KR20090073436A - Buckling-restrained brace and buckling-restrained brace unit thereby - Google Patents

Abstract

A buckling-restrained brace and a buckling-restrained brace unit using the same are provided to enable a hollow tube to slide along a core due to later force applied to a structure without the help of lubricating oil and center the core naturally by inserting the core into the hollow tube and fix the buckling-restrained brace on the structure. A buckling-restrained brace comprises: a hollow tube(50); a core(60) which is perpendicularly inserted inside the hollow tube, and is manufactured of metal; and a flat plate ring(70) being fixed along the outer circumference of the core at regular intervals and being inserted into the hollow tube with the core and being manufactured of metal; The flat plate ring is inserted into the hollow tube with the core and adheres to the inner circumference of the hollow tube and supporting the core on the hollow tube. The buckling-restrained brace unit comprises: the buckling-restrained brace; and a fastener unitarily fixing the both ends of the buckling-restrained brace on the structure. The fastener comprises: an end plate being unitarily fixed to the end of the core; and a base plate being unitarily fixed to the structure and being bolted or welded to the end plate.

Description

Non-buckling bracing and thereby non-buckling bracing unit {BUCKLING-RESTRAINED BRACE AND BUCKLING-RESTRAINED BRACE UNIT THEREBY}

The present invention relates to a brace and a brace unit thereby fixed integrally to a natural structure such as a rock or an artificial structure such as a bridge or a building to reinforce the rigidity of the structure while being integral with the structure.

In particular, the present invention relates to a non-buckling brace and a non-buckling brace unit thereby preventing buckling while performing a stable hysteretic behavior similar to when receiving a tension even when compressed by an axial force.

In general, natural or man-made structures are provided with braces to ensure the lateral forces of the column-beam framework against horizontal loads such as earthquakes or wind loads. These braces are used a lot of non-buckling braces that have a stable hysteresis behavior with respect to the axial force. This non-bucking bird can basically be used as a resistance system against earthquake loads. That is, the non-buckling brace dissipates the seismic energy input by hysteresis while surrendering to tensile and compressive forces when an earthquake occurs. Thus, buckling braces prevent damage to the structure. In other words, non-buckling braces prevent energy damage while countering energy during an earthquake.

Recently used non-buckling brace is produced by filling the concrete hollow tube (3) of the metal hollow tube 3, the metal core 1 is inserted as shown in FIG. At this time, the core 1 is inserted into the hollow tube 3 in a state where a lubricant such as grease is applied to the surface. Therefore, the core 1 forms a state separated from the hollow tube 3. That is, since the surface of the core 1 is not attached to the concrete 5 by the lubricating oil, the core 1 is separated from the hollow tube 3.

The non-buckling brace 10 is installed in the structure not shown to support the structure when a lateral force is applied to the structure. At this time, the core 1 is directly connected to the structure to directly support the structure, and the hollow tube 3 filled with the concrete 5 supports the outer circumferential surface of the core 1 and, while sliding by the lateral force, resists the compressive force. do. Thus, the structure is secured against lateral forces due to the bearing force of the core 1.

However, the general non-buckling bracing 10 must not only perform a process of applying lubricant to the surface of the core 1 for sliding the hollow tube 3, as described above, but also hollow the core 1 Since the concrete 5 is to be filled after the center of the hollow tube 3 is inserted into the tube 3, the manufacturing cost is excessively consumed and manufacturing is very difficult.

The present invention has been made to solve the conventional problems as described above, the hollow tubing can slide along the core by the lateral force applied to the structure without the aid of lubricant, and the core is naturally inserted into the hollow tube The purpose is to provide a non-buckling brace centered in the center of the hollow tube.

In addition, another object is to provide a non-buckling bracing unit that can be fixed to the structure as described above.

Non-buckling brace according to the present invention for achieving the above object, in the brace to reinforce the rigidity of the structure while forming a unitary structure, the hollow tube is formed therein; A metal core inserted into the hollow of the hollow tube; The core is fixed at equal intervals along the outer circumferential surface of the core and inserted into the hollow tube together with the core, and the outer circumferential surface is in close contact with the inner circumferential surface of the hollow tube to substantially support the core in the hollow tube. It includes; a plurality of metal plate ring sliding sliding friction with the inner peripheral surface of the tube.

And, the non-buckling brace unit according to an embodiment of the present invention, in the brace to reinforce the rigidity of the structure while integrally with the structure, the hollow tube formed therein; A metal core inserted into the hollow of the hollow tube; The core is fixed at equal intervals along the outer circumferential surface of the core and inserted into the hollow tube together with the core, and the outer circumferential surface is in close contact with the inner circumferential surface of the hollow tube to substantially support the core in the hollow tube. A plurality of metal plate rings sliding sliding with the inner circumferential surface of the hollow tube; And fasteners integrally fixing both ends of the core to which the flat plate ring is fixed to the structure.

Since the non-buckling brace according to the present invention is inserted into the hollow tube together with the core in a state where the flat ring is fixed to the core, the core is easily centered in the center of the hollow tube, and the flat ring slides in the hollow tube. Since the hollow tube is deformed and fixed, the hollow tube and the flat ring may also be slid when the hollow tube is deformed by the lateral force.

In addition, since the hollow tube supports the outer circumferential surface of the core through the plate ring, the rigidity of the core is also enhanced.

In particular, since the manufacturing process is completed by inserting the core with a flat plate ring into the hollow tube, there is an effect that can be easily manufactured.

On the other hand, the non-buckling bracing unit according to the present invention has the effect that can be firmly fixed to the structure the non-buckling bracing as described above through the fastener.

Hereinafter, with reference to the accompanying drawings, a non-buckling bracing according to the present invention and a non-buckling bracing unit according to the present invention will be described as follows, Figure 2 is a perspective view of the non-buckling bracing according to an embodiment of the present invention, 3 is a longitudinal cross-sectional view of the non-buckling bracing shown in Figure 2, Figure 4 is a side view showing a state of use of the non-buckling bracing unit according to an embodiment of the present invention.

2, the non-buckling bracing (BR) according to an embodiment of the present invention is a hollow tube 50 as shown; Core 60 and; And a flat ring 70.

The hollow tube 50 described above is inserted into the core 60 vertically therein as shown. The transferred core 60 is fixed to the plate ring 70 is attached to the surface at equal intervals along the outer circumferential surface as shown. The above-mentioned flat plate ring 70 is permanently fixed to the outer circumferential surface of the core 60 by welding. Therefore, the core 60 is inserted into the hollow tube 50 together with the plate ring 70.

Here, the core 60 and the plate ring 70 described above are all made of metal so as to be able to counter the lateral force. In other words, the core 60 and the plate ring 70 are made of metal. In addition, the hollow tube 50 may be configured in the form of a steel pipe, as shown by the metal material, otherwise may be configured by the precast concrete (50a) as shown in the enlarged view "C".

In addition, the hollow tube 50 and the core 60 and the flat ring 70 may be formed in a circular shape, as shown, may be formed in a polygon, such as triangular, square or octagonal, as shown. The shape of the hollow tube 50 and the core 60 and the plate ring 70 is determined by the yield strength against the lateral force.

On the other hand, when the hollow tube 50 is composed of a precast concrete (50a) can be configured to be integrally combined while being united into a plurality of divided configuration as shown in the enlarged view "C", otherwise do not divide It can also be configured in one piece. Of course, when it is configured as a single body, only the hollow is formed in the center. The hollow tube 50 is more preferably configured by inserting the reinforcing bar 52 therein as shown to enhance rigidity.

The hollow tube 50 configured as described above is manufactured in advance in a precast factory. Therefore, the hollow tube 50 is assembled with the core 60 and the plate ring 70 in a prefabricated manner. That is, the core 60 and the plate ring 70 are inserted into the hollow of the precast concrete 50a which has been manufactured and transported in advance.

Thus, the hollow tube 50 composed of precast concrete (50a) can be reinforced fiber sheet (S) wrapped on the surface as shown in the enlarged view "C". The reinforcing fiber sheet (S) is a rigid reinforcing member attached to the surface of the hollow tube 50 to support the hollow tube 50 while reinforcing the rigidity of the hollow tube 50. This reinforcing fiber sheet (S) is very robust to the precast concrete (50a) while wrapping the surface of the plurality of precast concrete (50a) as shown, when the precast concrete (50a) is divided as shown enlarged Unite yourself. Thus, the plurality of precast concretes 50a merged firmly maintain the form of a unitary body.

Of course, the reinforcing fiber sheet (S) can be applied even if the hollow tube 50 is made of a metal material as described above. That is, the reinforcing fiber sheet (S) may be wrapped on the surface of the metal hollow tube (50). Therefore, the metal hollow tube 50 maintains stronger rigidity.

As such, when the reinforcing fiber sheet S is attached to the hollow tube 50 made of the precast concrete 50a or the metal material, since the rigidity of the hollow tube 50 is strengthened, the thickness of the hollow tube 50 may be reduced. There is an advantage to that.

On the other hand, the above-mentioned reinforcing fiber sheet (S) may be applied to a fiber sheet composed of any one of carbon fiber, aramid fiber or glass fiber. The type of these fibers is determined by the designed strength.

On the other hand, the hollow tube 50 described above may be composed of a metal steel pipe 56 and a precast concrete 50a surrounding the steel pipe 56, as shown in the enlarged view "D" in the drawing. In this case, the precast concrete 50a may be divided as shown in enlarged form, or alternatively, may be composed of a single body. In addition, the precast concrete (50a) may be attached to the reinforced fiber sheet (S) on the surface as shown enlarged. This precast concrete 50a firmly supports the outer circumferential surface of the steel pipe 56. Therefore, the steel pipe 56 is greatly strengthened in rigidity.

Referring to FIG. 3, the core 60 is located at the center of the hollow tube 50 as shown. At this time, the core 60 is naturally centered in the center of the hollow tube 50 as the plate ring 70 is inserted into the hollow tube 50 as shown.

Core 60 is formed longer than the length of the hollow tube (50). Therefore, both ends of the core 60 are exposed outside the ends of the hollow tube 50. In other words, both ends of the core 60 protrude outward of the hollow tube 50.

The flat ring 70 is inserted into the hollow tube 50 together with the core 60, the outer peripheral surface is in close contact with the inner peripheral surface of the hollow tube 50. Thus, the plate ring 70 substantially supports the core 60 to the hollow tube 50. That is, the hollow tube 50 supports the outer peripheral surface (side) of the core 60 through the plate ring 70.

The flat ring 70 has an outer circumferential surface in close contact with the inner circumferential surface of the hollow tube 50, as shown in the enlarged view "A" in the drawing, but is not fixed to the inner circumferential surface of the hollow tube 50. The flat plate ring 70 slidingly rubs against the inner circumferential surface of the hollow tube 50 when the hollow tube 50 is compressed or tensilely deformed by the lateral force (axial force). Therefore, since only the hollow tube 50 is deformed by the lateral force, the core 60 is able to continuously support the structure not shown. That is, only the hollow tube 50 is yielded and buckled when the lateral force is generated, and the core 60 firmly supports the structure while maintaining the initial state or being slightly deformed by the support force of the hollow tube 50. Of course, the structure is not buckled by the bearing force of the core 60 even if the lateral force is applied.

On the other hand, the flat ring 70, as shown in the enlarged view "B" in the drawing may be formed ribs 72 to improve the bearing capacity of the core 60 to the hollow tube 50. The rib 72 is formed on the plate ring 70, as shown in the protrusion and inserted into the hollow tube 50 together with the plate ring 70, the plate ring 70 at the top of the plate ring 70 Together with one side is in close contact with the core 60, the other side is in close contact with the inner peripheral surface of the hollow tube (50). Therefore, the bearing force of the hollow tube 50 is transmitted to the core 60 not only through the flat ring 70 but also through the rib 72.

Referring to Figure 4, the non-buckling bracing according to the embodiment of the present invention, the non-buckling according to the embodiment of the present invention to be installed in the structure (S) to reinforce the rigidity of the structure (S) as shown Used as part of a new unit.

Here, the aforementioned non-buckling bracing unit is the above-described non-buckling bracing (BR) and; The non-buckling comprises a fastener (80) integrally fixing both ends of the bird (BR) to the structure (S).

The fastener 80 is, for example, an end plate 81 integrally fixed to the end of the core 60, as shown in enlarged views "C" and "D" in the drawings, and substantially identical to the core 60. ; The base plate 83 is fixed to the structure (S) to be substantially the same as the structure (S), coupled to the end plate 81 by bolting or welding; can be configured to include. Therefore, the core 60 is integrally fixed to the structure S through the end plate 81 and the base plate 83. That is, the non-buckling bracing BR according to the embodiment of the present invention is fixed to the structure (S) integrally through the end plate 81 and the base plate (83).

At this time, the fastener 80 shown in the enlarged view "C" is configured so that the end plate 81 and the base plate 83 are divided and bolted to the bolt (B). In addition, the fastener 80 shown in the enlarged view "D" is comprised so that the end plate 81 and the base board 83 may mutually be mutually the same by welding. In conclusion, the fastener 80 may divide the end plate 81 and the base plate 83, or may alternatively be composed of the same body.

On the other hand, the fastener 80, unlike the above-described enlarged view "E" as shown in the fixed flange (85) integrally fixed to the structure (S); An insertion tube 87 formed in the same body on the fixing flange 85 and into which an end of the core 60 is inserted; It may be configured to include; a support flange 89 formed in the same body at the end of the insertion tube 87 to support the end of the hollow tube (50). That is, the fastener 80 may be formed in a cylindrical shape as shown enlarged.

At this time, the support flange 89 is preferably welded to the end of the hollow tube 50 is configured to be permanently fixed to the hollow tube (50). The reason for this configuration is to prevent the end of the core 60 is separated from the insertion tube (87).

Insertion tube 87 may be formed on the outer peripheral surface of the dispersion rib 87a for dispersing the axial force transmitted from the hollow tube 50 to the fixed flange 85 as shown. The dispersion ribs 87a are formed on the outer circumferential surface of the insertion tube 87 as shown in the drawing to transmit and distribute the axial force applied from the support flange 89 to the fixed flange 85.

On the other hand, the fixing flange 85 is fixed to the structure (S) by welding or bolting after the support flange 89 is completed welding to the end of the hollow tube (50).

The non-buckling bracing unit according to the embodiment of the present invention as described above stably fixes the aforementioned non-buckling bracing BR to the structure (S) through the fastener (80). Thus, the structure S can be more firmly opposed to the lateral force.

Since the above embodiments are merely illustrative of preferred embodiments of the present invention, the scope of application of the present invention is not limited to the above, and appropriate modifications are possible within the scope of the same idea. Therefore, since the shape and structure of each component shown in the embodiment of the present invention can be carried out by deformation, it is natural that the modification of the shape and structure belong to the appended claims of the present invention.

1 is a perspective view of a typical non-buckling brace;

2 is a perspective view of a buckling brace according to an embodiment of the present invention;

3 is a longitudinal sectional view of the buckling brace shown in FIG. 2; And

Figure 4 is a side view showing a state of use of the non-buckling bracing unit according to an embodiment of the present invention.

<Description of Major Symbols in Drawing>

50: hollow tube

60: core

70: flat ring

72: rib

80: fastener

81: end plate

83: base plate

85: fixed flange

87: insertion tube

87a: Distributed rib

89: support flange

Claims (25)

In the brace to reinforce the rigidity of the structure (S) while integral with the structure (S), Hollow tube 50 is formed inside the hollow; A metal core 60 inserted into the hollow of the hollow tube 50; And It is fixed at equal intervals along the outer circumferential surface of the core 60 is inserted into the hollow tube 50 together with the core 60, the outer circumferential surface is in close contact with the inner circumferential surface of the hollow tube 50 to substantially hollow the core 60 A non-buckling bracing comprising: a plurality of metal flat plate ring (70) supported on the tube 50, sliding sliding friction with the inner circumferential surface of the hollow tube 50 by the deformation of the hollow tube 50 according to the axial force. The method of claim 1, The hollow tube 50 is a non-buckling bracing, characterized in that consisting of a metal steel pipe. The method of claim 1, The hollow tube 50 is a non-buckling bracing, characterized in that consisting of precast concrete. The method of claim 3, wherein The hollow tube 50 is divided into a plurality of non-buckling bracing, characterized in that the combined integrally. The method of claim 1, wherein the hollow tube 50, A metal steel pipe 56 into which the core 60 and the flat plate ring 70 are inserted; And Non-buckling bracing comprising a; precast concrete (50a) coupled to the outer circumferential surface of the steel pipe (56) to reinforce the rigidity of the steel pipe (56). The method of claim 1, Non-buckling bracing is further included; is fixed to the hollow tube 50, the rigid reinforcing member for strengthening the rigidity of the hollow tube 50 while supporting the hollow tube (50). The method of claim 6, wherein the rigid reinforcing member, Non-buckling bracing, characterized in that; attached to the surface of the hollow tube 50 is reinforced fiber sheet (S) to reinforce the rigidity of the hollow tube 50 in a state surrounding the hollow tube (50). The method of claim 1, wherein the flat ring 70, Non-buckling bracing, characterized in that the inner circumferential surface is fixed to the outer circumferential surface of the core 60 is permanently fixed to the core (60). The method of claim 1, wherein the flat ring 70, The buckling bracing further comprises; a rib (72) to improve the bearing capacity of the core (60) to the hollow tube (50). In the brace to reinforce the rigidity of the structure (S) while integral with the structure (S), Hollow tube 50 is formed inside the hollow; A metal core 60 inserted into the hollow of the hollow tube 50; It is fixed at equal intervals along the outer circumferential surface of the core 60 is inserted into the hollow tube 50 together with the core 60, the outer circumferential surface is in close contact with the inner circumferential surface of the hollow tube 50 to substantially hollow the core 60 A plurality of flat plate rings 70 supported on the tube 50 and slidingly frictionally with the inner circumferential surface of the hollow tube 50 by deformation of the hollow tube 50 according to the axial force; And And a fastener (80) integrally fixing both ends of the core (60) to which the flat plate ring (70) is fixed to the structure (S). The method of claim 10, wherein the flat ring 70, Non-buckling bracing unit, characterized in that the inner circumferential surface is fixed to the outer circumferential surface of the core 60 is permanently fixed to the core (60). The method of claim 10, wherein the flat ring 70, Ribs 72 to improve the bearing capacity of the core 60 with respect to the hollow tube (50); Non-buckling bracing unit further comprises. In the brace to reinforce the rigidity of the structure (S) while integral with the structure (S), Hollow tube 50 is formed inside the hollow; A metal core 60 inserted into the hollow of the hollow tube 50; It is fixed at equal intervals along the outer circumferential surface of the core 60 is inserted into the hollow tube 50 together with the core 60, the outer circumferential surface is in close contact with the inner circumferential surface of the hollow tube 50 to substantially hollow the core 60 A plurality of flat plate rings 70 supported on the tube 50 and slidingly frictionally with the inner circumferential surface of the hollow tube 50 by deformation of the hollow tube 50 according to the axial force; And And fasteners 80 integrally fixing both ends of the core 60 to which the flat plate ring 70 is fixed to the structure S. The flat ring 70, the inner peripheral surface is fixed to the outer circumferential surface of the core 60 is permanently fixed to the core 60, to improve the support force of the core 60 to the hollow tube 50 Rib 72; non-buckling bracing unit further comprises. In the brace to reinforce the rigidity of the structure (S) while integral with the structure (S), Hollow tube 50 is formed inside the hollow; A metal core 60 inserted into the hollow of the hollow tube 50; It is fixed at equal intervals along the outer circumferential surface of the core 60 is inserted into the hollow tube 50 together with the core 60, the outer circumferential surface is in close contact with the inner circumferential surface of the hollow tube 50 to substantially hollow the core 60 A plurality of flat plate rings 70 supported on the tube 50 and slidingly frictionally with the inner circumferential surface of the hollow tube 50 by deformation of the hollow tube 50 according to the axial force; And And fasteners 80 integrally fixing both ends of the core 60 to which the flat plate ring 70 is fixed to the structure S. The flat ring 70, the inner peripheral surface is fixed to the outer circumferential surface of the core 60 is permanently fixed to the core 60, to improve the support force of the core 60 to the hollow tube 50 Rib 72; further includes, It is fixed to the hollow tube 50, the rigid reinforcing member for strengthening the rigidity of the hollow tube 50 while supporting the hollow tube 50; The rigid reinforcing member is attached to the surface of the hollow tube 50, reinforcing fiber sheet (S) to reinforce the rigidity of the hollow tube 50 in a state surrounding the hollow tube 50; New units. The method according to any one of claims 10 to 14, The hollow tube 50 is a non-buckling bracing unit, characterized in that consisting of a metal steel pipe. The method according to any one of claims 10 to 14, The hollow tube 50 is a non-buckling bracing unit, characterized in that consisting of precast concrete. The method of claim 16, The hollow tube 50 is divided into a plurality of non-buckling bracing unit, characterized in that the unit is combined integrally. The method according to any one of claims 10 to 14, The hollow tube 50, A metal steel pipe 56 into which the core 60 and the flat plate ring 70 are inserted; And Non-buckling bracing comprising a; precast concrete (50a) coupled to the outer circumferential surface of the steel pipe (56) to reinforce the rigidity of the steel pipe (56). The method according to any one of claims 10 to 14, Non-buckling bracing unit further comprising; a rigid reinforcing member which is fixed to the hollow tube 50, and strengthens the rigidity of the hollow tube (50) while supporting the hollow tube (50). The method of claim 19, wherein the rigid reinforcing member, Non-buckling bracing unit, characterized in that; attached to the surface of the hollow tube 50 is reinforced fiber sheet (S) to reinforce the rigidity of the hollow tube 50 in a state surrounding the hollow tube (50). The method according to any one of claims 10 to 14, wherein the fastener 80, An end plate (81) integrally fixed to an end of the core (60) to be substantially identical to the core (60); And And a base plate (83) integrally fixed to the structure (S) to form substantially the same as the structure (S), and coupled to the end plate (81) by bolting or welding. The method according to any one of claims 10 to 14, wherein the fastener 80, A fixed flange 85 fixed to the structure S; An insertion tube (87) formed in the same body on the fixing flange (85) to insert an end of the core (60); And Non-buckling bracing unit comprising; support flange (89) formed in the same body at the end of the insertion tube (87) to support the end of the hollow tube (50). The method of claim 22, wherein the support flange 89, Non-buckling bracing unit, characterized in that the welded to the end of the hollow tube 50 is permanently fixed to the hollow tube (50). The method according to claim 22, The insertion tube 87, Non-buckling bracing unit further comprises; dispersion ribs (87a) for dispersing the axial force transmitted from the hollow tube (50) to the fixed flange (85). The method of claim 22, The support flange 89 is welded to the end of the hollow tube 50 is permanently fixed to the hollow tube 50, The insertion tube (87), non-buckling bracing unit further comprises; rib (87a) for dispersing the axial force transmitted from the hollow tube (50) to the fixed flange (85).

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