KR20200092824A - O-shaped buckling-restrained brace with internal filler - Google Patents

Abstract

The present invention relates to an O-shaped buckling prevention brace filled with internal fillers and, more specifically, to an O-shaped buckling prevention brace which is filled with internal fillers instead of mortar used as the fillers of the existing buckling prevention brace, thereby having more excellent internal pressure and deformation capacities compared to the prior art to resist external pressure. Provided is the O-shaped buckling prevention brace filled with the internal fillers to secure excellent lateral force and deformation capacities, thereby restricting a core material of the steel brace to induce stable deformation even when a large compressive force is applied. Thus, the O-shaped buckling prevention brace can decrease the entire weight and shorten a manufacturing time. To this end, the O-shaped buckling prevention brace includes a hollow pipe, the core material and a PCM layer.

Description

O-Shaped Bulkling-RESTRAINED BRACE WITH INTERNAL FILLER}

The present invention relates to an O-shaped buckling prevention brace filled with an inner filler, and more specifically, a PCM layer is integrally formed between a tube body and a core material inserted into a double structure to improve seismic performance through stable energy dissipation, , PCM layer reduces weight by more than 40% compared to the existing concrete reinforcement, and has excellent field construction, while the PCM layer is stretched and controlled in the field using the property that the strength is expressed within 24 hours after filling. It relates to an O-shaped buckling prevention brace filled with an internal filler that is elastically adjusted in length regardless of the distance variation of various steel structures.

In general, the brace (Brace) has a relatively high stiffness and strength, so it is advantageous for resistance to horizontal loads such as earthquakes and winds. Therefore, the brace is an excellent seismic element that controls damage caused by excessive horizontal displacement. Although it is widely applied, it is not only that the stiffness and strength are sharply reduced due to the buckling when an extreme load over the design earthquake load is applied, and the amount of energy dissipation is reduced due to unstable behavior, which does not exert a great resistance to earthquake loads. It has the disadvantage of not being able to.

In order to solve the buckling problem of the above brace, a buckling-restrained braces was proposed. Non-buckling braces are registered in Patent No. 10-1461805, in which a hollow material is formed inside and a deformation inducing part that induces deformation so that plastic deformation according to a load transmitted from the structure occurs at two or more positions. Including a steel core material having improved energy dissipation, including the deformation-inducing portion, the central steel member disposed at the center of the steel core member and the side steel members disposed at both sides of the steel core member are arranged to have different strengths. The central side steel material is formed with a higher strength than the both side steel materials, and a technique for inducing plastic deformation of the steel core material to occur on both sides of the central steel material has been previously registered.

However, the prior art is capable of dissipating a lot of energy by the stable hysteretic behavior of the steel core material and concrete, but as the concrete is filled between the core material and the base material, the weight increases, and the construction workability decreases, especially after pouring concrete. Since it takes more than 7 days to cure, the construction period was delayed, and in response to the distance error of the steel structure, the size was impossible to correct in the field.

Korean Registered Patent No. 10-1461805 (Registered on Nov. 4, 2014)

Accordingly, the present invention has been devised to solve the above-mentioned problems, and the PCM layer is integrally formed between the tube body and the core material inserted into the double structure to improve the seismic performance with stable energy dissipation, and the existing concrete due to the PCM layer. The weight is reduced by more than 40% compared to the reinforcement, and the field construction is excellent, and the PCM layer is stretch-controlled and filled with the PCM layer in the field using the characteristic that the strength is expressed within 24 hours after filling. The object is to provide an O-shaped buckling preventing brace filled with an inner filler that is elastically adjusted in length without any effect.

According to a preferred embodiment of the present invention, it is formed in a circular cross-sectional shape, the hollow tube 100 is hollow inside; The core material 200 is formed in a circular cross-sectional shape, accommodated in the tube body 100, and has an end plate 210 connected to the steel structure 1 at both ends and a polygonal hollow hole 220 therein. ; And a phase change material (PCM) is filled in a space between the tube body 100 and the core material 200, so that the PCM layer 300 is provided so that the inner peripheral surface of the tube body 100 and the outer peripheral surface of the core material 200 are integrally connected. ); is characterized by including.

According to another embodiment of the present invention, the tube body 100 is characterized in that it further comprises a side plate 110 at both ends to close between the tube body 100 and the core material 200.

According to another embodiment of the present invention, the center of the side plate 110 is formed with a diameter larger than the diameter of the core material 200, the through hole 111 having the same shape as the cross-sectional shape of the core material 200, through It characterized in that it further comprises a wedge-shaped stopper 112 that is fitted between the through-hole 111 and the core material 200 in a state where the core material 200 is inserted into the hole 111.

According to another embodiment of the present invention, one end of the end plate 210 is inserted into the hollow hole 220 formed in the core material 200, and the rod rods are elastically adjusted along the longitudinal direction of the hollow hole 220 ( 211), and characterized in that it further comprises a joint 213 fastened to the adjustment hole 212 and the adjustment hole 212 formed through one surface.

According to another embodiment of the present invention, the rod rod 211 further includes a plurality of filling bones 211a formed on the outer circumferential surface, and after the rod rod 211 is elastically adjusted, the tube body 100 and the core material When the phase change material is injected into the space between (200), the phase change material is filled between the plurality of filling bones 211a through the through holes 230 formed in the core material 200, and the PCM layer 300 is formed. It characterized in that the position of the rod rod 211 is fixed.

According to another embodiment of the present invention, the hollow hole 220 is connected to the rod rod 221, so that when the buckling stress is greater than or equal to the set value, the hollow hole 220 is allowed to expand and contract. It is characterized in that it further comprises an elastic body 221 or a hydraulic cylinder 222 installed on the inside.

According to another embodiment of the present invention, the elastic body 221 is characterized in that it is composed of at least one or more of a spring, a rubber block, a damper.

According to another embodiment of the present invention, the hydraulic cylinder 222 is installed on one or both sides of the core material 200, the first and second ports (222a, 222b) to which fluid is introduced and discharged, and the first , 2 ports (222a, 222b) is connected to the flow control valve 222c that is turned on/off so as to be connected/closed, and is connected to the flow control valve 222c, in the center of the hollow hole 220 formed in the core 200 When the detection value of the buckling detection unit 222d reaches a set value of buckling stress by further including the buckling detection unit 222d installed, the flow control valve 222c is turned on to allow expansion and movement of the end plate 210. It is characterized by being configured as possible.

According to another embodiment of the present invention, the hollow hole 220 is formed in the same shape as the cross-sectional shape of the hollow hole 220 therein, a reinforcing block formed with a length smaller than the length of the hollow hole 220 (223), the one end is connected to the end plate 210, the other side of the reinforcing block 223 further includes a rope 224, the rope 224 is formed in the end plate 210, the control device ( It is fastened to the joint 213 in the state exposed to the outside of the hollow hole 220 through 212 and adjusted in length, and the reinforcement block 223 installed and inserted into the hollow hole 220 according to the length adjustment of the rope 224 Characterized in that it is configured to adjust the position of.

On the other hand, since the description of the technology disclosed in this specification is merely an embodiment for structural or functional description, the scope of rights of the disclosed technology should not be interpreted as being limited by the embodiments described in the text. That is, since the embodiments can be variously changed and have various forms, it should be understood that the scope of rights of the disclosed technology includes equivalents capable of realizing the technical idea. In addition, the purpose or effect presented in the disclosed technology does not mean that a specific embodiment should include all or only such an effect, so the scope of rights of the disclosed technology should not be understood as being limited thereby.

In addition, the meaning of the terms described in the present invention should be understood as follows. Terms such as “first” and “second” are for distinguishing one component from other components, and the scope of rights should not be limited by these terms. For example, the first component may be referred to as a second component, and similarly, the second component may be referred to as a first component.

Furthermore, it should be understood that when a component is said to be "connected" to another component, it may be directly connected to the other component, but other components may exist in the middle. On the other hand, when a component is said to be “directly connected” to another component, it should be understood that no other component exists in the middle. On the other hand, other expressions describing the relationship between the components, that is, “between” and “between” or “neighboring to” and “directly neighboring to” should be interpreted similarly.

Singular expressions are to be understood as including plural expressions unless the context clearly indicates otherwise, and terms such as “comprises” or “having” refer to the features, numbers, steps, actions, components, parts or components described. It is to be understood that a combination is intended to indicate the existence, and does not preclude the existence or addition possibility of one or more other features or numbers, steps, operations, components, parts or combinations thereof.

According to the above configuration and operation, the present invention has a PCM layer integrally formed between a tube body and a core material inserted into a double structure to improve seismic performance through stable energy dissipation, and the PCM layer has a weight of 40% or more compared to a conventional concrete reinforcement. This is reduced, and the field construction is excellent, and the PCM layer is stretched and adjusted in the field using the property that the strength is expressed within 24 hours after filling, and the PCM layer is filled and formed to be elastically adjusted regardless of the distance variation of various steel structures. It works.

1 is a view showing the overall configuration of the O-buckling prevention brace filled with an internal filler according to an embodiment of the present invention.
Figure 2 is a block diagram showing the internal structure of the O-shaped buckling prevention brace filled with an internal filler according to an embodiment of the present invention.
3 is a block diagram showing a state of filling a phase change material into the space between the tube body and the core of the O-buckling prevention brace filled with an internal filler according to an embodiment of the present invention.
Figure 4 is a block diagram showing the longitudinal cross-sectional shape of the O-buckling prevention brace filled with an inner filler according to an embodiment of the present invention.
5 is a block diagram showing the end plate expansion and contraction adjustment structure of the O-shaped buckling prevention brace filled with an inner filler according to an embodiment of the present invention.
6 is a block diagram showing the end plate expansion and contraction adjustment structure by a hydraulic cylinder of an O-shaped buckling prevention brace filled with an inner filler according to an embodiment of the present invention.
7 is a block diagram showing a reinforcing block of an O-shaped buckling prevention brace filled with an inner filler according to an embodiment of the present invention.
Figure 8 is a block diagram showing the end plate expansion and contraction control structure by the PCM layer of the O-shaped buckling prevention brace filled with an inner filler according to an embodiment of the present invention.
Figure 9 is a test result table showing the load-displacement hysteresis curve (within the standard force) of the brace applied with the existing concrete reinforcement and the O-shaped buckling prevention brace filled with the inner filler of the present invention.
10 is a test result table showing a skeletom curve (within standard force) of the brace to which the O-shaped buckling prevention brace filled with the inner filler of the present invention and the existing concrete reinforcement are applied.
11 is a test result table showing the load-displacement hysteresis curve (within fatigue force) of the brace applied with the existing concrete reinforcement and the O-shaped buckling prevention brace filled with the inner filler of the present invention.
Figure 12 is a test result table showing the cumulative dissipation energy of the brace applied to the O-shaped buckling prevention brace and the existing concrete reinforcing material filled with the internal filler of the present invention.

Hereinafter, the present invention will be described in more detail with reference to preferred embodiments.

The present invention relates to an O-shaped buckling prevention brace filled with an inner filler, wherein the lightweight non-buckling brace system using PCM filler is a single layer of PCM between the tube body and the core that is inserted and formed to provide stable energy. Seismic performance is improved by dissipation, and the weight is reduced by 40% or more compared to the existing concrete reinforcement due to the PCM layer. After filling the PCM layer to make the length adjustable elastically regardless of the distance variation of various steel structures, it consists of the main components including the tube body (100), the core material (200), and the PCM layer (300).

The tube body 10 according to the present invention is formed of an empty hollow tube. At this time, the tube body 100 is formed of a circular tube or a polygonal tube, and FIG. 4 shows a state in which the tube body 100 is formed as a circular tube according to the present invention.

In addition, the tube body 100 has side plates 110 installed at both ends, and is provided to close between the tube body 100 and the core 200 described later. Figure 2 shows a state in which the core material 200 is installed inside the tube body 100, the core material 200 is formed in a smaller size than the inner diameter of the tube body 100, after assembly between the tube body 100 and the core material 200 An empty space is formed, and both ends of the space are closed by the side plate 110 to form an isolated compartment for filling a phase change material, which will be described later.

In addition, the core material 200 according to the present invention is accommodated in the tube body 100, end plates 210 are provided at both ends to be connected to the steel structure (1). The core material 200 is formed in a cross-sectional shape of any one of circular, polygonal, T-shaped, I-shaped, H-shaped and +-shaped, and is made of steel structure 1 by end plates 210 provided at both ends as shown in FIG. 1. ) Is used as a brace connecting between the frames.

At this time, in the center of the side plate 110, a through hole 111 having an extended size compared to the cross-sectional shape of the core 200 is formed, and the through hole 111 in a state where the core material 200 is inserted and installed in the through hole 111. Between the core material 200 and the wedge-shaped stopper 112 is fitted to be fitted to position.

Accordingly, the through-hole 111 is formed in an expanded size compared to the outer diameter of the core 200 to prevent interference with the side plate 110 when the core 200 is inserted into the tube body 100, and thereafter the wedge-shaped stopper 112 When fitted between the through-hole 111 and the core material 200, the core material 200 is firmly fixed in the center of the through-hole 111. On the other hand, the wedge-shaped stopper 112 is formed in the same shape as the outer circumferential surface of the core material 200, and a locking jaw is formed at one end to be closely fixed on the side plate 110.

In addition, the PCM layer 300 according to the present invention is provided so that the phase change material is filled in the space between the tube body 100 and the core material 200, so that the inner peripheral surface of the tube body 100 and the outer peripheral surface of the core material 200 are integrally connected. . The PCM layer 300 is formed on the side plate 110 as shown in FIG. 3, and is formed in a space between the tube body 100 and the core 200 by introducing a phase change material (PCM) through the injection port. At this time, the phase change material (PCM) is an elastomer, and is a lightweight material with a density of 1,180 kg/m 3. It absorbs or releases a lot of energy according to the change in the state of the material, exhibits excellent ductility, and has excellent energy dissipation ability. It is changed into a liquid and filled in the space between the tube body 100 and the core material 200, and then fixed while being cooled to form the PCM layer 300, and solidifies in the liquid phase within 24 hours to express structural strength, so manufacturing time and field construction This is possible.

That is, the PCM layer 300 is integrally formed between the tube body 100 and the core material 200 which are inserted and formed into a double structure, and the seismic performance is improved by stable energy dissipation, and in particular, the existing concrete is due to the PCM layer 300. The weight is reduced by more than 40% compared to the reinforcing material (e.g., when the PCM layer 300 reinforcing material is applied based on the tube body 100 of 300*300*3300mm, it is 290kg, whereas in the case of the existing concrete reinforcing material, the weight is reduced by 46% to 532kg) It has the advantage of excellent on-site workability.

Meanwhile, FIGS. 9 to 12 are brace performance test result tables to which the PCM layer 300 of the present application is applied and existing concrete reinforcement, and FIG. 9 is a test result table showing a load-displacement hysteresis curve (within the standard force), and FIG. 10 Is a test result table showing a skeletom curve (within standard force), FIG. 11 is a test result table showing a load-displacement hysteresis curve (within fatigue force), and FIG. 12 is a test result table showing cumulative dissipation energy. As shown in the test result table, while the performance of the brace applied with the PCM layer 300 of the present application and the brace applied with the existing concrete reinforcement is very different, the present application has an advantage of reducing the weight and shortening the manufacturing period.

In addition, the core material 200 is formed of a tube body 100 in which a hollow hole 220 is formed. Figure 4 (a) shows a hollow hole 220 is formed in a circular shape, Figure 4 (b) shows a rectangular hollow hole 220, but is not limited to polygonal, T-type, I-type, H-type and It is also possible to form a hollow hole having a cross-sectional shape in any one of + shapes.

In FIG. 5, the end plate 210 is provided with a rod rod 211 at one end, and the rod rod 211 is provided to be stretch-controlled through the hollow hole 220 of the core 200, and the rod rod 211 ) Is connected to the elastic body 221 or the hydraulic cylinder 222 installed in the hollow hole 220 of the core material 200, and is provided to allow expansion and contraction movement when the buckling stress is greater than or equal to the set value. Rod rod 211 is formed in the same cross-sectional shape as the hollow hole 220, the length is adjusted while being transported straight through the hollow hole 220.

In addition, the rod rod 211 has one end connected to the elastic body 221 or the hydraulic cylinder 222, wherein the elastic body 221 is composed of at least one of a spring, a rubber block, and a damper, and the elastic body 221 When the buckling stress acts above the set value by its own elastic strength, the elastic rod rod 211 is provided to be allowed to move, or it is fixed by a trigger composed of a separate key and keyway, and the buckling stress acts above the set value. When the trigger is unlocked, it is possible to configure the rod rod 211 to be moved.

In FIG. 6, the hydraulic cylinder 50 is provided with first and second ports 222a, 222b for fluid input and discharge while being installed on one or both sides of the core 200, and operates on/off of the flow control valve 222c. It is configured to connect/close the first and second ports 222a and 222b, and the flow control valve 222c is connected to the buckling detection unit 222d installed in the center of the hollow hole 220 of the core 200. .

At this time, when the first and second ports 222a and 222b communicate by the flow control valve 222c on operation, the fluid filled in the compression chambers on both sides of the piston of the hydraulic cylinder 50 is freely shared while the hydraulic cylinder 50 length Is configured to switch to the free movement state.

In addition, the buckling detection unit 222d is provided as a sensor type, and the on/off operation of the flow control valve 222c is controlled by the control unit, or the buckling detection unit 222d is formed as a hydraulic cylinder type, and is provided in the hollow hole 220. When the core 200 is bent by the buckling by installing both ends supported on the wall, the hydraulic cylinder type buckling detection unit 222d is compressed, and at this time, the flow control valve 222c is turned on/off by the compressed hydraulic pressure. It can also be configured.

Accordingly, when the detection value of the buckling detection unit 222d reaches a set value of buckling stress, the flow control valve 222c is turned on to allow expansion and contraction of the end plate 210, thereby causing brace damage due to stress to the strong buckling stress. Prevention and longevity are prolonged. On the other hand, when the detection value of the buckling detection unit 222d reaches the buckling stress setting value, a warning signal (alarm tone, danger signal transmission by a communication network, announcement) is sent to prevent a disaster (system emergency transmission, rescue, and recovery personnel) It is also possible to activate the input command transmission).

In FIG. 7, a hollow hole 220 and a reinforcing block 223 having the same shape as the cross-sectional shape are inserted into the hollow hole 220 of the core 200, and the reinforcing block 223 is a hollow hole 220 It is formed in a size shorter than the length, and is connected to one end plate 210 by a rope 224, and the rope 224 has a hollow hole through an adjusting hole 212 formed at one end plate 210. 220) The length is adjusted by being fastened to the joint 213 in an exposed state, and is provided so that the position of the reinforcing block 223 in the hollow hole 220 is adjusted by the length of the rope 224.

Here, the rope 224 calculates the distance from the adjuster 212 to the central position in the longitudinal direction of the hollow hole 220, and the value is obtained by subtracting the half value of the length of the reinforcing block 223 to the hollow hole 220 When entering the inside and fixing the position by fastening the joint 213 to the rope 224 from the outside of the hollow hole 220, the reinforcing block 223 is located at the midpoint in the longitudinal direction of the hollow hole 220 to concentrate the buckling stress. The durability of the bracing middle area is reinforced. Meanwhile, in FIG. 7, the reinforcing block 223 is installed in one place, but is not limited thereto, and it is also possible to install two or more spaces apart on the rope 224.

In FIG. 8, the end plate 210 is provided with a rod rod 211 at one end, a plurality of filling bones 211a are formed on the outer circumferential surface of the rod rod 211, and the rod rod 211 is the core 200 A hollow hole 220 is provided to be stretch-controlled, and the through-hole 230 penetrates into a plurality of locations in a 360° direction along the circumference of the core 200, and the rod rod 211 in consideration of the distance of the steel structure 1 ) After the expansion and contraction adjustment, when the phase change material is injected into the space between the tube body 100 and the core material 200, the phase change material is filled between the plurality of filling bones 211a through the through hole 230 and the PCM layer 300 ) Is formed, the position of the rod rod 211 is fixed.

That is, one end plate 210 is connected to the steel structure 1, and the other end plate 210 is stretched and adjusted by the rod rod 211 to fasten the other side of the steel structure 1. Subsequently, when the phase change material is injected into the space between the tube body 100 and the core material 200, the PCM layer 300 is formed while being filled and solidified to the inside of the plurality of filling bones 211a through the through hole 230, and the PCM layer 300 serves as a fixing means for fastening the core 200 and the rod rod 211 in the 360° direction.

As described above, the rod rod 211 is fixed inside the hollow hole 220 of the core 200 by the PCM layer 300, and thus has excellent dissipation ability against buckling stress when an external force (earthquake) is applied, particularly the PCM layer ( 300) After the charge is performed, the entire length of the core 200 is adjusted simply by adjusting the position of the end plate 210 in the field using the property of expressing strength within 24 hours, and then filling the PCM layer 300 to form it. The versatility of precision construction is provided regardless of the distance deviation (error) of various steel structures.

Although described above with reference to preferred embodiments of the present invention, those skilled in the art variously modify and change the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. You can do what you can.

1: Steel structure 100: tube body
110: side plate 111: through hole
112: stopper 200: core material
230: through 210: end plate
212: adjuster 211: rod rod
211a: filling bone 220: hollow hole
300: PCM layer 211: elastic body
222: hydraulic cylinder 222a: first port
222b: second port 222c: flow control valve
222d: Buckling detection unit 223: Reinforcement block
224: rope 213: joint

Claims (7)

A hollow tube body 100 formed in a circular cross-sectional shape and having an empty interior;
The core material 200 is formed in a circular cross-sectional shape, accommodated in the tube body 100, and has an end plate 210 connected to the steel structure 1 at both ends and a polygonal hollow hole 220 therein. ; And
A phase change material (PCM) is filled in a space between the tube body 100 and the core material 200, and the PCM layer 300 is provided so that the inner peripheral surface of the tube body 100 and the outer peripheral surface of the core material 200 are integrally connected. O-buckling prevention brace filled with an internal filler, characterized in that it comprises a.
According to claim 1, wherein the tube body 100 has an O-shaped buckling prevention is filled with an inner filler, characterized in that it further comprises a side plate (110) at both ends to close between the tube body (100) and the core material (200). bird.
According to claim 2, The center of the side plate 110 is formed with a diameter larger than the diameter of the core material 200, the through-hole 111 and the through-hole 111 of the same shape as the cross-sectional shape of the core material (200) O-buckling prevention with an inner filler filled with an inner filler characterized in that it further comprises a wedge-shaped stopper 112 that is fitted between the through-hole 111 and the core 200 in a state where the core material 200 is inserted and installed. bird.
According to claim 1, One end of the end plate (210) is inserted into the hollow hole (220) formed in the core material (200) and the rod rod (211) that is stretch-controlled along the longitudinal direction of the hollow hole (220), and one surface O-buckling prevention brace filled with an internal filler, characterized in that it further comprises a joint 213 that is fastened to the throttle 212 and throttle 212 formed therethrough.
According to claim 4, The rod rod 211 further comprises a plurality of filling bone (211a) formed on the outer circumferential surface, after the rod rod 211 is elastically adjusted, between the tube body 100 and the core material (200) When the phase change material is injected into the space, the phase change material is filled between the plurality of filling bones 211a through the through holes 230 formed in the core material 200, and the PCM layer 300 is formed to form the rod rod 211. O-buckling prevention brace filled with an internal filler, characterized in that the position of the fixed.
According to claim 4, The hollow hole 220 is connected to the rod rod 221 is installed on the inside of the hollow hole 220 to allow the expansion and contraction of the rod rod 211 when the buckling stress acts above the set value O-buckling prevention brace filled with an inner filler, characterized in that it further comprises an elastic body (221) or a hydraulic cylinder (222).
According to claim 6, The elastic body 221 is spring, rubber block, damping prevention brace O-shaped filled with an internal filler, characterized in that at least one or more of a damper.

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