CN204753879U - Viscoplasticity - prevent bucking power consumption to support - Google Patents
Viscoplasticity - prevent bucking power consumption to support Download PDFInfo
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- CN204753879U CN204753879U CN201520441071.5U CN201520441071U CN204753879U CN 204753879 U CN204753879 U CN 204753879U CN 201520441071 U CN201520441071 U CN 201520441071U CN 204753879 U CN204753879 U CN 204753879U
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Abstract
The utility model relates to a viscoplasticity - prevent bucking power consumption to support, its structure includes that inner core power consumption unit, I grade of peripheral restraint mechanism, II grades of peripheries retrain the mechanism, glue elastic material component, tip shrouding component and do not have bonding filler material component, inner core power consumption unit is including " one " font power consumption inner core component and tip stiffening rib component, I grade of peripheral restraint mechanism includes square steel tube component and connecting plate component, II grades of peripheral restraint mechanisms are square barrel, it sets up to glue the elastic material component the steel sheet component with between the connecting plate component. The utility model discloses can be for buckling restrained brace provide bigger sidewise restraint rigidity, be favorable to the full play of buckling restrained brace power consumption ability, the application of gluing elastic material simultaneously can make should power consumption to support consumes energy under little displacement, the vibratory action that declines, and the satisfied difference damping demand under the seismic action of seting up defences for the major structure provides bigger damping demand, has improved the safety stock of member simultaneously.
Description
Technical field
The utility model relates to a kind of curvature-prevention support component, specifically a kind of viscoplasticity-buckling-restrained energy-dissipation.
Background technology
Viscoelastic damper can for structure certain rigidity is provided while larger damping is provided; Its power and displacement lagging curve approximation are in ellipse, and energy dissipation capacity is strong, and the wind that can effectively reduce building shakes and earthquake response.Compared with displacement relationship type damper (such as buckling-restrained energy-dissipation), viscoelastic damper can consume energy under all vibration conditions, even if under less vibration condition, also can consume energy.It needs larger relative displacement unlike hysteresis energy consuming device (as metal energy-dissipating device and friction energy consuming device) could there is yield deformation or overcome friction to play their power consumption effect.So viscoelastic damper can simultaneously for earthquake and the wind dynamic control of structure, turn avoid the problem how energy consumer initial stiffness that other power consumption (damping) device exists matches with lateral displacement stiffness of structure.
In prior art, anti-buckling support is that a kind of axis pressure by steel draws catabiotic displacement relationship type damper, it is primarily of core unit in anti-buckling support and restraining tube constraint mechanism composition, interior core unit and restraining tube is inter-agency leaves gap or adopt non-cohesive material to fill.Anti-buckling support inner core is as axially loaded component, it is under the lateral restraint of peripheral constraint mechanism, when the effect of under tension and pressure, all can reach the abundant surrender of total cross-section, the seismic energy of input structure can be consumed better, thus play the effect of energy dissipation.
Desirable anti-buckling support requires that its performance is: one is low surrender, to guarantee just can consume energy under little shake; Two is that energy dissipation capacity is large, to ensure the effect that also can reach damping power consumption under large shake; Three is that deflection is large, to adapt with the stratified deformation of the building under geological process.
But, in actual implementation process, anti-buckling support has following two problems: one is because buckling-restrained energy-dissipation belongs to displacement relationship type dissipative member, relevant with agent structure relative storey displacement size, when structure is under little shake state, structure relative floor displacement is less, be difficult to reach buckling-restrained energy-dissipation yield story drift, component is in elastic stage, the re-set target consumed energy can not be realized, the inertia force because little shake produces and structural vibration cannot be cut down, wind load cannot be cut down in normal conditions of use simultaneously, the structural vibration that outdoor environment etc. cause.Two is that anti-buckling being supported for the while that structure adding rigidity has attached certain weight, so just needs agent structure to bear consequent gravity and Earthquake Inertia Force Acting, increases the stressed of agent structure., vibration source higher for instructions for use (as little sidesway, micro-vibration etc.) is comparatively strong but have vibration damping demand, or need to guarantee building function under moderate (as fortification intensity) earthquake, simultaneously, when needing to ensure excellent anti-seismic performance under rarely occurred earthquake, the anti-buckling support technology of single use is just difficult to accomplish that both have taken into account.
Utility model content
The purpose of this utility model is just to provide a kind of viscoplasticity-buckling-restrained energy-dissipation, with solve existing buckling-restrained energy-dissipation can increase the stressed of agent structure and cannot cut down under little shake state the inertia force that produced by little shake and structural vibration, in normal state cannot the problem of relief features vibration.
The utility model is achieved in that a kind of viscoplasticity-buckling-restrained energy-dissipation, comprises inner core power consumption unit, I grade of restraining tube mechanism, II grade of restraining tube mechanism, viscoelastic material component, end close board component and soap-free emulsion polymeization packing material component.
Described inner core power consumption unit comprises " one " font energy consumption inner core component and end stiffener rib component; Described " one " font energy consumption inner core component is the rectangular plate body that end is wide, middle part is narrow, described end stiffener rib Member Welding is on the end face center line in expanded letter portion, described " one " font energy consumption inner core component two ends and bottom center's line in expanded letter portion, two ends, and it is criss-cross end matrix that two ends of described inner core power consumption unit form cross section respectively.
Described I grade of restraining tube mechanism comprises four square steel pipe components and four junction plate components; Described square steel pipe component is arranged on corner around described inner core power consumption unit; Described junction plate Member Welding is on the coplanar lateral wall of adjacent two described square steel pipe components, and square steel pipe component and junction plate component form the cavity that inside is " ten " font; The two ends of described junction plate component have center and intert bar seam, the side in the expanded letter portion, two ends of described " one " font energy consumption inner core component along or the side of described end stiffener rib component intert in bar seam along the center of the described junction plate component interted on position; One end of described I grade of restraining tube mechanism is welded on the described end matrix of described inner core power consumption unit one end, and the other end of described I grade of restraining tube mechanism is free end.
Described II grade of restraining tube mechanism is by four steel plate members by the formed square cylinder that connects successively along limit, and each described steel plate member is arranged in the outer face of a described junction plate component of described I grade of restraining tube mechanism, center cross-under bar seam is had at the two ends of each described steel plate member, the side in expanded letter portion, described " one " font energy consumption inner core component two ends along or the side of described end stiffener rib component along in the center cross-under bar seam of the described steel plate member of cross-under on position, described steel plate member wherein one end center cross-under bar seam and the side of described " one " font energy consumption inner core component penetrated along or the described end stiffener rib member side that penetrates along being fixedly connected by welding manner, the other end of described II grade of restraining tube mechanism is free end, the free end of described II grade of restraining tube mechanism and the free end of described I grade of restraining tube mechanism divide and are located at described inner core and consume energy the two ends of unit.
Described viscoelastic material component is arranged between described steel plate member and described junction plate component, and described I grade of restraining tube mechanism and described II grade of restraining tube mechanism are linked together.
Gap is left between described I grade of restraining tube mechanism and end close board component; Gap is left between described II grade of restraining tube mechanism and end close board component.
Described soap-free emulsion polymeization packing material component is arranged on described I grade of restraining tube mechanism and described inner core consumes energy between unit.
The two ends of described junction plate component are concordant with the two ends of described square steel pipe component, weld with consume energy unit and end close board component of described inner core.
The utility model is a kind of viscoplasticity-buckling-restrained energy-dissipation, in frequently occurred earthquake and wind action process, this anti-buckling support can be the initial stiffness that agent structure provides larger, reduce the relative storey displacement of structure, under it is in thin tail sheep state, inner core power consumption unit member is not yet surrendered and is in elastic stage, in this stressed stage, due to I grade of restraining tube mechanism and II grade of inter-agency generation relative velocity of restraining tube, viscoelastic material component is made to provide required damping, now I grade of restraining tube mechanism, II grade of restraining tube mechanism and viscoelastic material component serve the effect of viscoelastic damper jointly, inner core power consumption unit member, I grade of restraining tube mechanism and II grade of restraining tube mechanism play the effect of anti-buckling support jointly, for agent structure provides rigidity, not additional damping, achieve at little sidesway, power consumption re-set target under micro-effect of vibration.In middle chance earthquake or when having stronger vibration source, along with the increase of external action, relative floor displacement and interlayer relative velocity increase all to some extent, and inner core power consumption unit member of the present utility model starts surrender power consumption, and viscoelastic material component continues further power consumption.Under rarely occurred earthquake effect, along with the further increasing of outside geological process, the earthquake response of the agent structure of building also continues to increase, inner core power consumption unit member of the present utility model fully surrenders power consumption, viscoelastic material component continues power consumption, now the utility model can be the demand that agent structure provides maximum damping, ensure that agent structure has excellent anti-seismic performance, reaches the functional objective of the utility model expection.
The utility model has merged viscoelastic damper vibration damping and anti-buckling support energy-dissipating and shock-absorbing two technology, reasonably make use of the characteristic that visco-elastic damping material provides damping and abatement shake (shaking) energy under little sidesway, micro-effect of vibration, having expanded the power consumption scope of existing buckling-restrained energy-dissipation, is the application extension space of anti-buckling support.Meanwhile, the utility model adopts anti-buckling support technology, and significantly reducing viscoelastic damper, agitate the factor such as frequency because of outside different and reduce the impact of damping effect.
The utility model adopts inside and outside pair of constraint mechanism, can be the lateral restraint rigidity that anti-buckling support provides larger, is conducive to giving full play to of anti-buckling support energy consumption ability, for agent structure provides larger damping requirements, improves the safety stock of component simultaneously.
The utility model can realize the low and needs that bulk deformation is large of dissipative member initial yield, realize the little shake stage, support provides enough rigidity to provide additional damping simultaneously, the performance requirement of power consumption all can be surrendered under achieving different earthquake fortification, consumed energy by different technologies, component self energy dissipation capacity obtains reasonable distribution, reduce the burden adopting single power consumption technology to bring component self, avoid the destruction in large load action lower support, ensure that the safety of support, extend the application life of support.
The component that the utility model adopts and Energy dissipating material are steel, and material source is wide, and cost is low, long service life.
The utility model can be widely used in civil engineering structure energy-dissipating and shock-absorbing (shaking) technology.
Accompanying drawing explanation
Fig. 1 is structural representation of the present utility model.
Fig. 2 is that the A-A of Fig. 1 is to sectional drawing.
Fig. 3 is that the B-B of Fig. 1 is to sectional drawing.
Fig. 4 is that the C-C of Fig. 1 is to sectional drawing.
In figure: 1, end stiffener rib component, 2, steel plate member, 3, viscoelastic material component, 4, junction plate component, 5, square steel pipe component, 6, " one " font energy consumption inner core component, 7, end close board component, 8, soap-free emulsion polymeization packing material component.
Detailed description of the invention
As shown in Figure 1, the utility model comprises: inner core power consumption unit, I grade of part such as restraining tube mechanism, II grade of restraining tube mechanism, viscoelastic material component 3, end close board component 7 and soap-free emulsion polymeization packing material component 8.
Described inner core power consumption unit comprises " one " font energy consumption inner core component 6 and end stiffener rib component 1; " one " font energy consumption inner core component 6 is the strip-shaped steel plate that end is wide, middle part is narrow, end stiffener rib component 1 is welded on the end face center line in expanded letter portion, " one " font energy consumption inner core component 6 two ends and bottom center's line in expanded letter portion, two ends, and it is criss-cross end matrix (Fig. 2) that end stiffener rib component 1 forms cross section respectively with two ends of " one " font energy consumption inner core component 6.The constraint surrender section of this inner core power consumption unit adopts " one " font cross section (Fig. 4), adopt " ten " font cross section (Fig. 2) without constraint non-compliant section, namely the constraint surrender Duan Yuwu changeover portion retrained between non-compliant section retrains non-compliant section and adopts " ten " font cross section (Fig. 3).
Described I grade of restraining tube mechanism comprises four square steel pipe components 5 and four junction plate components 4.Square steel pipe component 5 adopts square steel pipe, is arranged in inner core power consumption unit.The two ends of square steel pipe component 5 are arranged on the cross separation trough with straight angle interior (Fig. 3) of the end matrix of inner core power consumption unit.Four square steel pipe components 5 form the Distribution Pattern of sphere of movements for the elephants shape, and two the square steel pipe components 5 be disposed adjacent respectively have a lateral wall to be in same plane.Junction plate component 4 is junction steel plate, on the coplanar lateral wall being welded on adjacent two square steel pipe components 5 (Fig. 4); Four square steel pipe components 5 that field word distributes just weld together by four junction plate components 4.Bar seam is interted at the center that has at the two ends of each junction plate component 4, the side in the expanded letter portion, two ends of " one " font energy consumption inner core component 6 along and the side of end stiffener rib component 1 intert bar seam along this center of the junction plate component 4 interted on respective position respectively in (Fig. 3).One end of I grade of restraining tube mechanism is welded on the end matrix of inner core power consumption unit one end, and the other end of I grade of restraining tube mechanism is free end.
Described II grade of restraining tube mechanism is by the successively docking of four steel plate members 2 by dual-side edge, again after butt welding seam, form a steel square cylinder (Fig. 4), each steel plate member 2 is arranged on the outer face of a junction plate component 4 of I grade of restraining tube mechanism.Have center cross-under bar seam at the two ends of each steel plate member 2, the edge, side in expanded letter portion, " one " font energy consumption inner core component 6 two ends and the side of end stiffener rib component 1 are along in the center cross-under bar seam of the steel plate member 2 of difference cross-under on respective position (Fig. 3).Steel plate member 2 wherein one end center cross-under bar seam and the side of " one " font energy consumption inner core component 6 penetrated along or the side of end stiffener rib component 1 that penetrates along being fixedly connected by welding manner, the other end of II grade of restraining tube mechanism is free end.The free end of the free end of I grade of restraining tube mechanism and II grade of restraining tube mechanism divides and is located at inner core and consumes energy the two ends of unit.
Viscoelastic material component 3 adopts viscoplasticity high-damping rubber material to make, be arranged between steel plate member 2 and junction plate component 4, by adopting the processing method of sulfuration process, make it with steel plate member 2 and square steel pipe component 5 sulfuration as a whole, I grade of restraining tube mechanism and II grade of restraining tube mechanism are linked together, just can give full play to the damping energy dissipation performance of viscoelastic material component 3 thus.
As shown in Figure 1, left end and the end close board component 7 of I grade of restraining tube mechanism leave gap, and the other end and end close board component 7 and inner core consume energy unit welding edges; II grade of restraining tube mechanism right-hand member and end close board component 7 leave gap, and the other end and end close board component 7 and inner core consume energy the welding edges of unit.
End close board component 7 is rectangle steel plate body.
Consume energy between unit in I grade of restraining tube mechanism and inner core and be provided with soap-free emulsion polymeization packing material component 8.Soap-free emulsion polymeization packing material component 8 can adopt silica gel plate, rubber tile or vinyl polymer material to make, its unsticking layer consumed energy between unit as I grade of restraining tube mechanism and core, effectively reduce the friction that I grade of restraining tube mechanism and core consume energy between unit, be conducive to the lateral restraint effect improving restraining tube mechanism, give full play to inner core power consumption effect.Because silica gel plate is water insoluble and any solvent, nonpoisonous and tasteless, stable chemical nature, does not react with any material except highly basic, hydrofluoric acid, thus can preferably silica gel plate as soap-free emulsion polymeization packing material.
Claims (2)
1. viscoplasticity-buckling-restrained energy-dissipation, is characterized in that, comprises inner core power consumption unit, I grade of restraining tube mechanism, II grade of restraining tube mechanism, viscoelastic material component, end close board component and soap-free emulsion polymeization packing material component;
Described inner core power consumption unit comprises " one " font energy consumption inner core component and end stiffener rib component; Described " one " font energy consumption inner core component is the rectangular plate body that end is wide, middle part is narrow, described end stiffener rib Member Welding is on the end face center line in expanded letter portion, described " one " font energy consumption inner core component two ends and bottom center's line in expanded letter portion, two ends, and it is criss-cross end matrix that two ends of described inner core power consumption unit form cross section respectively;
Described I grade of restraining tube mechanism comprises four square steel pipe components and four junction plate components; Described square steel pipe component is arranged on corner around described inner core power consumption unit; Described junction plate Member Welding is on the coplanar lateral wall of adjacent two described square steel pipe components, and square steel pipe component and junction plate component form the cavity that inside is " ten " font; The two ends of described junction plate component have center and intert bar seam, the side in the expanded letter portion, two ends of described " one " font energy consumption inner core component along or the side of described end stiffener rib component intert in bar seam along the center of the described junction plate component interted on position; One end of described I grade of restraining tube mechanism is welded on the described end matrix of described inner core power consumption unit one end, and the other end of described I grade of restraining tube mechanism is free end;
Described II grade of restraining tube mechanism is by four steel plate members by the formed square cylinder that connects successively along limit, and each described steel plate member is arranged in the outer face of a described junction plate component of described I grade of restraining tube mechanism, center cross-under bar seam is had at the two ends of each described steel plate member, the side in expanded letter portion, described " one " font energy consumption inner core component two ends along or the side of described end stiffener rib component along in the center cross-under bar seam of the described steel plate member of cross-under on position, described steel plate member wherein one end center cross-under bar seam and the side of described " one " font energy consumption inner core component penetrated along or the described end stiffener rib member side that penetrates along being fixedly connected by welding manner, the other end of described II grade of restraining tube mechanism is free end, the free end of described II grade of restraining tube mechanism and the free end of described I grade of restraining tube mechanism divide and are located at described inner core and consume energy the two ends of unit,
Described viscoelastic material component is arranged between described steel plate member and described junction plate component, and described I grade of restraining tube mechanism and described II grade of restraining tube mechanism are linked together;
Gap is left between described I grade of restraining tube mechanism and end close board component; Gap is left between described II grade of restraining tube mechanism and end close board component;
Described soap-free emulsion polymeization packing material component is arranged on described I grade of restraining tube mechanism and described inner core consumes energy between unit.
2. viscoplasticity-buckling-restrained energy-dissipation according to claim 1, is characterized in that, the two ends of described junction plate component are concordant with the two ends of described square steel pipe component, welds with consume energy unit and end close board component of described inner core.
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CN201520441071.5U CN204753879U (en) | 2015-06-25 | 2015-06-25 | Viscoplasticity - prevent bucking power consumption to support |
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN104947827A (en) * | 2015-06-25 | 2015-09-30 | 河北华研卓筑加固工程有限公司 | Viscoelasticity-buckling-preventing energy dissipating brace |
CN109098515A (en) * | 2017-05-17 | 2018-12-28 | 大连大学 | The energy consumption inner core of anti-unstability device |
CN109113204A (en) * | 2017-06-08 | 2019-01-01 | 大连大学 | The classification shock-dampening method of damper for fire-fighting |
CN109505363A (en) * | 2018-11-21 | 2019-03-22 | 大连大学 | The anti-buckling support of assembled |
-
2015
- 2015-06-25 CN CN201520441071.5U patent/CN204753879U/en not_active Withdrawn - After Issue
Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN104947827A (en) * | 2015-06-25 | 2015-09-30 | 河北华研卓筑加固工程有限公司 | Viscoelasticity-buckling-preventing energy dissipating brace |
CN109098515A (en) * | 2017-05-17 | 2018-12-28 | 大连大学 | The energy consumption inner core of anti-unstability device |
CN109113204A (en) * | 2017-06-08 | 2019-01-01 | 大连大学 | The classification shock-dampening method of damper for fire-fighting |
CN109113204B (en) * | 2017-06-08 | 2020-06-26 | 大连大学 | Grading damping method for fire-fighting damper |
CN109505363A (en) * | 2018-11-21 | 2019-03-22 | 大连大学 | The anti-buckling support of assembled |
CN109505363B (en) * | 2018-11-21 | 2024-04-02 | 大连大学 | Assembled buckling restrained brace |
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Granted publication date: 20151111 Effective date of abandoning: 20171114 |
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AV01 | Patent right actively abandoned |