KR100952404B1 - Hybrid Buckling Restrained Brace - Google Patents

Abstract

The present invention relates to a hybrid non-buckling brace that is effective not only in a great earthquake but also in weak and wind loads. More specifically, the non-buckling brace in the inelastic region acts as a viscoelastic damper in the elastic region, and the hysteresis damper is the same as the conventional non-buckling brace. It is a hybrid non-buckling brace that can flexibly cope with earthquakes, weakness, and wind loads by resisting it.

Hybrid non-buckling brace of the present invention, steel core material; A reinforcing steel tube installed to surround the center of the steel core material, the one end of which is constrained to the steel core material so that the other end is not bound to the steel core material; An end plate having a larger area than the cross section of the steel core material, the end plate being joined to the cross section of the steel core material under the other end of the reinforcing steel tube not constrained to the steel core material; And a viscoelastic damper installed to be simultaneously restrained on the other end of the reinforcing steel tube and the end plate not restrained by the steel core material.

Non-buckling bracing, hybrid, viscoelastic dampers, hysteresis dampers

Description

Hybrid Buckling Restrained Brace

The present invention relates to a hybrid buckling restrained brace (H-BRB), which is effective not only in a great earthquake but also in weak and windy loads. More specifically, the present invention relates to a viscoelastic damper in an elastic region, and to a conventional inelastic region. By acting as a hysteresis damper such as a non-buckling brace, the present invention relates to a hybrid non-buckling brace that can flexibly respond to earthquakes, weakness, and wind loads as well as resist them.

Braced frame has a relatively high stiffness and strength, which is advantageous for resistance to horizontal loads such as earthquakes and winds. Braced frames are excellent seismic elements, and are structured to control damage caused by excessive horizontal displacement. It is applied to many elements.

However, the braced frame does not exhibit great resistance to earthquake loads because buckling occurs when the ultimate load is greater than the design earthquake load, resulting in a sudden drop in stiffness and strength, as well as less energy dissipation due to unstable behavior. There is a disadvantage in that, in addition, there is a problem that brittle fracture of the brace and the junction occurs according to the repeated load. In particular, in the case of a concentrically braced frame, an unbalanced force is applied to the tension brace and the compression brace after buckling of the compression brace. The layer that cannot support the imbalance force causes a great problem in structural stability such as damage is concentrated and formed into a soft story.

Buckling-Restrained Braces have been proposed to solve the buckling problem of braces. Non-buckling braces are proposed to produce inelastic deformation when subjected to large earthquake loads, and as shown in FIG. 1 (a), steel pipes 12 or / and fillers (mortar, concrete, etc.) 13) It is manufactured by the method of reinforcement. That is, the non-buckling brace can dissipate a lot of energy by the stable hysteretic behavior of the reinforced steel pipe and concrete, and has a high cumulative plasticity rate to become a hysteretic damper against earthquake loads. The non-buckling brace can be completed in various cross sections as shown in Figure 1 (b) depending on the shape of the steel core material 11 and its reinforcement method.

However, the non-buckling bracing as shown in FIG. 1 is installed as shown in FIG. The problem is that it does not dissipate. This means that the non-buckling bracing system is adopted to cope with earthquakes that cause large deformations in high-rise buildings where seismic performance and wind usability are important design variables. This leads to the problem of installing additional damping devices such as tuned mass dampers and tuned liquid dampers.

The present invention has been proposed to improve the above-mentioned conventional problems, and has the following technical problems.

First, the present invention has a technical problem to provide a hybrid non-buckling brace that can flexibly respond to earthquake as well as weak and wind loads.

Second, another technical problem of the present invention can dissipate energy not only for earthquake loads but also for wind loads, so that hybrid non-buckling braces can be advantageously applied to high-rise buildings that act as design variables where seismic performance and windability are important. To provide.

In order to solve the above technical problem, the present invention, the hybrid non-buckling brace of the present invention, steel core material; A reinforcing steel tube installed to surround the center of the steel core material, the one end of which is constrained to the steel core material so that the other end of the steel core material is not bound to the steel core material; An end plate having a larger area than the cross section of the steel core material, the end plate being joined to the cross section of the steel core material under the other end of the reinforcing steel tube not constrained to the steel core material; And a viscoelastic damper installed to be simultaneously restrained at the other end of the reinforcing steel tube and the end plate not restrained by the steel core material.

According to the present invention, the following effects are expected.

First, by combining viscoelastic dampers with steel cores reinforced with reinforcement steel tubes and completing them with hybrid non-buckling braces, the vibration control range confined to the strong vibration of non-buckling braces can be extended to constant vibration control by wind.

Second, since energy can be dissipated not only for earthquake loads but also for wind loads, it can be advantageously applied to high-rise buildings where seismic performance and wind usability are important design variables.

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

3 to 7 is a view showing an embodiment of a hybrid non-buckling bracing according to the present invention, as shown, the hybrid non-buckling bracing 100 of the present invention is reinforced with a steel tube core center portion 110 steel plate There is a configuration feature that is completed by binding the viscoelastic damper 200 to the existing non-buckling bracing 100 completed.

Specifically, the present invention, steel core material 110; Reinforcing steel tube 120 is installed so as to surround the central portion of the steel core member 110, one end is constrained to the steel core material and the other end is not constrained to the steel core material; End plate 130 is a member having a larger area than the cross-section of the steel core member 110, the end plate 130 is joined to the cross-section of the steel core member 110 under the other end of the reinforcing steel tube 120 that is not constrained to the steel core material; And a viscoelastic damper 200 which is installed to be simultaneously restrained on the other end of the reinforcing steel tube 120 and the end plate 130 that are not restrained by the steel core material.

As a result, the viscoelastic damper 200 dissipates energy by elastic deformation during wind or weak vibration, while the reinforcement portion of the steel core material by the reinforcing steel tube 120 hysterically acts during the earthquake to dissipate energy. That is, in the present invention, since the center portion of the steel core material 110 is reinforced while being surrounded by the reinforcing steel tube 120, as in the existing non-buckling brace, the same behavior as the existing non-buckling brace acts as a hysteresis damper. Unlike the conventional non-buckling bracing, the reinforcement steel tube 120 is installed so that one end is not constrained to the steel core material 110 while being restrained by welding to the steel core material 110, while the viscoelastic damper 200 is Since the end plate 130 and the reinforcing steel tube 120 are installed to be simultaneously constrained, when a load is applied during wind or weakening, a relative displacement occurs between the reinforcing steel tube 120 and the viscoelastic damper 200 and the viscoelastic damper ( Shear strain of 200 will dissipate energy. As a result, the hybrid non-buckling brace 100 of the present invention can extend the vibration control range to constant vibration control by wind or weak vibration as well as strong vibration.

3 to 6 are embodiments of the hybrid non-buckling brace according to the present invention, and are classified according to the type of viscoelastic damper 200 installed to be simultaneously constrained to the end plate 130 and the reinforcing steel tube 120.

3 is a first viscoelastic body 210a constrained to the outer surface of the other end of the reinforcing steel tube 120, which is not constrained to the steel core material; and the first viscoelastic body 210a therebetween; For example, a viscoelastic damper 200 configured to be disposed to face 120 and coupled to the first viscoelastic body 210a and bonded to the end plate 130 is installed. 3 shows elevation and cross section. The first viscoelastic body 210a may be restrained by attaching directly to the reinforcing steel tube 120 and the core connecting plate 220, or although not illustrated, the reinforcing steel tube 120 and the core connecting plate 220 are provided. After bonding the binding pins to each other, the binding pins may be restrained by biting the first viscoelastic body 210a.

Viscoelastic damper 200 of Figure 3 is a relative displacement between the reinforcement steel tube 120 and the core connection plate 220 as shown in Figure 4 (d) when the lateral load at the time of wind or weakening is applied to the non-buckling bracing 100 While producing a structure to dissipate energy through the shear deformation of the first viscoelastic body 210a between the reinforcing steel tube 120 and the core material connection plate 220.

FIG. 5 is an example in which a viscoelastic damper 200 is further provided to supplement the viscoelastic damper 200 of FIG. 3 to further increase the damping effect. The viscoelastic damper 200 of FIG. 4 may include a first viscoelastic body 210a and a core connection plate. In addition to (220), the second viscoelastic body (210b) bound to the outer surface of the core connecting plate 220; and the U-shaped member is divided into a central surface and both sides, the center surface is the second viscoelastic body The other end of the reinforcing steel tube 120 is disposed so as to face the reinforcing steel tube 120 with the 210b interposed therebetween, and is constrained to the second viscoelastic body 210b and both sides are not constrained to the steel core material. It is configured to further include; tube connection plate 230 bonded to the surface. This becomes more apparent when looking at the cross-sectional view of FIG.

The viscoelastic damper 200 of FIG. 5 is applied to the reinforcing steel tube 120 and the core connecting plate 220 as shown in FIG. 6 (d) when the lateral load at the time of wind or weakness is applied to the non-buckling bracing 100. The first viscoelastic body 210a and the core connecting plate 220 between the reinforcing steel tube 120 and the core connecting plate 220 while causing a relative displacement between the connecting plate 220 and the tube connecting plate 230. It becomes a structure that dissipates energy through the shear deformation of the second viscoelastic body 210b between the tube connection plate 230. Since the tube connecting plate 230 is directly bonded to the reinforcing steel tube 120, the tube connecting plate 230 causes displacement in the same direction as the reinforcing steel tube 120, but the intermediate core connecting plate 220 is The first and second viscoelastic layers 210a and 210b are connected to the reinforcing steel tube 120 and the tube connecting plate 230, but do not directly bond with them, causing relative displacement with them.

4 and 6 show an example in which the pin joint 310 is further bonded to the end plate 130 for the pin joint installation of the hybrid non-buckling brace according to the present invention. It is also possible to pin the hybrid non-buckling bracing 100 by bolting 130 directly to the framework.

In addition, FIG. 7 shows an example in which the + -shaped moment junction 320 is further bonded to the end plate 130 for the moment junction installation of the hybrid non-buckling brace according to the present invention. In particular, Figure 7 (b) and Figure 7 (c) shows the moment bonding detail, the + -shaped bracket 400 bonded to the frame back to the + -shaped moment junction (320) of the hybrid non-buckling bracing brace connected to the connection plate ( 410 is joined by a high-strength bolt 420. Of course, it is also possible to moment-bond the hybrid non-buckling bracing 100 by welding the end plate 130 directly to the frame without a separate moment junction (320).

Meanwhile, the present invention proposes a state in which two viscoelastic dampers 200 are installed at positions facing each other in parallel to a web of the H-steel core 110 through FIGS. 3 to 7. Of course, the steel core material 110 can be adopted as a member of a variety of cross-section, but the present invention proposes an excellent H-section steel section performance. Considering the installation state of the non-buckling bracing 100 consisting of the H-shaped steel core member 110, the viscoelastic damper 200 is installed side by side with the web of the H-shaped steel core core 110, the viscoelastic damper 200 and the installation finish It is preferable to reduce the interference. In addition, when two viscoelastic dampers 200 are disposed to face each other, balanced vibration control is possible.

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.

1 and 2 is a view showing a conventional non-buckling brace and its installation state.

3 to 7 show an embodiment of a hybrid non-buckling brace according to the present invention.

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

10: Existing Unbuckled Braces

100: Hybrid Unbuckled Brace

11, 110: steel core material 12, 120: reinforcing steel tube

130: end plate

200: viscoelastic damper

210a: first viscoelastic body 210b: second viscoelastic body

220: core connecting plate 230: tube connecting plate

310: pin joint hole 320: moment joint hole

Claims (4)

delete delete Steel core material 110; Reinforcing steel tube 120 is installed so as to surround the central portion of the steel core member 110, one end is constrained to the steel core material, the other end is not constrained to the steel core material; End plate 130 is a member having a larger area than the cross-section of the steel core member 110, the end plate 130 is joined to the cross-section of the steel core member 110 under the other end of the reinforcing steel tube 120 that is not constrained to the steel core material; And, And a viscoelastic damper (200) installed to be simultaneously restrained at the other end of the reinforcing steel tube (120) and the end plate (130) that are not restrained by the steel core material. The viscoelastic damper 200, A first viscoelastic body 210a coupled to the outer surface of the other end of the reinforcing steel tube 120 not bound to the steel core material; A core material connection plate 220 disposed to face the reinforcing steel tube 120 with the first viscoelastic body 210a interposed therebetween and constrained to the first viscoelastic body 210a and bonded to the end plate 130; A second viscoelastic body 210b constrained to an outer surface of the core connecting plate 220; The U-shaped member is divided into a central surface and both sides, the central surface is disposed so as to face the reinforcing steel tube 120 with the second viscoelastic body (210b) between the restrained coupling to the second viscoelastic body (210b) And, both sides of the tube connecting plate 230 is bonded to the outer surface of the other end of the reinforcing steel tube 120 is not constrained to the steel core material; Hybrid non-buckling brace, characterized in that consisting of. 4. The method of claim 3, The steel core material 110 is H-shaped steel, The viscoelastic damper 200 is a hybrid non-buckling brace, characterized in that the two are installed in a position facing each other between the web of the H-shaped steel core material 110.

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