CN113417502B - Double-yield-point buckling restrained brace - Google Patents

Abstract

The utility model provides a two yield point bucking restraint support, includes the body, and the body includes the linkage unit at core unit, outer restraint unit, unbonded slip mechanism unit and both ends, and the core unit includes the compoboard of surrendering stage by stage, and the compoboard of surrendering stage by stage includes first surrendering steel board and second surrendering steel board, and outer restraint unit includes overcoat steel pipe and stopping, and unbonded slip mechanism unit sets up between core unit and stopping, linkage unit fixed connection is in the outside of the first linkage segment and the second linkage segment of joining region. The buckling restrained brace comprises two yielding sections, the buckling restrained brace is provided with two yielding points through the structure, energy consumption can be achieved through yielding under a small earthquake, the structural deformation is increased along with the increase of the earthquake action, and when the earthquake reaches a medium earthquake or a large earthquake, the second yielding section enters a working state, so that the requirement of the earthquake-resistant performance design of the structure is well met.

Description

Double-yield-point buckling restrained brace

Technical Field

The invention relates to a structural anti-seismic component, in particular to a buckling restrained brace capable of yielding in stages.

Background

The buckling restrained brace is composed of a core energy consumption section and an outer-coated restraining component, when the core energy consumption section bears axial pressure, the outer-coated restraining unit is used for restraining the transverse deformation of the core energy consumption section, buckling of the core energy consumption section is prevented, the core energy consumption section can be subjected to full-section yielding under the action of axial force, and symmetrical stress performance is obtained in the stretching and compressing directions. The buckling restrained brace has the characteristics of clear damping mechanism, obvious damping effect, safety, reliability, economy and reasonability, and can meet the anti-seismic requirements of different structures. Under the normal use state and the action of small earthquake, the buckling restrained brace provides lateral stiffness for the building structure, and plays a role of common bracing; under the action of a large earthquake, the buckling restrained brace can dissipate the energy input by the earthquake through repeated pulling and pressing hysteresis.

The buckling restrained brace is characterized in that an energy consumption section is a main stressed unit and is generally made of steel with a low yield point, the restraining unit provides a restraining mechanism to prevent the energy consumption unit from being unstable or bent partially when being pressed, the restraining unit can be made of steel pipe concrete, a steel concrete coat, a circular or polygonal steel pipe and the like, and an unbonded material provides a sliding interface between the energy consumption unit and the restraining unit, so that the buckling restrained brace has similar mechanical properties when being pulled and pressed as much as possible, and the increase of axial force caused by friction between the energy consumption unit and the restraining unit after being pressed and expanded is avoided. In general, the buckling-restrained energy-dissipation brace only has one yielding section, does not yield under the action of a frequent earthquake, only provides additional rigidity, does not participate in energy dissipation, and provides additional rigidity and additional damping under the action of a rare earthquake.

In recent years, some researchers begin to develop a staged yielding buckling restrained brace, one part of the yielding restrained brace firstly yields and consumes energy under a small earthquake, and most of the yielding restrained brace yields and consumes energy under a medium earthquake or a large earthquake, so that the energy consumption capability of the yielding restrained brace for resisting earthquakes with different strengths is effectively improved. The existing implementation method of the staged energy consumption buckling restrained brace comprises the combination of dampers with different energy consumption mechanisms and the combination of dampers with different energy consumption materials. For example, oucault indica et al sets a friction damper between a sleeve and a connecting section of a common buckling restrained brace, the friction damper and an energy dissipation section of the buckling restrained brace are in a parallel connection relationship to form a composite energy dissipater yielding in stages, because the rigidity of the energy dissipation section of the buckling restrained brace is far greater than the initial rigidity of the friction damper, the buckling restrained brace bears more axial force, and because the rigidity of the friction damper is smaller, the axial force shared by the friction damper is limited, thereby influencing the energy dissipation effect of the friction damper under a small earthquake; ma Hua and the like adopt a mode that an energy consumption section with a low yield point and an energy consumption section with a high yield point are connected in parallel, and the problem also exists, the rigidity of the energy consumption section with the high yield point is much higher than that of the energy consumption section with the low yield point, so that the energy consumption of the energy consumption section with the low yield point is greatly influenced, and the staged yield cannot be well realized.

Disclosure of Invention

The invention aims to provide a buckling restrained brace with double yield points, and aims to solve the technical problems that the rigidity of an energy consumption section with a high yield point is higher than that of an energy consumption section with a low yield point, so that the energy consumption of the energy consumption section with the low yield point is greatly influenced, and the staged yielding cannot be really realized.

In order to realize the purpose, the invention adopts the following technical scheme:

a double-yield-point buckling restrained brace comprises a body, wherein the body comprises a core unit, an outer restraining unit, an unbonded sliding mechanism unit and connecting units at two ends,

the core unit comprises a staged yield composite plate, the staged yield composite plate comprises a first yield steel plate and a second yield steel plate which are arranged in the front and back centers, are opposite to each other, are tightly adhered and are fixedly connected, the thickness of the first yield steel plate is smaller than that of the second yield steel plate, the first yield steel plate and the second yield steel plate are both steel plates with straight cross sections,

the stress area of the body is divided into a core area at the middle part, transition areas at two sides of the core area and connecting areas at the outer sides of the transition areas along the longitudinal direction,

the first yield steel plate comprises a first core section positioned in the core area, a first transition section positioned in the transition area and a first connecting section positioned in the connecting area,

the second yield steel plate comprises a second core section positioned in the core area, a second transition section positioned in the transition area and a second connecting section positioned in the connecting area,

the length of the first core segment is longer than the length of the second core segment,

the external constraint unit comprises an outer sleeve steel pipe sleeved outside the core unit and also comprises a filling material filled between the outer sleeve steel pipe and the core unit, the unbonded sliding mechanism unit is arranged between the core unit and the filling material,

the connecting unit is fixedly connected to the outer sides of the first connecting section and the second connecting section of the connecting area.

The first yield steel plate and the second yield steel plate have the same length.

The plate width of the first core section is smaller than that of the second core section, and the plate widths of the first connecting section and the second connecting section are the same.

The first connecting section has a plate width greater than that of the first core section, and the first transition section smoothly transitions between the first core section and the first connecting section.

The second connecting section has a plate width greater than that of the second core section, and the second transition section smoothly transitions between the second core section and the second connecting section.

The cross section of the outer sleeve steel pipe is rectangular.

The stopping is the concrete, the unbonded coating that the unbonded slip mechanism unit set up for core unit surface still is equipped with one deck slidable material between first yield steel board and the second yield steel board, slidable material is polytetrafluoroethylene.

The edge of the outer sleeved steel pipe is aligned with the outer edge of the first transition section.

The linkage unit includes coupling assembling, coupling assembling is including connection group board and connecting bolt, connection group board is including pressing from both sides the splint of establishing in the outside of first linkage segment and second linkage segment, two parallels, set up a set of bolt hole that supplies connecting bolt to pass on the splint, also opened corresponding first connecting hole and second connecting hole on the position that this bolt hole corresponds first linkage segment and second linkage segment, first connecting hole, second connecting hole and bolt hole align one by one and pass through the connecting bolt and connect, connection group board still includes the limiting plate of perpendicular fixed connection in the splint outside, the inboard surface of limiting plate is all hugged closely with the outside end face of second connecting plate to the outside end face of first linkage segment, connection group board still includes the otic placode of fixed connection in the limiting plate outside placed in the middle, the otic placode is parallel and it has the otic placode hole to surmount the combined plate with surrender stage.

The first connecting hole and the second connecting hole are round holes, or the first connecting hole is a round hole, the second connecting hole is a long round hole, or the first connecting hole is a long round hole, the second connecting hole is a round hole, or the first connecting hole and the second connecting hole (24) are long round holes.

Compared with the prior art, the invention has the following characteristics and beneficial effects:

the invention provides a buckling restrained brace with two yield sections, the novel buckling restrained brace is provided with two yield points through a structure, the buckling restrained brace can be subjected to yielding energy consumption under a small earthquake, the structural deformation is increased along with the increase of the earthquake action, when the earthquake reaches a middle earthquake or a large earthquake, the second yield section enters a working state, and the requirement of the structural anti-seismic performance design is well met.

The first yielding section has a longer core section, smaller thickness, smaller axial rigidity, and larger yielding displacement and ultimate displacement; the second yielding section core section is shorter than the first yielding section, larger in thickness, large in axial rigidity, and smaller in yielding displacement and ultimate displacement.

The working principle is as follows:

under the action of small vibration: the first yielding section core section firstly enters yielding energy consumption, and the second yielding section core section does not enter a working state due to the release effect of the long round bolt hole, so that the energy dissipation effect of the first yielding section core section is not influenced.

Under the action of medium or large earthquake: the interlayer horizontal deformation ratio of the structure is remarkably increased under small earthquake, the length released by the long round bolt hole is reached or exceeded, the second yielding section core section enters a working state, axial deformation energy dissipation is generated, and the rigidity and the bearing capacity of the second yielding section core section are remarkably higher than those of the first yielding section core section, so that the increase of earthquake action and the energy dissipation requirement of the structure are well adapted, and the energy dissipation function is jointly played with the first yielding section core section.

The first yield section core section has larger ultimate displacement, so the first yield section core section can normally work under heavy shock, and the requirement of ultimate deformation is easily met; the ultimate displacement of the second yielding section core section is smaller, but the yielding energy dissipation starts under the medium or large earthquake, and the requirement of ultimate deformation is easily met.

The double-yield-point buckling restrained brace well utilizes the energy dissipation mechanism and product characteristics of the buckling restrained brace, is suitable for gradual increase of earthquake action, is well suitable for structural grading performance design, and is a shock absorption product with excellent performance.

Drawings

The present invention will be described in further detail with reference to the accompanying drawings.

FIG. 1 is a schematic diagram of the present invention.

Fig. 2 is a schematic diagram of the longitudinal side view structure of fig. 1.

Fig. 3 is another longitudinal side view of the structure of fig. 2.

Fig. 4 is a schematic structural view of the core unit and the connection unit of fig. 3.

Fig. 5 is a coupling disassembled view of the core unit and the coupling unit of fig. 4.

Fig. 6 is a structural view of the first yield steel plate.

Fig. 7 is a structural view of a second yield steel plate.

Fig. 8 isbase:Sub>A schematic structural view ofbase:Sub>A sectionbase:Sub>A-base:Sub>A in fig. 2.

Fig. 9 is a schematic structural view of a section B-B in fig. 2.

Fig. 10 is a schematic view of the structure of the connection plate.

Fig. 11 is a disassembled structural schematic view of the present invention.

Reference numerals: 1-a first yield steel plate, 11-a first core section, 12-a first transition section, 13-a first connecting section, 14-a first connecting hole, 2-a second yield steel plate, 21-a second core section, 22-a second transition section, 23-a second connecting section, 24-a second connecting hole, 3-an external constraint unit, 31-an outer steel tube, 32-a filler, 4-a connecting unit, 41-a clamping plate, 42-a limiting plate, 43-an ear plate, 44-an ear plate hole, 5-a connecting bolt, 6-a bolt hole, 7-a core unit and 8-a slidable material.

Detailed Description

Examples referring to fig. 1-5 and 11, a dual yield point buckling restrained brace comprises a body including a core unit 7, an outer restraining unit 3, an unbonded sliding mechanism unit and a connecting unit 4.

The core unit 7 comprises a staged yielding combined plate, the staged yielding combined plate comprises a first yielding steel plate 1 and a second yielding steel plate 2 which are arranged in the front and back, centered, just opposite to each other, tightly attached to each other and fixedly connected with each other, the thickness of the first yielding steel plate 1 is smaller than that of the second yielding steel plate 2, and the first yielding steel plate 1 and the second yielding steel plate 2 are both steel plates with straight cross sections.

The stress area of the body is divided into a core area at the middle part, transition areas at two sides of the core area and connecting areas at the outer sides of the transition areas along the longitudinal direction,

referring to fig. 6, the first yield steel plate 1 includes a first core section 11 at a core region, a first transition section 12 at a transition region, and a first connection section 13 at a connection region,

referring to fig. 7, the second yield steel plate 2 includes a second core section 21 at the core region, a second transition section 22 at the transition region and a second connection section 23 at the connection region,

the length of the first core section 11 is longer than the length of the second core section 21.

The external restraint unit 3 comprises an outer sleeve steel pipe 31 sleeved outside the core unit, and also comprises a filling material 32 filled between the outer sleeve steel pipe 31 and the core unit, and the unbonded sliding mechanism unit is arranged between the core unit and the filling material 32.

The connection unit 4 is fixedly connected to the outside of the first and second connection sections 13 and 23 of the connection area.

The first yield steel plate 1 and the second yield steel plate 2 have the same length. The plate width of the first core section 11 is smaller than that of the second core section 21, and the plate widths of the first connecting section 13 and the second connecting section 23 are the same. The first connecting section 13 has a plate width larger than that of the first core section 11, and the first transition section 12 smoothly transitions between the first core section 11 and the first connecting section 13. The second connecting section 23 has a plate width larger than that of the second core section 21, and the second transition section 22 smoothly transitions between the second core section 21 and the second connecting section 23.

Referring to fig. 8 to 9, the shape of the cross section of the outer steel casing 31 is rectangular, the filler 32 is concrete, the unbonded sliding mechanism unit is an unbonded coating provided on the outer surface of the core unit, a layer of slidable material is further provided between the first yield steel plate 1 and the second yield steel plate 2, the width of the slidable material is not greater than the width of the first core section 11, the end of the slidable material does not exceed the outer edge of the first transition section 12, and the slidable material is polytetrafluoroethylene. The edge of the outer jacket steel tube 31 is aligned with the outer edge of the first transition section 12. The slidable material can further ensure the independence of two sections of yielding of the core unit.

Referring to fig. 5 and 10, the connection unit 4 includes a connection assembly including a connection assembly plate and a connection bolt 5, the connection assembly plate includes two parallel clamp plates 41 clamped outside the first connection section 13 and the second connection section 23, a set of bolt holes 6 for the connection bolt 5 to pass through is opened on the clamp plates 41, corresponding first connection holes 14 and second connection holes 24 are also opened on positions of the bolt holes 6 corresponding to the first connection section 13 and the second connection section 23, the first connection holes 14, the second connection holes 24 and the bolt holes 6 are aligned one by one and bolted through the connection bolt 5, the connection assembly plate further includes a limit plate 42 vertically and fixedly connected outside the clamp plates, an outer side end surface of the first connection section 13 and an outer side end surface of the second connection plate 23 are tightly attached to an inner side surface of the limit plate 42, the connection assembly plate further includes an ear plate 43 centrally and fixedly connected outside the limit plate 42, the ear plate 43 is parallel to the staged combination plate and has an ear plate hole 44 opened thereon.

In this embodiment, the plate body width of the clamping plate 41 is equal to the width of the first connecting section 13 and the second connecting section 23, the limiting plate 42 is a circular plate and is fixedly connected to the outer side of the clamping plate in the middle, and the connecting bolts 5 are calculated according to the design, and six are arranged on each side in this example.

Claims (5)

1. The utility model provides a two yield point buckling restrained brace, includes the body, its characterized in that: the body comprises a core unit (7), an external constraint unit (3), an unbonded sliding mechanism unit and connecting units (4) at two ends,

the core unit (7) comprises a staged yield composite plate, the staged yield composite plate comprises a first yield steel plate (1) and a second yield steel plate (2) which are arranged in the front and back, are centered, are just close to each other and are fixedly connected, the thickness of the first yield steel plate (1) is smaller than that of the second yield steel plate (2), the first yield steel plate (1) and the second yield steel plate (2) are both steel plates with straight cross sections,

the stress area of the body is divided into a core area at the middle part, transition areas at two sides of the core area and connecting areas at the outer sides of the transition areas along the longitudinal direction,

the first yield steel plate (1) comprises a first core section (11) positioned in the core area, a first transition section (12) positioned in the transition area and a first connecting section (13) positioned in the connecting area,

the second yield steel plate (2) comprises a second core section (21) positioned in the core area, a second transition section (22) positioned in the transition area and a second connecting section (23) positioned in the connecting area,

the length of the first core segment (11) is longer than the length of the second core segment (21),

the external restraint unit (3) comprises an outer sleeve steel pipe (31) sleeved outside the core unit, and also comprises a filling material (32) filled between the outer sleeve steel pipe (31) and the core unit, the unbonded sliding mechanism unit is arranged between the core unit and the filling material (32), the connecting unit (4) is fixedly connected to the outer sides of the first connecting section (13) and the second connecting section (23) of the connecting area,

the first yield steel plate (1) and the second yield steel plate (2) have the same length,

the plate width of the first core section (11) is smaller than that of the second core section (21), the plate width of the first connecting section (13) is the same as that of the second connecting section (23),

the filling material (32) is concrete, the unbonded sliding mechanism unit is an unbonded coating arranged on the outer surface of the core unit, a layer of slidable material (8) is further arranged between the first yielding steel plate (1) and the second yielding steel plate (2), the slidable material (8) is polytetrafluoroethylene,

the connecting unit (4) comprises a connecting assembly, the connecting assembly comprises a connecting assembly plate and a connecting bolt (5), the connecting assembly plate comprises two parallel clamping plates (41) which are clamped outside a first connecting section (13) and a second connecting section (23), a group of bolt holes (6) for the connecting bolt (5) to pass through are formed in the clamping plates (41), the bolt holes (6) correspond to the first connecting section (13) and the second connecting section (23) and are also provided with corresponding first connecting holes (14) and second connecting holes (24), the first connecting holes (14), the second connecting holes (24) and the bolt holes (6) are aligned one by one and are bolted through the connecting bolt (5), the connecting assembly plate further comprises a limiting plate (42) which is vertically and fixedly connected outside the clamping plates, the outer side end face of the first connecting section (13) and the outer side end face of the second connecting section (23) are tightly attached to the inner side surface of the limiting plate (42), the connecting assembly plate further comprises an ear plate (43) which is fixedly connected outside the limiting plate (42) in the middle, and the ear plate (43) and is combined with a lug plate (44) which is parallel to yield and is opened on the connecting assembly plate in a staged,

the bolt holes are round holes, the first connecting holes (14) are long round holes, and the second connecting holes (24) are round holes.

2. The dual yield point buckling restrained brace of claim 1, wherein: the first connecting section (13) has a plate width greater than that of the first core section (11), and the first transition section (12) smoothly transitions between the first core section (11) and the first connecting section (13).

3. The dual yield point buckling restrained brace of claim 1, wherein: the plate width of the second connecting section (23) is larger than that of the second core section (21), and the second transition section (22) smoothly transitions between the second core section (21) and the second connecting section (23).

4. The dual yield point buckling-restrained brace of any one of claims 1-3, wherein: the cross section of the outer sleeved steel pipe (31) is rectangular.

5. The dual yield point buckling restrained brace of claim 4, wherein: the edge of the outer sleeved steel pipe (31) is aligned with the outer edge of the first transition section (12).

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