation in its production, when multiple sites are placed at the same time, the reality is that the lead standard is very difficult and the orderer is aware of the producer.

In addition, the conventional composite beam is using a cold-formed product by welding, the distortion of the plate may occur during cold forming, there is a problem that it is difficult to produce a variety of products when using the welding. In addition, the conventional welded composite beam, when used in large beams, has a problem that it is difficult to meet the limitation of the plate width thickness ratio of the compressed steel element subjected to bending.

Patent Document 1: Republic of Korea Patent Registration No. 10-1404515 Publication Date June 27, 2014 Patent Document 1: Republic of Korea Patent Registration No. 10-1186267 Publication Date September 27, 2012

An object of the present invention is to provide a composite beam structure that can be easily installed in the field by providing a structure for coupling the auxiliary flange pre-installed with a stud bolt for shear connection to the composite beam.

In order to achieve the above object, the prefabricated composite beam for field installation optimization according to an embodiment of the present invention, the upper flange which is horizontally bent outwardly at the top and the lower flange is horizontally bent inwardly at the bottom, A first web plate constituting a side plate; A second web plate symmetrical to the first web plate and constituting the other side plate of the composite beam; A lower plate coupled to a lower flange of the first web plate and a lower flange of the second web plate to form a bottom of the composite beam; A first auxiliary flange coupled to an upper inner side of the first web plate; And a second auxiliary flange coupled to an inner side of an upper end of the second web plate in a form symmetrical with the first auxiliary flange.

In this case, the first auxiliary flange and the second auxiliary flange, respectively, may be coupled to have the same height as the height of the upper flange of the first web plate and the upper flange of the second web plate as a-shaped steel.

In this case, the first auxiliary flange and the second auxiliary flange, respectively, can be coupled to the web and the bolt / nut of the first web plate and the second web plate.

In this case, each of the first auxiliary flange and the second auxiliary flange may include a plurality of stud bolts for shear connection in a horizontal portion corresponding to the upper flange of the first web plate and the upper flange of the second web plate. .

The apparatus may further include a first fixing plate connecting and fixing the first web plate and the second web plate.

Meanwhile, each of the first web plate and the second web plate may have a bracket for fixing the first fixing plate on an inner side thereof, and may fix the first fixing plate by bolt / nut coupling.

In addition, the lower plate and the first web plate, or may further include a second fixing plate for connecting and fixing the lower plate and the second web plate.

In addition, the second fixing plate, the first fixing hook for coupling to the lower plate; A second fixing hook coupled to the first web plate or the second web plate; And a connection bar connecting the first fixing hook and the second fixing hook.

At this time, the first fixing hanger and the second fixing hanger may be provided with a U-shaped groove corresponding to the outer diameter of the bolt to be coupled.

On the other hand, the first fixing hook and the second fixing hook may have a fixing hole corresponding to the outer diameter of the bolt to be coupled.

According to the prefabricated composite beam for field installation optimization according to an embodiment of the present invention,

First, since the horizontal portion of the first auxiliary flange is coupled to have the same height as the upper flange, it is possible to obtain the effect of extending the protruding length of the upper flange.

Second, since the horizontal portion serves to extend the protruding length of the upper flange by the first auxiliary flange coupling, it is possible to install a stud bolt for shear connection in the horizontal portion.

Third, in the factory, it is possible to secure a plurality of shear connection stud bolts on the horizontal portion of the first auxiliary flange, and transfer to the site to couple the first auxiliary flange to the first web plate, thereby optimizing the field installation.

1 is a perspective view of a prefabricated composite beam according to an embodiment of the present invention.
Figure 2a is a cross-sectional view of the prefabricated composite beam shown in FIG.
Figure 2b is a cross-sectional view of the prefabricated composite beam according to another embodiment of the present invention.
2C and 2D are cross-sectional views of the prefabricated composite beam according to another embodiment of the present invention.
3 and 4 are cross-sectional views of the prefabricated composite beam according to another embodiment of the present invention.
FIG. 5 is a perspective view illustrating only the second fixing plate illustrated in FIG. 4.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In this case, the same components in the accompanying drawings are to be noted with the same reference numerals as possible. In addition, detailed descriptions of well-known functions and configurations that may blur the gist of the present invention will be omitted. For the same reason, in the accompanying drawings, some components are exaggerated, omitted or schematically illustrated.

1 is a perspective view of a prefabricated composite beam according to an embodiment of the present invention, Figure 2a is a cross-sectional view of the prefabricated composite beam shown in Figure 1, Figure 2b is a cross-sectional view of a prefabricated composite beam according to another embodiment of the present invention, Figure 3 4 is a cross-sectional view of a prefabricated composite beam according to another embodiment of the present invention, and FIG. 5 is a perspective view illustrating only the second fixing plate illustrated in FIG. 4.

1 to 5, the prefabricated composite beam 1000 according to an embodiment of the present invention may include a first web plate 100, a second web plate 200, a lower plate 300, and a first auxiliary flange 500. ) And a second auxiliary flange 400.

The first web plate 100 has an upper flange 130 horizontally bent outward at the top and a lower flange 120 horizontally bent inwardly at the bottom, and connects the upper flange 130 and the lower flange 120. Web 110.

The upper flange 130, the web 110 and the lower flange 120 may be formed by bending the integral steel sheet. That is, the first web plate 100 may be formed by bending one steel plate.

The second web plate 200 is symmetrical with the first web plate 100 and forms the other side plate of the composite beam.

The second web plate 200 has an upper flange 230 horizontally bent outward at the upper end and a lower flange 220 horizontally bent inwardly at the lower end, and connects the upper flange 230 and the lower flange 220. Web 210. The second web plate 200 may also be formed by bending one steel plate.

The lower plate 300 is combined with the lower flange 120 of the first web plate 100 and the lower flange 220 of the second web plate 200 to form the bottom of the composite beam 1000.

At this time, the lower flange 120 of the first web plate 100 and the lower flange 220 of the second web plate 200 are coupled by a bolt (B) / nut (N) coupling method. Washers have been omitted for the sake of brevity.

As shown, the bolt B is inserted from the outside of the composite beam 1000 to the inside to engage with the nut N, but this is only one of the embodiments, the insertion direction of the bolt (B) is implemented It can be changed according to the rule.

In some embodiments, a reinforcing plate (not shown) may be further provided between the lower plate 300 and the lower flanges 120 and 220 to reinforce the lower plate 300.

In addition, one or more reinforcing bars (not shown) may be further provided in the lower plate 300 in the longitudinal direction of the lower plate 300.

The first auxiliary flange 500 is an a-shape steel that is coupled to the upper inner side of the first web plate 100, and is provided for the purpose of assisting the protruding length of the upper flange 130.

Figure 2a is a cross-sectional view of the prefabricated composite beam shown in FIG. Referring to FIG. 2A, the first auxiliary flange 500 is a form in which the horizontal portion 510 and the vertical portion 510 are coupled at right angles, and may be formed by bending a steel plate or may be implemented as a shaped steel produced in a shape. have.

The second auxiliary flange 400 is coupled to the upper inside of the second web plate 200 in a symmetrical form with the first auxiliary flange 500.

The first auxiliary flange 500 and the second auxiliary flange 400 are webs 110 and 210 and bolts B and nuts N of the first web plate 100 and the second web play 200, respectively. By fastening and coupling. At this time, the welding (W) reinforcement may be further performed to the coupling portion according to the operator. In addition, as shown in the examples of FIGS. 2C and 2D, the coupling may be performed only by the welding W without the coupling by the bolt B / nut N.

Since the second auxiliary flange 400 has the same purpose as the first auxiliary flange 500 and is also symmetrical in shape, the first auxiliary flange 500 and the first web plate 100 will be described only for the sake of brevity. Shall be.

As shown in FIG. 2A, the bolt B is inserted into the inner side of the composite beam 1000 to be coupled with the nut N, but this is only one of the embodiments, and the insertion of the bolt B is performed. The direction may vary depending on the practitioner.

The first auxiliary flange 500 is coupled to have a height equal to the height of the upper flange 130 of the first web plate 100 as a-shaped steel.

That is, the horizontal portion 510 of the first auxiliary flange 500 is coupled to have the same height as the upper flange 130, thereby obtaining the effect of extending the protruding length of the upper flange 130.

When the first web plate 100 is formed by bending steel, it is difficult to form the protruding length L of the upper flange 130 longer than a predetermined length by the plate width thickness ratio L / T.

For example, in the case of 4.5T steel, L should be formed to 60 mm or less, and in the case of 6T steel, L should be formed to 80 mm or less.

However, the upper flange 130 is to support the deck, if the L is less than 60mm or 80mm deck can support but does not have a length to install the stud bolt (S) for shear connection.

In the present invention, since the horizontal portion 510 serves to extend the protruding length of the upper flange 130 by coupling the first auxiliary flange 500, a stud bolt S for shear connection is installed in the horizontal portion 510. Can be.

The first auxiliary flange 500 and the second auxiliary flange 400 each have a horizontal portion corresponding to the upper flange 130 of the first web plate 100 and the upper flange 230 of the second web plate 200. A plurality of stud bolts S for shear connection are provided at 510 and 410.

That is, a plurality of shear connection stud bolts S are fixed to the horizontal portion 510 of the first auxiliary flange 500 at the factory, and the first auxiliary flange 500 is first web plate 100 at the site after the transfer. ) To enable field installation optimization.

Figure 2b is a cross-sectional view of the prefabricated composite beam according to another embodiment of the present invention. According to another embodiment,

The first auxiliary flange 500 and the second auxiliary flange 400 are angles of the upper flange 130 of the first web plate 100 and the upper flange 230 of the second web plate 200, respectively, as a-shaped steels. It is coupled to have the same height as, each end of the vertical portion (420, 520) is coupled to have the same height as the upper flange (130, 230).

The first auxiliary flange 500 and the second auxiliary flange 400 are webs 110 and 210 and bolts B and nuts N of the first web plate 100 and the second web play 200, respectively. By fastening and coupling. At this time, the welding (W) reinforcement may be further performed to the coupling portion according to the operator. In addition, the coupling may be performed only by the welding (W) without the coupling by the bolt (B) / nut (N) according to the operator.

That is, the second web plate 200 is coupled to a shape in which the b shape is in contact with the a shape by, for example, coupling the vertical portion 420 of the second auxiliary flange 400 to the inner surface of the web 210. .

Each of the first auxiliary flange 500 and the second auxiliary flange 400 includes a plurality of stud bolts S for shear connection in the horizontal portions 510 and 410, respectively.

At this time, the stud bolt (S ') is preferably coupled to rise to the upper surface of the composite beam (1000). That is, the stud bolt S 'longer than the length of the vertical portion 420 may be used.

On the other hand, according to another embodiment of the present invention prefabricated composite beam 1000 further includes a first fixing plate 600 for preventing the opening of the first web plate 100 and the second web plate 200.

The first web plate 100 and the second web plate 200 play a role close to the formwork rather than supporting the attraction or tension generated by the superstructure in the prefabricated composite beam. In other words, the tension applied to the lower side of the beam is supported by the lower plate 300, and the attraction force is supported by the concrete that is poured and cured in the composite beam.

Therefore, in order to prevent waste of steel, the first web plate 100 and the second web plate 200 are formed by bending steel materials of 4.5T to 6T. When concrete is poured into a composite beam, the weight of concrete poured The first web plate 100 and the second web plate 200 may be opened.

As shown in FIG. 3, the first web plate 100 and the second web plate 200 each secure the first fixing plate 600 to the inner side to fix the first fixing plate 600. And brackets 140 and 240 for fixing the first fixing plate 600 by fastening the brackets 140 and 240 to the bolts / nuts.

Meanwhile, as shown in FIG. 4, second fixing plates 700 and 700 which connect and fix the lower plate 300 and the first web plate 100 or the lower plate 300 and the second web plate 200. It may further include ').

The second fixing plate 700 may include a first fixing hook 730 coupled to the lower plate 300, a second fixing hook 710 coupled to the first web plate 100, or a second web plate 200. The first fixing hanger 710 and the second fixing hanger 730 is formed in the form including a connecting bar 720 for connecting.

At this time, the second fixing plate 700 is a U-shaped groove corresponding to the outer diameter of the bolt coupled to the first fixing hanger 710 and the second fixing hanger 730 as shown in the example of Figure 5 (a) ( H ').

Alternatively, as shown in FIG. 5B, the second fixing plate 700 ′ is fixed to correspond to the outer diameter of the bolt coupled to the first fixing hanger 710 ′ and the second fixing hanger 730 ′. The hole H may be provided.

Although not shown, the first fixing hanger 710 is provided with a U-shaped groove (H '), the second fixing hanger 730 is provided with a fixing hole (H) or fixed to the first fixing hanger (710) The hole H is provided, and the second fixing plate 730 may be provided with a second fixing plate in a form in which the U-shaped groove H 'is provided.

The first fixing hooks 710 and 710 'are fixed in a form in which the first auxiliary flange 500 is fastened to a bolt / nut provided to be coupled to the web 100.

The second fixing hooks 730 and 730 ′ may be fixed to the bolts / nuts provided to be coupled to the lower plate 300 and the lower flanges 120 and 130.

The second fixing plate 700 may be provided in a staggered form as described in FIG. 5 to prevent the first web plate 100 and the second web plate 200 from spreading. In this case, the second fixing plate 700 may be implemented together with the first fixing plate 600 as necessary.

In addition, although not shown, the second fixing plate 700 and the first fixing plate 600 may be applied to the embodiment of FIG. 2B in the form of being used together or together.

The embodiments of the present invention disclosed in the specification and the drawings are only specific examples to easily explain the technical contents of the present invention and aid the understanding of the present invention, and are not intended to limit the scope of the present invention. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention can be carried out in addition to the embodiments disclosed herein.

1000: Prefabricated Composite Beam
100: first web plate 200: second web plate
300: lower plate 400: first auxiliary flange
500: second auxiliary flange 600: first fixing plate
700: second fixing plate

Claims (5)

A first web plate having an upper flange horizontally bent outwardly at an upper end and a lower flange horizontally bent inwardly at a lower end, and forming one side plate of the composite beam;
A second web plate symmetrical to the first web plate and constituting the other side plate of the composite beam;
A lower plate coupled to a lower flange of the first web plate and a lower flange of the second web plate to form a bottom of the composite beam;
A first auxiliary flange coupled to an upper inner side of the first web plate; And
Prefabricated composite beam comprising a second auxiliary flange coupled to the inside of the upper end of the second web plate in a form symmetrical with the first auxiliary flange. The method according to claim 1,
The first auxiliary flange and the second auxiliary flange, respectively,
Prefabricated composite beam, characterized in that coupled to the a-shaped steel having the same height as the height of the upper flange of the first web plate and the upper flange of the second web plate. The method according to claim 2,
The first auxiliary flange and the second auxiliary flange, respectively,
Prefabricated composite beam, characterized in that the coupling of the web and bolt / nut of the first web plate and the second web plate. The method according to claim 3,
The first auxiliary flange and the second auxiliary flange, respectively,
And a plurality of stud bolts for shear connection at a horizontal portion corresponding to the upper flange of the first web plate and the upper flange of the second web plate. The method according to claim 1,
Prefabricated composite beam further comprises a first fixing plate for connecting and fixing the first web plate and the second web plate.