KR20030012831A - Honeycomb Type Composite Beam Stiffened with Prestressed Concrete Panel having Novel Connecting Structure - Google Patents

Abstract

PURPOSE: A honeycomb girder type precast concrete panel composite beam having a solid assembly structure is provided to compound a honeycomb girder type steel beam and a precast concrete panel simply. CONSTITUTION: The honeycomb girder type precast concrete panel composite beam having a solid assembly structure is formed by assembling a steel beam(10) and a precast concrete panel(20), wherein the steel beam(10) contains cutting parts(14) formed on a web(12) and a lower flange(31) attached on the non-cutting part of the web(12), and the precast concrete panel(20) contains many vertical reinforcing bars, many horizontal reinforcing bars and a concave lower flange receiver(21) to hold the lower flange.

Description

Honeycomb Type Composite Beam Stiffened with Prestressed Concrete Panel having Novel Connecting Structure}

The present invention relates to a concrete panel composite beam composed of a honeycomb girder-type steel beam and a precast concrete panel, specifically, a honeycomb girder-type steel beam and a precast concrete panel to be assembled in a simple and robust manner A honeycomb girder type precast concrete panel composite beam having a new type assembly structure is provided.

The precast concrete panel composite beam has a structure in which a precast concrete panel and a steel beam, to which prestress is applied by tension of a tension member, are assembled.

As described above, since the precast concrete panel composite beam is a composite of the steel beam and the precast concrete panel, it is absolutely important to allow the steel beam and the precast concrete panel to be firmly connected and structurally integrally behave.

Patent application No. 2000-54489 discloses an example of a precast concrete panel composite beam prestressed, the connection structure between the precast concrete panel and the I-type steel beam is adopted as shown in Figs. 1a to 1c.

In FIG. 1A, a plate 4 having a buried stud 5 at the bottom thereof is installed on the upper surface of the precast concrete panel 2, and the lower flange 3 and the plate 4 of the I-type steel beam 1 are provided. An example of connecting the type I steel beam and the precast concrete panel 2 is shown as a method of welding.

In FIG. 1B, the stud is not provided in the lower part of the plate 4, and only the plate 4 and the high tension bolt 6 are installed on the upper surface of the precast concrete panel 2, and the high tension bolt 6 is disposed upward. ) Is shown through the lower flange (3) of the I-type steel beam (1) and fastened.

Meanwhile, FIG. 1C shows a structure in which a U-shaped reinforcement 7 is installed in the precast concrete panel 2 and the end of the reinforcement 7 passes through the lower flange 3 of the I-type steel beam 1 to be fastened. Is shown.

The conventional connection structure as shown in FIGS. 1A to 1C has the following problems.

First, in the case of FIG. 1A, when welding the plate 4 and the lower flange 3 of the I-type steel beam 1, the plate 4 made of steel expands by welding heat, so The probability of cracking in concrete is very high. The cracking of the concrete around the plate 4 results in the plate 4 and the precast concrete panel 2 becoming unintegrated. Thus, a composite beam in which the type I steel beam 1 and the precast concrete panel 2 are not structurally firmly coupled is made.

On the other hand, in the assembly structure of FIG. 1B, since the plate 4 is only coupled to the precast concrete panel 2 only by the bolt 6, the I-type steel beam 1 and the precast concrete panel 2 ), The connection of the beams is very weak, so that the type I steel beam 1 and the precast concrete panel 2 cannot be structurally firmly coupled.

In the assembly structure of FIG. 1C, since the lower flange 3 of the I-type steel beam 1 and the upper surface of the precast concrete panel 2 directly contact each other without the plate 4, this is also not firmly connected. It is not structurally firmly coupled. In particular, the upper surface of the lower flange 3 and the precast concrete panel 2 is not in contact with any adhesive force, but only coupled by the fastening force by the reinforcing rod 7 and the bolts and nuts fastening thereto. Therefore, a gap may be generated between the lower flange 3 and the upper surface of the precast concrete panel 2 so that rainwater may be injected, and the fixing state of the end of the reinforcing bar 7 is loosened due to the vibration load applied to the beam. There is a problem that the upper surface of the lower flange 3 and the precast concrete panel 2 collide with each other and become damaged, and the gap therebetween becomes larger.

The present invention overcomes the disadvantages and limitations of the prior art as described above, and to provide a technique suitable for applying to honeycomb girder-type steel beam, in the present invention, the honeycomb girder-type steel beam and precast concrete panel is more robust. It is an object of the present invention to provide a honeycomb girder-type precast concrete panel composite beam having an assembly structure that can be combined to make a structurally completely integral behavior and such a combination can be made easily.

1A to 1C are cross-sectional views illustrating an assembly structure of a steel beam and a precast concrete panel in a conventional precast concrete panel composite beam, respectively.

Figure 2a is an exploded perspective view of a precast concrete panel composite beam according to the present invention.

2b is a bottom perspective view of the lower flange according to the present invention;

Figure 2c is a perspective view of a precast concrete panel according to the present invention.

Figure 3a is a perspective view showing the assembled state of the precast concrete panel composite beam according to the present invention.

3B is a cross-sectional view taken along the line A-A of FIG. 3A showing the assembly structure of the precast concrete panel composite beam shown in FIG. 3A.

3C is a cross-sectional view taken along the line B-B of FIG. 3A.

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

1: steel beam 2: precast concrete panel

3: lower flange 4: plate

5: buried stud 6: high tension bolt

7: rebar 10: steel beam

11: upper flange 12: abdomen

14: cutout 20: precast concrete panel

21: lower flange receiving portion 22: connecting rebar

23: reinforcing bar portion 24: axial rebar

25: transverse rebar 26: non-contraction concrete

31: lower flange 32: buried stud

33: height adjustment member

In the present invention, in order to achieve the above object, as a composite beam of a structure in which the honeycomb girder-type steel beam and the precast concrete panel is integrally assembled, a cutout cut into the abdomen in the abdomen of the steel beam at a predetermined interval A lower flange having a predetermined length and width is integrally attached to a lower portion of the formed honeycomb girder and not cut off from the abdomen of the steel beam; A precast concrete panel, in which the longitudinal and transverse reinforcement bars are arranged, has a concave lower flange receiving portion for receiving the lower flange on an upper surface thereof; A reinforcing bar portion is embedded in the side wall of the concave lower flange receiving portion, and one end of the reinforcing bar portion is integrally coupled with an end of the transverse reinforcing bar; The other end of the reinforcing bar is connected to the connecting bar, so that when the lower flange of the steel beam is accommodated in the lower flange receiving portion 21 of the precast concrete panel, the connecting bar is integrally formed on the bottom surface of the lower flange Attached; When the lower flange of the steel beam is accommodated in the lower flange receiving portion and the non-condensed concrete is poured into the lower flange receiving portion to cure, the honeycomb girder-type steel beam and the precast concrete panel is integrally assembled and synthesized Provided is a honeycomb girder type precast concrete panel composite beam having a.

In the present invention, the bottom surface of the lower flange, may be provided with a height adjusting member for adjusting the balance when the steel beam is disposed on the lower flange receiving portion for coupling on the precast concrete panel.

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

2A is an exploded perspective view of a precast concrete panel composite beam according to the present invention.

As shown in FIG. 2A, the precast concrete panel composite beam according to the present invention is made by combining a honeycomb girder type steel beam 10 and a precast concrete panel 20. The abdomen 12 of the honeycomb girder-shaped steel beam 10 is formed with a trapezoidal cutout portion 14 at predetermined intervals. In the case of the honeycomb girder-type beam as described above, by cutting a part of the abdomen of the beam having a relatively low structural importance, the use of steel is reduced, thereby reducing the cost and weight. In the drawing, reference numeral 11 is the upper flange 11.

In the present invention, a lower flange 31 having a predetermined length and width is integrally attached to a lower portion of the honeycomb girder-type steel beam 10 that is not cut off from the abdomen. 2b shows a schematic perspective view of the lower flange 31 such that its bottom face is upward, the bottom surface of the lower flange 31 according to the present invention, as well as a predetermined number of buried studs 32 The height adjusting member 33 is provided at the center. The height adjusting member 33 adjusts the height of the lower flange 31 so that the honeycomb girder-like steel beam 10 is installed on the precast concrete panel 20 in a balanced manner. Function to adjust.

2c shows a perspective view of the precast concrete panel 20, the upper surface of the precast concrete panel 20 corresponding to accommodate the lower flange 31 of the honeycomb girder-shaped steel beam 10. The lower flange accommodating part 21 is formed in the position.

The inner side surface of the lower flange receiving portion 21 of the concave shape is provided with a predetermined number of reinforcing bar 23, the connecting bar 22 is mounted on the reinforcing bar 23. As an example of a specific configuration in which the connecting reinforcing bar 22 is mounted on the reinforcing bar portion 23, the reinforcing bar 23 forms a screw portion on an inner surface thereof, and corresponds to an end of the connecting reinforcing bar 22. By forming a screw portion there is a configuration for screwing the end of the connecting reinforcing bar 22 to the reinforcing bar (23). However, the coupling of the reinforcing bar 23 and the connecting reinforcing bar 22 is not limited to such screw coupling and may be coupled by various methods.

In FIG. 2C, the right first lower flange assembly accommodating portion 21 is a state in which the connecting reinforcing bar 22 is coupled, and the other lower flange assembly accommodating portion 21 shows only the reinforcing bar portion 23. It is.

The combination of the steel beam 10 and the precast concrete panel 20, the lower flange 31 of the steel beam 10 is accommodated in the lower flange assembly receiving portion 21 to the connecting reinforcement 22 After connecting the lower flange 31 and the non-condensed concrete 26 to the lower flange receiving portion 21 is made by curing.

Next, the method of assembling the steel beam and the precast concrete panel will be described in detail by examining the finished precast concrete composite beam and its cross section in detail.

Figure 3a is a perspective view of the assembled precast concrete panel composite beam according to the present invention is shown. As shown in FIG. 3A, in the assembled state, the lower flange 31 is completely covered with non-contraction concrete and does not appear to the outside.

3B is a cross-sectional view taken along the line A-A of FIG. 3A, and FIG. 3C is a cross-sectional view taken along the line B-B of FIG. 3A. As shown in FIGS. 3B and 3C, the precast concrete panel 20 has a longitudinal reinforcement 24 and a transverse reinforcement 25 disposed therein as shown in the figure. As shown in FIG. 3C, in the present invention, the transverse reinforcing bars 25 passing through the lower flange receiving portion 21 are preferably formed in a C shape facing each other. And both ends of the transverse reinforcing bar 25 is provided with a reinforcing bar 23, the one side of the reinforcing bar 23 is connected to the inner side of the lower flange receiving portion 21 is connected to the reinforcing bar 22 It is configured to be combined.

The lower flange 31 is placed on the lower flange receiving portion 21 while the connecting reinforcing bar 22 is coupled to the reinforcing bar portion 23, and the connecting reinforcing bar 22 is connected to the lower flange 31. It is integrally attached to the lower surface and the steel beam 10 is primarily coupled to the precast concrete panel 20. When the connecting reinforcing bar 22 is coupled to the lower flange 31, it is convenient for construction to use a method of welding the side of the lower flange 31 and the connecting reinforcing bar 22, as shown in FIG. 3C. . The steel beam 10 is supported by the height adjusting member 33 and the connecting reinforcing bar 22 installed at the center of the bottom surface of the lower flange 31.

As such, the non-concrete concrete is poured into the lower flange receiving portion 21 in a state in which the lower flange 31 and the precast concrete panel 20 are primarily coupled by the connecting reinforcing bars 22, thereby curing the lower flange 31. ) And the precast concrete panel 20 is firmly coupled, and thus the synthesis of the honeycomb girder-shaped steel beam 10 and the precast concrete panel 20 is completed, and thus the precast concrete panel composite beam according to the present invention is completed. do. It is preferable to form irregularities on the side walls and the bottom of the lower flange receiving portion 21 so as to enhance the adhesion effect of the non-concrete concrete and the precast concrete, which is poured and cured later.

The process of arranging the steel wire in the precast concrete panel 20 and applying prestress by the tension of the steel wire may use a general known method, and a detailed description thereof will be omitted.

According to the present invention as described above, by installing the honeycomb girder-type steel beam on the precast concrete panel, the lower flange receiving portion is formed on the upper surface, and the non-condensed concrete is poured and combined, very simply the honeycomb girder-type steel beam and Precast concrete panels can be synthesized.

In addition, as described above, in the present invention, when the lower flange is installed in the precast concrete panel, parallelism, straightness, etc. can be precisely adjusted by the height adjusting member and the connecting rebar, thereby enabling precise construction. And the studs provided on the lower flange and the connecting reinforcing bar coupled by the lower flange and the welding or other coupling method has a structure in which the bonding force by the concrete can be further strengthened.

Claims (2)

A composite beam having a structure in which the steel beam 10 and the precast concrete panel 20 are integrally assembled, The abdomen 12 of the steel beam 10 is made of a honeycomb girder type formed with a cutout portion 14 cut into the abdomen in a predetermined interval, the portion which is not cut from the abdomen 12 of the steel beam 10 A lower flange 31 having a predetermined length and width is integrally attached to the lower portion of the lower portion of the lower portion; The precast concrete panel 20 has a plurality of longitudinal reinforcing bars 24 and a plurality of transverse reinforcing bars are disposed therein, the upper surface of the concave lower flange receiving portion for accommodating the lower flange 31 (21) are formed; Reinforcing bar 23 is embedded in the side wall of the concave lower flange receiving portion 21 and one end of the reinforcing bar 23 passes through the lower flange receiving portion 21 of a plurality of transverse rebars. Integrally engaged with the end of the directional reinforcement 25; The other end of the reinforcing bar 23 is coupled to the connecting bar 22, the lower flange 31 of the steel beam 10 is accommodated in the lower flange receiving portion 21 of the precast concrete panel 20 When the connecting reinforcing bar (22) is integrally attached to the bottom of the lower flange (31); In the state where the lower flange 31 of the steel beam 10 is accommodated in the lower flange receiving portion 21, non-condensed concrete is poured into the lower flange receiving portion 21 to cure the honeycomb girder steel beam ( 10) and a honeycomb girder-type precast concrete panel composite beam, characterized in that it has a structure in which the precast concrete panel 20 is integrally assembled and synthesized. The method of claim 1, On the bottom of the lower flange 31, the height adjusting member 33 for adjusting the steel beam 10 to balance when placed in the lower flange receiving portion 21 for coupling on the precast concrete panel 20 Honeycomb girder-type precast concrete panel composite beam characterized in that it is provided.