KR101038290B1 - Bonding structure of precast slab and steel beam for slim floor and construction method thereof - Google Patents

Abstract

PURPOSE: A bonding structure of precast slab and steel beam for slim floor and a construction method thereof are provided to prevent slip between PC slab and steel beam. CONSTITUTION: A bonding structure of precast slab and steel beam for slim floor comprises a PC slab(20), an I-shaped steel beam(10), a steel portion(22), and a connecting reinforcing bar. The PC slab comprises an uneven portion and a ring(23). The I-shaped steel beam comprises a stud(15). The stud is coupled with the upper portion of an L-shaped support plate(14). The steel portion is mounted on the L-shaped support plate. The connecting reinforcing bar is connected between the steel portions of the adjacent PC slabs.

Description

BONDING STRUCTURE OF PRECAST SLAB AND STEEL BEAM FOR SLIM FLOOR AND CONSTRUCTION METHOD THEREOF}

The present invention relates to a joint structure and construction method of the cheolgolbo and PC slab, and more specifically to the PC slab and cheolgolbo pre-fabricated in the factory in the field to prevent air shortening, layer reduction and slip phenomenon is excellent in synthetic power The present invention relates to a joint structure of a new type of high-tension steel beam and PC slab and its construction method.

Conventional steel composite beam structure, as shown in Figure 1, the steel deck plate (6) is fixed or welded to the steel deck plate 6 on the steel frame (1), and arc welding the stud (5) on the deck plate (6), It was made by pouring slab concrete (7) on the deck plate (6). Steel frame composite beam structure of this type has the advantage that the steel deck plate (6) acts as a formwork for concrete casting, not only can shorten the air for the formwork installation, but also the steel deck plate (6) also serves as a structural material The height of the cheolgolbo (1) and the slab concrete (7) is located on the cheolgolbo (1) has a disadvantage that the floor height is very high.

In addition, as shown in FIG. 2, the upper flange 3 of the cheolgolbo 1 has a narrow width, the lower flange 4 has a wider width, and then the steel deck plate 6 is placed on the lower flange 4. After the installation, a slim floor method of placing slab concrete (7) thereon was developed. This slim floor method has the advantage of reducing the height of the steel structure, but the slab concrete (7) that is placed on both sides of the cheolgolbo (1) is separated by the cheolgolbo (1) cheolgolbo (1) and slab concrete (7) Since the slip phenomenon occurs between the cheolgolbo (1) and the slab concrete (7) is not completely integrated there is a problem that the structural stability is lowered.

3, the web hole 2a is formed at a portion where the upper flange 3 and the web 2 of the cheolgolbo 1 meet so that both concretes are integrated, and the slab concrete ( 7) The U-shaped support plate 8 is fixed by welding the U-shaped support plate 8 with the lower flange 4 so as to prevent slippage of the concrete during pouring, by the web hole 2a formed between the upper flange 3 and the web 2. Although there is an advantage that can reduce the amount of steel by increasing the composite effect, due to the process of pouring and hardening the slab concrete (7) in the field there is a problem that the field construction properties are bad and the air is greatly increased.

The present invention has been made to solve the above-mentioned problems, compared to the conventional composite beam is excellent in preventing the slip phenomenon between the cheolgolbo and the slab is excellent in the synthetic force by the integration of the cheolgolbo and slab, ensuring structural stability, field workability and air It is an object of the present invention to provide a joint structure and a construction method of a slab-reduced cheolgolbo and PC slab that are greatly shortened.

In order to achieve the above object, the present invention includes a PC slab including a concave-convex portion continuously formed at an end portion, and a ring protruding from the recess portion; An I-shaped steel ball including an upper / lower flange, a web connected vertically between the upper and lower flanges, an L-shaped support plate connected to both ends of the lower flange, and a stud coupled to an upper portion of the L-shaped support plate; Joining, but fastening the hook to the stud so that the convex portion of the PC slab is seated on the L-shaped support plate, the height of the PC slab bonded to the cheolgolbo is formed higher than the upper flange, adjacent PC It provides a joint structure of high-layered slab-saving PC slab and cheolgolbo characterized in that connecting reinforcing bar is connected between the steel parts of the slab.

At this time, there is also a feature that the non-shrink mortar or concrete is poured in the interior of the cheolgolbo and the recess of the PC slab.

In addition, the ring is characterized by being semicircular.

In addition, the convex portion is characterized in that the tip is tapered outward.

Further, the PC slab is characterized in that the reinforcing bar is provided in the longitudinal direction of the cheolgolbo at the end where the concave-convex portion is formed.

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Here, there is also a feature that the non-contraction mortar or concrete is poured to include the connecting reinforcing bar.

In addition, the present invention is a PC slab including a concave-convex portion continuously formed at the end of the factory manufactured, and a ring protruding from the recess; An I-shaped steel ball including an upper / lower flange, a web connected vertically between the upper and lower flanges, an L-shaped support plate connected to both ends of the lower flange, and a stud coupled to an upper portion of the L-shaped support plate; After joining, but fixed the hook to the stud in the field so that the iron portion of the PC slab is seated on the L-shaped support plate, through the main portion of the PC slab to cast mortar or concrete inside the cheolgolbo, The PC slab is poured to include the recessed part of the slab, and the height of the PC slab bonded to the cheolgolbo is higher than the upper flange, characterized in that the connection between the convex portions of the adjacent PC slab prior to the casting It provides a method of construction of a junction structure of a layer-reduced PC slab and cheolgolbo.

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In this case, the casting is also characterized by pouring mortar or concrete, including the connecting reinforcing bar.

According to the present invention, the steel construction beam and PC slab in advance after the factory production and transported by joining the field construction properties are increased and the air is greatly shortened, combined with the PC slab to the steel plate to reduce the floor height to implement a slim floor. In addition, by improving the joint structure of the cheolgolbo and PC slab, it can prevent slippage between the cheolgolbo and the PC slab, thereby integrating it. The effect provided by the method can be obtained.

1 is a view showing the structure of a conventional steel composite beam.
Figure 2 is a view showing another conventional steel composite beam structure.
Figure 3 is a view showing another conventional steel composite beam structure.
Figure 4 is a view showing a joining structure of the PC slab and cheolgolbo according to an embodiment of the present invention.
5 (a) and 5 (b) are diagrams of PC slabs according to one embodiment of the present invention, respectively.
6 is a view showing an example of a joint structure provided with a reinforcing bar in the present invention.
7 is a view showing an example of a joining structure in which the connecting bar is installed in the present invention.
Figure 8 (a) is a plan view showing a joining structure of the PC slab and cheolgolbo according to an embodiment of the present invention, Figure 8 (b) is a cross-sectional view of AA ', Figure 8 (c) is a cross-sectional view of BB'.
Figure 9 (a) is a plan view showing a joining structure of the PC slab and cheolgolbo according to another embodiment of the present invention, Figure 8 (b) is a cross-sectional view of AA ', Figure 8 (c) is a cross-sectional view of BB'.

EMBODIMENT OF THE INVENTION Hereinafter, the structure of this invention is described in detail with reference to drawings.

The present invention is excellent in the effect of preventing the slip phenomenon between the cheolgolbo and the slab compared to the conventional composite beam by improving the joint structure of the cheolgolbo and PC slab, excellent synthesizing force by the integration of the cheolgolbo and slab, structural stability is secured, cheolgolbo and PC By manufacturing the slab in advance in the factory and transporting it to the site, the construction and the air are greatly shortened, and the bonding structure of the high-strength layered steel beam and PC slab that can realize the slim floor by combining the PC slab with the steel golbo to reduce the floor height and The construction method is characterized by the above-mentioned.

As shown in FIG. 4, the present invention relates to a joining structure of an I-type cheolgolbo 10 and a PC slab 20, wherein the cheolgolbo 10 is disposed horizontally and has a lower flange 13 that becomes the bottom surface of the beam. ), A web 11 vertically installed at the center upper surface of the lower flange, and an upper flange 12 connected to an upper end of the web 11 and formed horizontally, wherein the lower flange The width of the 13 is made larger than the width of the upper flange 12.

In addition, a bar-shaped support plate 14 is formed at both ends of the lower flange 13, and the bar-shaped support plate 14 is formed upwardly bent from both ends of the lower flange 13, and then the upper end thereof. It is formed by horizontally bending the inside. At this time, the L-shaped support plate 14 may be welded to the lower flange 13, but is preferably manufactured in one piece for structural stability. The a-shaped support plate 14 serves as a support for supporting the end side of the PC slab 20 in joining the PC slab 20 to the cheolgolbo 10, structurally more by being formed inside the cheolgolbo 10 In addition to being stable, there is an advantage that it is aesthetically advantageous because it is not exposed to an external gaze. However, since the a-shaped support plate 14 is directed toward the inside, it may be difficult to input the inside of the cheolgolbo 10 in placing non-contraction mortar or concrete 30, so that the width of the cheolgolbo 10 should have an appropriate size. .

Here, the L-shaped support plate 14 may be adjusted by adjusting the position of bending the horizontally bent PC slab 20 is installed.

And, the stud 15 is installed on the upper portion of the L-shaped support plate 14 spaced apart at a predetermined interval, the stud 15 is to improve the integration performance of the PC slab 20 and the cheolgolbo 10. If this performance is manifested, it will be possible to install any type of stud.

In addition, as shown in FIG. 5, the PC slab 20 is formed with a continuous concave-convex portion (22, 22) at the end continuously, the shape of the concave-convex portion (22, 22) It can be variously modified bar, in which the tip of the convex portion 22 is preferably tapered outward to form a trapezoid, which is to increase the size of the concave portion 21 due to the reduced size of the convex portion 22 This is because the on-site casting of the non-shrink mortar or concrete into the cheolgolbo 10 through the recessed portion 21 after the bonding of the PC slab 20 and the cheolgolbo 10 is easier.

In addition, a ring 23 protrudes from the recess 21, and the shape of the hook 23 is preferably a semicircular shape in order to increase a fixed coupling force with the stud 15, and the end of the PC slab 20 is cheolgolbo 10. In order to be stably seated on the L-shaped support plate 14, it is preferable to be formed so as not to protrude outward from the convex portion 22. The ring 23 is configured using a steel wire, a stranded wire, a steel bar, and the like, and is fixedly coupled to the inside of the PC slab 20 by using reinforcing bars in the PC slab 20.

By such a configuration, the hook 23 is fixed to the studs 15 of the cheolgolbo 10 so that the convex portion 22 of the PC slab 20 is seated on the L-shaped support plate 14, thereby Before placing the contracted mortar or concrete 30, the PC slab 20 can be prevented from slipping down from the cheolgolbo 10 and prevent slippage between the PC slab and the cheolgolbo after in-situ can be integrated. Excellent synthetic power makes it structurally stable.

In addition, as shown in Figure 6, it is preferable that the reinforcing bar 24 is installed in the longitudinal direction of the cheolgolbo 10 at the end of the PC slab 20 is formed with the concave-convex portion (21, 22), the reinforcement bar Since 24 is installed through a plurality of iron parts 22, not only increases the rigidity of the iron part 22, but also increases the synthesizing effect by integrating the PC slab 20 and the cheolgolbo 10. Here, the reinforcing bar 24 is preferably provided so that at least two are provided on the ring 23 so that the studs 15 of the cheolgolbo 10 can be fixed between the two reinforcing bars 24.

And, as shown in Figure 7, when the PC slab 20 is bonded higher than the height of the cheolgolbo 10, by connecting the connecting reinforcement 25 between the convex portion 22 of the adjacent PC slab 20 It is desirable to increase the integration stiffness of the PC slab 20 and the cheolgolbo 10. However, it would be more desirable to pour non-shrink mortar or concrete to include the connecting reinforcing bar 25.

Hereinafter, with reference to the drawings with respect to the construction method of the junction structure of the layer-reduced PC slab and cheolgolbo according to the present invention will be described in detail.

After the PC slab 20 and the I-type cheolgolbo 10 having the above-described configuration is manufactured and transported to the site, the cheolgolbo 10 is first connected to the PC pillar in the field.

Next, as shown in FIG. 8, the hooks 23 of the PC slab 20 are fixed to the studs 15 of the cheolgolbo 10 so that the convex portions 22 of the PC slab 20 are formed with a L-shaped support plate ( 15) to be seated. In this case, when two reinforcing bars 24 are installed at the ends of the PC slab 20, the studs 15 are coupled to be positioned between the two reinforcing bars.

And, when the PC slab 20 is bonded higher than the height of the cheolgolbo 10, as shown in Figure 9, connecting the reinforcing bar 25 between the convex portions 22 of the adjacent PC slab 20 before the site cast To connect).

In addition, through the concave portion 21 of the PC slab 20 to place the non-contraction mortar or concrete 30 in the interior of the cheolgolbo 10 to be filled up to the concave portion (21). Of course, when the PC slab 20 is bonded higher than the height of the cheolgolbo 10 is poured mortar or concrete (30) to fill up to the connecting reinforcement (25).

As a result, as described above, the bonding structure and construction method of the layered slab-saving PC slab and the cheolgolbo according to the present invention may be manufactured by pre-fabricating the PC slab and the cheolgolbo in advance, and then transported to the field to increase the field construction and greatly shorten the air. In addition, it is possible to realize a slim floor by combining the PC slab with the steel plate to reduce the layer height, and to improve the bonding structure of the PC slab and the cheolgolbo to prevent the slip phenomenon between the PC slab and the cheolgolbo to achieve integration, with excellent synthetic power. Therefore, it is possible to obtain an effect of providing a structurally stable joint structure of the high-layered layered PC slab and cheolgolbo.

Embodiment mentioned above in this invention is an illustration, Comprising: This invention is not limited to this. Anything that has substantially the same configuration as the technical idea described in the claims of the present invention and achieves the same effect is included in the technical scope of the present invention.

1. Cheolgolbo 2. Web
2a. Web holes 3. upper flange
4. Bottom flange 5. Stud
6. Deck Plate 7. Slab Concrete
8. U shaped support plate
10. Cheolgolbo 11. Web
12. Upper flange 13. Lower flange
14. angled support plate 15. stud
20. PC slab 21. Main part
22. Iron 23. Ring
24. Rebar 25. Connecting bars
30. Non-shrink mortar or concrete

Claims (10)

A PC slab 20 including a concave-convex portion continuously formed at an end portion and a ring 23 protruding from the concave portion 21;
A web 11 connected vertically between the upper and lower flanges 12 and 13, the upper and lower flanges 12 and 13, and an L-shaped support plate 14 connected to both ends of the lower flange 13, respectively. And, I-shaped cheolgolbo 10 including a stud 15 coupled to the upper portion of the L-shaped support plate 14;
Fixing the hook 23 to the stud 15 so that the convex portion 22 of the PC slab 20 is seated on the L-shaped support plate 14,
The height of the PC slab 20 bonded to the cheolgolbo 10 is formed higher than the upper flange 12, the connecting reinforcement 25 is connected between the convex portion 22 of the adjacent PC slab 20 Bonding structure of high-definition PC slab and cheolgolbo characterized by the above-mentioned. The method of claim 1,
Bonding structure of the layer-reduced PC slab and cheolgolbo, characterized in that the non-shrink mortar or concrete is poured into the interior of the cheolgolbo 10 and the main portion of the PC slab (20). The method according to claim 1 or 2,
The ring (23) is a semi-circular shape, characterized in that the bonding structure of high-layer PC slab and cheolgolbo. The method according to claim 1 or 2,
The convex portion 22 is a junction structure of a high-layer PC slab and cheolgolbo, characterized in that the tip is tapered outward. The method according to claim 1 or 2,
The PC slab 20 is a joint structure of the high-strength PC slab and cheolgolbo, characterized in that the reinforcing bar 24 is provided in the longitudinal direction of the cheolgolbo 10 at the end formed with the concave-convex portion. delete The method of claim 2,
Bonding structure of the floor-reduced PC slab and cheolgolbo, characterized in that the non-contraction mortar or concrete was poured to include up to the connecting reinforcing bar (25). delete A PC slab 20 which includes a factory-produced concave-convex portion continuously formed at an end portion and a ring 23 protruding from the concave portion 21; A web 11 connected vertically between the upper and lower flanges 12 and 13, the upper and lower flanges 12 and 13, and an L-shaped support plate 14 connected to both ends of the lower flange 13, respectively. And, I-shaped cheolgolbo 10 including a stud 15 coupled to the upper portion of the L-shaped support plate 14;
After fixing the hook 23 to the stud 15 in the field so that the convex portion 22 of the PC slab 20 is seated on the L-shaped support plate 14,
The mortar or concrete is poured into the inside of the cheolgolbo 10 through the recess portion 21 of the PC slab 20, including up to the recess portion 21 of the PC slab 20,
The height of the PC slab 20 bonded to the cheolgolbo 10 is to be higher than the upper flange 12, but connecting the reinforcing bars 25 between the convex portion 22 of the adjacent PC slab 20 before the casting The construction method of the junction structure of the layer-reduced PC slab and cheolgolbo characterized in that the connection. 10. The method of claim 9,
The placing method includes the construction of the joint structure of the floor-reduced PC slab and cheolgolbo, characterized in that the mortar or concrete, including up to the connecting reinforcing bar (25).

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