CN208777801U - The cydariform energy dissipation brace of built-in energy consumption square steel tube - Google Patents
The cydariform energy dissipation brace of built-in energy consumption square steel tube Download PDFInfo
- Publication number
- CN208777801U CN208777801U CN201821032115.9U CN201821032115U CN208777801U CN 208777801 U CN208777801 U CN 208777801U CN 201821032115 U CN201821032115 U CN 201821032115U CN 208777801 U CN208777801 U CN 208777801U
- Authority
- CN
- China
- Prior art keywords
- energy
- energy consumption
- curved surface
- elliptical aperture
- steel tube
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Fee Related
Links
Landscapes
- Buildings Adapted To Withstand Abnormal External Influences (AREA)
Abstract
The utility model relates to the cydariform energy dissipation braces for the square steel tube that consumes energy built in one kind, belong to building construction vibration control field, using the energy consumption mode and curved surface Wasted-energy steel plate of quadruple barrel structure tension and compression, the energy consumption mode of energy consumption square steel tube and foamed aluminium Energy dissipating material mutual extrusion friction, it can be mutually coordinated, the big energy consumption square steel tube of elliptical aperture is set in being arranged, the small energy consumption square steel tube energy consumption effect for inside setting elliptical aperture is good, steel utilization ratio is high, it is big to surrender area, it is arranged in multiple and sets elliptical aperture, the energy consumption rib of formation not only saves material, and keep Structural Energy Dissipation more abundant, without obvious stress concentration phenomenon, the foamed aluminium Energy dissipating material energy consumption effect of setting is good, the energy such as structure kinetic energy or elastic potential energy can be made to be converted to the forms such as thermal energy to dissipate, it is strong with energy dissipation capacity, the processing is simple, the advantages that easy for installation, it can be used in existing engineering reinforcement Maintenance, new building Aseismic Design, make it possess good anti-seismic performance, ductility and hysteretic energy ability.
Description
Technical field
The utility model belongs to building construction vibration control field, more particularly to the cydariform for the square steel tube that consumes energy built in one kind
Energy dissipation brace.
Background technique
Earthquake disaster have it is sudden and crushing, seriously threaten the safety of human life, property.Annual hair in the world
Raw ruinous earthquake nearly thousand times, a violent earthquake can cause the economic loss of more than one hundred billion dollar, cause hundreds of thousands people dead or tight
It is severely injured residual.China is located on two most active earthquake zones in the world, is the one of the countries with the most serious ... that suffers disaster from an earthquake, earthquake
Caused by casualties occupy first place in the world, economic loss is also very huge.In earthquake the considerable damage of building with collapse, be to make
At the immediate cause of earthquake disaster.When earthquake occurs, ground vibration causes the earthquake response of structure.Ground is fixed in for basis
Building structure, reaction along highly from top to bottom successively amplification.Since the earthquake response of works a part (accelerates
Degree, speed or displacement) it is excessive, so that main body load-carrying members is seriously destroyed or even is collapsed;Although or main structure is not destroyed, is built
Facing, finishing or other non-structural accessories etc. is built to damage and lead to heavy losses;Or indoor expensive instrument, damage of facilities cause sternly
The loss or secondary disaster of weight.In order to avoid the generation of above-mentioned disaster, people must control the earthquake response of structural system
System, and eliminate " amplifier " effect of structural system, structure energy-eliminating shock-absorbing technology be certain nonload bearing elements of structure (such as
Shear wall, connector etc.) it is designed to energy dissipating rod piece, or at certain positions (interlayer space, node, connecting sewing etc.) of structure
Energy dissipator is installed.In small wind or small shake, these energy dissipating rod pieces (or energy dissipator) and structure itself have enough sides
To rigidity to meet requirement, structure is in elastic stage;When there is big shake or strong wind, with the increasing of structure lateral deformation
Greatly, energy dissipation component or energy dissipator take the lead in starting to work, and generate larger damping, a large amount of earthquakes for consuming input structure or wind shake energy
Amount, makes the energy such as kinetic energy or the elastic potential energy of structure be converted to the forms such as thermal energy and dissipates, the earthquake of rapid attenuating structure or wind
Vibration reaction (displacement, speed, acceleration etc.) makes main structure avoid the occurrence of apparent inelastic state, protects main structure
And component in macroseism or strong wind from destroy.It is that structure produces because the reasons such as earthquake are transferred to the external energy of building structure
The root of raw vibration increases energy consumption, it will reduce the dynamic respons of structure so energy-consuming device is arranged in the structure.At present
The confined concrete of the anti-buckling energy-consumption component of research and development is easily crushed and loses constraint and anti-buckling effect, causes it
Energy dissipation capacity is greatly reduced.Therefore, some dissipative member manufacturing process, there is still a need for further improvements for energy-dissipating property etc..
Utility model content
In order to solve above-mentioned technical problem, the utility model provides the cydariform energy consumption of the built-in energy consumption square steel tube of one kind
Support, primarily to a kind of good anti-seismic performance, ductility and the strong energy dissipation brace of hysteretic energy ability are developed, using quadruple cylinder knot
The energy consumption of the energy consumption mode and curved surface Wasted-energy steel plate of structure tension and compression, consume energy square steel tube and foamed aluminium Energy dissipating material mutual extrusion friction
Mode, can be mutually coordinated, can be used in existing engineering reinforcement maintenance, new building Aseismic Design, can effectively avoid building
There is too strong earthquake response in earthquake in object, can effective protection building structure, extend the service life.
To achieve the goals above, the technical solution adopted in the utility model are as follows:
The cydariform energy dissipation brace of built-in energy consumption square steel tube, including upper plate, lower plate, upper plate screw hole, lower plate screw hole, large curved surface consumption
Can steel plate, the interior big energy consumption square steel tube for setting elliptical aperture, it is interior set elliptical aperture, coordinate connection reinforcing bar, energy consumption rib, small curved surface energy consumption steel
Plate, interior small energy consumption square steel tube, foamed aluminium Energy dissipating material and the locking nut for setting elliptical aperture;The utility model uses quadruple cylinder knot
Structure, outermost large curved surface Wasted-energy steel plate use cydariform cylinder, the interior big energy consumption side for setting elliptical aperture on the inside of large curved surface Wasted-energy steel plate
Steel pipe uses square tube, inside sets the small curved surface Wasted-energy steel plate on the inside of the big energy consumption square steel tube of elliptical aperture using cydariform cylinder, small curved surface
The small energy consumption square steel tube of elliptical aperture is set on the inside of Wasted-energy steel plate using square tube, four coaxial, large curved surface Wasted-energy steel plate and small
Bending radius of the curved surface Wasted-energy steel plate from centre to two sides is gradually reduced, and setting coordinates connection reinforcing bar and is each passed through large curved surface energy consumption
In steel plate and the interior big energy consumption square steel tube for setting elliptical aperture, small curved surface Wasted-energy steel plate and the interior small energy consumption square steel tube for setting elliptical aperture
Point is locked at both ends using locking nut, the top of structure is provided with upper plate, in the case where the bottom of structure is provided with
Plate, in the outer ring of upper plate and lower plate, correspondence opens up upper plate screw hole and lower plate screw hole, sets the big energy consumption square steel tube of elliptical aperture inside
With the four sides of the interior small energy consumption square steel tube for setting elliptical aperture be respectively provided in set elliptical aperture and energy consumption rib, set the long axis of elliptical aperture inside as water
Square to, large curved surface Wasted-energy steel plate, the interior big energy consumption square steel tube for setting elliptical aperture, small curved surface Wasted-energy steel plate and interior set the small of elliptical aperture
The upper/lower terminal of energy consumption square steel tube is fixedly connected with upper plate, lower plate respectively, is surrounded in upper plate, lower plate and large curved surface Wasted-energy steel plate
Structure in filled and process aluminium Energy dissipating material.
Further, large curved surface Wasted-energy steel plate and small curved surface Wasted-energy steel plate are made using low yield point steel plate.
Further, foamed aluminium Energy dissipating material is made using foamed aluminium.
Further, it large curved surface Wasted-energy steel plate, the interior big energy consumption square steel tube for setting elliptical aperture, small curved surface Wasted-energy steel plate and interior sets
The upper/lower terminal of the small energy consumption square steel tube of elliptical aperture is respectively with upper plate, lower plate using welded connecting.
Further, upper plate screw hole is equidistantly opened up in the outer ring of upper plate, equidistantly opens up lower plate spiral shell in the outer ring of lower plate
Hole.
The utility model has the beneficial effects that
The effect and advantage of the utility model are with energy dissipation capacity is strong, the processing is simple, easy for installation, using quadruple cylinder knot
The energy consumption of the energy consumption mode and curved surface Wasted-energy steel plate of structure tension and compression, consume energy square steel tube and foamed aluminium Energy dissipating material mutual extrusion friction
Mode, can be mutually coordinated, and energy consumption effect is good, steel utilization ratio is high, surrender area is big, is arranged in multiple and sets elliptical aperture, is formed
Energy consumption rib not only save material, but also keep Structural Energy Dissipation more abundant, without obvious stress concentration phenomenon, can make structure kinetic energy or
The energy such as elastic potential energy are converted to the forms such as thermal energy and dissipate, and can be used in the reinforcing maintenance of existing engineering, can be used for creating
The Aseismic Design of architectural engineering makes it possess good anti-seismic performance, ductility and hysteretic energy ability.
Detailed description of the invention
Fig. 1 is the cydariform energy dissipation brace floor map of built-in energy consumption square steel tube.
Fig. 2 is the A-A sectional view of Fig. 1 in the utility model.
Fig. 3 is the elevational schematic view of the interior big energy consumption square steel tube for setting elliptical aperture in the utility model.
Fig. 4 is the elevational schematic view of the interior small energy consumption square steel tube for setting elliptical aperture in the utility model.
In figure: 1 is upper plate;2 be lower plate;3 be upper plate screw hole;4 be lower plate screw hole;5 be large curved surface Wasted-energy steel plate;6 be interior
If the big energy consumption square steel tube of elliptical aperture;7 set elliptical aperture to be interior;8 be coordination connection reinforcing bar;9 be energy consumption rib;10 consume energy for small curved surface
Steel plate;11 be the interior small energy consumption square steel tube for setting elliptical aperture;12 be foamed aluminium Energy dissipating material;13 be locking nut.
Specific embodiment
In order to further illustrate the utility model, the utility model is retouched in detail with reference to the accompanying drawings and embodiments
It states, but they cannot be interpreted as to the restriction to scope of protection of the utility model.
Embodiment, as Figure 1-Figure 4, it is built-in energy consumption square steel tube cydariform energy dissipation brace, including upper plate 1, lower plate 2, on
Plate screw hole 3, lower plate screw hole 4, large curved surface Wasted-energy steel plate 5, the interior big energy consumption square steel tube 6 for setting elliptical aperture, it is interior set elliptical aperture 7, coordinate
Connect reinforcing bar 8, energy consumption rib 9, small curved surface Wasted-energy steel plate 10, interior small energy consumption square steel tube 11, the foamed aluminium Energy dissipating material for setting elliptical aperture
12 and locking nut 13;The utility model uses quadruple barrel structure, and outermost large curved surface Wasted-energy steel plate 5 uses cydariform cylinder, greatly
The big energy consumption square steel tube 6 for setting elliptical aperture in 5 inside of curved surface Wasted-energy steel plate inside sets the big energy consumption square steel of elliptical aperture using square tube
The small curved surface Wasted-energy steel plate 10 of 6 inside of pipe uses cydariform cylinder, and the small energy consumption of elliptical aperture is set in small 10 inside of curved surface Wasted-energy steel plate
Square steel tube 11 uses square tube, and four coaxial, and large curved surface Wasted-energy steel plate 5 and small curved surface Wasted-energy steel plate 10 are curved from centre to two sides
Bilge radius is gradually reduced, and setting coordinates connection reinforcing bar 8 and is each passed through large curved surface Wasted-energy steel plate 5 and the interior big energy consumption side for setting elliptical aperture
The midpoint of steel pipe 6, small curved surface Wasted-energy steel plate 10 and the interior small energy consumption square steel tube 11 for setting elliptical aperture uses locking nut 13 at both ends
It is locked, the top of structure is provided with upper plate 1, the bottom of structure is provided with lower plate 2, in upper plate 1 and lower plate 2
Outer ring correspondence opens up upper plate screw hole 3 and lower plate screw hole 4, sets the big energy consumption square steel tube 6 and the interior elliptical aperture that sets of elliptical aperture inside
The four sides of small energy consumption square steel tube 11 sets elliptical aperture 7 and energy consumption rib 9 in being respectively provided with, and inside sets the long axis of elliptical aperture 7 as horizontal direction, greatly
Curved surface Wasted-energy steel plate 5, the interior big energy consumption square steel tube 6 for setting elliptical aperture, small curved surface Wasted-energy steel plate 10 and the interior small energy consumption for setting elliptical aperture
The upper/lower terminal of square steel tube 11 is fixedly connected with upper plate 1, lower plate 2 respectively, is enclosed in upper plate 1, lower plate 2 and large curved surface Wasted-energy steel plate 5
At structure in filled and process aluminium Energy dissipating material 12;Large curved surface Wasted-energy steel plate 5 and small curved surface Wasted-energy steel plate 10 use low-yield
Steel plate is made;Foamed aluminium Energy dissipating material 12 is made using foamed aluminium;Large curved surface Wasted-energy steel plate 5, the interior elliptical aperture that sets
The upper/lower terminal of big energy consumption square steel tube 6, small curved surface Wasted-energy steel plate 10 and the interior small energy consumption square steel tube 11 for setting elliptical aperture respectively with it is upper
Plate 1, lower plate 2 are using welded connecting;Upper plate screw hole 3 is equidistantly opened up in the outer ring of upper plate 1, is equidistantly opened in the outer ring of lower plate 2
Set plate screw hole 4.
The above is only the preferred embodiment of the utility model, it is noted that for the common skill of the art
For art personnel, without departing from the principle of this utility model, several improvements and modifications can also be made, these improve and
Retouching also should be regarded as the protection scope of the utility model.
Claims (3)
1. the cydariform energy dissipation brace of built-in energy consumption square steel tube, it is characterised in that: including upper plate (1), lower plate (2), upper plate screw hole
(3), lower plate screw hole (4), large curved surface Wasted-energy steel plate (5), the interior big energy consumption square steel tube (6) for setting elliptical aperture, it is interior set elliptical aperture (7),
Coordinate connection reinforcing bar (8), energy consumption rib (9), small curved surface Wasted-energy steel plate (10), the interior small energy consumption square steel tube (11) for setting elliptical aperture, bubble
Foam aluminium Energy dissipating material (12) and locking nut (13);The cydariform energy dissipation brace of built-in energy consumption square steel tube uses quadruple barrel structure, most
The large curved surface Wasted-energy steel plate (5) in outside uses cydariform cylinder, the interior big energy consumption side for setting elliptical aperture on the inside of large curved surface Wasted-energy steel plate (5)
Steel pipe (6) uses square tube, inside sets the small curved surface Wasted-energy steel plate (10) on the inside of the big energy consumption square steel tube (6) of elliptical aperture using cydariform
Tin, the interior small energy consumption square steel tube (11) for setting elliptical aperture on the inside of small curved surface Wasted-energy steel plate (10) is using square tube, and four are coaxial, greatly
The bending radius of curved surface Wasted-energy steel plate (5) and small curved surface Wasted-energy steel plate (10) from centre to two sides is gradually reduced, and setting is coordinated to connect
It connects reinforcing bar (8) and is each passed through large curved surface Wasted-energy steel plate (5) and the interior big energy consumption square steel tube (6) for setting elliptical aperture, small curved surface energy consumption steel
The midpoint of plate (10) and the interior small energy consumption square steel tube (11) for setting elliptical aperture is locked at both ends using locking nut (13),
The top of structure is provided with upper plate (1), and the bottom of structure is provided with lower plate (2), in the outer of upper plate (1) and lower plate (2)
Circle correspondence opens up upper plate screw hole (3) and lower plate screw hole (4), sets the big energy consumption square steel tube (6) of elliptical aperture inside and interior sets ellipse
The four sides of the small energy consumption square steel tube (11) in hole sets elliptical aperture (7) and energy consumption rib (9) in being respectively provided with, and inside sets the long axis of elliptical aperture (7)
For horizontal direction, large curved surface Wasted-energy steel plate (5), the interior big energy consumption square steel tube (6) for setting elliptical aperture, small curved surface Wasted-energy steel plate (10) and
The upper/lower terminal for inside setting the small energy consumption square steel tube (11) of elliptical aperture is fixedly connected with upper plate (1), lower plate (2) respectively, in upper plate
(1), filled and process aluminium Energy dissipating material (12) in the structure that lower plate (2) and large curved surface Wasted-energy steel plate (5) surround.
2. the cydariform energy dissipation brace of built-in energy consumption square steel tube according to claim 1, it is characterised in that: large curved surface energy consumption steel
Plate (5), the interior big energy consumption square steel tube (6) for setting elliptical aperture, small curved surface Wasted-energy steel plate (10) and the interior small energy consumption square steel for setting elliptical aperture
The upper/lower terminal of (11) is managed respectively with upper plate (1), lower plate (2) using welded connecting.
3. the cydariform energy dissipation brace of built-in energy consumption square steel tube according to claim 1, it is characterised in that: in upper plate (1)
Outer ring equidistantly opens up upper plate screw hole (3), equidistantly opens up lower plate screw hole (4) in the outer ring of lower plate (2).
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201821032115.9U CN208777801U (en) | 2018-07-02 | 2018-07-02 | The cydariform energy dissipation brace of built-in energy consumption square steel tube |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201821032115.9U CN208777801U (en) | 2018-07-02 | 2018-07-02 | The cydariform energy dissipation brace of built-in energy consumption square steel tube |
Publications (1)
Publication Number | Publication Date |
---|---|
CN208777801U true CN208777801U (en) | 2019-04-23 |
Family
ID=66153147
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN201821032115.9U Expired - Fee Related CN208777801U (en) | 2018-07-02 | 2018-07-02 | The cydariform energy dissipation brace of built-in energy consumption square steel tube |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN208777801U (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN112144690A (en) * | 2020-10-30 | 2020-12-29 | 中国地震局工程力学研究所 | Bending shear mixed type square steel pipe damper and manufacturing method |
-
2018
- 2018-07-02 CN CN201821032115.9U patent/CN208777801U/en not_active Expired - Fee Related
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN112144690A (en) * | 2020-10-30 | 2020-12-29 | 中国地震局工程力学研究所 | Bending shear mixed type square steel pipe damper and manufacturing method |
CN112144690B (en) * | 2020-10-30 | 2023-03-17 | 中国地震局工程力学研究所 | Bending shear mixed type square steel pipe damper and manufacturing method |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN108915331A (en) | A kind of multidirectional damper | |
CN108951916A (en) | Double-layer combined energy-dissipation structure | |
CN109518832A (en) | A kind of tension and compression support construction limiting sublevel | |
CN208777801U (en) | The cydariform energy dissipation brace of built-in energy consumption square steel tube | |
CN102912882B (en) | Chinese character Tian-shaped anti-buckling energy dissipation support | |
CN104278770B (en) | Flexing buckling-restrained energy-dissipation | |
CN108978921A (en) | Lateral drawing and pressing type energy dissipation brace | |
CN108678507A (en) | The Wasted-energy steel plate support construction of built-in circle mild-steel energy-consumption inner cylinder | |
CN208309873U (en) | A kind of energy dissipation brace structure of friction energy-dissipating formula | |
CN208870472U (en) | The frictional square steel energy dissipation brace of tension and compression | |
CN104294957B (en) | A kind of multistage multiple anti-buckling huge support of big power consumption and processing method thereof | |
CN108678510A (en) | The frictional square steel energy dissipation brace of tension and compression | |
CN208441590U (en) | The energy dissipation brace that the steel pipe that consumes energy wraps up | |
CN208685847U (en) | Combined steel plate energy dissipation brace | |
CN108678505A (en) | The cydariform energy dissipation brace of built-in energy consumption square steel tube | |
CN208733849U (en) | Lateral drawing and pressing type energy dissipation brace | |
CN207959577U (en) | The energy consumption strenthening member of separate type right angle | |
CN208748873U (en) | A kind of dual-caliber energy consumption square steel tube supporting member | |
CN208749202U (en) | A kind of multidirectional damper | |
CN208518422U (en) | The Wasted-energy steel plate support construction of built-in circle mild-steel energy-consumption inner cylinder | |
CN109518829A (en) | Superposed type resets energy consumption connection | |
CN208777485U (en) | A kind of segmented lead dot locking energy dissipation brace | |
CN108867927A (en) | The compound tension and compression energy dissipation brace of lead dot locking | |
CN208748888U (en) | The compound tension and compression energy dissipation brace of lead dot locking | |
CN208748871U (en) | A kind of limit energy dissipation brace structure |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
GR01 | Patent grant | ||
GR01 | Patent grant | ||
CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20190423 Termination date: 20210702 |
|
CF01 | Termination of patent right due to non-payment of annual fee |