KR100787492B1 - Composite system of steel beam-concrete slab for damping - Google Patents

Abstract

A compound of a steel beam and a concrete slab is provided to reduce vibration of a floor by forming a damping layer at a center shaft of the steel beam and concrete slab compound structure. A compound of a steel beam and a concrete slab for damping vibration of a floor comprises a steel beam(10) having an upper flange(11), a vibration damper(20), a front stud(30), and a concrete slab(40). The vibration damper is contacted with an upper surface of the upper flange of the steel beam. The front stud is coupled to the upper surface of the upper flange of the steel beam. The concrete slab is integrally constructed with the steel beam when burying the front stud.

Description

Composite system of steel beam-concrete slab for damping

1 is a diagram illustrating the concept of a floor vibration damping system.

2 shows a conventional method for implementing a floor vibration damping system.

3 to 5 is a view showing a method for implementing a floor vibration damping system according to the present invention in the composite structure of cheolgolbo and concrete slab.

6 is a view showing a design concept according to the moment distribution in the case of FIG.

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

10: Cheolgolbo 11: upper flange

20: vibration damper 21: dustproof layer

30: Shear Stud

40: concrete slab 41: iron plate deck

The present invention relates to a composite structure of a cheolgolbo and concrete slab for damping the floor vibration, and more specifically, by forming a dustproof layer near the neutral axis in the composite structure of the cheolgolbo and concrete slab to maximize the floor vibration damping effect and at the same time The present invention relates to a composite structure of cheolgolbo and concrete slab for damping floor vibration that can be easily applied to the construction process.

Recently, the dry method has been applied a lot away from the conventional wet method (concrete on-site casting method) to shorten the air and improve the economic efficiency by improving the construction productivity. In other words, the main structural members such as beams or columns are unitized and assembled at the site to build a structure, thereby improving construction efficiency, facilitating quality control, and reducing manpower.

The most common dry construction method is steel structure, and medium and large buildings of medium (about 10 floors) scale are being constructed in almost steel structure because of the expected effect. Steel structure refers to a structure in which steel members manufactured in a factory (in some cases on-site) are assembled by joining methods such as rivets, bolts, or welding, and are useful for high-rise buildings and large-span buildings as well as construction efficiency. In addition, there are advantages such as free design and internal planar construction and easy expansion and renovation. However, such a steel structure has a problem that it is vulnerable to vibration, and in particular, in recent buildings designed with a large space, the installation of non-structural materials exhibiting a dustproof effect such as a partition wall is reduced, and thus the floor vibration problem is highlighted.

In general, the method of increasing the frame size has been applied to solve the floor vibration problem. That is, to increase the stiffness of the frame by increasing the thickness of the concrete slab having a sound insulation performance or the dance of the cheolgolbo due to the material properties. However, such a method is not preferable in many ways, such as an increase in the use of the frame material leads to an increase in construction cost or a lower floor height resulting in a decrease in space efficiency. Therefore, in recent years, a method of introducing a damping layer into the frame has been proposed to solve the vibration problem, which dissipates vibration energy through shear deformation of the vibrationproof layer as shown in FIG. It is a principle to improve the dustproof effect of the. In general, the dustproof layer has been introduced into the lower flange of the cheolgolbo as shown in Figure 2 (a) or as a floor finishing material on the slab surface as shown in Figure 2 (b). However, in order to provide a dustproof layer on the lower flange of the cheolgolbo as shown in Fig. 2 (a) is inconvenient according to the special cheolgolbo production, as shown in Fig. 2 (b) to be installed over the entire floor to provide a dustproof layer on the slab surface Therefore, it is inevitable to increase the construction cost due to the increase in the use of dustproof materials, and it is cumbersome in terms of work because the floor finishing process must be performed in a separate process.

The present invention has been made to improve the above-described problems, to maximize the floor vibration damping effect by forming a dust-proof layer near the neutral axis in the composite structure of cheolgolbo and concrete slab and at the same time can be easily applied to existing field construction process Its technical purpose is to provide a composite structure of steel beams and concrete slabs for damping possible floor vibrations.

It is another object of the present invention to provide a composite structure of a cheolgolbo and concrete slab for damping the floor vibration can be completed while responding flexibly to the demand strength curve.

The present invention for achieving the above object is cheolgolbo having an upper flange; Vibration damper which is installed in contact with the upper surface of the upper flange of the cheolgolbo; Shear studs are bonded to the upper surface of the upper flange of the cheolgolbo; And a concrete slab which is constructed integrally with the cheolgolbo while embedding the shear stud and the vibration damper. Provides a composite structure of the cheolgolbo and concrete slab for floor vibration damping, characterized in that it comprises a.

Hereinafter, the present invention will be described according to the accompanying drawings and preferred embodiments.

3 to 5 is a view showing a method for implementing a floor vibration damping system according to the present invention in the composite structure of the cheolgolbo and concrete slab, as shown in the present invention the cheolgolbo 10 having an upper flange (11) ; Vibration damper 20 is installed in contact with the upper surface of the upper flange 11 of the cheolgolbo; Shear studs 30 are attached to the upper surface of the upper flange 11 of the cheolgolbo; And a concrete slab 40 which is integrally constructed with the cheolgolbo 10 while the shear stud 30 is embedded therein. That is, the vibration damper 20 is installed between the cheolgolbo 10 and the concrete slab 40.

In the composite structure of cheolgolbo and concrete slab, the neutral axis of the composite section is located at almost the same position as the boundary between cheolgolbo 10 and concrete slab 40, which means that the shear is near the boundary between cheolgolbo 10 and concrete slab 40. This means that the stress will appear at maximum. In view of such a point, the present invention provides vibration energy by installing the vibration damper 20 near the neutral axis (the boundary between the steel beams and the concrete slab) where the shear stress is maximized and inducing the shear deformation of the vibration damper 20 to the maximum. The consumption rate is maximized and, as a result, the vibration damping effect of the structure is maximized. Particularly, the present invention completes the vibration damping structure by installing the vibration damper 20 at the boundary between the cheolgolbo 10 and the concrete slab 40, so that the conventional cheolgolbo 10 can be applied as it is. It is advantageous in that it can be easily applied in the field while following the construction method (simply adding a process of installing a vibration damper).

3 to 5 show differently according to the installation method of the vibration damper 20.

3 is a case in which the vibration damper 20 is installed on the entire upper surface of the upper flange 11 of the cheolgolbo, the shear stud provided with a through hole 23 in the vibration damper 20 to be joined to the cheolgolbo upper flange 11 ( 30 is an example in which the vibration damper 20 is installed to pass through the through hole 23. Since the cheolgolbo 10 and the concrete slab 40 is integrated as a whole by the shear stud 30, the composite behavior over the entire section, and even if the vibration damper 20 is simply installed on the upper flange 11 of the cheolgolbo vibration The frictional resistance of the damper 20 and the cheolgolbo 10 is sufficient to transfer the load.

4 is a case in which the vibration damper 20 is installed to be arranged in two rows only at both ends of the width direction of the cheolgolbo 10, the shear stud 30 is only in the center of the width direction of the cheolgolbo 10 without the vibration damper 20 is installed This is an example of installation. In the case of FIG. 3, since the cheolgolbo 10 and the concrete slab 40 are integrated as a whole by the shear stud 30, the synthetic behavior is performed over the entire section.

5 is a case in which the vibration damper 20 is installed only at both ends of the longitudinal direction of the cheolgolbo 10, the shear stud 30 is an example in which only the longitudinal center portion of the cheolgolbo 10 without the vibration damper 20 is installed. . In the case of FIG. 5, the shear stress of both ends of the beam in the longitudinal direction is large, and the effect of the efficient use of the vibration damper 20 is expected. However, unlike the case of FIGS. 3 and 4, since the shear studs 30 are installed only in the center portion, the cheolgolbo 10 and the concrete slab 40 will be integrated only at the center portion, and thus will be partially synthesized. Considering that the entire section is uniformly designed based on the central part where the load capacity is required, structural stability is not a problem even if the strength of the retaining end is smaller than that of the central part. 6, the embodiment of FIG. 5 will be an optimized installation form of the vibration damper 20, since it can flexibly correspond to the required strength curve of the composite structure. Of course, the composite section by the shear stud 30 should be made to include at least a constant moment section.

3 to 5, the upper damper plate 22a as the vibration damper 20; Lower iron plate 22b; And a dustproof layer 21 made of a viscoelastic material such as rubber disposed between the upper and lower iron plates 22a and 22b. Even if the vibration damper 20 is embedded in concrete, since the dustproof layer 21 is protected by the upper and lower iron plates 22a and 22b, the dustproof layer 21 can faithfully perform the role of removing the dust.

In the present invention, as a construction method of the concrete slab 40 has been proposed a construction method using the iron plate deck 41 which is adopted in the conventional steel frame construction. That is, the steel plate deck 41 is mounted on the vibration damper 20 so as to connect the cheolgolbo 10 to each other, and the site concrete 42 is poured over the steel plate deck 41. At this time, the iron plate deck 41 may be adopted, such as a gold deck made by bending the iron plate in a bone shape, a truss deck bonded to the truss reinforcing steel plate.

When the iron plate deck 41 is mounted on the vibration damper 20 and the mounting state of the iron plate deck 41 is not fixed and the separation of the iron plate deck 41 is concerned, the iron plate deck 41 is replaced with the vibration damper ( 20) to fix it directly by welding (welding or pin bonding). However, when the iron plate deck 41 is installed while securing a sufficient mounting area or the iron plate deck itself has a sufficient self-weight, its mobility will be controlled considerably, so the iron plate deck 41 may not be directly connected to the vibration damper 20. something to do.

In addition, when the vibration damper 20 is installed only at both ends of the cheolgolbo 10 as in the embodiment of FIG. 5, the iron plate deck 41 installed at the center of the cheolgolbo 10 has a joint space of the shear stud 30. Because it is difficult to secure a sufficient mounting space is directly bonded to the upper flange 11 of the cheolgolbo by means of spot welding, etc., it is considerable, iron plate deck 41 is installed on both ends of the vibration damper 20 of cheolgolbo 10 If only the binding with the iron plate deck 41 installed in the center of the cheolgolbo 10 will be fixed in position that will not have to do a separate joining work.

Although the present invention has been described in detail with reference to the described embodiments, those skilled in the art to which the present invention pertains will be capable of various substitutions, additions and modifications without departing from the technical spirit described above. It is to be understood that such modified embodiments also fall within the protection scope of the present invention as defined by the appended claims below.

According to the present invention as described above, the following effects are expected.

First, in the composite structure of cheolgolbo and concrete slab, the vibration damping effect can be maximized by forming a dustproof layer near the neutral axis.

Second, simply install the vibration damper on the upper flange of Cheolgolbo. It can be easily applied and applied to the existing site construction process.

Third, it can be completed while flexibly responding to the required strength curve of the structure it is possible to optimize the installation state of the vibration damper.

Claims (6)

Cheolgolbo (10) having an upper flange (11); Vibration damper 20 is installed in contact with the upper surface of the upper flange 11 of the cheolgolbo; Shear studs 30 are attached to the upper surface of the upper flange 11 of the cheolgolbo; And, Concrete slab 40 is integrally constructed with the cheolgolbo 10 while purchasing the shear stud 30; Composite structure of cheolgolbo and concrete slab for damping floor vibrations, characterized in that comprising a. In claim 1, The vibration damper 20 is installed on the entire upper surface of the upper flange 11 of the cheolgolbo, The shear stud 30 is a composite structure of the steel golbo and concrete slab for damping the floor vibration, characterized in that installed through the vibration damper (20). In claim 1, The vibration damper 20 is installed only at both ends of the longitudinal direction of the cheolgolbo 10, The shear stud 30 is a composite structure of the cheolgolbo and concrete slab for floor vibration damping, characterized in that installed only in the longitudinal center portion of the cheolgolbo 10, the vibration damper 20 is not installed. In claim 1, The vibration damper 20 is installed to be arranged in two rows only at both ends of the width direction of the cheolgolbo 10, The shear stud 30 is a composite structure of the cheolgolbo and concrete slab for the floor vibration damping, characterized in that the vibration damper 20 is installed only in the center of the width direction of the cheolgolbo 10 is not installed. The method according to any one of claims 1 to 4, The vibration damper 20 is Upper plate 22a; Lower iron plate 22b; And, A dustproof layer 21 made of viscoelastic material disposed between the upper and lower iron plates 22a and 22b; Composite structure of the cheolgolbo and concrete slab for damping the floor vibration, characterized in that consisting of. The method according to any one of claims 1 to 4, The concrete slab 40 is A steel plate deck (41) mounted on the vibration damper (20) to be installed to connect the cheolgolbo (10) to each other; On-site concrete 42 is poured over the iron plate deck (41); Composite structure of the cheolgolbo and concrete slab for damping the floor vibration, characterized in that consisting of.

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